{"paper_id":"23e54c63-a197-4df7-bb1a-7b4f05a7a1bd","body_text":"Vascular endothelial growth factors (VEGF) and their receptors (VEGFR) are critical factors of angiogenesis, a process critical for physiological and pathological conditions. 1 , 2  Specifically, the signaling axis of VEGF-VEGFR controls endothelial cell (EC) proliferation, migration, and survival, thereby facilitating the organized development of new blood vessels. Vascular development is indispensable for embryonic growth, wound healing, and the female reproductive cycle. 1  However, when VEGF signaling is dysregulated, various disorders such as cancer, diabetic retinopathy (DR, diabetes-induced retinal vascular disorder), and age-related macular degeneration (AMD, retinal disease characterized by macular degeneration) develop. 3  Extensive research on VEGF-VEGFR signaling has advanced the development of therapeutic inhibitors that disrupt pathological angiogenesis. As a result, this therapeutic intervention has achieved significant milestones, especially in cancer therapy and ocular disease treatment. Despite this progress with anti-angiogenic drugs, therapeutic resistance and the complex regulation of angiogenesis remain major challenges, highlighting the critical need to target the VEGF-VEGFR pathway across various indications effectively.\nThe concept of angiogenesis has been acknowledged as a fundamental biological process since the 18th century (Fig.  1 ). British surgeon John Hunter first observed vascular growth in rabbit ears exposed to cold, with his 1794 publication laying the foundation for vascular research. 4 , 5  Carl Thiersch later linked angiogenesis to tumor biology by demonstrating that new vessels in carcinoma originate from preexisting capillaries. 6  Further expanding this understanding, the role of angiogenesis in cancer was emphasized by Rudolf Virchow and Ernst Goldmann, who proposed its dual function in tumor progression. 4 , 6  This connection was further strengthened by Algire and Chalkley’s studies, which culminated in Judah Folkman’s 1971 hypothesis that tumor growth is angiogenesis-dependent, thereby establishing angiogenesis as a therapeutic target. 7 Fig. 1 Timeline of key discoveries in angiogenesis research. The timeline begins with John Hunter’s observation of blood vessel growth and follows major advancements, including Folkman’s hypothesis, which links tumor growth to angiogenesis (1971). The significant milestones include the discovering the vascular permeability factor in 1983 and identifying vascular endothelial growth factor (VEGF), its receptors, and other VEGF family members between 1989 and 1997. It also highlights the approval of several anti-angiogenic drugs: pegaptanib for age-related macular degeneration (AMD) in 2004, bevacizumab for metastatic colorectal cancer in 2004, ranibizumab for AMD in 2006, aflibercept for AMD in 2011, ramucirumab for advanced gastric cancer in 2014, brolucizumab for AMD in 2019, the combination of atezolizumab and bevacizumab for hepatocellular carcinoma (HCC) in 2020, and faricimab for AMD in 2022. Created in BioRendender.com\nTimeline of key discoveries in angiogenesis research. The timeline begins with John Hunter’s observation of blood vessel growth and follows major advancements, including Folkman’s hypothesis, which links tumor growth to angiogenesis (1971). The significant milestones include the discovering the vascular permeability factor in 1983 and identifying vascular endothelial growth factor (VEGF), its receptors, and other VEGF family members between 1989 and 1997. It also highlights the approval of several anti-angiogenic drugs: pegaptanib for age-related macular degeneration (AMD) in 2004, bevacizumab for metastatic colorectal cancer in 2004, ranibizumab for AMD in 2006, aflibercept for AMD in 2011, ramucirumab for advanced gastric cancer in 2014, brolucizumab for AMD in 2019, the combination of atezolizumab and bevacizumab for hepatocellular carcinoma (HCC) in 2020, and faricimab for AMD in 2022. Created in BioRendender.com\nA major breakthrough occurred in 1983 when Harold Dvorak and colleagues identified vascular permeability factor (VPF), a protein that significantly increased vascular permeability. 8  Subsequent purification and sequencing confirmed that VPF was identical to VEGF, 8 , 9  with Napoleone Ferrara successfully isolating VEGF from bovine pituitary follicular cells in 1989. 10  This identification revealed VEGF as a potent endothelial mitogen with high specificity, further confirmed by studies on its role in vascular permeability and EC proliferation. 11 , 12  The discovery of VEGF catalyzed the identification of additional family members, including VEGF-B, VEGF-C, and VEGF-D, and their receptors VEGFR1, VEGFR2, and VEGFR3. 13 – 18  Moreover, alternative splicing of VEGF-A generated isoforms such as VEGF-A121, VEGF-A165, and VEGF-A189, which differ in receptor binding and bioavailability. 11 , 19\nThe identification of VEGF as a central regulator of angiogenesis established its importance in both physiological and pathological contexts. Targeting VEGF has since become a cornerstone of anti-angiogenic therapies, profoundly impacting oncology and ophthalmology. This review examines VEGF family members and their receptors in angiogenesis and lymphangiogenesis, therapeutic interventions, and emerging research directions to advance precision medicine.\n\nThe VEGF family, comprising VEGF-A, VEGF-B, VEGF-C, and VEGF-D, regulates vascular and lymphatic development through isoforms generated by alternative splicing 20  or proteolytic cleavage. 21  These proteins share a cystine-knot motif critical for receptor binding and dimerization, 22 , 23  interacting with VEGFR1, VEGFR2, VEGFR3, and neuropilin (NRP) as a co-receptor to modulate diverse functions. 24\nVEGF-A exists in multiple isoforms (Fig.  2a ), including VEGF-A111, 121, 145, 165, 183, 189, and 206, generated through alternative splicing of exons such as 6A, 6B, 7A, and 7B, which tailor their lengths and interactions with extracellular matrix (ECM) components to specific tissues and contexts. 24 – 26  All isoforms share a conserved N-terminal region responsible for binding to VEGFRs and initiating signaling. 24 Fig. 2 Schematic representation of alternative splicing variants and proteolytic processing of vascular endothelial growth factors (VEGFs).  a  VEGF-A isoforms generated by alternative splicing including VEGF-A111, VEGF-A121, VEGF-A145, VEGF-A165, VEGF-A183, VEGF-A189, VEGF-A206, and VEGF165b. Each isoform is represented by its exon composition, highlighting the variations in exons 6A, 6B, 7, and 8 across the isoforms contributing to differences in receptor-binding affinities and functional properties.  b  Alternative splicing generates two VEGF-B isoforms, VEGF-B167 and VEGF-B186. These isoforms differ in their use of either exon 6A or 6B, which determines their specific molecular characteristics.  c  VEGF-C and VEGF-D exist in unprocessed dimerized forms, and their proteolytic processing occurs through cleavage by the protein convertases, kallikrein 3 (KLK3), cathepsin D (CTSD), or thrombin, resulting in mature, active forms with modified functional properties. Created in BioRendender.com\nSchematic representation of alternative splicing variants and proteolytic processing of vascular endothelial growth factors (VEGFs).  a  VEGF-A isoforms generated by alternative splicing including VEGF-A111, VEGF-A121, VEGF-A145, VEGF-A165, VEGF-A183, VEGF-A189, VEGF-A206, and VEGF165b. Each isoform is represented by its exon composition, highlighting the variations in exons 6A, 6B, 7, and 8 across the isoforms contributing to differences in receptor-binding affinities and functional properties.  b  Alternative splicing generates two VEGF-B isoforms, VEGF-B167 and VEGF-B186. These isoforms differ in their use of either exon 6A or 6B, which determines their specific molecular characteristics.  c  VEGF-C and VEGF-D exist in unprocessed dimerized forms, and their proteolytic processing occurs through cleavage by the protein convertases, kallikrein 3 (KLK3), cathepsin D (CTSD), or thrombin, resulting in mature, active forms with modified functional properties. Created in BioRendender.com\nVEGF-A111, excluding exons 5–7, diffuses easily, resists proteolysis, and is induced by DNA damage, 27  while VEGF-A121, lacking exons 6A and 7, is soluble, forming stable homodimers resilient to oxidative stress. 19 , 25 , 28  In contrast, VEGF-A145, missing exon 7, strongly binds ECM but exhibits reduced binding with its receptor and NRP1 due to missing motifs. 29 , 30  VEGF-A165, the predominant isoform, features an N-terminal receptor-binding domain (RBD) and a C-terminal heparin-binding domain (HBD), enabling ECM retention and systemic distribution. 31 – 35  This isoform binds VEGFR2 with a dissociation constant (Kd) of 1–10 nM, ensuring rapid receptor engagement at physiological levels, 24 , 36  and forms a homodimer (Fig.  4a ), with each monomer stabilized by hydrogen bonds and hydrophobic contacts, notably Glu64 and Asp63, interacting with the VEGFR2 D2 domain. 37 – 39  The HBD of VEGF-A165 anchors it to the ECM, prolonging receptor activation and enhancing vascular stability. 40\nHowever, VEGF-A121, lacking this HBD (Fig.  2a ), disperses widely but is unable to bind co-receptor, NRP1, resulting in lower VEGFR2 activation and approximately 10-100 times reduced mitogenic activity, often leading to leakier vessels due to limited tissue retention. 30 , 41 , 42  Similarly, VEGF-A145 retains partial ECM-binding capacity but has reduced heparin affinity compared with VEGF-A189, forming intermediate gradients that support vascularization when VEGF-A165 is insufficient. 29  VEGF-A183, with a truncated exon 6A, exhibits intermediate heparin-binding affinity, remaining ECM-associated, 43 , 44  whereas VEGF-A189 and VEGF-A206, both retaining exons 6 and 7 (Fig.  2a ), tightly bind heparan sulfate proteoglycans (HSPGs), restricting diffusion and forming steep VEGF gradients that promote dense, structured vascular networks. 25 , 45  Furthermore, VEGF-A189’s interaction with NRP1 enhances VEGFR2 signaling, although proteolytic cleavage modulates its bioavailability. 46  Lastly, VEGF-A206, the longest isoform, contains an extended HBD, strongly binding the ECM to localize angiogenic activity, particularly in fetal and pathological tissues. 20 , 25 , 47  Thus, the diverse isoforms of VEGF-A, through their unique structural properties and receptor interactions, finely tune angiogenesis across physiological and pathological contexts.\nVEGF-B exists in two isoforms, VEGF-B167 and VEGF-B186 (Fig.  2b ), arising from alternative splicing and distinguished by their C-terminal domains. 14  Both share an identical N-terminal domain containing a VEGF homology domain (VHD) and eight cysteine residues crucial for forming intra- and intermolecular disulfide bonds, predominantly resulting in homodimers with a molecular weight of 44–54 kDa, widely expressed in normal and tumor tissues. 14 , 48  Specifically, VEGF-B167, featuring a heparin-binding C-terminal domain (CTD), attaches to cell surface heparan sulfate proteoglycans (HSPGs) and constitutes >80% of VEGF-B levels in most tissues. 49  In contrast, VEGF-B186, with a hydrophobic O-glycosylated CTD, is freely soluble, upregulated in several primary tumors and tumor cell lines, and prone to proteolytic cleavage that generates biologically active fragments. 50  Additionally, both isoforms can form disulfide-linked heterodimers with VEGF-A, which remain cell-associated, unlike the secreted VEGF-A homodimers, suggesting diverse functions across physiological contexts. 14 , 51  Functionally, VEGF-B binds exclusively to VEGFR1 (Fig.  4a ), engaging the same region as VEGF-A but with slightly lower affinity (Kd 1–3 nM for VEGF-B167), and plays a specialized role in tissue protection and metabolic regulation rather than promoting angiogenesis. 52 – 57  However, despite this high-affinity binding, VEGF-B167 induces minimal signaling due to low kinase activity of VEGFR1, constrained by an inhibitory sequence in the juxtamembrane region, thus limiting its ability to transduce angiogenic signals. 52 , 58 , 59  Consequently, unique structural and binding properties of VEGF-B underscore its distinct contributions to tissue homeostasis and disease.\nVEGF-C stands out in the VEGF family for its structural complexity and intricate post-translational modifications. 15  It is a 419-amino acid protein with 30% sequence identity to VEGF-A and 27% to VEGF-B. 15 , 60  VEGF-C is initially synthesized as an inactive precursor sequestered in the ECM (Fig.  2c ) and undergoes sequential proteolytic cleavages to achieve full activation. 61\nProprotein convertases (PC) including furin generate a partially active intermediate, while the final cleavage by ADAMTS3 produces the mature form (~21 kDa) with high affinity for VEGFR2 and VEGFR3, driving lymphangiogenesis and vascular remodeling. 62 , 63  Additionally, proteases, such as plasmin, thrombin, KLK3, and cathepsin D, modify VEGF-C, altering its receptor-binding affinities and activity profiles. 61 , 64  These modifications, particularly in the tumor microenvironment (TME), fine-tune the role of VEGF-C in cancer progression, metastasis, and tumor-associated lymphangiogenesis.\nVEGF-D was identified from a human EST sequence, resulting in a full-length cDNA encoding a 354-amino acid protein with 23% identity to VEGF-C. 16  It is structurally similar to VEGF-C but features unique N- and C-terminal extensions. VEGF-D undergoes proteolytic processing (Fig.  2c ) to generate isoforms with distinct receptor affinities. 65 , 66  The unprocessed precursor (~50 kDa) is inactive until N- and C-terminal propeptides are cleaved. Intermediate forms (31–35 kDa) bind VEGFR3 with high affinity but exhibit lower activity than the fully processed form (~21 kDa), which binds VEGFR2 and VEGFR3, promoting angiogenesis and lymphangiogenesis. This maturation, regulated by extracellular proteases such as PC and plasmin, modulates receptor specificity and bioactivity. 65 , 67  VEGF-D differs from VEGF-C in expression patterns, predominantly found in the lungs, heart, skeletal muscle, and intestines. 67 , 68  VEGF-C and VEGF-D regulate lymphangiogenesis via VEGFR3 and contribute to angiogenesis through VEGFR2 under specific conditions. 69 , 70  This dual functionality highlights its role in coordinating vascular and lymphatic growth, particularly in cancer metastasis, underscoring its significance in tissue homeostasis and disease progression.\nVEGF-C and VEGF-D primarily drive lymphangiogenesis by binding to VEGFR3 (Fig.  4a ), a receptor predominantly expressed in lymphatic endothelial cells (LECs). 71  Both ligands require proteolytic processing for full activity. Initially, full-length VEGF-C exhibits low affinity for VEGFR3, but cleavage by enzymes such as ADAMTS3 (Fig.  2c ) enhances its binding strength, potently activating VEGFR3 to promote LEC proliferation and migration. 15 , 72  Similarly, VEGF-D binds both VEGFR2 and VEGFR3 (Fig.  4a ), with its affinity increasing post-processing, enabling the mature form to strongly support angiogenesis and lymphangiogenesis, while the unprocessed form binds VEGFR3 less effectively. 66 , 67 , 73  Additionally, VEGF-D can activate VEGFR2/VEGFR3 heterodimers, contributing to lymphatic dilation and vascular remodeling, particularly in cancer. 74\nVEGF-A isoforms are primarily pro-angiogenic; however, specific inhibitory variants, known as VEGFxxxb isoforms, 75  such as VEGF165b, arise through alternative splicing at the distal splice site of exon 8 (Fig.  2a ). These isoforms feature a C-terminal sequence (SLTRKD) that replace the pro-angiogenic CDKPRR sequence in VEGF-Axxx isoforms, 76  allowing them to bind VEGFR2 competitively without initiating complete receptor phosphorylation and signaling, which reduce angiogenic responses. 77\nThe existence and role of VEGFxxxb isoforms in angiogenic balance are debated. Some studies suggest they may be methodological artifacts, as large-scale RNA-seq often fails to detect them in human tissues, and antibody specificity is questioned. 78 – 81  This inconsistency fuels skepticism, implying VEGFxxxb isoforms might only appear under specific experimental conditions. However, VEGF-A165b, known for its anti-angiogenic properties, is elevated in peripheral artery disease (PAD) and linked to reduced vascularization despite higher total VEGF-A levels. 82  In a PAD mouse model, metabolic dysfunction and Wnt5a signaling increased VEGF-A165b, impairing angiogenesis, while its neutralization restored revascularization. These results indicate VEGF-A165b may suppress pathological angiogenesis in PAD, suggesting potential as a therapeutic target. While the physiological relevance of VEGFxxxb remains controversial, the evidence of VEGF-A165b’s inhibitory effect in PAD highlights their potential clinical significance.\nPlGF is a VEGF family glycoprotein sharing ~42% sequence homology with VEGF-A. 83 , 84  It features a conserved VHD essential for dimerization and receptor binding. Alternative splicing of PlGF generates four isoforms: PlGF-1, PlGF-2, PlGF-3, and PlGF-4, distinguished by C-terminal variations that affect their receptor affinities, spatial distribution, and biological properties. 85 – 87\nPlGF-1 (131 amino acids) is the most studied isoform, lacking HBD and circulating as a soluble protein. It forms homo- and heterodimers with VEGF family members to modulate VEGF-A activity. 83 , 88  PlGF-2 (152 amino acids) contains an additional 21-amino acid HBD, enabling interactions with the ECM and cell surface, confining its distribution and enhancing localized paracrine signaling. 85 , 89  PlGF-3 (203 amino acids) includes a unique 72-amino acid C-terminal region, with tissue-specific roles yet to be fully defined, suggesting potential regulatory functions in specific pathological contexts. 86  In addition, PlGF-4 (224 amino acids) is the longest isoform, similar to PlGF-2 in HBD-mediated ECM and cell interactions, although expressed at lower levels. 90  Notably, the VEGF-A/PlGF heterodimer primarily binds to VEGFR1, which leads to enhanced receptor activation compared with the individual factor alone, 88  thereby promoting EC migration, permeability, particularly in pathological conditions, such as cancer and ischemia, where it facilitates neovascularization and vascular inflammation. 53\nPlGF binds exclusively to VEGFR1 (Fig.  4a ), playing a significant role in pathological angiogenesis. 91  Through high-affinity binding, it promotes VEGFR1 dimerization and activation, 88  triggering unique angiogenic and inflammatory signaling pathways despite the lower kinase activity of VEGFR1. 53  PlGF modulates VEGF-A signaling by competing for VEGFR1 binding, reducing VEGF-A sequestration. 92  This competition shifts receptor dynamics, freeing more VEGF-A to engage VEGFR2, thereby amplifying VEGF-A-driven angiogenesis. Furthermore, PlGF enhances vascular remodeling and inflammation through VEGFR1 signaling, extending its effect beyond direct receptor activation.\nVEGFR1, also known as Fms-like tyrosine kinase-1 (Flt1), 93  regulates various aspects of angiogenesis through its complex multi-domain structure, serving as a decoy receptor. 94  Its extracellular domain (ECD) comprises seven immunoglobulin-like (Ig) domains, with D2 and D3 forming the primary ligand-binding interface that confers high affinity for VEGF-A (Fig.  3a ). This interaction sequesters VEGF-A, reducing its availability for VEGFR2, and thus modulates angiogenic signaling. 54 , 95  The remaining Ig-like domains (D4-D7) contribute to structural integrity and facilitate receptor dimerization, supporting interactions with other receptors and stabilizing the receptor complex. 96 – 99 Fig. 3 Structural domains of vascular endothelial growth factor receptors (VEGFRs) and isoforms of soluble VEGFR1.  a  Domain organization of VEGFR1, VEGFR2, and VEGFR3. Each receptor has key structural features, including Ig-like extracellular domains (D1-D7), transmembrane domain (TMD), juxtamembrane domain (JMD), kinase domain (KD), and C-terminal domain (CTD).  b  Alternative splicing generates five distinct splice variants of VEGFR1: the full-length VEGFR1, VEGFR1 with intron 13 retention (sVEGFR1-i13), VEGFR1 with intron 14 retention (sVEGFR1-i14), and the soluble isoforms sVEGFR1-e15a and sVEGFR1-e15b with alternative terminal exons. The schematic highlights the differences in domain configurations between full-length receptors and their soluble forms, illustrating the structural diversity resulting from alternative splicing. Created in BioRendender.com\nStructural domains of vascular endothelial growth factor receptors (VEGFRs) and isoforms of soluble VEGFR1.  a  Domain organization of VEGFR1, VEGFR2, and VEGFR3. Each receptor has key structural features, including Ig-like extracellular domains (D1-D7), transmembrane domain (TMD), juxtamembrane domain (JMD), kinase domain (KD), and C-terminal domain (CTD).  b  Alternative splicing generates five distinct splice variants of VEGFR1: the full-length VEGFR1, VEGFR1 with intron 13 retention (sVEGFR1-i13), VEGFR1 with intron 14 retention (sVEGFR1-i14), and the soluble isoforms sVEGFR1-e15a and sVEGFR1-e15b with alternative terminal exons. The schematic highlights the differences in domain configurations between full-length receptors and their soluble forms, illustrating the structural diversity resulting from alternative splicing. Created in BioRendender.com\nThe transmembrane domain (TMD) is crucial for anchoring the receptor to the cell membrane and facilitating its function in VEGF signaling. 100  Notably, VEGFR1 is expressed in two isoforms: a membrane-bound full-length form and a soluble variant lacking the TMD. 94  The TMD anchors VEGFR1 to the cell surface, enabling it to modulate the spatial distribution of VEGF and regulate downstream signaling. 101  The intracellular domain (ICD) of VEGFR1 (Fig.  3a ) comprises the juxtamembrane domain (JMD), split tyrosine kinase domain (KD), and C-terminal tail. VEGFR1 exhibits low kinase activity compared with VEGFR2, which is linked to unique structural features. The JMD includes a repressor sequence with three serine residues that inhibit downstream signaling, such as PI3K activation, even in the presence of VEGF. 59  Additionally, an “electrostatic latch” in the JMD maintains VEGFR1 in an auto-inhibitory conformation, preventing ligand-independent activation. 102  Moreover, VEGFR1 catalytic function is impaired by a critical asparagine in its activation loop, replacing a conserved aspartic acid, which disrupts transphosphorylation of essential tyrosine residues, further limiting its activity. These structural elements collectively define its unique role in signaling. 103 , 104  Collectively, the complex architecture and regulatory features of VEGFR1 enable it to fine-tune angiogenesis by modulating VEGF availability and selectively suppressing signaling.\nThe sVEGFR1 isoforms, sVEGFR1-i13, sVEGFR1-i14, sVEGFR1-e15a, and sVEGFR1-e15b (Fig.  3b ), arise from alternative splicing and retain VEGF-binding capacity without downstream signaling. 105  Produced by various cells, including endothelial and melanoma cells, sVEGFR1 often circulates bound to VEGF, playing a key role in regulating angiogenesis, particularly in pathological states such as pre-eclampsia. 106\nsVEGFR1-i13, the most common isoform, is generated by intron 13 retention 107  and acts as a VEGF scavenger, inhibiting VEGF-A-induced angiogenesis by forming non-signaling complexes with VEGFR2. 108  sVEGFR1-i14, generated via intron 14 retention (Fig.  3b ), is primarily expressed in the brain and testes, 109  where it regulates local VEGF activity and vascular stability. sVEGFR1-e15a, formed through exon 15a inclusion, is abundant in the placenta, playing a crucial role in vascular development. 105 , 109  Elevated levels are linked to pre-eclampsia, disrupting angiogenesis. Moreover, sVEGFR1-e15b, produced by exon 15b inclusion (Fig.  3b ), features matrix-binding properties and is expressed in the placenta and vascular tissues, contributing to abnormal angiogenesis in cancers and ocular diseases. 105  Functioning as decoy receptors, these isoforms regulate VEGF ligand distribution, limiting VEGFR2 activation and attenuating pro-angiogenic signaling. Collectively, these variants provide a dynamic regulatory mechanism that ensures tissue-specific vascular stability and growth control.\nVEGFR2, also known as kinase insert domain receptor (KDR) in humans and fetal liver kinase-1 (Flk1) in mice, is a receptor tyrosine kinase (RTK). 110 – 112  The ECD comprises seven Ig-like domains (D1-D7), each with D2 and D3 primarily responsible for high-affinity VEGF binding (Fig.  3a ). D2 forms hydrophobic interactions as the main binding site, while D3 stabilizes the receptor-ligand complex through hydrophilic interactions. 113 , 114  Ligand binding induces conformational changes in D2 and D3, essential for receptor dimerization and activation. 113 , 115  D4 and D5 support receptor dimerization and allosteric regulation, ensuring proper alignment of the intracellular kinase domains, 116  while D7 facilitates receptor dimerization via charged interactions in its E-F loop. 116 , 117  Ligand binding also reorients TMD helices, a prerequisite for the kinase domain activation. 118  Although VEGFR2 can dimerize, ligand binding ensures correct helix alignment downstream signaling. 119\nThe JMD functions as a regulatory gate, keeping the receptor in an inactive state until ligand-induced conformational changes activate the KD. 100  The KD phosphorylates specific tyrosine residues, such as Tyr1059 (Y1059) in the activation loop, transitioning the kinase to an active state. 120  The kinase insert domain (KID) serves as a docking platform for downstream signaling molecules, with phosphorylation at sites such as Y951 enabling interactions with effectors such as TSAd, which mediate vascular permeability and remodeling. 121  The CTD stabilizes the receptor in an inactive state but undergoes structural rearrangements upon ligand binding to facilitate full activation. Phosphorylation of key residues within the CTD, such as Y1175, recruits signaling proteins including PLCγ1, driving EC proliferation and migration. 122  Moreover, the KID and CTD are integral to intrinsic receptor dimerization, which is essential for full kinase activation. 123  Deletion of these domains diminishes dimerization efficiency and compromises signaling. Together, these structural features ensure precise regulation of VEGFR2 activity, supporting its pivotal role in vascular development and pathological angiogenesis.\nVEGFR3, also known as Fms-related tyrosine kinase-4, is an RTK essential for vascular development but is primarily involved in lymphangiogenesis. A unique feature of VEGFR3 is the proteolytic cleavage of its ECD (Fig.  3a ), resulting in a mature form linked by disulfide bonds. 124  D1-D3 in the ECD are critical for VEGF-C binding, particularly through interactions with D2, while D1 stabilizes the ligand-receptor complex. D4-D7 mediate receptor dimerization and activation. 67 , 124  Proteolytic cleavage at D5 divides the ECD into two subunits, which remain connected by disulfide bonds. This cleavage is essential for effective ligand binding, signaling, and receptor activation, facilitated by homotypic interactions between D5 and D7. 124  The TMD and ICD are structurally similar to those of VEGFR1 and VEGFR2, featuring a single-pass transmembrane region and split tyrosine KD, enabling ligand-induced dimerization and autophosphorylation. 125  VEGFR3 primarily mediates lymphangiogenesis through VEGF-C and VEGF-D signaling in lymphatic endothelial cells (LECs). It also modulates VEGFR2 activity via heterodimerization, indirectly supporting blood vessel development while maintaining its distinct role in lymphatic growth.\nVEGFR homodimers are formed when two identical receptors pair in response to ligand binding. VEGFR2 homodimers (Fig.  4 ) are mainly activated by VEGF-A, which triggers a series of key processes in ECs. 126 , 127  Upon activation, these receptors undergo autophosphorylation, initiating intracellular signaling cascades, which drive angiogenesis. 126  In contrast, VEGFR1 homodimers, which are capable of binding to VEGF-A and other ligands, play a regulatory role. They regulate VEGFR2 signaling and inhibit excessive angiogenic responses. 127  VEGFR2 can exist in a monomeric or dimeric state without ligand binding. 128 , 129  VEGFR2 forms dimers without ligands at physiological levels, showing low levels of basal phosphorylation. 129  This pre-formed, partially active state enables rapid angiogenic signaling, offering a refined model of RTK activation beyond traditional ligand-induced dimerization. Fig. 4 Vascular endothelial growth factor (VEGF) family members and their receptors. Binding of VEGF-A, -B, -C, -D, and PlGF with their respective receptors, VEGFR1, VEGFR2, and VEGFR3, highlighting the primary receptor specificities. VEGF-A binds VEGFR1 and VEGFR2, VEGF-B and PlGF selectively interact with VEGFR1. VEGFR2 is the primary mediator of VEGF-A-driven angiogenesis, also binding VEGF-C. VEGFR3 predominantly binds VEGF-C and VEGF-D, regulating lymphangiogenesis. This binding schematic illustrates the selective affinities of VEGF family members for their receptors and their distinct roles in vascular and lymphatic regulation. Additionally, VEGF-B is depicted as a metabolic regulator that acts through VEGFR1, while PlGF is shown to modulate inflammation and vascular homeostasis. Created in BioRendender.com\nVascular endothelial growth factor (VEGF) family members and their receptors. Binding of VEGF-A, -B, -C, -D, and PlGF with their respective receptors, VEGFR1, VEGFR2, and VEGFR3, highlighting the primary receptor specificities. VEGF-A binds VEGFR1 and VEGFR2, VEGF-B and PlGF selectively interact with VEGFR1. VEGFR2 is the primary mediator of VEGF-A-driven angiogenesis, also binding VEGF-C. VEGFR3 predominantly binds VEGF-C and VEGF-D, regulating lymphangiogenesis. This binding schematic illustrates the selective affinities of VEGF family members for their receptors and their distinct roles in vascular and lymphatic regulation. Additionally, VEGF-B is depicted as a metabolic regulator that acts through VEGFR1, while PlGF is shown to modulate inflammation and vascular homeostasis. Created in BioRendender.com\nHeterodimerization fine-tunes VEGF signaling by modulating receptor activity in response to ligand concentrations and receptor abundances. VEGFR1-VEGFR2 heterodimers (Fig.  4 ) regulate VEGF-A activity by inhibiting VEGFR2, primarily through reduced PI3K-mediated phosphorylation, balancing EC migration and angiogenic processes. 130  VEGFR2-VEGFR3 heterodimers, induced by VEGF-C and VEGF-D (Fig.  4 ), are critical for blood and lymphatic vessel formation, particularly in angiogenic tip cells where they control sprouting and branching. 131 , 132  Modeling studies predict that VEGFR1-VEGFR2 heterodimers constitute 10–50% of active signaling complexes, depending on receptor expression levels. High VEGFR2 abundance suppresses VEGFR1 homodimer formation, favoring VEGFR2 signaling. 128  Notably, VEGFR1-VEGFR2 heterodimers are more prevalent in neuronal cells, whereas VEGFR2 homodimers dominate in ECs. 133  This differential dimerization may explain VEGF’s distinct roles in nerve regeneration versus blood vessel growth, underscoring the various regulatory functions of receptor interactions across physiological contexts.\nHeteromeric complexes between VEGFRs and non-VEGFRs generate diverse signaling outcomes, enhancing functional flexibility. VEGFR1 forms heterodimers with NRP1 (Fig.  5a ), increasing VEGF binding and modulating signaling. 134  Additionally, VEGFR1 also forms a complex with NRP2 (Fig.  5a ), enabling NRP2 to bind VEGF-A121. 135  Moreover, VEGFR1 interacts with integrin α5β1 (Fig.  5a ) to mediate endothelial adhesion to the ECM 136  and binds FGFR1, suppressing FGF2-induced angiogenesis. 137 Fig. 5 Interactions of vascular endothelial growth factor receptors (VEGFR) with co-receptors and structural features of Neuropilin.  a  Interaction of VEGFR1 with co-receptors NRP1 and NRP2, α5β1 integrin, and FGFR1. The VEGFR1-NRP2 interaction facilitates VEGF-A121 binding, whereas VEGFR1 engagement with α5β1 promotes EC adhesion to the extracellular matrix. Additionally, the interaction of VEGFR1 with FGFR1 blocks FGF2-induced angiogenesis, highlighting the role of the VEGFR1 complex in modulating angiogenic signaling pathways and EC behavior.  b  Association of VEGFR2 with various co-receptors and adhesion molecules, including NRPs (NRP1 and NRP2), PDGFRβ, EGFR, CD44, EphA4, VE-Cadherin, and c-Met. These interactions contribute to the specificity and complexity of VEGF signaling, enabling crosstalk between VEGF receptors and other signaling pathways. Such an association with co-receptors and adhesion molecules enhances cellular responses, including EC migration, adhesion, and survival, supporting key physiological processes such as angiogenesis, vascular maturation, and cellular adhesion dynamics within the VEGF pathway.  c  Interaction between VEGFR3 and the co-receptor NRP2, which plays a critical role in promoting lymphangiogenesis and supporting EC survival.  d  NRP is shown with additional structural motifs, including the CUB, FV/VIII, MAM, and SEA domains. These domains contribute to receptor interactions and enhance signaling specificity within the VEGF pathway, potentially influencing binding affinities and receptor-ligand selectivity. NRP neuropilin, FGFR fibroblast growth factor receptor, PDGFR platelet-derived growth factor receptor, EGFR epidermal growth factor receptor. Created in BioRendender.com\nInteractions of vascular endothelial growth factor receptors (VEGFR) with co-receptors and structural features of Neuropilin.  a  Interaction of VEGFR1 with co-receptors NRP1 and NRP2, α5β1 integrin, and FGFR1. The VEGFR1-NRP2 interaction facilitates VEGF-A121 binding, whereas VEGFR1 engagement with α5β1 promotes EC adhesion to the extracellular matrix. Additionally, the interaction of VEGFR1 with FGFR1 blocks FGF2-induced angiogenesis, highlighting the role of the VEGFR1 complex in modulating angiogenic signaling pathways and EC behavior.  b  Association of VEGFR2 with various co-receptors and adhesion molecules, including NRPs (NRP1 and NRP2), PDGFRβ, EGFR, CD44, EphA4, VE-Cadherin, and c-Met. These interactions contribute to the specificity and complexity of VEGF signaling, enabling crosstalk between VEGF receptors and other signaling pathways. Such an association with co-receptors and adhesion molecules enhances cellular responses, including EC migration, adhesion, and survival, supporting key physiological processes such as angiogenesis, vascular maturation, and cellular adhesion dynamics within the VEGF pathway.  c  Interaction between VEGFR3 and the co-receptor NRP2, which plays a critical role in promoting lymphangiogenesis and supporting EC survival.  d  NRP is shown with additional structural motifs, including the CUB, FV/VIII, MAM, and SEA domains. These domains contribute to receptor interactions and enhance signaling specificity within the VEGF pathway, potentially influencing binding affinities and receptor-ligand selectivity. NRP neuropilin, FGFR fibroblast growth factor receptor, PDGFR platelet-derived growth factor receptor, EGFR epidermal growth factor receptor. Created in BioRendender.com\nVEGFR2 similarly forms complexes with non-VEGFRs, notably NRP1 and NRP2, 138  which act as co-receptors (Fig.  5b ). VEGFR2-NRP1 heterodimers enhance VEGF binding and signaling potential. VEGF facilitates these interactions by bridging VEGFR2 and NRP1, forming complexes in  cis  (within the same cell) or  trans  (between cells), with the  cis  configuration being kinetically favored. 139 , 140  The VEGF-NRP1 interaction relies on the C-terminal tail of VEGF binding to the b1 domain of NRP1, offering structural flexibility that allows these complexes to adapt to diverse cellular contexts.\nαvβ3 integrin binds vitronectin to amplify VEGFR2 phosphorylation and angiogenic signaling. Similarly, α4β1 integrin forms a complex with VEGFR2 in chronic lymphocytic leukemia cells (Fig.  5b ), enhancing VEGF signaling and inducing apoptosis when disrupted, 141  underscoring a therapeutic target. VEGFR2-platelet-derived growth factor receptor β (PDGFRβ) heterodimers (Fig.  5b ) link angiogenesis to vessel maturation via pericyte recruitment, stabilizing tumor vasculature. 142  VEGFR2-epidermal growth factor receptor (EGFR) heterodimers, formed in the presence of both EGF and VEGF, offer a ligand-dependent mechanism for diversifying cancer signaling. 143  Moreover, the CD44v6 isoform acts as a co-receptor for VEGFR2 in ECs, 144  enhancing ERK signaling (Fig.  5b ). EphA4, a receptor tyrosine kinase involved in neuronal development, forms a kinase-dependent complex with VEGFR2 (Fig.  5b ), promoting neuronal differentiation in neural stem and progenitor cells when activated by ephrin A1 and VEGF-A165. 145\nVEGFR2 forms a complex with VE-cadherin (VE-cad) at cell-cell junctions (Fig.  5b ), limiting VEGFR2 phosphorylation by recruiting phosphatases. 146  This interaction reduces VEGF-induced proliferation while promoting EC survival. Additionally, VEGFR2 interacts with c-Met (hepatocyte growth factor receptor) in a heterocomplex (Fig.  5b ), where VEGF-A recruits protein tyrosine phosphatase 1B (PTP1B) to dephosphorylate c-Met, inhibiting its signaling and reducing tumor cell migration and invasiveness. 147  VEGFR3 also forms a complex with NRP2 (Fig.  5c ), enhancing lymphangiogenesis and supporting EC survival. 148  VEGF-C stimulation strengthens this interaction, leading to increased VEGFR3 phosphorylation and activation of downstream signaling. This association with non-VEGFRs highlights the complex regulation of angiogenesis and lymphangiogenesis, offering new avenues for therapeutic intervention for abnormal blood and lymphatic vessel formation.\nNRP1 and NRP2 are non-tyrosine kinase co-receptors that enhance VEGF signaling by binding to the VEGF family in conjunction with VEGFRs. 149  Although they lack catalytic activity, their ECD enhance VEGF-VEGFR signaling, playing critical roles in angiogenesis and lymphangiogenesis.\nBoth NRP1 and NRP2 feature a structured ECD comprising two complement-binding (CUB) domains (a1/a2) and two coagulation factor homology domains (b1/b2), which enable their binding ligands such as VEGFs and semaphorins (Fig.  5d ). The a1/a2 domains are essential for binding semaphorins, such as sema3A, involved in axonal guidance, while the b1 domain allows high-affinity binding to VEGF-A165 in NRP1 and to VEGF-C in NRP2, with the b2 domain enhancing these interactions. 140  Additionally, both NRPs contain a MAM domain (c) that supports homodimerization and receptor interactions, strengthening their signaling roles. 150  Although both have short ICDs without catalytic activity, they feature PDZ-binding motifs (SEA) that allow interactions with intracellular proteins, such as synectin, to facilitate downstream signaling. 151  NRP2 uniquely includes soluble splice variants (sNRP2) that act as decoy receptors by sequestering VEGF-C and VEGF-D, thus modulating their bioavailability and lymphangiogenic functions. 152  Together, the structural motifs of NRP1 and NRP2 enable their versatile roles across physiological and pathological processes.\n\nSpecific tyrosine phosphorylation sites on VEGFR1 are crucial for recruiting adaptor molecules and mediating key signaling pathways to regulate cell migration, proliferation and survival. In particular, Y794 is located in the JMD region (Fig.  6a ) and is an important site for PLCγ1 binding. 153  Additionally, activation of endothelial nitric oxide synthase (eNOS) depends on Y794, resulting in nitric oxide (NO) release, which is essential for forming capillary-like networks in vitro. 154  Y1169 was identified as a major phosphorylation site, 153 , 155  critical for recruiting PLCγ1. Y1213, Y1242, and Y1333 were identified as key phosphorylation sites for VEGFR1’s biological functions (Fig.  6a ). Phosphorylation at Y1213 enables the binding of several SH2 domain-containing proteins, such as PLCγ1, SHP2, and GRB2. Specifically, PLCγ1 and SHP2 were found to be directly associated with Y1213 in a phosphotyrosine-dependent manner. 156  They also facilitate the binding of PI3K, which play an important role in cell proliferation and survival in response to VEGF. 157  Although Y1242 and Y1333 retain kinase activity and support PLCγ1 phosphorylation, they cannot mediate downstream mitogenic signals. 156 , 158  Y1333 also binds important signaling proteins such as NCK and CRK, while it allows for PLCγ1 recruitment, it is insufficient for full signal transduction and biological responses such as cell proliferation. 156 , 158  Interestingly, phosphorylation at Y1333 was inhibited by VEGF165b in ischemic muscle and blocking VEGF165b restored VEGFR1 phosphorylation and enhanced the VEGFR1-STAT3 pathway, promoting angiogenesis and perfusion recovery in PAD. 159 Fig. 6 Signal transduction of vascular endothelial growth factor receptors.  a  VEGFR1: Schematic representation of critical phosphorylation sites and their roles in signaling. Y794 in the juxtamembrane domain facilitates PLCγ1 binding and eNOS activation, promoting nitric oxide (NO) release and tubular structure formation. Y1169 recruits PLCγ1, while Y1213 enables binding of SH2 domain proteins such as PLCγ1, SHP2, and GRB2, supporting PI3K-mediated cell survival and proliferation. Y1242 and Y1333 support PLCγ1 phosphorylation but are insufficient for full mitogenic signaling. VEGF165b inhibits Y1333 phosphorylation, suppressing VEGFR1-STAT3 signaling, which can be restored to enhance angiogenesis in peripheral artery disease.  b  VEGFR2: Key phosphorylation sites and their roles in vascular functions. Y801 and Y1214 activate GAB1, promoting PI3K/AKT signaling, endothelial survival, migration, and NO production. Y951 (Y949 in mice) binds TSAd, regulating vascular permeability via the VEGFR2-TSAd-SRC complex. Y1054 and Y1059 are essential for full kinase activity, while Y1175 recruits adaptor proteins such as SHB and PLCγ1. Serine phosphorylation at S1183 and S1188 in mice (S1185 and S1190 in humans) promotes VEGFR2 degradation via β-TRCP1-mediated ubiquitination, regulating receptor stability.  c  VEGFR3: Schematic representation of essential phosphorylation sites and their roles in cell signaling. Phosphorylation at Y1063 recruits CRK I/II, activating the JNK pathway to support cell survival. Y1230 and Y1231 facilitate GRB2 recruitment, initiating ERK and AKT signaling pathways that promote cell proliferation and migration. Y1337 acts as a docking site for the GRB2-SHC complex, driving RAS-mediated signaling. PLCγ1 Phospholipase C gamma 1, GAB1 GRB2-associated binding protein 1, SHP2 Src homology-2 domain-containing protein tyrosine phosphatase-2, GRB2 growth factor receptor-bound protein 2, PI3K Phosphoinositide 3-kinase, TSad T cell-specific adapter protein, SHC SH2 domain protein C1, SHB SH2 domain-containing adapter protein B, SCK SHC-like protein, CRK I/II CT10 regulator of kinase I and II. Created in BioRendender.com\nSignal transduction of vascular endothelial growth factor receptors.  a  VEGFR1: Schematic representation of critical phosphorylation sites and their roles in signaling. Y794 in the juxtamembrane domain facilitates PLCγ1 binding and eNOS activation, promoting nitric oxide (NO) release and tubular structure formation. Y1169 recruits PLCγ1, while Y1213 enables binding of SH2 domain proteins such as PLCγ1, SHP2, and GRB2, supporting PI3K-mediated cell survival and proliferation. Y1242 and Y1333 support PLCγ1 phosphorylation but are insufficient for full mitogenic signaling. VEGF165b inhibits Y1333 phosphorylation, suppressing VEGFR1-STAT3 signaling, which can be restored to enhance angiogenesis in peripheral artery disease.  b  VEGFR2: Key phosphorylation sites and their roles in vascular functions. Y801 and Y1214 activate GAB1, promoting PI3K/AKT signaling, endothelial survival, migration, and NO production. Y951 (Y949 in mice) binds TSAd, regulating vascular permeability via the VEGFR2-TSAd-SRC complex. Y1054 and Y1059 are essential for full kinase activity, while Y1175 recruits adaptor proteins such as SHB and PLCγ1. Serine phosphorylation at S1183 and S1188 in mice (S1185 and S1190 in humans) promotes VEGFR2 degradation via β-TRCP1-mediated ubiquitination, regulating receptor stability.  c  VEGFR3: Schematic representation of essential phosphorylation sites and their roles in cell signaling. Phosphorylation at Y1063 recruits CRK I/II, activating the JNK pathway to support cell survival. Y1230 and Y1231 facilitate GRB2 recruitment, initiating ERK and AKT signaling pathways that promote cell proliferation and migration. Y1337 acts as a docking site for the GRB2-SHC complex, driving RAS-mediated signaling. PLCγ1 Phospholipase C gamma 1, GAB1 GRB2-associated binding protein 1, SHP2 Src homology-2 domain-containing protein tyrosine phosphatase-2, GRB2 growth factor receptor-bound protein 2, PI3K Phosphoinositide 3-kinase, TSad T cell-specific adapter protein, SHC SH2 domain protein C1, SHB SH2 domain-containing adapter protein B, SCK SHC-like protein, CRK I/II CT10 regulator of kinase I and II. Created in BioRendender.com\nAlthough VEGF-B binds to VEGFR1 with high affinity, 160  it does not induce tyrosine phosphorylation. 55  However, in human retinal ECs, it leads to only a modest increase in VEGFR1 phosphorylation. 161  This contrasts with other VEGF family ligands such as VEGF-A, which robustly activate VEGFR1, triggering extensive phosphorylation at multiple tyrosine residues. Mass spectrometry analysis revealed that stimulation with human PlGF-2 resulted in Y1309 phosphorylation of VEGFR1 whereas Y1213 remained unphosphorylated, 162  highlighting a selective phosphorylation pattern in response to different ligands that could lead to the differential signaling potential of VEGF-B and PlGF on VEGFR1.\nsVEGFR1 is highly expressed in trophoblasts, particularly under hypoxic conditions, it reduces VEGF-mediated EC migration and angiogenesis. This upregulation, linked to conditions such as pre-eclampsia, correlates with impaired placental angiogenesis. 163  Additionally, VEGF-A stimulates its own negative regulator, sVEGFR1, through the VEGFR2-PKC-MEK pathway, establishing a feedback loop that limits VEGF-A activity and angiogenesis. 164\nHowever, in squamous cell lung carcinoma, sVEGFR1-i13 regulates a β1 integrin/VEGFR autocrine loop, promoting tumor proliferation and resistance to anti-angiogenic therapies. 165  Elevated sVEGFR1-i13 levels are associated with advanced disease stages and poor outcomes. Moreover, sVEGFR1 interacts with α5β1 integrins, modulating cytoskeletal dynamics, and activating RAC1 signaling, thereby driving EC migration and motility through the phosphorylation of proteins such as MARCKS and RADIXIN. Notably, sVEGFR1 is essential for podocyte function and glomerular barrier integrity, interacting with lipid microdomains to regulate cytoskeletal organization and actin dynamics. 166  Moreover, loss of sVEGFR1 disrupts the cytoskeleton, leading to proteinuria and glomerular dysfunction. These findings highlight the dual functions of sVEGFR1, acting as both an inhibitor and promoter of angiogenesis depending on the biological context and its molecular interactions.\nVEGFR2 dimerizes and autophosphorylates upon VEGF binding, activating pathways that regulate EC proliferation, migration, and vascular permeability. Activation of VEGFR2 is characterized by significant heterogeneity at the single-molecule level, with receptor mobility and interactions varying across the EC surface. 167  VEGF binding triggers diverse activation mechanisms, including ligand-induced dimerization and engagement with pre-formed dimers. Even without VEGF, VEGFR2 exists as dimers with low phosphorylation levels, with ligand binding enhancing kinase activity through conformational change. 129  Structural studies emphasize inter-domain contacts in stabilizing dimer formation, but pathogenic mutations such as C482R and R1051Q disrupt regulation, 168  causing ligand-independent activation and altered membrane dynamics, underscoring the complexity of VEGFR2 regulation and its implications for signaling and disease progression.\nKinase assays and phosphopeptide mapping analysis reveal VEGFR2 contains 19 tyrosine residues, with 11 potential phosphorylation sites in non-catalytic regions. 169 , 170  Key phosphorylation sites include Y951 in the KID and Y1054, Y1059, Y1175, and Y1214 in the C-terminal tail (Fig.  6b ), while other residues, such as Y801, Y822, Y938, and Y996 remain unphosphorylated. Low-level phosphorylation at Y1305, Y1309, and Y1319 suggest minor role or transient roles. Phosphorylation at Y801 and Y1214, activates GAB1, 170  promoting PI3K/AKT signaling for EC survival, migration, and NO production. Y951 (Y949 in mice) phosphorylation recruits TSAd, essential for vascular permeability by destabilizing VE-cad via the VEGFR2-TSAd-SRC complex. 169  Mice with the Y949 mutation ( Flk1 Y949F/Y949F ) show reduced VEGFA-induced vascular leakage and metastasis, offering therapeutic potential for conditions such as oxygen-induced retinopathy. 171\nY1054 and Y1059 in the kinase activation loop are critical for full VEGFR2 activity, with mutations at these sites impairing downstream signaling. 172  Y1175 recruits adaptor proteins such as SHB (SRC homology 2 domain-containing adaptor protein B), SCK (Shc-like protein), PLCγ1, and Y1173F mutations ( Flk1 Y1173F/+ ; Y1175 in humans) in mice reduce vascular leakage and improve chemotherapy responses while preserving normal vessel development. 153 , 173 – 175  Y1214 phosphorylation activates CDC42, leading to SAPK2/p38 activation, stress fiber formation, and cell migration via NCK and FYN recruitment. 176 , 177  Y1212F mutations in mice ( Flk1 Y1212F/Y1212F ;Y1214 in humans) show strain-specific effects, with C57Bl/6 mutants exhibiting partial embryonic lethality and reduced EC proliferation whereas FVB mutants display delayed retinal vascular development and vessel instability, suggesting the essential role of Y1212 in vascular integrity. 178\nSerine phosphorylation at S1183 and S1188 (S1185 and S1190 in humans) in the proline, glutamic acid, serine and threonine (PEST) domain (K1171-K1209) of mouse VEGFR2 has been reported. 179 , 180  These phosphorylation recruit β-TRCP1 E3 ligase (Fig.  6b ), promoting VEGFR2 ubiquitination and proteasomal degradation. Mutation of these serine residues reduces ubiquitination, whereas phosphomimetic mutations enhance it, underscoring the role of serine phosphorylation in VEGFR2 stability. While tyrosine phosphorylation is well-studied and crucial for VEGFR2 signaling, serine phosphorylation remains less explored and threonine phosphorylation has yet to be identified.\nVEGFR3 phosphorylation occurs at several tyrosine residues upon VEGF-C binding with different patterns depending on whether VEGFR3 forms a homodimer or heterodimer with VEGFR2. In VEGFR3 homodimers, five key tyrosine residues are phosphorylated: Y1230, Y1231, Y1265, Y1337, and Y1363 (Fig.  6c ). When VEGFR3 forms a heterodimer with VEGFR2, only Y1230, Y1231, and Y1265 are phosphorylated. 131  Phosphorylation at Y1063 recruits adapter proteins, CRK I/II (Fig.  6c ), activating the JNK pathway, which is vital for promoting cell survival. Similarly, phosphorylation at Y1230 and Y1231 plays a key role in recruiting GRB2, triggering the ERK and AKT pathways that drive cell proliferation and migration. 181  Y1337 has also been identified as a critical phosphorylation site and serves as a docking site for the GRB2-SHC complex (Fig.  6c ), which participates in RAS signaling. 182  In the analysis of families with primary lymphedema, it was found that VEGFR3 proteins carrying mutations such as G857R, R1041P, and L1044P are tyrosine kinase-negative. 183  Additionally, these mutant VEGFR3 receptors exhibit a longer half-life compared with wild-type receptors. Consequently, they accumulate on the cell surface, potentially contributing to the dominant-negative effects observed in individuals harboring with these mutations.\nNRPs utilize a conserved binding site structured by the b1 coagulation factor loop, which specifically interacts with the C-terminal arginine motif present in certain VEGF ligands. 184 , 185  The interaction of VEGF-A165 with NRP1 is facilitated through specific residues in the b1 domain, where the ligand C-terminal arginine forms a salt bridge with Asp320 in NRP1. 186  Additional hydrogen bonds between other amino acids stabilize this interaction, allowing for precise isoform-specific binding, which is critical for the selective signaling roles of NRP1 and NRP2. 186  Structural studies have demonstrated that VEGF-A isoforms bind exclusively to NRP1, while VEGF-C and its related isoforms target NRP2. This distinction enables NRP1 to dominate blood vessel formation and NRP2 to dominate lymphatic vessel development.\nNRP1 lacks intrinsic signaling activity. Instead, it relies on its activity to enhance VEGFR2 signaling by recruiting VEGF-A165 and positioning VEGFR2 to amplify downstream pathways. 187  When VEGF-A165 binds to VEGFR2 with NRP1 assistance, it initiates a cascade of phosphorylation events in VEGFR2. Importantly, NRP1-mediated VEGF-A165/VEGFR2 signaling is also involved in vascular permeability, allowing for better tumor infiltration by blood vessels. 188 , 189  NRP2, structurally similar to NRP1, is more selective in lymphangiogenesis, particularly through its interactions with VEGF-C and VEGFR3. 138 , 190  NRP2 enhances VEGF-C binding to VEGFR3, facilitating the LEC responses required for lymphangiogenesis. Tumors often induce high expression levels of VEGF-C, which, through the VEGF-C/VEGFR3/NRP2 axis, promotes the proliferation, migration, and survival of LECs. 191 , 192  This mechanism is especially relevant in lymphatic metastasis, as lymphatic vessels serve as conduits for tumor cells to reach and colonize distant sites.\nAngiopoietin (Ang) ligands and TIE receptors dynamically interact with the VEGF-VEGFR system to regulate vascular homeostasis and adapt to physiological and pathological changes. Ang1, via TIE2 activation, stabilizes blood vessels, supporting EC survival, vascular barrier integrity, and quiescence. In contrast, Ang2 acts as a context-dependent modulator, often destabilizing vessels under conditions such as inflammation, ischemia, and tumor angiogenesis. 193 , 194  By increasing vessel permeability, Ang2 sensitizes ECs to VEGF, enhancing angiogenic sprouting. 195 , 196  Notably, VEGF signaling upregulates Ang2, creating a feedback loop where VEGF-induced Ang2 expression counteracts TIE2 stabilization by Ang1. 197\nAdditionally, vascular endothelial protein tyrosine phosphatase (VE-PTP) modulates TIE2 and VEGFR2, stabilizing endothelial junctions by dephosphorylating these receptors. 198 , 199  Its inhibition enhances TIE2 signaling and strengthens the endothelial barrier, emphasizing the interplay between the VEGF and Ang-TIE pathways in regulating vascular stability. In pathological conditions, such as cancer and retinal diseases, this balance is disrupted. Combined inhibition of VEGF and Ang2, as seen with faricimab, normalizes tumor vessels, reduces vascular permeability, and improves outcomes in diseases such as diabetic macular edema (DME, a complication of diabetes characterized by the accumulation of fluid in the macula due to damaged blood vessels) and AMD. 200 – 202  This Ang-TIE-VEGF interplay is critical for vascular stability, and its imbalance contributes to diseases such as cancer.\n\nThe VEGF family is tightly regulated at transcriptional and translational levels in response to factors such as hypoxia and metabolic changes. Disruption of this delicate regulation can lead to diseases such as cancer and lymphedema in which abnormal blood vessel growth or lymphatic function becomes a problem.\nThe expression of VEGF genes is highly controlled by a complex interplay between transcription factors, signaling pathways, and external stimuli. This network reflects the essential role of VEGFs in physiological processes, as well as in pathological conditions such as cancer.\nOne of the most significant regulatory mechanisms of VEGF-A transcription is hypoxia, which is mediated by hypoxia-inducible factor 1 (HIF-1). 203  Under normoxic conditions, HIF-1α is hydroxylated by prolyl hydroxylases, marking it for degradation via the von Hippel-Lindau tumor suppressor protein. 204  However, under low oxygen conditions, HIF-1α is stabilized, allowing it to dimerize with HIF-1β and bind to the hypoxia response element located in the VEGF-A promoter region. 205  This binding leads to enhanced transcription of VEGF-A and drives angiogenesis in oxygen-deprived tissues, such as growing tumor. Interestingly, HIF-1-mediated activation is not the only factor involved in VEGF-A regulation under hypoxic conditions. Additional regions upstream of the HIF-1 binding site also contribute to transcriptional activation. For example, the AP1 transcription factor binds to the region between -1168 and -1015 of the promoter, 206  which is essential for full transcriptional activation under hypoxic conditions, particularly in glioblastoma cells.\nSeveral studies reveal VEGF regulation mechanisms independent of the HIF pathway, highlighting alternative angiogenesis routes. Peroxisome proliferator-activated receptor gamma coactivator 1α (PGC1α) promotes VEGF expression and angiogenesis via estrogen-related receptor α (ERRα) binding to the VEGF gene, identified in muscle cells aiding ischemic recovery. 207  Oxidative stress also drives VEGF production, as seen in hypertrophied adipocytes releasing VEGF-A120 through the PI3K pathway without hypoxia. 208  Similarly, cold-induced angiogenesis in adipose tissue, mediated by sympathetic activation and VEGFR2 signaling, further demonstrates hypoxia-independent regulation. 209  Notably, a nuclear VEGF fragment (N-VEGF) upregulates VEGF-A and hypoxia-related genes independently, offering a novel HIF-bypassing mechanism. 210\nPromoters of VEGF family members exhibit unique regulatory features enabling differential responses to stimuli. VEGF-A and VEGF-B promoters contain Sp1 and AP2 transcription factor binding sites and a CpG island, but VEGF-B uniquely includes Egr-1 sites and lacks AP1 and HIF-1 binding sites, suggesting distinct regulatory pathways. 48 , 211  The VEGF-C promoter lacks a TATA box but contains Sp1, AP2, and NF-κB binding sites with a long 5’-untranslated region potentially affecting post-transcriptional regulation. 212  Additionally, VEGF-D regulation involves a critical direct repeat element in its proximal region, where orphan nuclear receptors HNF-4A and COUP-TF1/TF2 bind coactivators such as CBP and GRIP-1 to enhance expression. The AP1 pathway, particularly c-Fos/c-Jun-dependent, regulates VEGF-D in lung cancer, 213  with IL-7/IL-7R signaling upregulating VEGF-D via AP1 binding, promoting lymphangiogenesis through enhanced c-Fos/c-Jun heterodimers.\nN6-methyladenosine (m6A) is a prevalent modification in eukaryotic mRNA that plays a critical role in post-transcriptional regulation. m6A modifications occur at specific adenine residues in a consensus sequence and are dynamically regulated by m6A writers (methyltransferases, such as METTL3 and METTL14), erasers (demethylases, such as FTO and ALKBH5), and readers (binding proteins, such as YTH domain family proteins). 214  m6A modification in the 5′UTR of VEGF-A mRNA enhances cap-independent translation, driven by METTL3-mediated methylation and YTHDC2/eIF4GI interactions, which promotes VEGF-A expression and tumor progression. Knockdown of METTL3 reduced VEGF-A translation and angiogenesis, demonstrating the therapeutic potential of targeting the m6A/VEGF-A axis in lung cancer. 215  In addition, Wilms tumor 1-associated protein (WTAP), a key component of the m6A methyltransferase complex, promotes colorectal cancer progression by enhancing VEGF-A through m6A modification mediated by YTHDC1. 216  Interestingly, YTHDF2, an m6A reader protein, promotes hepatocellular carcinoma (HCC) progression by enhancing ETV5 translation, which upregulates PD-L1 and VEGF-A, driving immune evasion and angiogenesis. Targeting YTHDF2 with siRNA-loaded liposomes effectively reduces tumor growth and restores immune activity, highlighting its therapeutic potential. 217  m6A modification is a dynamic regulatory mechanism that enhances VEGF-A expression, contributing to tumor progression and angiogenesis in various cancers. Targeting key components of the m6A machinery, such as METTL3, WTAP, and YTHDF2, offers promising therapeutic strategies for inhibiting VEGF-A-driven oncogenic pathways.\nMicroRNAs (miRNAs) are small, evolutionarily conserved non-coding RNAs, approximately twenty-two nucleotides in length, first discovered in  C. elegans . 218  Typically, miRNAs act as negative regulators by binding to complementary sequences in the 3′-UTR of mRNAs, promoting mRNA degradation or inhibiting translation. 219  This post-transcriptional regulation is essential for controlling homeostatic and developmental events.\nmiR-126 is a key regulator of VEGF signaling, 220  which elevates angiogenesis by suppressing negative regulators such as SPRED1 and PIK3R2, affecting the MAPK and PI3K pathways. 221  miR-126 downregulation elevates VEGF-A expression, driving tumor angiogenesis. Epigenetic silencing of miR-126 increases VEGF-A levels, enhancing neovascularization and metastasis. 222  Conversely, miR-16 directly targets VEGF-A in cancers such as multiple myeloma and lung cancer, reducing tumor growth and angiogenesis. 223 , 224  Similarly, miR-205 is a key regulator in various cancers, affecting angiogenesis, metastasis, and chemoresistance. In breast cancer, miR-205 enhances chemosensitivity by targeting VEGF-A and FGF2, reducing resistance to drugs, such as doxorubicin and paclitaxel, and promoting apoptosis through the PI3K/AKT pathway. 225  In HCC, miR-205 inhibits tumor growth and metastasis by directly targeting VEGF-A, suggesting its potential as a therapeutic target. 226  Additionally, in breast cancer-associated fibroblasts, miR-205 mediates VEGF-independent angiogenesis through the YAP1-IL-11/IL-15-STAT3 axis, providing new strategies to combat resistance to anti-VEGF treatments. 227  These findings underscore the dual role of miRNAs in regulating VEGF-A expression and angiogenesis, either promoting or inhibiting tumor growth and metastasis. The activity of specific miRNAs, such as miR-126 and miR-205, to modulate key pathways associated with tumor progression and angiogenesis highlights their significance in disease mechanisms and their potential as therapeutic targets.\nLong non-coding RNAs (lncRNAs), RNA molecules over 200 nucleotides long, regulate gene expression without encoding proteins. 228 , 229  They function through various mechanisms such as chromatin remodeling or acting as decoys for proteins or miRNAs. Maternally expressed gene 3 (MEG3), a key lncRNA, regulates angiogenesis and vascular function by exerting anti-proliferative and pro-apoptotic effects, partly through p53 accumulation. 229 – 231  In DR, MEG3 downregulation exacerbates microvascular damage by increasing VEGF and inflammatory cytokines. 232 , 233  MEG3 also regulates VEGFR2 expression in ECs, and its reduction impairs VEGF-driven angiogenesis. 234  Overexpression of MEG3 can mitigate high glucose-induced VEGF and TGFβ1 levels, suggesting therapeutic potential for pathological angiogenesis. 233  In contrast, the lncRNA MALAT1 plays a pro-angiogenic role. In DR, MALAT1 supported EC growth and migration via the YAP1/miR-200b-3p/VEGF-A pathway. 235  In retinopathy of prematurity (ROP, eye disorder of abnormal retinal blood vessel development in premature infants), MALAT1 inhibition with siRNA reduced retinal neovascularization and lowered VEGF and inflammatory markers, highlighting its role in abnormal retinal vessel development. 236  Together, MEG3 and MALAT1 illustrate the diverse and opposing roles of lncRNAs in angiogenesis and vascular pathology.\n\nPost-translational modifications enhance protein diversity and help cells maintain homeostasis by altering the protein structure, stability, and interactions.\nGlycosylation of VEGF and VEGFR family members plays a subtle yet key role in their stability, secretion, and interactions, although it is not always essential for core functions, such as receptor binding. For VEGF-A, glycosylation at Asn74 (N74) is not essential for receptor binding or EC proliferation, 237  although it enhances protein stability and binding to GAGs. Similarly, VEGF-B186 is glycosylated in its C-terminal region, increasing its molecular weight and solubility compared with the non-glycosylated VEGF-B167, facilitating its secretion and extracellular stability. 14  N-glycosylation is critical for VEGF-D, as glycosylation at N155 and N185 ensures proper folding, solubility, and secretion. 238  Similarly, for VEGFR2, glycosylation at N247 regulates receptor activation, specifically, removing sialylated N-glycans at this site increases ligand-induced activation, which, in turn, regulates receptor dimerization and downstream signaling. 239  Moreover, glycosylation and sialylation of VEGFR2 regulate its stability, trafficking, and receptor-ligand interactions, underscoring their critical role in regulating VEGF/VEGFR signaling and function.\nSUMOylation is a reversible process in which small ubiquitin-like modifier (SUMO) proteins are attached to target proteins, and regulate key functions, such as DNA repair. 240 , 241  This modification involves a series of enzymes (E1, E2, and E3) that attach SUMO to specific lysine residues, while SUMO-specific proteases (SENPs) remove it, allowing for dynamic control of protein activity. SUMOylation of Lys1270 of VEGFR2 leads to its retention in the Golgi, reducing its expression on the cell surface and impairing VEGFR2 signaling. 242  SENP1, a SUMO-specific protease, removes this modification, allowing VEGFR2 to reach the cell membrane and activate angiogenesis. 242 , 243  In SENP1-deficient cells, VEGFR2 remains hyper-SUMOylated and trapped in the Golgi, leading to impaired angiogenesis. Moreover, SENP6 deSUMOylates VEGFR2, promoting its transport from the Golgi to the cell membrane and enhancing VEGFR2-mediated angiogenesis. 244  This process is particularly important in conditions such as diabetic microangiopathy, where altered SUMOylation dynamics can affect pathological angiogenesis. 244  Similarly, SUMOylation at Lys1270 inhibits VEGFR2 activity by reducing its phosphorylation and downstream signaling pathways, such as the AKT and ERK pathways. This modification also impairs cell proliferation and migration while promoting apoptosis in non-small cell lung carcinoma cells. Conversely, deSUMOylation of VEGFR2 by enzymes such as SENP1 can enhance VEGFR2 activity and restore angiogenic signaling. 245\nVEGFR2 ubiquitination is a critical post-translational modification that regulates its signaling, stability, and degradation, and directly affects angiogenesis. Among the key regulators, various E3 ubiquitin ligases, such as c-CBL, β-TRCP, and RNF121, activate VEGFR2 with ubiquitin, marking it for degradation through the endosomal-lysosomal system. This process is particularly important because ligand-dependent ubiquitination is necessary for regulating receptor expression on the membrane and preventing overstimulation of VEGF-A signaling. 246 , 247  In addition, the CUL3-SPOP-DAXX axis has been identified as a key regulator of VEGFR2 expression. 248 , 249  This complex facilitates ubiquitination of VEGFR2, reducing its expression and subsequently limiting angiogenic signaling. Moreover, E2 ubiquitin-conjugating enzymes such as UBE2D1 and UBE2D2 play crucial roles in modulating VEGFR2 ubiquitination. Notably, their depletion leads to increased VEGFR2 levels, enhancing VEGF-A-stimulated signaling pathways, such as MAPK, AKT, and PLCγ1, and promoting EC migration and tubulogenesis. 250  Thus, the balance of ubiquitination, recycling, and degradation orchestrates the intensity and duration of VEGFR2 signaling in physiological and pathological angiogenesis. Conversely, USP8, a deubiquitinating enzyme, removes ubiquitin chains from VEGFR2, facilitating its recycling from early endosomes back to the membrane and preventing its degradation in the lysosome. 251  However, when USP8 is depleted, VEGFR2 accumulates in early endosomes, leading to the generation of a novel 120 kDa proteolytic fragment. As a result, this accumulation also impairs VEGF-A-induced signaling, particularly through the AKT and ERK pathways.\n\nVEGFR activity is tightly regulated by various molecular processes that maintain vascular homeostasis and modulate the angiogenic response. These regulatory mechanisms include both positive and negative modulators, which fine-tune VEGFRs signaling to prevent excessive or insufficient angiogenesis.\nVE-PTP, a receptor-type phosphatase, is crucial for regulating endothelial junctions and blood vessel development. 252 , 253  VE-PTP is highly expressed in ECs, especially during vascular development, VE-PTP interacts with TIE2 (Fig.  7a ), dephosphorylating it to regulate Ang/TIE2 signaling. 254  It also negatively regulates VEGFR2 phosphorylation at endothelial junctions, controlling VEGFR2 activity and preventing excessive angiogenic signaling. 255  VE-PTP ensures proper EC polarity and lumen formation with its deficiency leading to increased VEGFR2 phosphorylation, abnormal vessel sprouting and endothelial dysfunction. 256 , 257  Recent studies showed that activin A, a member of the TGFβ family, reduces VEGF-induced vascular permeability by increasing VE-PTP expression which dephosphorylates VEGFR2 and dampens VEGF signaling, 258  suggesting therapeutic potential for conditions such as DR (Fig.  7a ). Fig. 7 Negative regulation and fine-tuning of VEGFR2-mediated signaling pathways.  a  VE-PTP regulates TIE2 and VEGFR2 dephosphorylation to balance angiogenic signaling and support vessel integrity. Activin A enhances VE-PTP expression and reduces VEGF-induced permeability, which may help control excessive vessel leakage in conditions such as diabetic retinopathy.  b  PTP1B regulates VEGFR2 signaling by binding to its cytoplasmic domain and dephosphorylating it, thereby acting as a negative regulator.  c  SHP1 acts as a negative regulator of VEGFR2 by dephosphorylating key tyrosine residues (Y996, Y1059, and Y1175) essential for endothelial cell proliferation.  d  TSP-1 modulates VEGFR2 activity by binding to CD36 and recruiting SHP1, which dephosphorylates VEGFR2 at Y1175. This action suppresses VEGF signaling and inhibits angiogenesis.  e  Notch signaling coordinates angiogenesis by balancing the roles of tip and stalk cells. Dll4 on tip cells activates Notch in stalk cells, reducing VEGFR expression and VEGF sensitivity to stabilize newly formed vessels. Fringe, a glycosyltransferase in stalk cells, enhances Dll4-Notch signaling, further reducing VEGFR levels and reinforcing stalk cell quiescence. Meanwhile, Jagged1 counteracts Dll4 by modulating Notch in stalk cells, allowing some cells to remain responsive to VEGF, supporting sprouting. This interplay ensures selective sprouting while maintaining vessel stability. Notably, the Notch-VEGFR3 pathway can also promote angiogenesis independently of VEGF-A/VEGFR2. VE-PTP vascular endothelial protein tyrosine phosphatase, VEGFR vascular endothelial growth factor receptor, PTP1B protein tyrosine phosphatase 1B, SHP-1 Src homology 2 domain-containing phosphatase-1, TSP-1 Thrombospondin-1. Created in BioRendender.com\nNegative regulation and fine-tuning of VEGFR2-mediated signaling pathways.  a  VE-PTP regulates TIE2 and VEGFR2 dephosphorylation to balance angiogenic signaling and support vessel integrity. Activin A enhances VE-PTP expression and reduces VEGF-induced permeability, which may help control excessive vessel leakage in conditions such as diabetic retinopathy.  b  PTP1B regulates VEGFR2 signaling by binding to its cytoplasmic domain and dephosphorylating it, thereby acting as a negative regulator.  c  SHP1 acts as a negative regulator of VEGFR2 by dephosphorylating key tyrosine residues (Y996, Y1059, and Y1175) essential for endothelial cell proliferation.  d  TSP-1 modulates VEGFR2 activity by binding to CD36 and recruiting SHP1, which dephosphorylates VEGFR2 at Y1175. This action suppresses VEGF signaling and inhibits angiogenesis.  e  Notch signaling coordinates angiogenesis by balancing the roles of tip and stalk cells. Dll4 on tip cells activates Notch in stalk cells, reducing VEGFR expression and VEGF sensitivity to stabilize newly formed vessels. Fringe, a glycosyltransferase in stalk cells, enhances Dll4-Notch signaling, further reducing VEGFR levels and reinforcing stalk cell quiescence. Meanwhile, Jagged1 counteracts Dll4 by modulating Notch in stalk cells, allowing some cells to remain responsive to VEGF, supporting sprouting. This interplay ensures selective sprouting while maintaining vessel stability. Notably, the Notch-VEGFR3 pathway can also promote angiogenesis independently of VEGF-A/VEGFR2. VE-PTP vascular endothelial protein tyrosine phosphatase, VEGFR vascular endothelial growth factor receptor, PTP1B protein tyrosine phosphatase 1B, SHP-1 Src homology 2 domain-containing phosphatase-1, TSP-1 Thrombospondin-1. Created in BioRendender.com\nPTP1B, another phosphatase, binds to the cytoplasmic domain of VEGFR2 and directly dephosphorylates it (Fig.  7b ), acting as a negative regulator. 259  Overexpression of PTP1B reduces VEGF-induced VEGFR2 autophosphorylation, inhibiting downstream signaling ERK signaling and EC proliferation. PTP1B also dephosphorylates VEGFR2 at Y1175 site during endocytic trafficking, suppressing VEGF signaling and the PLCγ1-MAPK pathway essential for arterial development. 260  Similarly, SHP1 negatively regulates VEGFR2 by dephosphorylating key tyrosine residues (Y996, Y1059, Y1175) (Fig.  7c ) upon VEGF stimulation via a c-SRC-dependent mechanism. 261  In addition, thrombospondin-1 (TSP-1) enhances this regulation by binding to CD36 and recruiting SHP1 to dephosphorylate VEGFR2 at Y1175 (Fig.  7d ), further suppressing VEGF signaling and angiogenesis. 262  While this study focuses on tyrosine phosphatases, serine/threonine phosphatases also play distinct roles in VEGFR2 regulation and downstream signaling.\nNegative feedback regulation maintains homeostasis by reducing or turning off a signaling pathway once the desired response is achieved. 263  Key regulators such as Sprouty, suppressor of cytokine signaling (SOCS), and ErbB receptor feedback inhibitor-1 (ERRFI1) inhibit excessive signaling by targeting pathways such as RTKs, JAK/STAT, and RAS/MAPK pathways, ensuring tight control over signaling cascades. 264 , 265\nVasohibin (VASH), identified as a VEGF-inducible gene in ECs, acts as a negative regulator of angiogenesis. 266 , 267  VASH inhibits EC migration, proliferation, and network formation, specifically targeting ECs without affecting other cell types. 266 , 268  Its expression is downregulated by hypoxia and inflammatory cytokines, such as TNF-α, potentially impairing its anti-angiogenic activity in conditions such as cancer. VASH has two isoforms: VASH1 and VASH2. VASH1, with two variants (VASH1A and VASH1B), primarily functions as an anti-angiogenic factor. 269  VASH1A normalizes tumor vessels, improving perfusion and chemotherapy efficacy, while VASH1B induces autophagic cell death in ECs, leading to vascular pruning and increased hypoxia. 270  In contrast, VASH2 promotes angiogenesis and is highly expressed in cancers, supporting tumor growth and metastasis by facilitating new blood vessel formation. 271 – 273  This dual role of VASH, acting as both an inhibitor and a promoter of angiogenesis, highlights its dynamic function in tumor development and therapeutic outcomes.\nThe VEGF/VEGFR and Notch/Dll4 pathways function together in a finely tuned negative feedback loop. 274 , 275  Indeed, Notch signaling is essential for angiogenesis, coordinating blood vessel formation. 276 , 277  When Dll4 on endothelial tip cells binds to Notch receptors on neighboring stalk cells, it triggers the release of Notch intracellular domain (NICD), which moves to the nucleus to affect gene expression. This Notch/Dll4 signaling balances tip and stalk cell roles during vessel sprouting and acts closely with VEGF signaling to maintain blood vessel formation (Fig.  7e ). Tip cells, which lead to new vessel sprouting, are highly affected by VEGF-A/VEGFR2 activation, which triggers strong ERK signaling and upregulates tip cell-specific genes such as Dll4. 278 – 280  In turn, Dll4 interacts with Notch receptors in nearby stalk cells, reducing their expression of VEGFR2 and VEGFR3 and making them less responsive to VEGF. 281 , 282  As a result, these cells adopt the role of stabilizing newly formed vessels rather than participating in further sprouting. This feedback loop ensures that stalk cells stabilize new vessels rather than participating in further sprouting, maintaining a balance between sprouting and stabilization. 281 , 282  This tightly regulated interaction is vital for proper vascular development, as it ensures that sprouting occurs in a controlled manner.\nIn contrast, Jagged1, another Notch ligand, promotes angiogenesis by antagonizing Dll4-Notch signaling (Fig.  7e ), especially in cells expressing the Fringe glycosyltransferase. 283  Fringe enhances Dll4-Notch signaling while diminishing the Jagged1 effect, allowing Jagged1 to support tip cell formation and sprouting. This interplay between Dll4 and Jagged1 finely balances angiogenesis. Interestingly, Notch signaling can drive angiogenesis independently of VEGF-A and VEGFR2 by upregulating VEGFR3, enabling vessel sprouting even when VEGFR2 is inhibited. 284  Blocking Notch signaling increased sprouting and vessel density in the absence of VEGFR2, revealing a VEGF-A-independent mechanism. This challenges the traditional reliance on VEGF-A/VEGFR2 in angiogenesis and suggests that targeting Notch and VEGFR3 could offer new strategies, particularly for tumors resistant to anti-VEGF treatment. Overall, this complex interplay between Notch, Dll4, Jagged1, VEGF, and VEGFR signaling pathways forms a multilayered feedback system that precisely controls angiogenic sprouting and vessel stability, highlighting a sophisticated regulatory network essential for balanced vascular growth.\n\nIn multicellular animals, the slow efficiency of oxygen and nutrient diffusion limits their reach to short distances. 285  To address the high demand for oxygen and nutrients driven by body size expansion during evolution, the development of an internal transport and exchange system became essential for substance delivery and waste removal. Invertebrates evolved circulatory systems - both open and closed - with vessels lined by ECM. 286  Vertebrates, however, developed a closed circulatory system featuring vessels with a true endothelial lining. 287  This endothelial lining, composed of tightly interconnected ECs anchored to a basement membrane (BM) with basoapical polarity, represents an evolutionary innovation. Beyond forming a functional vasculature for oxygen and nutrient delivery, ECs interact with perivascular cells to regulate blood flow, modulate immune cell trafficking, and produce signaling molecules to maintain tissue homeostasis.\nAngiogenesis has been recognized since ancient times, with early descriptions by the Greek physician Galen, who compared embryonic growth along umbilical veins to plant growth. 288 , 289  While its morphological features were detailed in the 1960s, 290 , 291  the molecular mechanisms were not elucidated until the 1970s by Judah Folkman and others. 292\nAngiogenesis begins (Fig.  8a ) with (1) the degradation of BM and loss of pericyte coverage in response to angiogenic stimuli. (2) ECs then migrate toward the stimulus with stalk cells aligning under the control of tip cells. (3) tip cells survey the microenvironment and connect to sprouts. Following this, (4) vessel maturation occurs, involving new BM formation and coverage by perivascular cell types, (5) blood flow is established, supporting the survival of new vessels. 293 , 294  Angiogenesis is tightly regulated by a balance of pro-angiogenic and anti-angiogenic factors. Among these, VEGF/VEGFR signaling is the best-defined key stimulator, demonstrated in models such as chicken embryos, 11  and primate, 295  and plays a critical role in every step of angiogenesis. Fig. 8 VEGF/VEGFR signaling controls angiogenesis and vascular permeability.  a  Role of VEGF/VEGFR signaling pathway in angiogenesis. (1) The vascular stability of quiescent microvessels covered by pericytes and basement membrane (BM) is maintained by non-VEGF/VEGFR signaling pathways such as Ang/TIE signaling. (2) Upon VEGF ligand stimulation, the BM degrades and releases bio-unavailable VEGF ligands. Endothelial cells (ECs) lose structural support and key adhesion molecules such as VE-cadherin and undergo tip cell selection. (3) VEGF signaling strongly induces the tip cell phenotype and metabolic characteristics, providing guidance cue for tip cells, whereas VEGFR2 and VEGFR3 are highly expressed in tip cells. Tip cells inhibit VEGFR2 and VEGFR3 and increase VEGFR1 and sVEGFR1 in stalk cells. VEGF supports perpendicular proliferation of stalk cells and lumen formation. (4) Tip cells recognize each other and induce sprout anastomosis. sVEGFR1, possibly produced by macrophages, regulates this process. VEGF negatively regulates vessel maturation.  b  Role of VEGF/VEGFR signaling in vascular permeability. The vascular permeability of quiescent microvessels is maintained by pores in ECs, glycocalyx, and EC junctions. VEGFR2 Y949 phosphosite in mice downregulates VE-cadherin via SRC. VEGFR2 also promotes nitric oxide (NO) production to reduce the expression of adhesion molecules required for paracellular permeability. VEGF has also been shown to stimulate vesicovacuolar organelles (VVO) and fenestrae formation for transcellular permeability. However, whether the glycocalyx can be cleaved by VEGF stimulation is not fully understood. Created in BioRendender.com\nVEGF/VEGFR signaling controls angiogenesis and vascular permeability.  a  Role of VEGF/VEGFR signaling pathway in angiogenesis. (1) The vascular stability of quiescent microvessels covered by pericytes and basement membrane (BM) is maintained by non-VEGF/VEGFR signaling pathways such as Ang/TIE signaling. (2) Upon VEGF ligand stimulation, the BM degrades and releases bio-unavailable VEGF ligands. Endothelial cells (ECs) lose structural support and key adhesion molecules such as VE-cadherin and undergo tip cell selection. (3) VEGF signaling strongly induces the tip cell phenotype and metabolic characteristics, providing guidance cue for tip cells, whereas VEGFR2 and VEGFR3 are highly expressed in tip cells. Tip cells inhibit VEGFR2 and VEGFR3 and increase VEGFR1 and sVEGFR1 in stalk cells. VEGF supports perpendicular proliferation of stalk cells and lumen formation. (4) Tip cells recognize each other and induce sprout anastomosis. sVEGFR1, possibly produced by macrophages, regulates this process. VEGF negatively regulates vessel maturation.  b  Role of VEGF/VEGFR signaling in vascular permeability. The vascular permeability of quiescent microvessels is maintained by pores in ECs, glycocalyx, and EC junctions. VEGFR2 Y949 phosphosite in mice downregulates VE-cadherin via SRC. VEGFR2 also promotes nitric oxide (NO) production to reduce the expression of adhesion molecules required for paracellular permeability. VEGF has also been shown to stimulate vesicovacuolar organelles (VVO) and fenestrae formation for transcellular permeability. However, whether the glycocalyx can be cleaved by VEGF stimulation is not fully understood. Created in BioRendender.com\nDuring BM degradation step, ECs lose structural support and tissues undergo decompartmentalization, enabling sprouting. The BM, composed of collagen, 296  laminin, 297  and elastin, 298  and inter-EC adhesion molecules such as VE-cad, 299  claudin, 300  and junctional adhesion molecules, 301  separates blood from underlying tissue. BM degradation, mediated by the proteolytic process of urokinase plasminogen activator (uPA) and matrix metalloproteinases (MMPs), facilitates angiogenesis. 302  ECM-degrading enzymes regulate VEGF signaling through: releasing bio-unavailable ligands: due to the varying heparin-binding and heparan sulfate-binding capacities of VEGF isoforms, some VEGF ligands are sequestered in the ECM. These bio-unavailable VEGF ligands are released following proteoglycan degradation, promoting angiogenesis 303 ; directly cleaving matrix-bound VEGF isoforms to modulate their angiogenic properties; 304  and stimulating VEGF expression via membrane-type MMP and SRC tyrosine kinases. 305 , 306  Following degradation, ECM fragments such as endorepellin, 307  endostatin, 308  thrombospondin-1, 309  and tumstatin, 310  often act as endogenous inhibitors, balancing pro-angiogenic and anti-angiogenic signals.\nreleasing bio-unavailable ligands: due to the varying heparin-binding and heparan sulfate-binding capacities of VEGF isoforms, some VEGF ligands are sequestered in the ECM. These bio-unavailable VEGF ligands are released following proteoglycan degradation, promoting angiogenesis 303 ;\ndirectly cleaving matrix-bound VEGF isoforms to modulate their angiogenic properties; 304  and\nstimulating VEGF expression via membrane-type MMP and SRC tyrosine kinases. 305 , 306  Following degradation, ECM fragments such as endorepellin, 307  endostatin, 308  thrombospondin-1, 309  and tumstatin, 310  often act as endogenous inhibitors, balancing pro-angiogenic and anti-angiogenic signals.\nAccompanying BM degradation, VEGF also disrupts inter-EC adhesion in quiescent vessels by: adherens junction dissociation: VEGF induces rapid dissociation of the EC-specific tyrosine phosphatase VE-PTP from VE-cad (Fig.  8b ), thereby disrupting the endothelial barrier; 311 endocytosis of adhesion molecules: VEGF stimulation promotes endocytosis of VE-cad, enabling EC migration and proliferation; 312  and regulating adherens junctions to control tight junctions: VE-cad promotes intracellular signaling that upregulates claudin-5, a major component of tight junction component, ensuring coordinated regulation of endothelial permeability. 313\nadherens junction dissociation: VEGF induces rapid dissociation of the EC-specific tyrosine phosphatase VE-PTP from VE-cad (Fig.  8b ), thereby disrupting the endothelial barrier; 311\nendocytosis of adhesion molecules: VEGF stimulation promotes endocytosis of VE-cad, enabling EC migration and proliferation; 312  and\nregulating adherens junctions to control tight junctions: VE-cad promotes intracellular signaling that upregulates claudin-5, a major component of tight junction component, ensuring coordinated regulation of endothelial permeability. 313\nThus, VEGF downregulates both junction types and promotes angiogenesis. Conversely, adherens junction proteins, including VE-cad and PECAM1 (also known as CD31) can be phosphorylated by mechanical forces, activating VEGFR-related signaling. 314 , 315  This integrates mechanical and chemical stimuli in ECs, driving angiogenesis. 316\nOnce the barrier is breached, a small subset of ECs undergoes an angiogenic switch, enabling migration and proliferation. At this stage, tip cells emerge from this EC subpopulation, becoming the leading cells of sprouting vessels (Fig.  8a ). Morphologically distinct, tip cells function as sensors, using dynamic filopodia to survey the environment for guidance cues and direct migration. This process resembles the insect tracheal system, where specialized cells guide migration and determine cell fate. 317  Interestingly, although tip cells were observed in the 1970s, 318  their molecular understanding emerged in the 2000s. 293\nVEGF signaling strongly drives the tip cell phenotype. During retinal development, tip cells exhibit high VEGFR2 expression compared with stalk or quiescent ECs. 319  VEGF ligands guide tip cell migration and are essential for tip cell filopodia formation, extension, and orientation. 319  In addition to VEGF/VEGFR2 signaling, VEGFR3 is highly expressed in tip cells and sustains angiogenesis even when VEGFR2 is inhibited. 320  VEGFR2/3 heterodimers often found on tip cell filopodia, 132  likely mediate responses to VEGF-A and VEGF-C in vivo. Beyond regulating tip cell behavior, VEGF also affects its metabolic phenotype. While ECs in perfused vessels rely on oxygen, VEGF-driven tip cells depend on glycolysis, mediated by 6-phosphofructo-2-kinase/fructose-2,6-bisphosphatase (PFKFB). 321 , 322\nUncontrolled tip cell formation results in dysfunctional vessels, so tip cells must regulate neighboring ECs to maintain the stalk cell phenotype. In zebrafish, VEGFR1 is highly expressed in stalk cells, and its loss leads to excessive tip cells and hyperbranching, indicating that VEGFR1 negatively regulates the tip cell phenotype. 323  Furthermore, through Notch signaling, tip cells suppress VEGFR2 and VEGFR3 expression whereas increasing VEGFR1 and sVEGFR1 in stalk cells, reducing their sensitivity to VEGF and maintain the stalk phenotype. 277 , 324  Tip cells also produce various immune and angiogenic modulators that facilitate tip-stalk cell communication. 325  Importantly, tip and stalk cells are not fixed phenotypes. Therefore, continuous communication is essential to sustain their distinct roles during angiogenesis. 326\nStalk cells follow tip cells, proliferating perpendicular to their guidance to elongate vessels and form lumens for tubular morphogenesis. Disrupted VEGF signaling misorients stalk cell division, causing vessel dysmorphogenesis, indicating a flow-independent regulatory mechanism. 327  During lumen formation, cell-cell contact is crucial for EC shape changes. In mouse aortic development, VEGF recruits myosin to apical cell surfaces at EC contact sites, driving morphological alterations. 328\nThe mechanism of tip cell fusion during sprout anastomosis remains unclear but appears to involve tip cell recognition, EC polarization, and apical membrane fusion. VE-cad and filopodia are essential for this process. 329 , 330  Interestingly, the spatial distribution of VEGFR1 regulates anastomosis, as in vitro studies show that tip cells make transient contacts before stable vessel connection, while VEGFR1 reduces contact frequency and alters vessel connection site. 331  Perivascular cells may act as chaperones 332  and resident macrophages, which secrete sVEGFR1 via a non-canonical pathway, 333  could play a regulatory role in sprout anastomosis.\nAfter sprouting, vessels undergo remodeling and maturation, a critical step for establishing a functional vascular network. 334  Blood flow delivers oxygen and mechanical forces that shape vascular remodeling. 335 , 336  As vessels mature, ECs form a new BM to stabilize and pattern the vasculature. 337  Perivascular cells, including pericytes, are recruited and stabilize vessels through non-VEGF signals such as PDGF, TGFβ, Ang1, and Notch. 338 , 339  Notably, VEGF signaling inhibits vessel maturation, highlighting its role in early angiogenesis rather than stabilization. 142\nSeveral angiogenic factors, including FGFs and Ang, stimulate angiogenesis under physiological conditions, differing from VEGF pathways. 340 , 341  For example, FGFs are widely expressed, promoting EC proliferation, 342  whereas VEGF is mainly EC-specific, exerting diverse regulatory effects. During development, FGF1 and FGF2 are less critical, 343  whereas TIE2, expressed in ECs, interacts with Ang1 and Ang2. Ang1 stabilizes quiescent blood vessels, 344  whereas Ang2 modulates the Ang1/TIE2 axis, sensitizing vessels to VEGF and other factors. 341  Ang1 and VEGF complement in each other in early vascular development, with VEGF initiating vessel formation and Ang1 supporting subsequent maturation. 345  Ang2 is required for post-natal angiogenesis. 346  These factors, along with VEGF, synergistically orchestrate angiogenesis to meet tissue-specific vascular needs. 347 , 348\nVEGF signaling is central to every step of angiogenesis (Fig.  8a ), yet its exact role in processes such as sprout anastomosis remain unclear due to EC heterogeneity and dynamic phenotypic changes. The involvement of other cell types also requires further investigation. Recent single-cell studies may provide deeper insights. 349  While the molecular mechanisms of VEGF signaling in angiogenesis are well understood, angiogenesis relies on precise spatiotemporal regulation to ensure proper vascular development. A comprehensive understanding of these dynamic processes may open new avenues for therapeutic strategies targeting pathological angiogenesis.\nVasculogenesis involves the de novo formation of blood vessels from endothelial progenitor cells (EPC), occurring during early embryonic development or rapid vascularization of avascular tissues. 350 , 351  Endothelial and hematopoietic progenitor cells arise from the embryonic mesoderm, yolk sac, allantois, and placenta, migrating to blood islands where they differentiate into angioblasts (forming ECs) and hematopoietic precursors (forming blood cells). 352 , 353  Differentiated ECs polarize and form a vascular lumen, through intracellular vesicle fusion or slit formation, 354  eventually forming major vessels such as aorta or middle cerebral artery after BM deposition. 355\nMorphogens including Wnt, Hedgehog, TGFβ, and FGFs, collectively regulate blood island formation, angioblast induction, and yolk sac vasculogenesis. 356  Additionally, VEGF, expressed in the extra-embryonic endoderm and mesoderm, 357  is crucial for vasculogenesis; for instance, embryos lacking VEGF, VEGFR2, or VEGFR3 exhibit severe defect (Table  1 ), including failed blood island formation, aortic abnormalities, or large vessel defects, 358 – 361  Moreover, VEGFR1 inhibits EC overgrowth and thereby tightly regulates VEGF signaling during vasculogenesis. 362 Table 1 Phenotype analysis of VEGF and VEGFR mouse models Mouse model Targeted gene Targeting strategy Phenotype Reference  Vegfa -/- Vegfa Exon 3 replaced with neomycin resistance cassette Null mutation, embryonic lethality (E8.5–9.5), severe vascular defects 358 , 359 Vegfa120/120 Vegfa120 ( Soluble isoform only ) Exons 6 and 7 replaced with neomycin resistance cassette Vascular defects, impaired vessel patterning, cardiac abnormalities, early postnatal lethality 700 Vegfa164/164 Vegfa164 Replacement of exons 4, 5, 7, 8 Normal vascular development, sufficient for vascular growth and remodeling Vegfa188/188 Vegfa188 Replacement of exons 4 through 8 Normal venular growth, arteriolar defects, underdeveloped arterioles Vegfa loxP/loxP  x  VE-Cad-Cre Vegfa  (ECs) Exon 3 flanked by loxP sites, VE-Cadherin promoter drives Cre Vascular degeneration, EC apoptosis, hemorrhage, cardiac dysfunction, early death 416 Vegfa loxP/loxP  x  Mlc2v-Cre Vegfa  (Cardiac muscle) Exon 3 flanked by loxP sites, Mlc2v promoter drives Cre Thin, dilated ventricles, hypovascularization, reduced cardiac function 454 Vegfa loxP/loxP  x  VMD2-Cre Vegfa  (RPE cells) Exon 3 flanked by loxP sites, VMD2 promoter drives Cre Loss of choriocapillaris, rapid cone photoreceptor dysfunction, severe vision loss 535 Vegfb -/- Vegfb Exons 3 to 7 replaced with promoter β-geo cassette Smaller heart, reduced coronary function, impaired recovery from ischemia, otherwise healthy 391 Vegfb loxP/loxP  x  Adipoq-Cre Vegfb  (Adipocytes) LoxP sites in intron 1 and 6, Adipoq promoter drives Cre Reduced plasma non-esterified fatty acids, improved insulin sensitivity, reduced ischemic stroke damage 701 Vegfb loxP/loxP  x  RIP-Cre Vegfb  (β-cells) LoxP sites between exons 1, 2 and 6, 7, RIP promoter drives Cre Increased insulin gene expression, enhanced insulin secretion, no significant effect on glucose tolerance 702 Vegfb loxP/loxP  x  Cd4-Cre Vegfb  (T cells) LoxP sites around exons 2-6, CD4 promoter drives Cre Increased CD4 + /CD8 + T cell apoptosis, impaired mitochondrial function, reduced T-cell survival and memory, alleviated autoimmune disease symptoms 703 Vegfc -/- Vegfc Exon 1 replaced with lacZ-neo cassette, removing translation start Severe lymphatic defects, absence of lymphatic vessels, prenatal lethality by E12.5 375 Vegfc loxP/loxP  x  Rosa-CreER T2 Vegfc LoxP sites around exon 3, tamoxifen-inducible Cre with Rosa-CreERT2 Impaired lymphangiogenesis, compromised lymphatic repair mechanisms 704 Vegfd -/- Vegfd Signal sequence and first/second coding exons replaced with lacZ-neo Viable, normal lymphatic development, no significant developmental abnormalities 376 Plgf -/- Plgf Exons 3 to 6 deleted Normal embryonic development, impaired pathological angiogenesis in ischemia, inflammation, wound healing, tumors 87 Vegfr-1 -/- \n (Flt1 -/- ) Vegfr1 Exon encoding signal peptide replaced with lacZ-neo, creating null allele Severe vascular defects, embryonic lethality (E8.5), disorganized vasculature in yolk sac 362 Vegfr1 loxP/ loxP  x  Rosa26-CreER T2 Vegfr1 LoxP sites around exon 3, tamoxifen-inducible Cre Enhanced angiogenesis, increased retinal vessel density and branching, sensitivity to VEGF-A-induced permeability 705 Vegfr1(Flt1)-tk-KO Vegfr1  (deletion of  Flt1  tyrosine kinase) Exon 17 replaced with neomycin cassette, removing tyrosine kinase domain Normal vascular development, reduced VEGF-induced macrophage migration, tyrosine kinase domain required for macrophage response 706 Vegfr2 -/- \n (flk1 -/- ) Vegfr2 First coding exon replaced with lacZ-neo Embryonic lethality (E8.5–9.5), severe vasculogenesis defects, absence of organized blood vessels 360 Vegfr2 loxP/loxP  x  VE-Cad-Cre Vegfr2  (ECs) LoxP sites around critical exon, VE-cadherin promoter drives Cre Impaired angiogenesis, reduced endothelial sprouting, decreased retinal vessel density 284 Vegfr2 loxP/loxP  x  Nestin-Cre Vegfr2  (Neural progenitors) LoxP sites flanking essential exons, Nestin promoter drives Cre Impaired cortical and hippocampal vascularization, reduced brain vascular density 707 Vegfr2 loxP/loxP  x  Lyve1-Cre Vegfr2  (LECs) LoxP sites around essential exons, Lyve-1 promoter drives Cre Lymphatic hypoplasia, reduced lymphatic vessel density in skin, embryonic lethality (E14.5) 708 Vegfr3 -/- Vegfr3 Translation start codon replaced with LacZ cassette Defective cardiovascular development, severe vascular malformations, embryonic lethality by E9.5 361 Vegfr3 ΔLBD/ΔLBD , Vegfr3 tyrosine kinase mutant Vegfr3  (LBD, tyrosine kinase domain) Deletion or point mutation of LBD and kinase domains LBD deletion: severe lymphatic defects, impaired lymphangiogenesis; Tyrosine kinase mutant: impaired lymphatic development but normal angiogenesis 377 EC  endothelial cell,  Mlc2v  myosin light chain-2,  VMD2  vitelliform macular dystrophy,  RPE  retinal pigment epithelium,  tk  tyrosine kinase,  LEC  lymphatic endothelial cells,  LBD  ligand binding domain\nPhenotype analysis of VEGF and VEGFR mouse models\nEC  endothelial cell,  Mlc2v  myosin light chain-2,  VMD2  vitelliform macular dystrophy,  RPE  retinal pigment epithelium,  tk  tyrosine kinase,  LEC  lymphatic endothelial cells,  LBD  ligand binding domain\nIntussusceptive angiogenesis involves vessels splitting to form new vessels, observed in developing organs and pathological vascular remodeling. 363 , 364  During this process, transluminal tissue pillars develop and fuse, creating new vascular structures. While VEGF and Notch signaling are implicated in intussusceptive angiogenesis, 365 , 366  the detailed molecular mechanisms remain unclear. Alternatively, another mode of vascular formation involves the segregation of cells from a common precursor vessel into discrete arterial and venous vessels, as seen in zebrafish embryo development. Specifically, VEGF-induced Ephb2a directs angioblast migration, determining vessel identity. 367  Compared with angiogenesis, vasculogenesis and other types of vascular formation are less studied with most descriptive studies, offering limited insights into molecular mechanisms. This is partly due to the transient nature of these processes and their overlapping occurrence in vivo, which complicates understanding. To address this, models that can specifically induce distinct forms of vascular formation are needed to clarify whether and how VEGF signaling affects these processes.\nApproximately 400 years ago, lymphatic vessels were first described by Gaspare Aselli in Italy and their route was correctly identified by Jean Pecquet in France. 368  Functioning as a parallel circulatory system to blood vessels, lymphatic vessels maintain tissue homeostasis by draining interstitial fluid and transporting antigens and immune cells to lymph nodes for immune surveillance. During early development, lymphatic vessels originate from the cardinal, 369  as demonstrated by genetic tracing of Prox1 cells in mice. 370\nSince the 1990s, lymphangiogenic factors have been identified with the VEGF-C/D-VEGFR3 axis emerging as the most critical signaling pathway regulating lymphangiogenesis. 371 , 372  Notably, VEGF-C transgenic mice exhibited overgrowth of lymphatic vessels but not blood vessels, underscoring its specific role in lymphangiogenesis. 373  Subsequently, VEGF-D was identified and shown to also promote lymphangiogenesis. 73 , 374  However, while  Vegfc -deficient mouse embryos failed to form lymphatic vessels, this defect could be rescued by external VEGF-C or -D supplementation. 375  Interestingly, although VEGF-D is a potent lymphangiogenic factor, it is not essential for lymphatic development. 376  VEGFR3 is crucial for blood and lymphatic vascular formation during early developmental stages. Studies involving mutations in the ligand-binding domain or tyrosine KD of VEGFR3 revealed that ligand binding is essential for lymphatic vessel development but not for blood vessel development. This supports a regulatory model where VEGFR3 modulates VEGF-A/VEGFR2 signaling through VEGFR2/3 heterodimers for blood vascular formation. Thus, the VEGF-C/D-VEGFR3 axis plays a pivotal role in lymphangiogenesis, distinct from its tole in blood vessel development. 377  Furthermore, other members of the VEGF/VEGFR family also contribute significantly to lmphangiogenesis. LEC-specific knockout of  Vegfr2  ( Flk1 ) leads to hypoplastic yet functional lymphatic vessels, indicating that VEGFR2, activated by both VEGF-A and VEGF-C, plays a role in this process. Additionally, VEGF-A alone has been shown to induce lymphangiogenesis, 378 , 379  although this effect is partially mediated by macrophage recruitment. 380 , 381  Thus, while VEGF-C/D-VEGFR3 remains central to lymphangiogenesis, VEGFR2 and VEGF-A also play supportive roles, often involving indirect mechanisms such as macrophage involvement.\nAng-TIE signaling, 346 , 382  FGF signaling, 342 , 383  and other factors including HGF, 384  PDGF, 385  and IGF 386  have been shown to promote lymphangiogenesis. 372 , 387  However, despite the identification of numerous lymphangiogenic factors, it remains unclear whether the mechanisms of lymphatic vessel sprouting and guidance resemble those of angiogenesis. The current model divides lymphangiogenesis into four key steps: (1) guidance/alignment, (2) proliferation, (3) sprouting, and (4) redirection. 372  In this process, the BM stabilizes lymphatic vessels, 388  LEC tip cells guiding sprouting, 389  and tissue macrophages provide VEGF-C guidance. 390  Future studies should focus on dissecting each step of lymphangiogenesis and uncovering the molecular mechanisms underlying these processes.\nBlood vessels are present in nearly all tissues, making VEGF signaling crucial for regulating angiogenesis and maintaining tissue homeostasis, including vascular permeability. To highlight its physiological significance, VEGF signaling plays key roles in (1) embryonic development by regulating angiogenesis, (2) maintaining endocrine organ homeostasis through vascular permeability, and (3) exerting neurotrophic functions independent of ECs.\nMouse embryos lacking VEGF ligands or their receptors exhibit embryonic lethality due to vascular defects (Table  1 ). 358 – 362 , 375  Specifically, VEGF-A, VEGFR2, and VEGFR3 promote hematopoietic and EC development, while VEGFR1 ensures precise blood vessel assembly. In contrast, PlGF and VEGF-B have minimal roles in development 87 , 391  whereas VEGF-C drives lymphatic vascular formation. Even slight alterations in VEGF levels, such as deletion of a single allele or modest overexpression, lead to abnormal blood vessel development and embryonic lethality, 358 , 359  emphasizing the need for precise VEGF signaling regulation during embryonic development. Postnatally, VEGF signaling is critical for organ development, as its disruption causes glomerular defects in neonates, 392  but not in adult mice. 393  Although VEGF/VEGFR signaling is vital for embryonic development, it remains active in adults, affecting both pathological and physiological conditions. For instance, modestly elevated circulating VEGF levels from early adulthood have been shown to preserve a youthful microvascular phenotype and extend lifespan in mice. 394  Thus, while VEGF signaling is indispensable during development, its regulation continues to play a beneficial role in maintaining physiological health throughout life.\nVascular permeability is a selective mechanism that regulates material exchange between blood vessels and surrounding tissues through small and large pores, 395  glycocalyx, and tight junctions on ECs (Fig.  8b ). 396  Under normal conditions, the endothelium allows the passage of solutes and small molecules while restricting larger molecules. However, in response to stimuli, the endothelium can become more permeable, enabling the leakage of larger molecules or cells. This permeability varies across organs based on physiological needs; for example, fenestrated endothelial in endocrine glands and kidney peritubular capillaries facilitate rapid transport, while the blood–brain barrier features tight junctions and perivascular coverage to restrict permeability. This plasticity is tightly controlled by various extracellular signaling molecules, including VEGF, Ang, histamine, platelet-activating factor, as well as intracellular mediators, such as NO, focal adhesion kinase (FAK), and GTPases. 397 , 398\nVEGF-A/VEGFR2 signaling is widely recognized for promoting vascular permeability through multiple mechanisms. Specifically, the Y949 (Y951 in humans) in VEGFR2 in mice binds to TSad, regulating c-SRC signaling at the EC junction. 399  Disruption of Y949 signaling stabilizes adherens junctions, blocking extravasation. 171  In contrast, the Y1173 in mice (Y1175 in humans) binds to PLCγ1, driving EC proliferation, 400  and its disruption halts developmental processes. 401  Notably, the role of VEGFR2 in permeability depends on its co-receptor NRP1, as SRC signaling in EC is largely NRP1-dependent. 189  Beyond direct junction regulation, VEGFR2 activates AKT and eNOS to promote NO synthesis, 402  indirectly enhancing vascular permeability, a process regulated by caveolin-1. 403 , 404  These findings highlight the critical role of VEGF-A/VEGFR2 in paracellular permeability, surpassing even certain inflammatory cytokines in potency. 171  Additionally, VEGF stimulates the formation of vesiculo-vacuolar organelles (VVO) in EC, 405  interconnected structures spanning the EC lumen, which support transcellular permeability and macromolecular extravasation. Thus, VEGF signaling plays a dual role in regulating both paracellular and transcellular permeability, underscoring its importance in vascular function. 406  VEGF/VEGFR signaling primarily regulates endothelial permeability through VEGFR2, facilitating the rapid extravasation of macromolecules (Fig.  8b ). Furthermore, the glycocalyx, a key structural component for vascular permeability, can be cleaved by inflammatory cytokines. 407  While it remains unclear whether VEGF signaling directly regulates the glycocalyx in EC, the glycocalyx itself inhibits VEGFR2 internalization, reducing VEGF-induced vessel permeability. 408  Overall, these interactions highlight the complex relationship between VEGF signaling and the glycocalyx in regulating vascular function.\nUnder physiological conditions, most tissues require a certain degree of vascular permeability for efficient substance exchange. Particularly, endocrine organs exhibit high permeability to facilitate hormone delivery, maintained by both general and organ-specific factors. 409  For example, the thyroid gland, the largest endocrine organ, 410  features a dense capillary network with abundant endothelial fenestrae, 410  which are VEGF-dependent for their maintenance. 411  Recent studies highlight that VEGF/VEGFR signaling, rather than Ang/TIE signaling molecules, is prominently expressed in thyroid organs. 412  Blocking VEGF or VEGFR2 in the thyroid leads to thickened cytoplasmic membrane, loss of EC fenestration, and accumulation of caveolae, modestly reducing circulating hormone levels. 412 , 413  Importantly, VEGF-VEGFR2 inhibition not only alters vascular permeability but also causes significant vascular regression in thyroid, more pronounced than tumors. 413 , 414  Clinically, this is evident as bevacizumab rapidly reduces thyroid perfusion. 415  Even in healthy adults, autocrine VEGF is essential for blood vessel homeostasis, as endothelial-specific deletion of  Vegf  results in progressive endothelial degeneration. 416  Thus, endocrine organs uniquely depend on VEGF-VEGFR2 signaling not only for vascular permeability but also for maintaining vascular homeostasis.\nAnimal models, including various VEGF and VEGFR knockout and conditional knockout mouse lines, have provided pivotal insights into the complexities of VEGF signaling in endothelial and lymphatic cells. These models reveal how genetic alterations in the VEGF/VEGFR pathways affect vascular development, lymphangiogenesis, and pathological processes, offering a detailed view of the VEGF regulatory network in both physiological and pathological contexts. These distinct phenotypes underscore the crucial roles of VEGF signaling in various biological processes (Table  1 ).\n\nThe discovery of VEGF has been a pivotal milestone and has significantly advanced our understanding of angiogenesis. Recent studies have investigated the specific roles of different VEGF isoforms under various conditions. These isoforms have also been found to contribute to several cardiovascular, ocular, metabolic, and reproductive disease. Despite this advancement in our knowledge, the intricate relationship between hyperglycemia, oxidative stress, inflammation, and VEGF expression remains a challenging area of research.\nCancer, the second leading cause of death worldwide, is projected to account for approximately 618,120 fatalities and 2 million new cases in the US in 2025, according to the American Cancer Society’s latest estimates. 417  Globally, the burden continues to escalate, with projections suggesting new cancer cases could surpass 35 million by 2050. This complex disease can originate in nearly any part of the body, characterized by the uncontrolled proliferation of abnormal cells that invade neighboring tissues and metastasize to distant sites through blood vessels, reflecting its developmental intricacy and diverse manifestations.\nDr. Folkman proposed the existence of a tumor angiogenic factor (TAF) critical for tumor growth, suggesting that inhibiting TAF could suppress tumor progression. 7  Angiogenesis, essential for solid tumor growth and metastasis, is regulated by a balance of pro- and anti-angiogenic factors. 418  Tumor cells promote angiogenesis by secreting VEGFs, stabilized by HIF-1α in a hypoxic TME, 84 , 419  while oncogenes such as RAS and RAF (Fig.  9 ) further affect VEGF expression. 420 – 422  In turn, VEGF from tumor and stromal cells drives pathological angiogenesis by activating VEGFR1 and VEGFR2 on tumor ECs. 423 Fig. 9 VEGF/VEGFR signaling under pathological conditions. The diverse roles of VEGF ligands and their receptors drive pathological processes, including tumor angiogenesis, cardiovascular diseases, ocular diseases, and metabolic/immune-related/reproductive disorders. Key molecular interactions and downstream signaling pathways are upregulated or dysregulated in disease states, thereby promoting cell survival, migration, and proliferation. These pathways highlight the therapeutic potential of targeting VEGF/VEGFR signaling across various disease contexts. ATH atherosclerosis, MI myocardial ischemia, DR diabetic retinopathy, AMD age-related macular degeneration, FA fatty acid, NAFLD non-alcoholic fatty liver disease, RA rheumatoid arthritis, PE pre-eclampsia, EM endometriosis. Created in BioRendender.com\nVEGF/VEGFR signaling under pathological conditions. The diverse roles of VEGF ligands and their receptors drive pathological processes, including tumor angiogenesis, cardiovascular diseases, ocular diseases, and metabolic/immune-related/reproductive disorders. Key molecular interactions and downstream signaling pathways are upregulated or dysregulated in disease states, thereby promoting cell survival, migration, and proliferation. These pathways highlight the therapeutic potential of targeting VEGF/VEGFR signaling across various disease contexts. ATH atherosclerosis, MI myocardial ischemia, DR diabetic retinopathy, AMD age-related macular degeneration, FA fatty acid, NAFLD non-alcoholic fatty liver disease, RA rheumatoid arthritis, PE pre-eclampsia, EM endometriosis. Created in BioRendender.com\nRecent studies show that most VEGF family members, except PlGF, correlate with angiogenesis and lymphangiogenesis in cancer. 424  However, the role of PlGF remains complex, as it can either promote 425 , 426  or inhibit tumor growth 427 , 428  depending on the context. Similarly, VEGF-B exhibits varying effects on tumor angiogenesis and survival, with its dual functions linked to FGF-2/FGFR activity. 137  Likewise, VEGF-C, activating VEGFR2 and VEGFR3, promotes blood vessel growth in breast cancer, while its overexpression enhances lymphangiogenesis and lymphatic metastasis. 61 , 429 – 431  In addition, VEGF-A also supports lymphangiogenesis by activating VEGFR2, forming heterodimers with VEGFR3, and recruiting macrophages and mast cells to secrete VEGF-C and VEGF-D, thus promoting lymphatic vessel growth. 33 , 432  Furthermore, inhibition of VEGFR3 signaling blocks VEGF-C-induced lymphangiogenesis and tumor cell infiltration into lymphatic vessels. 433  Notably, VEGF-D overexpression can drive tumor growth and angiogenesis, enabling to anti-VEGF-A therapy and highlighting its critical role in cancer progression. 434 , 435  These findings underscore the complex and pivotal roles of VEGF family members in tumor angiogenesis, lymphangiogeneis, and therapeutic evasion.\nImportantly, a recent study presents a single-cell atlas of tumor vasculature, analyzing around 200,000 cells from various cancers. 349  Specifically, tumor angiogenesis is traced from venous ECs to capillary and arterial ECs through angiogenic stages, with apelin+ tip cells identified as biomarkers for poor prognosis and anti-VEGF therapy response. Furthermore, LECs show two lineages, one driving lymphangiogenesis and another enhancing antigen presentation. Additionally, BASP1+ matrix-producing pericytes linked to endoplasmic reticulum stress were shown to play a pro-angiogenic role. Moreover, neovascular ECs also contribute to an immunosuppressive TME through stromal and immune cell interactions. In summary, these findings highlight the interplay between vascular cells and the TME, offering insights into vascular heterogeneity and novel anti-angiogenic therapeutic targets.\nCardiovascular diseases (CVDs) encompass a range of disorders affecting the heart and blood vessels, rooted in vascular dysfunction, including atherosclerosis, myocardial infarction, and hypertension.\nVEGF plays a complex role in atherosclerosis, with both beneficial and detrimental effects. Systemic VEGF gene delivery does not induce atherosclerosis in hypercholesterolemic mice, 436  but local administration of VEGF-A and VEGF-D promotes angiogenesis and intimal hyperplasia in rabbits. 437  Moreover, VEGF can recruit macrophages and monocytes, potentially exacerbating plaque formation, 438  as demonstrated by intracoronary VEGF-A164 delivery, which worsened arteriosclerotic injury in rabbits. Similarly, macrophages in human plaques express VEGF-A via HIF-1α, 439  highlighting its inflammatory role. Additionally, PlGF-2 gene transfer increases VEGF-A levels, driving inflammatory angiogenesis, 440  while PlGF itself promotes atherosclerosis in hypercholesterolemic models despite reducing macrophage content. 441 , 442  Furthermore, VEGF facilitates macrophage infiltration through VEGFR1 and mobilizes endothelial and smooth muscle progenitor cells via VEGFR2, contributing to coronary arteriosclerosis. 443 , 444  Additionally, VEGF-A accelerates vascular remodeling by enhancing T cell recruitment to vessels. 445  Therefore, while VEGF supports angiogenesis and vascular repair, its role in plaque formation and progression underscores its context-dependent and multifaceted impact on atherosclerosis (Fig.  9 ).\nLow VEGF-C levels are linked to higher mortality in patients with coronary artery disease and may enhance plaque stability, positioning VEGF-C as a promising biomarker and therapeutic target for CVD. Specifically, its protective effects on smooth muscle cells, promotion of cholesterol efflux, and reduction of cellular stress underscore its role in maintaining vascular health and mitigating the progression of atherosclerosis. 446 , 447  Thus, further investigation is warranted to explore its clinical applications for risk stratification and innovative treatments. Similarly, VEGF-D is expressed at all stages of human atherosclerotic lesion development, implicating its involvement in the disease. 448  For example, adenovirus-mediated VEGF-D gene transfer has been shown to reduce neointimal thickening and macrophage infiltration, suggesting its therapeutic potential. 449  Moreover, elevated VEGF-D levels also independently predict mortality in patients with coronary artery disease undergoing elective angiography. 450  Collectively, these findings emphasize multifaceted role of VEGF-D in atherosclerosis, highlighting its potential as both a therapeutic target and a prognostic marker in CVD. Together, VEGF-C and VEGF-D represent critical factors in understanding and managing cardiovascular diseases.\nThe roles of VEGFs and VEGFRs in MI are complex, significantly impacting cardiac function and recovery. Specifically, ischemia triggers VEGF release from cardiomyocytes, binding to VEGFR1 and VEGFR2 on microvascular ECs, 17 , 451 , 452  promoting angiogenesis and vascular remodeling. However, recent studies show mild hypoxia in developing mouse hearts does not induce VEGF-A or coronary angiogenesis, 453  suggesting other factors. Moreover,  Vegfa  deletion in cardiomyocytes impairs blood vessel formation and worsens heart contractions. 454\nInflammation drives MI, with Annexin A1 promoting cardiac repair and angiogenesis via macrophage-derived VEGF-A. 455  Similarly, VEGFR2 signaling also aids barrier function with losartan treatment reduces ischemic reperfusion injury in mice. 456  Intracoronary VEGF-A gene transfer improves myocardial perfusion, offering a strategy for therapeutic angiogenesis in ischemic heart disease. 457  Furthermore, VEGF-B or PlGF overexpression enhances coronary vasculature and stimulates cardiomyocyte hypertrophy, yet long-term hypertrophy effects remain unclear. 56 , 458 , 459  Combining PlGF and VEGF-A enhances angiogenesis in ischemic myocardial tissue resistant to VEGF-A alone, suggesting synergistic benefits in certain clinical scenarios. 162  Notably, VEGF-B promotes coronary blood vessel development without permeability or inflammation, making it an attractive therapeutic target. 56 , 460\nPost-MI, VEGF-C enhances lymphangiogenesis, reduces fluid retention and inflammation (Fig.  9 ), and improves cardiac function. 461 , 462  Additionally, VEGF-C protects cardiomyocytes by activating AKT signaling through VEGFR2, thereby reducing apoptosis. 463  Similarly, VEGF-D increases vascular permeability, stimulates angiogenesis, and improves blood flow, yet it also contributes cardiac fibrosis, underscoring the need to balance its therapeutic benefits and adverse effects. 464 , 465  In summary, the VEGFs and their receptors diversely affect MI through angiogenesis, inflammation, cardiac repair, necessitating deeper understanding for targeted therapies.\nHypertension is the most common comorbidity associated with anti-VEGF therapy. 466 , 467  Under hypertensive conditions, disrupted VEGF signaling impairs endothelial dysfunction and alters hemodynamics. Specifically, VEGF-A binding to VEGFR2 or shear stress activates the PI3K/AKT pathway, stimulating eNOS to produce vasodilators such as NO and prostacyclin (PGI2), highlighting the critical role of VEGF signaling in vascular tone regulation. 468 , 469\nStudies in animal models and patients treated with VEGF signaling pathway (VSP) inhibitors show reduced urinary nitrite/nitrate excretion and serum NO metabolites, impairing NO-dependent microvasodilation. 470 , 471  Additionally, VSP inhibitors upregulate endothelin-1 (ET-1), a potent vasoconstrictor, contributing to hypertensive effects. These findings reveal the complex interplay between VEGF signaling, NO production, and blood pressure regulation. 472 , 473  In patients with gastrointestinal stromal tumors, regorafenib-induced ET-1 fluctuations correlated with therapy cycles and blood pressure changes. 474  In contrast, sorafenib did not significantly alter ET-1 levels in renal cell carcinoma patients, despite hypertension. 475  Similarly, preclinical studies in rats showed that sunitinib increased ET-1 and blood pressure, effects reversed by the endothelin receptor antagonist macitentan. 472  These results suggest a variable interplay between VSP inhibitors, ET-1, and blood pressure, depending on the inhibitor and cancer type. Moreover, VSP inhibition may trigger hypertension via microvascular rarefaction, reducing vessel density, or functional rarefaction, heightening vasomotor tone and limiting blood flow. 476  Recent studies also link VSP inhibitors to salt-sensitive hypertension through interstitial sodium buildup and osmotic stress, especially in the skin. 477 – 479  This complex interplay between VEGF signaling, endothelial function, and blood pressure highlights challenges in managing anti-VEGF therapy-induced hypertension, warranting further research for effective strategies.\nOcular diseases encompass a range of conditions that target the eye and its visual system, significantly impacting various retinal cell types and structures. Notably, the prevalence of ocular microvascular diseases, such as DR and AMD has risen considerably. These conditions pose significant threats to ocular health and visual acuity, often leading to visual impairment or blindness if not treated promptly.\nThe global rise in diabetes has intensified microvascular complications, notably, DR, a leading cause of vision. 480 , 481  Specifically, hyperglycemia forms AGEs, driving neovascularization, permeability, and macular edema in DR. 482  As a result, retinal cells such as ganglion cells, 483  astrocytes, 484  ECs, 484  pericytes, 485  microglia, 486  Müller glia, 487  and retinal pigment epithelial (RPE) cells 488  secrete VEGFs. Moreover, ischemia worsens inflammation and endothelial damage, upregulating VEGFs, VEGFRs, and HIF-1α to regulate neovascularization. 489 – 491\nVEGF-A plays a dual role in DR, both promoting vascular permeability and protecting retinal cells. 492  Initially, it increases edema, and disrupts blood-retinal barrier, 493 , 494  fueling endothelial proliferation and proliferative diabetic retinopathy (PDR), marked by abnormal retinal vessel growth. 495  Yet, it also guards neurons and Müller cells against apoptosis, 483 , 496  reflecting complex regulation. 497\nHyperglycemia-induced reactive oxygen species (ROS) abnormally phosphorylate VEGFR2 independently of VEGF-A, 498  with elevated VEGFR2 expression in diabetic retinal microvascular ECs, especially in the macula. 499  Consequently, VEGF-A phosphorylates tight junction proteins such as occludin, increasing permeability, 500 – 502  and activates pathways such as phospholipase A2, 503  PKC, 504  and PI3K/AKT, 505  driving endothelial dysfunction and plasma extravasation. Additionally, VEGF-A level variations affect DR risk, 506 , 507  with elevated VEGF-A, PlGF, and VEGF-B in vitreous and serum promoting angiogenesis and PDR. 508 , 509  However, their roles in progression and treatment response remain unclear.\nIn contrast, VEGF-B, VEGFR1, and NRP1 provide neuroprotection via AKT and ERK pathways, reducing apoptosis, 510  while low VEGF-B impairs vascular integrity by downregulating VE-cad, ZO-1, and CDC42. 511  Similarly, PlGF rises in diabetic macular edema (DME) and PDR, 512 – 514  disrupting RPE barrier integrity via MEK/ERK under hypoxia. 515  For instance, PlGF deletion in diabetic mice reduces apoptosis and microcapillary damage by inhibiting HIF-1α-induced VEGF signaling through AKT, 516  yet its overexpression increases microaneurysms, leakage, and inflammation via IL-6. 517  Additionally, dysfunctional lipid metabolism upregulates VEGF-A, VEGF-C, VEGF-D, and PlGF, advancing DR. 518  Notably, VEGFR2 localizes to leaky microvessels, while VEGFR3 is limited to specific PAL-E-positive vessels, indicating altered receptor expression. 519  Although VEGFs’ roles in DR are clear, isoform-specific contributions and receptor crosstalk require further study to refine targeted therapies.\nAMD is a complex, multifactorial disease influenced by aging, environmental factors, and genetic predisposition. Its pathogenesis is associated with chronic inflammation, lipid accumulation, oxidative stress, and ECM dysfunction. 520  In neovascular (wet) AMD (nAMD), immune cell recruitment to the macula leads to the release of pro-inflammatory and pro-angiogenic cytokines, including VEGF, driving pathological neovascularization.\nVEGF-A is the primary factor mediating this process, making it a key therapeutic target. 521  Additionally, VEGF-B overexpression disrupts the outer blood-retinal barrier and promotes inflammatory angiogenesis by upregulating cell survival factors. 522  Notably, patients with wet AMD and polypoidal choroidal vasculopathy exhibit elevated VEGF-B levels, suggesting its involvement in disease progression, particularly after VEGF-A inhibition. 523\nBeyond VEGF-A and VEGF-B, VEGF-C and VEGF-D, traditionally recognized for their roles in lymphangiogenesis via VEGFR-3, have recently been implicated in retinal and choroidal angiogenesis. 524 , 525  These factors can activate VEGFR-2, contributing to vascular permeability and neovascularization independently of VEGF-A. Importantly, VEGF-C and VEGF-D are upregulated following VEGF-A inhibition with agents such as aflibercept or bevacizumab, which may limit the efficacy of anti-VEGF-A therapy and lead to persistent disease activity. 526  RPE cells from wet AMD patients express VEGF-C and VEGF-D, further promoting neovascularization despite the absence of lymphatic vessels. 524  Inflammatory cytokines in AMD also upregulate VEGF-A and VEGF-C, with VEGFR-2 and VEGFR-3 detected in choroidal neovascularization (CNV) membranes, reinforcing the role of VEGF family members in disease progression. 527 , 528  Given the limitations of VEGF-A inhibition alone, novel approaches targeting VEGF-C and VEGF-D have emerged. A phase 2b clinical trial of OPT-302, a VEGF-C/D inhibitor, demonstrated that adding VEGF-C/D blockade to standard anti-VEGF-A therapy (ranibizumab) significantly improved visual outcomes in nAMD patients. 529  These findings suggest that dual VEGF-A and VEGF-C/D inhibition may enhance therapeutic efficacy by targeting alternative angiogenic pathways, although further studies are needed to confirm long-term benefits.\nMeanwhile, VEGFR1, highly expressed by infiltrating monocytes and macrophages in AMD, modulates angiogenesis by suppressing VEGF-A-induced migration when neutralized. 530  Blocking PlGF and VEGFR1 reduces monocyte recruitment after laser-induced injury, highlighting VEGFR1’s role in immune cell infiltration. 531 , 532  Additionally, excessive VEGF-A disrupts RPE barrier function, exacerbating choroidal neovascularization. 533  However, while VEGF-A/VEGFR-2 inhibition reduces vascular permeability, RPE-derived VEGF-A is essential for choriocapillaris maintenance, 534 , 535  underscoring the need for a delicate balance in anti-VEGF therapies to suppress pathological signaling without compromising retinal function.\nA comprehensive understanding of VEGF signaling in AMD, particularly the interplay between VEGF-A, VEGF-B, VEGF-C, and VEGF-D, is essential for optimizing therapeutic strategies and refining treatment approaches to improve long-term patient outcomes.\nMetabolic disorders arise from disruptions in energy utilization and storage, driven by hormonal, enzymatic, and cellular imbalances. In this context, VEGFs play a dual role in metabolic diseases, influencing vascular complications in diabetes mellitus, diabetic nephropathy, and non-alcoholic fatty liver disease with both protective and detrimental effects.\nT2DM is a metabolic disorder driven by insulin resistance or β-cell dysfunction, leading to vascular alterations in insulin-sensitive tissues. 536  Notably, VEGF-A, primarily produced by pancreatic α and β cells, plays a key role in islet microvasculature. 537  Deleting  Vegf  in insulin-producing cells reduces islet vascularization and impairs insulin secretion, while VEGF-A deficiency leads to islet hypoxia and elevated blood glucose levels. 537 – 539\nGlucose homeostasis and VEGF-A secretion are tightly linked. Lower glucose levels reduce VEGF-A secretion, whereas prolonged hypoglycemia induces apoptosis in ECs and β cells. 540  Exogenous VEGF-A mitigates hypoglycemia-induced damage, suggesting potential therapeutic applications. 541  However, chronic VEGF upregulation may be detrimental, contributing to β-cell dysfunction and PKC-mediated endothelial abnormalities in diabetic vasculopathy. 542 , 543  In the inflammatory context, VEGF-A exerts complex effects. Diabetic patients exhibit impaired monocyte responses to VEGF-A, hindering inflammatory cell infiltration in ischemic tissues and compromising wound healing. 544  Conversely, VEGF-A promotes macrophage recruitment, supporting β-cell proliferation and regeneration. 545 – 547  Blocking VEGF-B improves glucose tolerance (Fig.  9 ) and insulin sensitivity, 548  while VEGF-C accelerates wound healing in diabetic conditions. 549\nUltimately, VEGF signaling acts as a double-edged sword in T2DM. While essential for islet function, dysregulated VEGF expression may worsen β-cell dysfunction and vascular complications. Future research should clarify the roles of VEGF isoforms to develop targeted therapies that optimize VEGF levels, improving glycemic control and preventing diabetic complications.\nDN, a major renal complication of diabetes, arises from chronic hyperglycemia-induced oxidative stress, inflammation, and vascular dysfunction. 550 , 551  In the kidney, VEGF-A, mainly produced by podocytes and detected in distal tubules and collecting ducts, 552 – 554  is expressed in glomerular and tubular cells such as pericapillary ECs, mesangial cells, and interstitial fibroblasts, to maintain vascular integrity. 519 , 555 , 556  Initially, in early DN, rising VEGF-A levels in renal and urinary systems increase permeability and endothelial dysfunction, driving glomerular damage, 557 , 558  with elevated VEGF and VEGFR2 expression in diabetic models. 559 , 560  For example, in eNOS ( Nos3 ) knockout mice, higher VEGF-A correlates with glomerular hypervascularization, worsening DN. 561  However, anti-VEGF therapy reduces albuminuria and glomerular dysfunction in diabetic mice, 562 , 563  although excessive suppression risks endothelial injury and increased permeability. 564\nVEGF-B contributes to DN by inducing podocyte insulin resistance via lipid accumulation, 565  with elevated levels in T2DM patients linked to renal decline. 566  Notably, an anti-VEGF-B/IL-22 fusion protein mitigates oxidative stress, inflammation, and lipid deposition, offering therapeutic potential. 567  Similarly, VEGF-C and VEGF-D, signaling through VEGFR3, regulate glomerular permeability despite the absence of lymphatics in glomeruli, 568  as podocyte-derived VEGF-C enhances permeability via VEGFR3 and VEGFR2. 569 , 570  In contrast, podocyte-specific VEGF-C overexpression in diabetic mice improves albuminuria and endothelial function by lowering VEGFR2, 571 , 572  while elevated VEGF-D correlates with renal impairment, albuminuria, and proteinuria. 573\nNevertheless, excessive VEGF manipulation can be detrimental. Complete  Vegfa  loss in podocytes causes neonatal death, and a single allele leads to proteinuria and endotheliosis, 392  while its deficiency disrupts complement regulation, increasing C3 accumulation. 574  Likewise, bevacizumab-induced VEGF inhibition in humans causes endothelial injury and plasma buildup, 575  and  Vegfr1  deletion in podocytes triggers severe proteinuria, although kinase-deficient VEGFR1 mitigates this, suggesting sVEGFR1’s protective role. 166\nThus, VEGF signaling in DN balances vascular protection and pathological remodeling. The complex interplay of VEGF isoforms and receptors highlights the need for precise therapies to modulate VEGF activity, preserve renal function, and minimize harm, necessitating further research. 576 – 578\nNAFLD is a major public health concern characterized by excessive hepatic lipid accumulation in individuals with minimal or no alcohol consumption. 579  It encompasses a spectrum from simple steatosis to non-alcoholic steatohepatitis (NASH), which can progress to fibrosis, cirrhosis, and HCC. 580  The advancement of liver fibrosis is marked by increased vascular growth, as observed in both human and animal models. 581  Recent findings suggest a potential role for VEGF in NAFLD pathogenesis and progression. 582 , 583  Notably, VEGF and VEGFR1 mRNA levels are elevated in steatotic livers compared with NASH, indicating an early induction of angiogenesis in NAFLD. 584  However, clinical studies have shown conflicting results regarding VEGF-A and VEGFR alterations in NAFLD progression. 584 , 585\nHepatocytes play a key role in NAFLD progression by synthesizing VEGF-A, which promotes fibrosis and endothelial dysfunction, contributing to disease severity. 586  In a murine model of diet-induced NASH, VEGFR2 inhibition reduced steatosis and inflammation, highlighting VEGF signaling as a potential therapeutic target. 587  Beyond hepatic angiogenesis, adipose tissue metabolism affects NAFLD development. VEGF-B signaling enhances fatty acid uptake in the liver, driving hepatic steatosis in diabetic models. 588  Additionally, VEGF-B has been identified in the subcutaneous white adipose tissue of NAFLD patients, emphasizing its translational relevance in human disease. 589  Patients with NAFLD also exhibit elevated serum levels of angiogenic markers, including VEGF, sVEGFR1, and sVEGFR2, which correlate with hepatic fibrosis severity and may serve as biomarkers. 584\nEmerging evidence suggests VEGF-C as a therapeutic target for NAFLD, with flavonoid-based interventions showing potential in modulating VEGF-C activity. 590  The interplay between VEGF-A, VEGF-B, and VEGF-C contributes to hepatic lipid accumulation, fibrosis, and carcinogenesis, highlighting VEGF signaling as a critical target for therapeutic strategies in NAFLD.\nImmune-related diseases are characterized by dysregulation of the immune system, resulting in inflammation and tissue damage. VEGFs are critical in these conditions by promoting angiogenesis and modulating immune responses.\nRA is a chronic autoimmune disorder characterized by persistent synovial inflammation, leading to joint damage and functional impairment. 591  A key driver of RA progression is angiogenesis, which facilitates inflammatory cell infiltration and pannus formation, accelerating joint destruction. 592  Notably, HIF-1 and HIF-2 are highly expressed in the RA synovium, promoting VEGF production and excessive vascularization, which exacerbate inflammation and synovial hyperplasia. 593\nVEGF-A plays dual roles as both a pro-inflammatory mediator and an angiogenesis promoter within synovial tissue. 594  Synovial macrophages and fibroblasts produce VEGF, while osteoclasts and their precursors express VEGF receptors, forming a complex network that drives disease progression. 595  Elevated serum VEGF levels correlate with c-reactive protein (CRP), highlighting its diagnostic and prognostic value in RA. 596 , 597  Furthermore, VEGF supports rheumatoid synoviocyte survival and proliferation through IL-6/JAK2/STAT3 and Notch signaling, reinforcing its role in RA pathogenesis. 598\nOther VEGF family members contribute to RA pathology. 599  VEGF-B deficiency reduces synovial angiogenesis and inflammation, whereas VEGF-C promotes lymphangiogenesis, improving lymphatic drainage and reducing tissue damage. 600  Given the central role of VEGF signaling, targeted therapies such as soluble VEGFRs, anti-VEGF antibodies, and the VEGFR2 inhibitor ramucirumab have shown promise in reducing inflammation and disease severity. 601 – 603  Their efficacy is further enhanced in combination with methotrexate, presenting a potential therapeutic strategy for managing RA.\nPsoriasis is a chronic inflammatory skin disorder that significantly impacts the quality of life. 604  A key but underappreciated factor in its pathogenesis is aberrant angiogenesis, which increases vascular permeability, capillary dilation, and elongation, contributing to epidermal hyperplasia and disease progression. 605 , 606  Elevated VEGF-A levels in psoriatic epidermis and plasma promote EC proliferation, migration, and survival while enhancing vasodilation and permeability. 607  VEGF-A also regulates keratinocyte proliferation and differentiation, with VEGFR1, VEGFR2, and NRPs expressed in keratinocytes, indicating autocrine VEGF-A signaling. 608 , 609\nNon-lesional psoriatic skin overexpresses VEGF isoforms such as VEGF-A, VEGFR3, and sNRP1. 610 , 611  VEGFR1, VEGFR2, and VEGFR3 are upregulated in psoriatic lesions, while VEGF-C, in conjunction with nerve growth factor (NGF), has been implicated in disease development. 612  Preclinical models highlight the role of VEGF in psoriasis pathogenesis (Fig.  9 ). Transgenic VEGF delivery induces chronic inflammation with hyperplasia and vascular abnormalities resembling psoriasis. 613  Excess VEGF-A increases vascular density and permeability, exacerbating inflammation. In psoriasis mouse models, anti-VEGF therapies reduce inflammation, normalize epidermal structure, and decrease vascular density and immune infiltration. 614\nTargeting angiogenesis through anti-VEGF therapies holds potential for psoriasis treatment, yet further clinical studies are required to assess their efficacy and safety. A better understanding of the angiogenesis-inflammation interplay may lead to improved therapeutic strategies and better patient outcomes.\nReproductive disorders, a broad spectrum of conditions that affect male and female reproductive health, significantly affect hormone production, gamete formation, and reproductive capacity. VEGFs play a crucial role in the development and maintenance of reproductive tissues, including follicular development, corpus luteum formation, and endometrial vascularization.\nPE is a significant hypertensive disorder arising after the 20th week of gestation, often accompanied by complications such as proteinuria, maternal organ dysfunction, or uteroplacental dysfunction. 615  A key pathological feature is the disruption of angiogenic balance due to trophoblast dysfunction and incomplete spiral artery remodeling, leading to placental hypoxia, oxidative stress, and endothelial dysfunction. 616\nEndovascular trophoblasts and decidual leukocytes regulate VEGF and PlGF production in normal pregnancies. 617  Free VEGF helps counteract endothelial shear stress and inflammation, maintaining vascular quiescence. 618  However, PE is marked by elevated plasma sVEGFR1 levels before clinical diagnosis. 619  Placental hypoxia triggers VEGF secretion, 205  which in turn increases sVEGFR1 expression, disrupting angiogenic balance. 620  Experimental models confirm that sVEGFR1 infusion induces PE-like features, including hypertension and proteinuria. 621  Similarly, adenoviral sVEGFR1 overexpression reduces VEGF and PlGF, impairing placental and fetal growth. 622  Clinically, placental sVEGFR1 levels are markedly elevated in PE, antagonizing VEGF and PlGF, which leads to systemic endothelial dysfunction. 622  The severity of PE correlates with sVEGFR1 elevation, emphasizing the critical VEGF-sVEGFR1 balance. 623  The sVEGFR1:PlGF ratio serves as a predictive marker for PE risk. 105 , 624  Additionally, the sVEGFR1-e15a variant predominates in PE circulation, highlighting its role in disease pathogenesis. 625\nTargeting VEGF and PlGF have been explored in experimental PE models. In sVEGFR1-induced PE, recombinant VEGF-A121 administration lowered blood pressure without affecting proteinuria. 626  Similarly, in the reduced uterine perfusion pressure model (widely used animal model of pre-eclampsia), rhVEGF-A121 and recombinant PlGF reduced sVEGFR1 levels, improved renal function, and mitigated oxidative stress. 627 – 629  Furthermore, adenoviral VEGF expression in hypertensive mouse models decreased blood pressure and proteinuria. 630 , 631  Notably, modified VEGF-B conjugated with an elastin-like polypeptide showed therapeutic potential without inducing angiogenesis. 632\nDespite promising results, VEGF-based therapies raise safety concerns. Excess VEGF can cause in utero mortality due to cardiac failure, and its placental transfer remains unclear. 633  The potential fetal risks highlight the need for rigorous safety evaluations before clinical application. Careful translation of VEGF-targeted therapies from preclinical models to clinical practice is essential for effective PE management.\nEndometriosis is a persistent gynecological disorder characterized by the ectopic growth of endometrial-like tissue, primarily in the pelvic region. 634  Its pathogenesis involves endocrine, inflammatory, and pro-angiogenic factors, although their precise role—whether causal or secondary—remains debated. 635  Notably, angiogenesis is a key driver of lesion progression. 636\nVEGF is regulated by multiple signaling pathways, with IL-1β playing a significant role. 637  Normal endometrial stromal cells express VEGF at baseline, but its levels rise in response to estrogen and progesterone. 637 , 638  Patients with endometriosis exhibit increased VEGF concentrations in peritoneal fluid and ectopic lesions, fostering a pro-angiogenic environment. 639 , 640  VEGFR1/VEGF signaling in macrophages and fibroblasts further promotes lesion growth and lymphangiogenesis. 641 , 642\nHypoxia plays a crucial role in endometriosis pathogenesis. HIF-1α levels are significantly elevated in ovarian endometriomas, correlating with increased VEGF mRNA expression under hypoxic conditions. 643 – 645  Additionally, VEGF-C and VEGF-D contribute to lymphangiogenesis in endometriotic lesions, as observed in patients undergoing laparoscopic surgery. 646  VEGF-C levels are consistently elevated, with recent findings linking COUP-TFII deficiency in ectopic stromal cells to excessive VEGF-C production. This imbalance enhances immune cell migration and lymphatic vessel formation, driving disease progression. 647 – 649\nElevated VEGF-A, VEGFR2, and MMP9 levels correlate with lesion development in animal models. 650  Anti-angiogenic therapies such as pazopanib and sorafenib show potential in treating endometriosis. Pazopanib reduces lesion size by at least 45%, while sorafenib more effectively modulates VEGF levels, suggesting distinct therapeutic roles. 651  Given the cyclical regeneration of the endometrium, angiogenesis should remain precisely regulated. Further research is essential to refine targeted interventions while preserving normal reproductive function.\n\nThe development of VEGF-targeting therapies has transformed treatment strategies for angiogenesis-driven diseases. Bevacizumab, a humanized anti-VEGF-A Ab, the first FDA-approved VEGF inhibitor (Table  2 ), marked a breakthrough in VEGF/VEGFR research. 652  It has shown improved survival in metastatic colorectal cancer and other malignancies. 652 , 653  Additionally, decoy receptors such as aflibercept sequester VEGF family members have further enhanced therapeutic efficacy. 654 , 655 Table 2 FDA-approved drugs targeting VEGF/VEGFR signaling Generic name Brand name Targets Indications (approval year) Mechanism of action (MOA) Reference  Mechanism of resistance Monoclonal antibody  Bevacizumab Avastin VEGF-A Colorectal cancer (2004), non-small cell lung cancer (2006), metastatic breast cancer (2008), glioblastoma (2009), renal cell carcinoma (2009), cervical cancer (2014), ovarian cancer (2018) Monoclonal antibody that binds to VEGF-A, preventing it from activating VEGF receptors on the surface of endothelial cells 709 , 710 Activation of autocrine VEGF signaling and hypoxia tolerance. Activation of other angiogenic pathways, such as FGF and PDGF, enhancement pericyte recruitment around blood vessels. Activation of autophagy and suppression of the Akt/mTOR pathway  Bevacizumab-awwb Mvasi VEGF-A Metastatic colorectal cancer, non-small cell lung cancer, glioblastoma, renal cell carcinoma, cervical cancer (2017) A biosimilar to bevacizumab, it shares the same mechanism of action. Inhibiting the growth of blood vessels that supply tumors, essentially starving the tumor and slowing its growth 711  Ramucirumab Cyramza VEGFR2 Stomach cancer (2014), Gastric cancer (2014), non-small cell lung cancer (2014), colorectal cancer (2015), hepatocellular carcinoma (2019), metastatic EGFR-mutated non-small cell lung cancer (2020) IgG1 monoclonal antibody that binds to VEGFR2, blocking VEGF ligands (VEGF-A/C/D) from activating the receptor, thereby inhibiting angiogenesis 712 – 714 Resistance through alternative angiogenic pathways  Ranibizumab Lucentis VEGF-A Age-related macular degeneration (2006), retinal vein occlusion (2010), diabetic macular edema (2012), diabetic retinopathy (2015), myopic choroidal neovascularization (2017) IgG1 antibody fragment specifically designed for ophthalmic use that binds to VEGF-A, blocking its activity in the eye 715 Not well established, possible compensatory mechanisms in the eye  Faricimab Vabysmo VEGF-A, Ang2 Age-related macular degeneration (2022), diabetic macular edema (2022), retinal vein occlusion (2023) A bi-specific antibody targeting both VEGF-A and Ang2. By inhibiting VEGF-A, it reduces abnormal blood vessel formation and leakage, while inhibition of Ang-2 stabilizes blood vessels and reduces inflammation 716 Resistance related to compensatory pathways and angiogenesis factors Recombinant fusion protein  Aflibercept Eylea VEGF-A, VEGF-B, PIGF Age-related macular degeneration (2011), diabetic macular edema (2014), retinal vein occlusion (2014), diabetic retinopathy (2019) Trapping VEGF by binding VEGF-A, VEGF-B, and PIGF, thus preventing them from activating VEGF receptors 717 Upregulation of alternative angiogenic factors, allow tumors or disease to bypass VEGF inhibition  ziv-Aflibercept Zaltrap VEGF-A, VEGF-B, PIGF Metastatic colorectal cancer (2012) Trapping VEGF by binding VEGF-A, VEGF-B, and PIGF, thus preventing them from activating VEGF receptors 718 Oligonucleotide aptamer  Pegaptanib Macugen VEGF-A165 isoform Age-related macular degeneration (2004) RNA aptamer that binds to and inhibits VEGF 719 Tyrosine kinase inhibitor  Pazopanib Votrient VEGFR1-3, KIT, PDGFRα/β Renal cell carcinoma (2009), soft tissue sarcoma (2012) Oral tyrosine kinase inhibitor that targets multiple growth factor receptors, including VEGFRs, reducing angiogenesis and tumor growth 720 , 721 Resistance because of mutations or activation of compensatory pathways  Sorafenib Nexavar VEGFR1-3, KIT, RAF, PDGFRβ, FLT3, RET Renal cell carcinoma (2005), Hepatocellular carcinoma (2007), differentiated thyroid carcinoma (2013) Oral multi-kinase inhibitor that blocks various receptors involved in tumor growth and angiogenesis 722 Resistance via secondary mutations in target receptors or alternative angiogenic pathways  Sunitinib Sutent VEGFR1-3, KIT, CSF1R, PDGFRα/β, FLT3, RET Renal cell carcinoma (2006), gastrointestinal stromal tumors (2006), pancreatic neuroendocrine tumors (2011) Oral tyrosine kinase inhibitor targeting multiple pathways involved in angiogenesis and tumor growth 723 – 726 Revival of angiogenesis through the activation of VEGF-independent pathways including PTEN downregulation and AKT/mTOR inhibition, a reduced bioavailability either through increased efflux or lysosomal sequestration  Axitinib Inlyta VEGFR1-3, KIT, PDGFRα/β Advanced renal cell carcinoma (2012) A small molecule and orally bioavailable inhibitor of the ATP-binding domains of VEGFR1,2,3 of tyrosine kinases, axitinib reduces angiogenesis, leading to slower tumor growth and potentially shrinking tumors 727 , 728 LINC00467, one of the lncRNAs found in cancers, induces axitinib resistance of HCC through miR-509-3p/PDGFRA axis  Cabozantinib Cabometyx, VEGFR2, MET, AXL, RET, FLT3, TIE2, RON, KIT Advanced renal cell carcinoma (2016), hepatocellular carcinoma (2019), differentiated thyroid cancer (2021) Inhibits angiogenesis and tumor cell growth by blocking multiple pathways that support tumor survival and progression 729 – 731 Resistance arises from the activation of alternative signaling pathways, including FGF and HGF, circulating immune cells induce resistance via increased secretion of pro-angiogenic factors Cometriq Metastatic medullary thyroid cancer (2012) A biosimilar to cabometyx, it shares the same mechanism of action  Lenvatinib Lenvima VEGFR1-3, KIT, RET, PDGFRα, FGFR1-4 Differentiated thyroid cancer (2015), advanced renal cell carcinoma (2016), hepatocellular carcinoma (2018), endometrial carcinoma (2019) Blocks various growth factor receptors to inhibit angiogenesis and cancer growth 732 , 733 Resistance develops through upregulation of compensatory angiogenic factors or activation of escape pathways by EMT, DNA damage, ferroptosis, autophagy, lncRNA, RNA modification, and cytokines  Regorafenib Stivarga VEGFR1-3, KIT, TIE2, PDGFRβ, FGFR1, RET Advanced colorectal cancer (2012), advanced gastrointestinal stromal tumor (2013), hepatocellular carcinoma (2017) A small molecule inhibitor of multi-kinase that reduces angiogenesis and tumor cell survival through broad-spectrum kinase inhibition 734 – 736 Regorafenib induces early senescence-like state as a cell death escape mechanism or activation of alternative pathways such as PI3K/AKT  Vandetanib Caprelsa VEGFR2, EGFR, RET Advanced medullary thyroid cancer (2011) An orally active, small molecule, multi-targeted tyrosine kinase inhibitor blocks binding to VEGFR2/3, EGFR, RET tyrosine kinase receptor inducing angiogenesis and cell proliferation, slowing cancer growth 737 – 739 EGFR mutations, secondary RET mutations, or upregulation of MET  Ponatinib Iclusig VEGFR, PDGFR, EPH, FGFR, BCR-ABL1, SRC, RET, KIT Leukemia (2012), resistant or intolerant chronic-phase chronic myeloid leukemia (2020), Philadelphia chromosome+ acute lymphoblastic leukemia (2024) Tyrosine kinase inhibitor that targets BCR-ABL1 including a tough-to-treat mutant form (T315I) resisting many other drugs. In addition to BCR-ABL1, by inhibiting VEGFR, FGFR, PDGFR, KIT, and FLT3, it can slow down cancer growth, reduce blood supply to the tumor and help kill cancer cells 740 , 741 Resistance occurs through additional mutations in BCR-ABL1 or activation of alternative pathways such as PI3K/AKT  Apatinib Aitan VEGFR2, PDGFRβ, SRC, KIT, RET Advanced gastric cancer (2014) Small-molecule tyrosine kinase inhibitor that primarily targets VEGFR2. It blocks the signaling of VEGFR2, effectively reduces the supply of oxygen and nutrient to the cancer cells by limiting the tumor’s ability to form new blood vessels 742 – 744 Upregulation of DUSP1 as a regulator of MAPK and increase of asparagine and glutamate in amino acid response pathway  Nintedanib Ofev VEGFR1-3, PDGFRα/β, FGFR1-3, FLT3 Idiopathic pulmonary fibrosis (2014), systemic sclerosis or scleroderma (2019), chronic fibrosing interstitial lung diseases (2020) Oral tyrosine kinase inhibitor that works by blocking tyrosine kinases involved in angiogenesis, fibrosis, and inflammation. 745 , 746 Resistance through ATP-binding-cassette transporter B1 (ABCB1) overexpression\nFDA-approved drugs targeting VEGF/VEGFR signaling\nRecent clinical trials continue to highlight the importance of anti-VEGF therapies. For instance, the PAOLA-1 trial ( NCT02477644 ) demonstrated that combining olaparib, a PARP (poly ADP-ribose polymerase) inhibitor targeting DNA damage repair, with bevacizumab provides a significant survival benefit in ovarian cancer patients with homologous recombination deficiency-positive tumors. 656  Similarly, the BEACON CRC trial ( NCT02928224 ) showed that the combination of encorafenib (a BRAF inhibitor specifically targeting the BRAF V600E mutation), cetuximab (an anti-EGFR antibody), and bevacizumab substantially improves overall survival in BRAF-mutated metastatic colorectal cancer. 657  Likewise, the RELAY study ( NCT02411448 ) demonstrated that ramucirumab (anti-VEGFR2 Ab) plus erlotinib (EGFR TKI) significantly improved progression-free survival in EGFR-mutated metastatic non-small cell lung cancer (NSCLC), regardless of baseline mutations or resistance-associated alterations. 658  Liquid biopsy revealed worse outcomes in patients with detectable circulating EGFR mutations, but VEGFR2 inhibition still provided benefits, supporting its role in overcoming EGFR-TKI resistance. The VEGFR inhibition has also demonstrated strong clinical benefits, particularly in HCC. The REACH-2 trial ( NCT02435433 ) validated that ramucirumab provides significant survival benefits in patients with high levels of alpha-fetoprotein, a biomarker commonly used in HCC. 659  Furthermore, combining VEGF inhibition with immune checkpoint and epigenetic regulators has emerged as a promising strategy to enhance VEGF-targeted therapy, potentially offering synergistic benefits. 660  The CAPability-01 trial ( NCT04724239 ) showed that addition of bevacizumab to sintilimab (anti-PD-1 Ab) and chidamide (histone deacetylase inhibitor) significantly improved survival and response rates in microsatellite (MSS)/proficient mismatch repair (pMMR) colorectal cancer, further supporting the rationale for combinatorial treatment strategies.\nIn ophthalmology, novel anti-VEGF approaches are redefining treatment paradigms. Smaller molecules designed for rapid ocular penetration have revolutionized AMD management. Ranibizumab, a humanized anti-VEGF-A Ab fragment, and brolucizumab, a single-chain anti-VEGF-A Ab, continue to improve retinal disease outcomes. 661 , 662  The NORSE-EIGHT clinical trial validated ranibizumab’s superior efficacy over bevacizumab in improving best-corrected visual acuity. 663  Notably, bevacizumab, under the brand name LYTENAVA™, has received regulatory approval for wet AMD treatment in the EU and UK. 664\nCollectively, these advancements in anti-VEGF/VEGFR therapies reinforce their integral role across oncology and ophthalmology. As combination approaches and biomarker-driven treatments continue to emerge, optimizing dosing strategies and overcoming resistance remain key priorities in the field.\nIdentifying biomarkers for VEGF/VEGFR activity is critical for optimizing therapy and predicting patient outcomes. Circulating VEGF levels, sVEGFRs, and Ang2 are commonly studied biomarkers. Elevated VEGF levels correlate with poor prognosis in cancers such as breast and lungs, 665  whereas sVEGFR1 has been linked to pre-eclampsia and various cancers. Ang2 complements VEGF as a marker of vascular instability and disease severity. 666  Additionally, epigenetic markers such as DNA methylation and circulating miRNAs provide minimally invasive tools for monitoring pathway activity. 667 , 668\nAdvanced imaging techniques, including VEGF-specific PET tracers, enable real-time assessment of VEGF pathway activity, enhancing treatment precision. 669  Additionally, transcriptomic and proteomic analyses have identified unique biomarker signatures, establishing a foundation for personalized therapy. Ongoing research continues to explore novel biomarkers, aiming to refine therapeutic strategies and improve patient outcomes. Furthermore, microvessel density (MVD) in tumor tissues indirectly reflects VEGF activity and correlates with poor outcomes in cancers such as breast and colorectal cancer. 670 , 671  Circulating endothelial progenitor cells (EPCs) also serve as indicators of vascular repair and VEGF activity, with reduced EPC levels linked to impaired angiogenesis in cardiovascular diseases. 672 – 674\nThe multifaceted biology of VEGF presents challenges for anti-VEGF/VEGFR therapies. Several mechanisms contribute to their enhanced efficacy: (1) anti-angiogenesis, targeting immature and leaky tumor vasculature to inhibit growth. 7  (2) sensitization to chemotherapy, enhancing the anti-EC effects of low-dose chemotherapy by blocking EC survival. 675  (3) vessel normalization, improving blood flow and enhancing delivery of therapeutics. 351  (4) direct anti-tumor effects, interfering with tumor cell survival. 676  (5) off-tumor benefits, improving cancer-associated systemic syndromes. 677 , 678  (6) immune modulation, countering tumor immune privilege by enhancing dendritic cell (DC) differentiation. 679 , 680  (7) reduced toxicity, mitigating chemotherapy-induced adverse effects such as bone marrow suppression. 681\nResistance arises from alternative angiogenic pathways (e.g., FGF2, PDGF), vessel co-option, vasculogenic mimicry, or recruitment of myeloid-derived suppressor cells (MDSCs). 682 – 684  Moreover, tumor heterogeneity and hypoxic/inflammatory microenvironments select resistant clones, necessitating novel approaches. To tackle resistance, combination therapies are actively explored. One strategy pairs anti-VEGF agent with FGF or Ang2 inhibitors. Another integrates anti-VEGF therapies with immune checkpoint inhibitors (ICIs), such as anti-PD-1/PD-L1 therapies, where tumor vessel normalization enhances immune cell infiltration. 351  Consequently, FDA-approved regimens include atezolizumab (anti-PD-L1 Ab) plus bevacizumab for HCC, 685  pembrolizumab (anti-PD-1 Ab) plus axitinib (TKI) for renal cell carcinoma, 686  and atezolizumab (anti-PD-L1 Ab) plus bevacizumab (anti-VEGF-A Ab) with chemotherapy for NSCLC. 687  Yet, efforts persist to optimize patient selection and minimize toxicity. 688 , 689\nImportantly, the theoretical framework for combining anti-VEGF/VEGFR therapies with ICIs involves two key mechanisms: (1) immune modulation, where VEGF inhibition reduces immunosuppression and transforms tumors into a “hot” phenotype more responsive to ICIs, 690 , 691  and (2) vessel normalization, which enhances immune infiltration by improving vascular perfusion. 692  Yet, critical issues remain. Considering the anti-tumor effects observed in immunodeficient models, it remains unclear to what degree VEGF/VEGFR inhibition relies on immunomodulation. Additionally, in “non-angiogenic” tumors resistant to these therapies, 693  can the immunomodulatory benefits of combination therapy provide an advantage? While vessel normalization improves immune infiltration, excessive vascular reduction may impair it, underscoring the need to balance normalization with maintaining adequate vascular density. Moreover, unraveling the interplay between TME dynamics and VEGF signaling could unlock new strategies to overcome these limitations (Fig.  10 ). Fig. 10 Mechanisms of action of anti-VEGF/VEGFR therapies in combination therapy. In the tumor microenvironment (TME), the mechanisms of action of anti-VEGF/VEGFR therapies combined with chemotherapy or immune checkpoint inhibitors (ICIs) include reducing angiogenicity of vessels for tumor inhibition, inducing vessel normalization for better chemo-drug or immune cell delivery, directly inhibiting tumor cell proliferation, increasing anti-endothelial cell effect of chemotherapy, and modulating immune cells for better dendritic cell (DC) differentiation and T-cell activation. Outside the TME, the anti-VEGF/VEGFR therapies may reduce chemotoxicity and improve cancer-associated systemic syndromes, thereby improving therapeutic efficacy. Created in BioRendender.com\nMechanisms of action of anti-VEGF/VEGFR therapies in combination therapy. In the tumor microenvironment (TME), the mechanisms of action of anti-VEGF/VEGFR therapies combined with chemotherapy or immune checkpoint inhibitors (ICIs) include reducing angiogenicity of vessels for tumor inhibition, inducing vessel normalization for better chemo-drug or immune cell delivery, directly inhibiting tumor cell proliferation, increasing anti-endothelial cell effect of chemotherapy, and modulating immune cells for better dendritic cell (DC) differentiation and T-cell activation. Outside the TME, the anti-VEGF/VEGFR therapies may reduce chemotoxicity and improve cancer-associated systemic syndromes, thereby improving therapeutic efficacy. Created in BioRendender.com\nTo address these challenges, proteolysis-targeting chimeras (PROTACs) have emerged as a novel modality. Additionally, antibody-drug conjugates (ADC) targeting VEGF-VEGFR pathways represent another promising modality, combining precise targeting of angiogenic signaling with the delivery of cytotoxic agents to inhibit tumor growth and angiogenesis. 694  Concurrently, artificial intelligence (AI) is revolutionizing drug discovery by identifying dual-target VEGFR inhibitors with greater precision. 424  Coupled with genomic and transcriptomic profiling, AI provides critical insights into oncogenic pathways, enabling biomarker development and rational combination therapies. Despite progress, toxicity and biomarker gaps hinder adoption, necessitating refined patient selection. These advances signal a shift toward personalized, multi-modal approaches, tackling resistance and expanding therapeutic horizons.\n\nThe VEGF/VEGFR signaling pathway remains central to angiogenesis, lymphangiogenesis, and vascular remodeling, affecting diverse physiological and pathological processes. Over the past few decades, the development of VEGF-targeted therapies has transformed the treatment landscape for cancer, ocular diseases, and inflammatory disorders. Monoclonal antibodies, tyrosine kinase inhibitors, and VEGF-trap fusion proteins have significantly improved patient survival and quality of life. However, therapeutic resistance, systemic toxicities, and limitations in predictive biomarkers continue to present challenges.\nOne of the major challenges in anti-VEGF therapy is the emergence of compensatory pro-angiogenic pathways. The upregulation of FGF2, Ang, and the induction of vasculogenic mimicry - where tumor cells adopt endothelial-like characteristics - contribute to tumor escape from VEGF inhibition. Similarly, VEGF-C and VEGF-D-mediated lymphangiogenesis facilitates cancer progression and metastasis, emphasizing the need for combinatorial targeting strategies. In wet AMD and DR, VEGF-C/D upregulation has been implicated in resistance to anti-VEGF-A monotherapies. The ongoing development of VEGF-C/D inhibitors, such as OPT-302, 529  represents a promising approach to overcoming this resistance.\nThe role of VEGFs extends beyond angiogenesis, impacting fibrosis, metabolic syndromes, and neurodegeneration. VEGF-B, traditionally considered minimally angiogenic, has emerged as a critical player in neuroprotection, with potential implications for neurodegenerative disorders such as Alzheimer’s disease. 695 , 696  In addition, VEGF signaling contributes to endothelial dysfunction in diabetes and cardiovascular disease, highlighting its potential as a therapeutic target in metabolic disorders. Moreover, recent findings show VEGF-B inhibits angiogenesis by suppressing FGF2/FGFR1 signaling and forming VEGFR1/FGFR1 complexes that block ERK activation. 137  This raises concerns about therapies including aflibercept, which targets both VEGF-A and VEGF-B, as blocking VEGF-B may disrupt its regulatory function in pathological angiogenesis.\nAdvancements in precision medicine have introduced new opportunities for optimizing VEGF-targeted therapies. AI-driven biomarker identification and spatial transcriptomics hold promises for improving patient stratification and treatment personalization. However, the standardization of predictive biomarkers remains a challenge due to tumor heterogeneity and the dynamic nature of VEGF signaling. For instance, VEGF-A+ fibroblasts have been proposed as a biomarker in HCC, 697  yet their clinical validation across diverse patient cohorts is still lacking. Future efforts should focus on refining biomarker discovery approaches to enhance their clinical utility. Additionally, identifying non-invasive biomarkers, such as circulating exosomal VEGF or imaging-based vascular signatures, could improve real-time monitoring of treatment responses.\nTo address systemic toxicities associated with VEGF inhibition, emerging drug modalities offer alternative solutions. Long-acting gene therapy, nanoparticle-encapsulated siRNA, and CRISPR-based VEGF modulation represent promising strategies to mitigate hypertension, proteinuria, and impaired wound healing. Additionally, newer modalities such as bi-specific antibodies (e.g., faricimab, targeting both VEGF and Ang2) and VEGF-trap fusion proteins (e.g., conbercept in ocular diseases) provide enhanced specificity and efficacy. Recent advances in ADCs and PROTACs have further expanded the landscape of VEGF-related interventions, enabling more selective and potent therapeutic strategies. These approaches warrant further clinical exploration to determine their safety, efficacy, and long-term benefits.\nFurthermore, research into the interplay between VEGF and other angiogenic factors is essential for refining combination therapies. Dual inhibition of VEGF and HIF-1α has shown promise in overcoming hypoxia-induced resistance, while VEGF and PDGFRβ co-targeting strategies aim to enhance vascular normalization and drug delivery in tumors. 698 , 699  Additionally, integrating VEGF-targeted approaches with ICIs continues to gain momentum, particularly in cancers with immunosuppressive microenvironments. A deeper mechanistic understanding of these interactions will be critical for optimizing treatment regimens and improving patient outcomes.\nFuture research should also explore the impact of VEGF inhibition in aging and regenerative medicine. As the aging population grows, understanding the consequences of long-term VEGF suppression on vascular integrity, wound healing, and neurovascular health is crucial. VEGF plays a pivotal role in tissue repair and homeostasis, and prolonged inhibition may contribute to frailty, cognitive decline, and impaired organ regeneration. Balancing VEGF suppression for disease treatment while preserving its physiological functions will be essential for minimizing unintended side effects.\nAdditionally, continued investigation into the role of VEGFs in inflammatory and autoimmune diseases is warranted. VEGF has been implicated in conditions such as RA, psoriasis, and multiple sclerosis, where its modulation could provide therapeutic benefits. Exploring VEGF-targeting strategies in these diseases could expand the clinical applications of anti-angiogenic therapies beyond oncology and ophthalmology. Furthermore, understanding the interplay between VEGF signaling and the gut microbiome may offer novel insights into angiogenesis-related metabolic disorders, paving the way for innovative treatment approaches.\nIn conclusion, VEGF-targeted therapies have fundamentally reshaped disease management. However, their future success depends on overcoming resistance, enhancing treatment precision, and exploring novel applications beyond angiogenesis. Continued investigation into VEGF signaling complexity, combined with cutting-edge technological innovations, will be essential in maintaining VEGF inhibitors as a cornerstone of therapeutic intervention. As these efforts progress, VEGF-targeted therapies will continue to hold transformative potential across cancer, ocular diseases, and other fields, offering new hope to patients.","source_license":"CC-BY-4.0","license_restricted":false}