Cgas–Sting
The role of the cGAS–STING signaling pathway in various diseases has been extensively studied. In this section, we summarize the role of the cGAS–STING signaling pathway in neurological disorders, psychiatric disorders, digestive diseases, endocrine system diseases, circulatory system diseases, blood disorders, respiratory system diseases, urinary system diseases, reproductive system diseases, autoimmune diseases, pathogen infection, aging, and other diseases [Figure 3 ].
Human diseases associated with the cGAS–STING signaling pathway. The cGAS–STING signaling pathway is implicated in systemic disease processes, including autoimmunity, aging, infection, and cancer, as well as organ-specific disorders affecting the lungs, ENT and eyes, liver, pancreas, blood, neuropsychiatric system, endocrine system, heart, kidneys, gut, and reproductive system. The crucial upstream or downstream molecules are also shown. AD: Alzheimer’s disease; ALS: Amyotrophic lateral sclerosis; AGS: Aicardi–Goutières syndrome; A-T: Ataxia–telangiectasia; AKI: Acute kidney injury; CCFs: Cytoplasmic chromatin fragments; cGAS: Cyclic GMP-AMP synthase; CKD: Chronic kidney disease; CRS: Chronic rhinosinusitis; CXCL10: C-X-C motif chemokine ligand 10; eIF2α: Eukaryotic initiation factor 2α; ENT: Ear, nose, throat; HBV: Hepatitis B virus; HD: Huntington’s disease; HF: Heart failure; IBD: Inflammatory bowel disease; IFN: Interferon; IRF3: Interferon regulatory factor 3; IS: Ischemic stroke; MASLD: Metabolic dysfunction-associated steatotic liver disease; MI: Myocardial infarction; MM: Multiple myeloma; NF-κB: Nuclear factor kappa B; NLRP3: NOD-like receptor protein 3; PD: Parkinson’s disease; RA: Rheumatoid arthritis; ROS: Reactive oxygen species; SASP: Senescence-associated secretory phenotype; SLE: Systemic lupus erythematosus; STING: Stimulator of interferon genes; TBI: Traumatic brain injury; TBK1: Tank binding kinase 1. ↑: Increase; ↓: Decrease. Created with BioRender.com.
The cGAS–STING signaling pathway can be activated in the nervous system and is implicated in various neurological diseases [Figure 4 ]. Below, we summarize the mechanisms of the cGAS–STING signaling pathway in different neurological disorders.
The cGAS–STING signaling pathway drives neurological disease progression via multiple mechanisms. Activation of the cGAS–STING signaling pathway contributes to the pathogenesis of multiple neurological disorders, including AD, PD, HD, A-T, ALS, TBI, IS, and AGS. Mitochondrial dysfunction, DNA damage, vesicular transport defects, and acute injury collectively activate the cGAS–STING signaling pathway, subsequently inducing type I interferon responses and inflammatory cascade activation. AD: Alzheimer’s disease; AGS: Aicardi–Goutières syndrome; A-T: Ataxia–telangiectasia; ALS: Amyotrophic lateral sclerosis; cGAMP: Cyclic GMP-AMP; cGAS: Cyclic GMP-AMP synthase; HD: Huntington’s disease; IRF: Interferon regulatory factor; IS: Ischemic stroke; PD: Parkinson’s disease; STING: Stimulator of interferon genes; TBI: Traumatic brain injury; TBK1: Tank binding kinase 1. Created with BioRender.com.
Mitochondrial dysfunction is a key driver of STING activation in the nervous system. Defects in mitophagy, which clears damaged mitochondria and protein aggregates, lead to the release of mtDNA into the cytoplasm [Figure 4 ]. mtDNA is recognized by the cGAS–STING signaling pathway, initiating downstream immune responses. [ 38 ] For example, in Parkinson’s disease (PD), mutations in the Pink1 and Parkin genes impair mitophagy, causing the accumulation of damaged mitochondria and subsequent mtDNA release. [ 39 , 40 ] Similarly, protein aggregates, such as mutant TAR DNA-binding protein 43 and superoxide dismutase 1, which are associated with amyotrophic lateral sclerosis (ALS), disrupt mitochondrial membrane integrity, promote mtDNA leakage, and activate the cGAS–STING signaling pathway. [ 41 ] Protein aggregates characteristic of neurodegenerative diseases exacerbate mitochondrial dysfunction and lead to the release of mtDNA. In Alzheimer’s disease (AD), tau protein impairs mitochondrial membrane integrity and facilitates mtDNA leakage and subsequent STING activation. [ 42 , 43 ] Similarly, in Huntington’s disease (HD), mutant huntingtin aggregates increase mtDNA release and cGAS-mediated inflammation in the striatum and cortex. [ 44 ] Polyglutamine-binding protein 1 can act as a direct link between protein aggregates and STING activation. Polyglutamine-binding protein 1 recognizes polymerized tau in AD or mutant huntingtin in HDs, subsequently recruiting and activating the cGAS–STING signaling pathway. [ 38 , 45 ] The above data highlights the complexity of protein aggregates in STING-driven neuropathology.
Cytoplasmic leakage of nuclear DNA fragments resulting from genomic instability is another significant activator of STING [ 38 ] [Figure 4 ]. Disorders such as ataxia-telangiectasia (A-T) are classic examples of this mechanism. A-T is caused by mutations in the A-T-mutated gene, a key regulator of the DNA damage response. The loss of A-T-mutated function leads to the accumulation of dsDNA breaks and genomic instability. In this context, fragmented DNA escapes into the cytoplasm, triggering the cGAS–STING signaling pathway. [ 46 ] Evidence from human induced pluripotent stem cell (iPSC)-derived cortical organoids from A-T patients shows that cytoplasmic genomic DNA activates the STING signaling pathway. In contrast, treatment with STING inhibitors reduces both inflammation and neurodegeneration. [ 47 ] A similar phenomenon is observed in AD, where brain tissue presents elevated levels of dsDNA breaks and impaired DNA repair capacity. These abnormalities are particularly pronounced in the cortex and hippocampus. In AD mouse models (e.g., App / Ps1 transgenic mice), the levels of phosphorylated STING and downstream inflammatory markers (e.g., IFN-stimulated genes) are significantly increased, highlighting the involvement of STING in AD pathology. [ 48 ] Moreover, markers of STING activation, including phosphorylated TBK1, IRF3, and IRF7, are elevated in AD models and patient samples [ 49 , 50 ] [Figure 4 ]. In addition, in HD, cytoplasmic genomic DNA accumulation due to DNA repair deficits activates the cGAS–STING signaling pathway, contributing to neuroinflammation and neuronal loss. [ 38 ]
Proper vesicle trafficking is essential for maintaining STING homeostasis [Figure 4 ]. Disruptions in this process delay STING degradation, leading to its chronic activation. For example, mutations in Vps13c , which are associated with familial PD, impair lysosomal lipid homeostasis and result in prolonged STING signaling. [ 51 ] Similarly, C9orf72 mutations, which are commonly observed in individuals with ALS and frontotemporal dementia, can disrupt autophagy–lysosome signaling pathways and cause hyperactivation of STING. [ 52 , 53 ]
Acute injuries, such as traumatic brain injury (TBI) or ischemic stroke (IS), also trigger cGAS–STING signaling pathway activation [Figure 4 ]. These injuries induce the release of mtDNA into the cytoplasm, where it activates the signaling pathway. Elevated levels of cytoplasmic mtDNA have been observed in animal models of TBI and stroke, further supporting the involvement of STING in injury-induced neuroinflammation. [ 54 – 56 ]
Under certain genetic conditions, such as Aicardi–Goutières syndrome (AGS), the activation of retrotransposons, such as long interspersed nuclear element-1 (LINE-1), contributes to STING activation. Nucleation mutations accumulating retroelement-derived DNA can activate the cGAS–STING signaling pathway, eventually leading to inflammation and neurological symptoms in AGS patients. [ 57 , 58 ]
The activation of the STING signaling pathway in the nervous system is a common feature in many neurological diseases. The STING signaling pathway is driven by diverse mechanisms, including mitochondrial dysfunction, DNA damage, protein aggregation, and defects in cellular trafficking [Figure 4 ]. Understanding these signaling pathways provides critical insights into how STING contributes to neuroinflammation and offers potential therapeutic avenues for targeting STING in these disorders.
Psychiatric disorders represent a major global health burden, with an estimated 970 million individuals affected worldwide. [ 59 , 60 ] Increasing evidence implicates the cGAS–STING signaling pathway in the pathogenesis of various psychiatric conditions, including depression, anxiety, and schizophrenia [ 61 – 64 ] [Figure 3 ]. The cGAS–STING signaling pathway has emerged as a key mediator of neuroinflammation, influencing microglial activation and neuronal function.
Chronic stress induces depressive- and anxiety-like behaviors in murine models, accompanied by microglial activation and upregulation of the cGAS–STING signaling pathway in the basolateral amygdala [Figure 3 ]. [ 61 , 62 ] Furthermore, prenatal amoxicillin exposure disrupts the gut microbiota composition in offspring, impairing ARF1 N-myristoylation and subsequent STING degradation. This dysregulation leads to autophagic dysfunction, M1 microglial polarization, and depressive-like behaviors. [ 63 ] In schizophrenia, innate immune hyperactivation and neuronal apoptosis are frequently observed. The human endogenous retrovirus W envelope glycoprotein triggers an antiviral innate immune response via the linc01930–cGAS–STING axis, promoting neuronal apoptosis and contributing to disease pathology [ 64 ] [Figure 3 ].
Pharmacological inhibition of STING alleviates anxiety-like behaviors and suppresses microglial activation in chronic ethanol-exposed mice. [ 65 ] Similarly, betaine attenuates DNA damage and mitochondrial dysfunction, blocking the cGAS–STING signaling pathway and restoring hippocampal neurogenesis in dextran sulfate sodium-treated mice, thereby mitigating depressive- and anxiety-like behaviors. [ 66 ] In TBI models, STING-dependent interventions that reduce IFN-I signaling prevent prolonged microglial activation and cognitive impairment [ 67 , 68 ] [Figure 3 ]. In addition, electroacupuncture exerts antidepressant effects in mice, likely through inhibition of the cGAS–STING–NOD-like receptor protein 3 (NLRP3) axis [ 69 ] [Figure 3 ]. Interestingly, STING activation can also exert neuroprotective effects. The activated STING signaling pathway can increase microglial phagocytosis and suppress the release of the proinflammatory cytokines tumor necrosis factor (TNF)-α, interleukin (IL)-6, and IL-1β in the brains of restraint stress mice, which further leads to antidepressant effects. [ 62 ]
In summary, the current findings strongly support the involvement of the cGAS–STING signaling pathway in psychiatric disorders. However, the precise mechanisms remain unclear, with evidence suggesting that both proinflammatory and anti-inflammatory roles depend on the pathological context. Given its regulatory effects on neuroinflammation, microglial activation, and neuronal survival, STING represents a promising therapeutic target for psychiatric disorders.
EC ranks as the seventh most prevalent malignancy globally, with over 470,000 newly diagnosed cases annually. [ 70 ] Histologically, EC is classified into two types: esophageal adenocarcinoma (EAC) and esophageal squamous cell carcinoma (ESCC). Among these, ESCC is the sixth leading cause of cancer-related mortality worldwide. [ 71 ] In ESCC, increased levels of cytosolic dsDNA have been shown to activate the cGAS–STING signaling pathway. However, the role of this signaling pathway in ESCC remains a subject of debate. [ 72 , 73 ]
The p63 isoform acts as an oncogene in EC. Its depletion reduces cancer cell viability and increases STING expression, implicating the cGAS–STING axis in anti-tumor responses. [ 72 ] Stress-induced mtDNA release via mitochondrial transcription factor A (TFAM) silencing activates cGAS–STING signaling, enhancing innate immunity. [ 74 ] Conversely, reduced TFAM can activate this pathway, promoting autophagy and EC growth. [ 73 ] Thus, cGAS–STING signaling exhibits a paradoxical role in EC development.
Radiotherapy for ESCC triggers DNA damage, cytokine release, inflammation, and tumor microenvironment (TME) alterations that can suppress immunity and promote invasion/metastasis. [ 71 ] The intrinsic tumor cGAS–STING expression is crucial for radiation-induced immune cell activation within the TME, yet also recruits pro-tumorigenic M2 macrophages in ESCC. [ 75 ] Mn 2+ activates cGAS–STING, enhancing anti-tumor immunity, [ 76 ] whereas MnSe 2 -lipid enhances ESCC radiosensitivity by stimulating cGAS–STING-mediated immunity and chemodynamic therapy. [ 77 ] Therefore, optimizing ESCC chemoradiotherapy requires maximizing the therapeutic benefits of cGAS–STING while minimizing its detrimental effects.
GC is the fifth most prevalent malignancy globally and the third leading cause of cancer-related mortality, and its risk sharply increases among men after the age of 40 years, leading to a significant disparity in burden between men and women. [ 78 ] In human GC tissues, STING expression is significantly reduced in a tumor node metastasis stage-dependent manner, and Sting knockdown enhances GC cell survival. [ 79 ] In HER2-positive GC, HER2 signaling may inhibit STING activation in tumor cells, thereby suppressing immune cell activation in the TME. [ 80 ] The accumulation of cytosolic DNA activates the STING signaling pathway in GC. [ 81 ] A high level of STING in tumor-associated macrophages predicts poor survival of GC patients. Both Sting knockdown and activation by 2′3′-c-GAMP promote the differentiation of tumor-associated macrophages into a proinflammatory subtype and induce the apoptosis of GC cells via the IL6R–JAK–IL24 signaling pathway. [ 82 ] When activated in different cells, the cGAS–STING signaling pathway may promote or suppress the development of gastroesophageal cancers.
In summary, the cGAS–STING signaling pathway has dual roles in gastroesophageal cancers. When activated by cytosolic DNA, the cGAS–STING signaling pathway elicits innate immune responses and exerts anti-tumor effects. However, its activation can also promote tumor growth. The role of this signaling pathway depends on the cell type activated (cancer or immune cells), the disease stage, and the treatment context, such as chemoradiotherapy.
IBD, encompassing ulcerative colitis (UC), Crohn’s disease (CD), and unclassified IBD (IBDU), is a chronic relapsing gastrointestinal disorder. The cGAS–STING pathway is activated in the colonic mucosa of UC patients [ 83 ] [Figure 5 ]. Myeloid-specific Sting deletion in mice inhibits macrophage maturation, dendritic cell (DC) activation, and proinflammatory Th1/Th17 cell proliferation, protecting against acute/chronic colitis and colitis-associated carcinoma [ 84 ] [Figure 5 ]. In IBD patients, reduced DEAH-box helicase 9 expression triggers genomic instability and cGAS–STING-driven inflammation, impairing intestinal stem cell function and contributing to pathogenesis. [ 85 ] Heterochromatin protein 1γ (HP1γ) maintains nuclear integrity and genomic stability in enterocytes; its dysfunction enhances cGAS–STING activity, promoting intestinal inflammation. [ 16 ] Exosomal dsDNA exacerbates CD by activating cGAS–STING, correlated with disease severity, [ 86 ] whereas mtDNA from damaged epithelial cells activates STING in DCs, upregulating IL-12 family cytokines [ 84 ] [Figure 5 ]. Conversely, Sting deletion in established tumors promotes immunosuppression and tumor growth. [ 84 ] These findings underscore the role of STING in colitis pathogenesis and treatment.
The cGAS–STING signaling pathway is crucial in intestinal disease pathogenesis. The cGAS–STING signaling pathway regulates intestinal homeostasis by maintaining a delicate balance between microbial surveillance and inflammatory responses, while its dysregulation contributes to the pathogenesis of IBD and CRC. Anti-: Inhibit disease progression; cGAS: Cyclic GMP-AMP synthase; CRC: Colorectal cancer; IBD: Inflammatory bowel disease; IgA: Immunoglobulin A; Pro-: Promote disease progression; SENP3: SUMO-specific protease 3; STING: Stimulator of interferon genes; Th: T helper cell. Created with BioRender.com.
Emerging evidence indicates that the STING signaling pathway possesses anti-inflammatory properties, suggesting the potential of STING agonists as therapeutic agents for IBD. [ 87 , 88 ] Specifically, STING attenuates the pathogenic effects of Th1 cells in colitis by increasing the expression of the anti-inflammatory cytokine IL-10. [ 87 ] Furthermore, STING1 can translocate to the nucleus and activate the aryl hydrocarbon receptor; the interaction between nuclear STING1 and the aryl hydrocarbon receptor protects against intestinal pathology and dysbiosis in mice. [ 88 ] Therefore, further research is warranted to clarify the dual roles of the cGAS–STING signaling pathway in modulating both proinflammatory and anti-inflammatory responses in IBD.
IBD is characterized by an aberrant immune response to the intestinal microbiota. Dysbiosis exacerbates colitis by promoting the ubiquitination and accumulation of STING in myeloid cells [ 89 ] [Figure 5 ]. Gut microbiota-derived extracellular vesicles induce epithelial damage and inflammatory responses in IBD via the cGAS–STING signaling pathway. [ 90 ] STING enhances intestinal immunoglobulin A production by modulating acetate-producing bacteria. [ 91 ] Fecal microbiota transplantation effectively treats dextran sulfate sodium-induced colitis in a STING-dependent manner. Fecal microbiota transplantation regulates the differentiation of intestinal Th17 cells, macrophages, splenic Th1 and Th2 cells, and mesenteric lymph node Th1 cells through the STING signaling pathway [Figure 5 ]. This regulation leads to the downregulation of colonic M1/M2 and splenic Th1/Th2 cell ratios, which are essential for restoring immune homeostasis in the inflamed intestinal mucosa. [ 92 ] Consequently, restoring dysbiosis via STING-dependent mechanisms represents a promising therapeutic strategy for IBD.
CRC is the third most commonly diagnosed cancer worldwide. Among the digestive system cancers, colorectal cancer had the most severe burden in terms of both incidence and mortality. [ 93 ] The cGAS–STING signaling pathway has been recognized as crucial for preventing tumorigenesis and enhancing the efficacy of various antitumor therapies, including immune checkpoint therapy, chemotherapy, and radiotherapy. [ 84 , 94 ]
Sting -deficient mice exhibit increased susceptibility to colitis-associated carcinoma due to reduced pyroptosis of tumor cells [ 95 ] [Figure 5 ]. In addition, STING promotes the production of IL-18 and IL-1β by macrophages via the NLRP3 inflammasome, thereby optimizing the antitumor function of natural killer (NK) cells [ 96 ] [Figure 5 ]. DCs are critical for initiating antitumor immune responses. DC-derived reactive oxygen species (ROS) trigger SUMO-specific protease 3 accumulation and promote STING-dependent cytosolic DNA sensing, thereby enhancing DC antitumor functions in the TME [ 94 ] [Figure 5 ]. Barrier-to-autointegration factor 1 (BANF1) naturally inhibits cGAS activity on genomic self-DNA. Banf1 knockout activates antitumor immune responses mediated by the cGAS–STING signaling pathway. [ 97 ] Collectively, activating the cGAS–STING signaling pathway is essential for augmenting the antitumor immune response of macrophages and DCs in CRC [Figure 5 ].
Emerging evidence underscores the critical role of the microbiota in modulating responses to cancer therapies. [ 98 – 100 ] Specifically, the gut microbiota has been shown to colonize tumor sites and enhance immunotherapy efficacy through STING signaling. [ 99 ] The gut microbiota-associated metabolite methylglyoxal amplifies radiotherapy-induced activation of the cGAS–STING signaling pathway by increasing the number of dsDNA breaks. [ 101 ] Furthermore, Fusobacterium nucleatum has been found to enhance the antitumor response to programmed cell death protein 1 (PD-1)/ligand 1 (PD-L1) checkpoint blockade by activating STING signaling, which induces PD-L1 expression and promotes the accumulation of IFN-γ + CD8 + tumor-infiltrating lymphocytes. [ 98 ] Consistently, oral administration of Lactobacillus rhamnosus GG has been demonstrated to augment the antitumor effects of anti-PD-1 immunotherapy by increasing the infiltration of DCs and T cells into tumors. In DCs, Lactobacillus rhamnosus GG triggers IFN-β production through the cGAS–STING–TBK1–IRF7 signaling axis. [ 100 ]
In summary, the cGAS–STING signaling pathway has dual effects on intestinal diseases. In IBD, it can be activated by host DNA damage or dysbiosis, driving inflammation. However, it also has anti-inflammatory and barrier-protective effects through IL-10 induction, microbiota metabolism modulation, and increased IgA production. In CRC, the cGAS–STING signaling pathway can suppress tumorigenesis but may also be exploited by the TME to mediate immunosuppression. Microbial modulation could serve as a complementary strategy for IBD and cancer therapeutics.
Hepatitis B virus (HBV) is an enveloped, partially dsDNA virus that preferentially replicates within hepatocytes. The ability of HBV to evade the host immune response is a pivotal factor in the pathogenesis of hepatitis B. [ 102 , 103 ] Upon infection, the HBV genomic DNA within the nucleocapsid is transported into the nucleus of hepatocytes and converted into covalently closed circular DNA (cccDNA), which serves as the transcriptional template for viral RNA synthesis [Figure 6 ]. These HBV RNAs fail to stimulate an immune response in immunocompetent myeloid cells. In contrast, HBV DNA from viral particles and replication intermediates can be detected via the cGAS–STING signaling pathway, thereby triggering an immune response [ 104 ] [Figure 6 ]. Notably, enhanced disassembly of mature nucleocapsids in the cytoplasm promotes cccDNA amplification without activating the cGAS–STING-mediated innate immune response in hepatocytes. [ 105 ] The encapsidation of HBV DNA by the viral capsid, combined with the relatively low expression levels of cGAS and STING in hepatocytes, likely facilitates immune evasion by HBV during infection. [ 103 , 104 ] Agonist-induced STING activation in macrophages inhibits cccDNA-mediated transcription and HBV replication in hepatocytes, thereby mitigating liver injury and fibrosis in chronic cccDNA mouse models [ 8 ] [Figure 6 ]. HBV infection elevates the expression of histone acetyltransferase 1. HBV-elevated histone acetyltransferase 1 regulates the cGAS–STING signaling pathway and IFN-I signaling through acetylation of histones H4K5 and H4K12, thereby modulating viral innate immune evasion. [ 102 ] Thus, targeting the cGAS–STING signaling pathway may provide a potential therapeutic strategy to enhance the host immune response against HBV [Figure 6 ].
The cGAS–STING signaling pathway exhibits diverse roles across liver diseases. The cGAS–STING signaling pathway plays complicated roles in liver diseases. It inhibits HBV infection in hepatitis B patients, while its pro-inflammatory effects promote the development and progression of MASLD and liver fibrosis. In hepatocellular carcinoma, the cGAS–STING signaling pathway demonstrates a dual role, exerting both pro-tumorigenic and anti-tumorigenic effects. Anti-: Inhibit disease progression; cGAS: Cyclic GMP-AMP synthase; cccDNA: Covalently closed circular DNA; dsDNA: Double-stranded DNA; HBV: Hepatitis B virus; HCC: Hepatocellular carcinoma; HSC: Hepatic stellate cell; IFN: Interferon; IL: Interleukin; LSEC: Liver sinusoidal endothelial cell; MASH: Metabolic dysfunction-associated steatohepatitis; MASLD: Metabolic dysfunction-associated steatotic liver disease; PD-L1: Programmed cell death protein 1 ligand; Pro-: Promote disease progression; STING: Stimulator of interferon genes. Created with BioRender.com.
MASLD encompasses a spectrum of pathological states, ranging from simple steatosis (MASL) to metabolic dysfunction-associated steatohepatitis (MASH) and subsequent liver fibrosis. Emerging evidence highlights the cGAS–STING signaling pathway as a pivotal factor in the pathogenesis of MASLD [ 25 , 36 , 106 ] [Figure 6 ]. Specifically, cGAS can recognize aberrant DNA and activate STING to trigger immune responses that influence lipid metabolism and inflammatory pathways, leading to hepatic fat accumulation and hepatocyte injury. [ 107 ]
MASL is characterized by hepatic steatosis and lipotoxicity without significant inflammation or fibrosis. The STING–IRF3 axis is implicated in hepatocyte injury and dysfunction through disruptions in glucose and lipid metabolism, as well as the induction of inflammation and apoptosis [ 25 ] [Figure 6 ]. STING expression is elevated in MASL livers, promoting lipolysis in adipocytes and lipid uptake and synthesis in hepatocytes [ 34 , 107 ] [Figure 6 ]. Macrophage-specific Scap deletion attenuates Paigen diet-induced metaflammation and ectopic lipid deposition by reducing hepatic STING–NF-κB signaling pathway. [ 34 ]
MASH is a progressive form of MASLD characterized by liver steatosis, inflammation, hepatocellular damage, and varying degrees of fibrosis. The sterile inflammation mediated by the cGAS–STING signaling pathway is associated with MASH. In sterile inflammatory liver injury, impaired mitophagy in aged macrophages leads to mtDNA leakage into the cytosol, activating the STING signaling pathway [ 15 ] [Figure 6 ]. MASH patients exhibit elevated levels of ROS and mtDNA damage, [ 108 ] with mtDNA translocating to the cytoplasm to activate cGAS and immune responses. [ 109 ] Palmitic acid-induced mitochondrial damage and subsequent mtDNA leakage activate the cGAS–STING–IRF3 signaling pathway, leading to endothelial activation and inflammation [ 110 ] [Figure 6 ]. Kupffer cells and macrophages contribute to MASH by secreting proinflammatory cytokines such as transforming growth factor-β, IL-6, and TNF-α. [ 111 – 113 ] Increased STING activation in macrophages during MASH promotes a proinflammatory state, which enhances hepatic fat deposition and activates hepatic stellate cells, driving fibrosis [ 113 ] [Figure 6 ].
Liver fibrosis is a wound-healing response to chronic injury characterized by excessive accumulation of the extracellular matrix. The cGAS–STING signaling pathway activation exacerbates intrahepatic inflammation and promotes fibrosis progression. [ 114 ] In addition to the canonical cGAS–STING–TBK1–IRF3 signaling pathway, a noncanonical cGAS–STING–PERK–eIF2α signaling pathway involving cellular senescence has also been implicated in liver fibrosis pathogenesis [ 36 , 37 ] [Figure 6 ]. Cytoplasmic chromatin fragments (CCFs) from senescent cells trigger the senescence-associated secretory phenotype (SASP) via the cGAS–STING signaling pathway. [ 115 , 116 ] Moreover, activating the cGAS–STING–NLRP3 signaling pathway can accelerate liver fibrosis in a hepatocyte pyroptosis-dependent manner [ 117 ] [Figure 6 ]. These findings indicate that the cGAS–STING signaling pathway is critical in determining liver cell fate, including senescence and pyroptosis, during the progression of liver fibrosis.
Exposure to alcohol, drugs, radiation, and I/R can induce liver injury. In alcoholic liver disease (ALD), activation of the cGAS–STING signaling pathway is positively associated with the severity of ALD. The cGAS–STING signaling pathway triggers IRF3 in hepatocytes and adjacent tissues via gap junction intercellular communication, thereby exacerbating alcohol-induced liver injury. [ 118 ] Liver-specific dynamin-related protein 1 (DRP1) is an essential regulator of mitochondrial fission and is pivotal for maintaining cellular homeostasis. In alcohol-fed L-DRP1 knockout mice, the absence of DRP1 leads to increased cytosolic mtDNA levels and mitochondrial dysfunction, which subsequently activates the cGAS–STING signaling pathway and contributes to liver injury. [ 119 ] The expression of STING is upregulated in monocyte-derived macrophages and contributes to liver inflammation during I/R injury. [ 120 , 121 ]
Sting knockdown mitigates calcium-dependent macrophage caspase 1–gasdermin D-mediated I/R injury. [ 122 ] Notably, the activation of the cGAS–STING signaling pathway in liver I/R injury is caused primarily by the liberation of mtDNA rather than nuclear DNA. [ 123 ] Collectively, these findings indicate that the inhibition of STING may provide a protective effect against liver I/R injury.
HCC is the third leading cause of cancer-related mortality globally, with a 5-year relative survival rate of approximately 18%. The key risk factors for HCC include viral hepatitis, alcohol consumption, and nonalcoholic fatty liver disease. [ 124 ] The role of the cGAS–STING signaling pathway in HCC is complex and multifaceted. Most studies suggest that cGAS–STING signaling pathway activation is crucial for HCC progression and is associated with poor prognosis. [ 125 , 126 ] Specifically, mitochondrion-localized cGAS protects HCC cells from ferroptosis [Figure 6 ]. Without cGAS, tumor growth is suppressed via mitochondrial ROS accumulation and ferroptosis. [ 125 ] In addition, activation of the cGAS–STING signaling pathway induces PD-L1 expression via the STING–IRF3–Signal transducer and activator of transcription 1 (STAT1) signaling pathway, leading to immunosuppression and facilitating tumorigenesis and tumor progression [ 9 ] [Figure 6 ]. Conversely, cGAS is significantly downregulated in clinical HCC tissues, and its dysregulation contributes to HCC progression through cGAMP synthase. [ 127 ] In addition, activation of the cGAS–STING signaling pathway enhances immune cell infiltration in HCC tissues, thereby exerting an antitumor effect [ 128 , 129 ] [Figure 6 ].
In summary, the cGAS–STING signaling pathway plays a dual, context-dependent role in hepatic pathophysiology. Although the cGAS–STING signaling pathway is essential for innate immune defense against pathogens such as HBV, its chronic or dysregulated activation significantly contributes to pathology in sterile inflammatory conditions (e.g., MASLD/MASH, fibrosis, ALD, and I/R injury). In HCC, the cGAS–STING signaling pathway promotes tumor progression through immunosuppression and ferroptosis resistance but potentially enables antitumor immunity when appropriately modulated. This complexity necessitates disease- and stage-specific therapeutic strategies targeting the cGAS–STING signaling pathway. Future interventions require precise cell-type targeting (e.g., hepatocytes, macrophages, and hematopoietic stem cells) or modulation of specific downstream effectors to maximize therapeutic efficacy while minimizing detrimental inflammation and fibrosis.
Acute pancreatitis (AP) is a severe inflammatory disease characterized by acinar cell death and the subsequent release of inflammatory mediators. In AP mouse models, the STING protein is activated by DNA released from dying acinar cells, thereby activating the cGAS–STING signaling pathway in macrophages [Figure 7 ]. The cGAS–STING signaling pathway seems pivotal in initiating pancreatic inflammation. [ 130 ] Extracellular vesicles derived from M1 macrophages can penetrate pancreatic β cells and fuse with their mitochondria, resulting in lipid peroxidation and mitochondrial disruption. This process releases mtDNA into the cytosol, further activating the STING signaling pathway and inducing apoptosis [ 131 ] [Figure 7 ]. In addition, high-iron diets or depletion of the antioxidant enzyme glutathione peroxidase 4 can activate the STING signaling pathway, promoting macrophage activation and exacerbating experimental pancreatitis. [ 132 ] Severe acute pancreatitis-associated acute lung injury (SAP-ALI) is a severe complication of AP. Upregulated STING signaling can promote NLRP3 inflammasome-mediated pyroptosis in macrophages and increase the serum levels of IL-6, IL-1β, and TNF-α, thereby aggravating SAP-ALI. [ 24 ] These findings indicate that STING signaling in macrophages is pivotal in promoting inflammatory responses and AP progression.
The cGAS–STING signaling pathway plays a crucial role in pancreatic diseases. Research on the cGAS–STING signaling pathway in pancreatic diseases has focused primarily on AP and PDAC. In AP, cGAS–STING serves as a potent driver of inflammation and organ damage. In PDAC, STING activation typically promotes antitumor immunity and has therapeutic potential. AP: Acute pancreatitis; Anti-: Inhibit disease progression; BST2 + macrophage: Bone marrow stromal antigen 2-positive macrophage; cGAS: Cyclic GMP-AMP synthase; CXCL7: C-X-C motif ligand 7; dsDNA: Double-stranded DNA; EV: Extracellular vesicle; IFN-I: Type I interferon; PDAC: Pancreatic ductal adenocarcinoma; Pro-: Promote disease progression; STING: Stimulator of interferon genes. Created with BioRender.com.
Chronic pancreatitis (CP) is an inflammatory disease characterized by progressive fibrosis, leading to exocrine and endocrine dysfunction of the pancreas. Unlike in AP, STING activation in CP reduces pancreatic inflammation and fibrosis, whereas its absence exacerbates this disease. Mechanistically, STING deletion is associated with increased infiltration of Th17 cells into the pancreas. [ 133 ]
Pancreatic cancer is the seventh leading cause of cancer-related death worldwide. [ 134 ] Pancreatic cancer is an incurable malignant disease with an extremely poor prognosis and a complex TME. [ 135 ] Approximately 90% of pancreatic cancers are pancreatic ductal adenocarcinomas (PDACs). [ 134 ] Chromosomal instability promotes aggressive tumor growth, which is characterized by early dissemination and metastasis in a STING-dependent manner. [ 136 ] STING activation results in macrophage infiltration and activation in Kras-driven PDAC in mice. [ 132 ] Despite the immunosuppressive nature of pancreatic cancer, several studies have shown that activating STING signaling promotes antitumor immunity. [ 135 , 137 – 139 ] SMAD4, a key mediator of transforming growth factor-β signaling, is mutated or deleted in 20% of PDAC cases and significantly affects cancer development. Smad4 deficiency significantly increases tumor cell immunogenicity by promoting spontaneous DNA damage and stimulating STING-mediated IFN-I signaling [ 139 ] [Figure 7 ]. Activation of the cGAS–STING signaling pathway and proinflammatory signaling also activate macrophages and NK cells, further inhibiting tumor growth [ 140 ] [Figure 7 ]. In addition, A-T and Rad3-related protein inhibition suppress PDAC tumor growth by enhancing IFN signaling through tumor cell-intrinsic STING activation, [ 141 ] which depends on C-X-C motif chemokine receptor 3 expression. [ 138 ] These studies suggest that STING agonists may serve as promising therapeutic strategies for pancreatic cancer.
Pancreatic tumors are often referred to as “cold” tumors due to their immunosuppressive microenvironment, presenting significant challenges for immunotherapy. [ 142 ] In PDAC models, murine STING agonists increase inflammatory cytokine and chemokine production, facilitating T-cell migration, enhancing DC maturation, and augmenting the quantity and functionality of tumor-infiltrating cytotoxic T cells [Figure 7 ]. These effects collectively reverse tumor immune suppression. [ 143 ] Moreover, MEK inhibition potentiates the ability of STING agonists to induce IFN-I-dependent cell death and promote tumor regression. [ 144 ] CD11b agonists activate the STING/STAT/IFN signaling pathways and repress NF-κB in pancreatic cancer, leading to tumor cell death. [ 145 ] However, clinical trials of STING agonist monotherapy have faced significant challenges related to tumor resistance. Specifically, STING activation contributes to tumor resistance by inducing IL-35, which enhances regulatory B cell function and suppresses NK cell responses. [ 142 ]
In summary, research on the cGAS–STING signaling pathway in pancreatic diseases has focused primarily on AP and PDAC. In AP, cGAS–STING serves as a potent driver of inflammation and organ damage. In PDAC, STING activation typically promotes antitumor immunity and has therapeutic potential.
Obesity and its related metabolic diseases, such as diabetes, have become a significant societal burden. The cGAS–STING signaling pathway has been identified as a critical player in the development of obesity-related inflammation and insulin resistance [Figure 3 ]. Disulfide-bond A oxidoreductase-like protein (DsbA-L), a key molecule responsible for maintaining mitochondrial integrity in adipose tissue, has been shown to suppress cGAS–STING activation. DsbA-L deficiency promotes inflammation and insulin resistance by activating the cGAS–cGAMP–STING signaling pathway. [ 146 ] In addition, the endocytosis of apoptotic bodies containing self-DNA by conventional type 1 DCs in white adipose tissue drives STING-dependent IL-12 production, further exacerbating inflammation [ 147 ] [Figure 3 ]. These findings highlight the cGAS–STING signaling pathway as a potential therapeutic target in obesity and its metabolic complications.
MI represents a life-threatening form of coronary heart disease, with the most prominent pathological change being ischemic injury to cardiomyocytes. This ischemic injury induces an inflammatory response and infiltration of innate immune cells, including macrophages. [ 148 ] Macrophages, exhibiting plasticity, dynamically regulate both destructive and reparative processes post-MI through distinct phenotypic switching [ 149 ] [Figure 8 ]. Infarct expansion and adverse fibroblast remodeling of cardiac fibroblasts occur at a destructive stage mediated by M1 macrophages and deteriorate heart function. [ 150 ] IR injury can exacerbate cellular apoptosis and ROS accumulation. [ 151 ] The mitochondria are structurally and functionally damaged in ischemic and hypoxic conditions, further aggravated by oxidative stress. [ 152 ] The cGAS–STING signaling pathway in macrophages can detect mtDNA release and trigger inflammation through M1 macrophage polarization [ 153 ] [Figure 8 ]. The downstream reactions of IFN-Is can cause cellular apoptosis and cardiac fibrosis via IFN-β and CXCL10 production [ 154 ] [Figure 8 ]. Applying STING inhibitors alleviates cardiac contractile function and remodeling by reducing the inflammatory response after MI. [ 154 , 155 ] Emerging therapeutic strategies targeting the cGAS–STING signaling pathway have recently been proposed to reduce oxidative damage and regulate macrophage polarization, thereby accelerating cardiac repair. [ 153 ]
Activation of the cGAS–STING signaling pathway drives the progression of cardiovascular diseases. The cGAS–STING signaling pathway contributes to cardiovascular pathogenesis through distinct mechanisms: (A) Exacerbates ischemia-reperfusion injury by promoting proinflammatory M1 macrophage polarization to induce myocardial infarction. (B) Drive ventricular remodeling via fibrosis-mediated chronic inflammation to promote heart failure. (C) Promotion of cardiomyopathy progression through inflammation and cardiomyocyte pyroptosis. ATP: Adenosine triphosphate; cGAS: Cyclic GMP-AMP synthase; cGAMP: Cyclic GMP-AMP; CXCL10: C-X-C motif ligand 10; dsDNA: Double-stranded DNA; ER: Endoplasmic reticulum; GTP: Guanosine triphosphate; HF: Heart failure; IFIT1: Interferon-induced protein with tetratricopeptide repeats 1; IFN: Interferon; IKK: Inhibitor of NF-κB: kinase\IκB kinase; IL: Interleukin; IRF3: Interferon regulatory factor; ISGs: Interferon-stimulated genes; mtDNA: Mitochondrial DNA; NF-κB: Nuclear factor kappa B; NLRP3: NOD-like receptor protein 3; STING: Stimulator of interferon genes; TBK1: Tank binding kinase 1; TNF-α: Tumor necrosis factor α. Created with BioRender.com.
HF is a pervasive global health challenge characterized by cardiac remodeling, which involves cardiac structural, compositional, and cellular abnormalities that impair heart function. [ 156 ] Inflammatory cell infiltration and cytokine production have a complex and bidirectional relationship with cardiac remodeling in HF. [ 157 ] Recent studies have shed light on the intricate relationship between the cGAS–STING signaling pathway and HF. In overload HF animal models induced by transverse aortic constriction, the cGAS–STING signaling pathway is activated following cardiomyocyte apoptosis and DNA leakage as damage-associated molecular patterns [ 158 ] [Figure 8 ]. Dynamic observations revealed fluctuations in cGAS–STING expression in the HF model. These findings suggest a critical role of the cGAS–STING pathway in HF, correlated with the innate immune-mediated short-term adaptation phase following early myocardial injury [ 159 ] [Figure 8 ]. The cGAS–STING signaling pathway and downstream NF-κB and IRF3, along with cytokines including IL-6, IL-1β, monocyte chemoattractant protein-1, and TNF-α, might regulate the early inflammatory response and promote myocardial fibrosis and cardiomyocyte hypertrophy during HF [ 160 – 162 ] [Figure 8 ]. Moreover, cardiomyocytes exhibit robust metabolic activity, characterized by pronounced metabolic flexibility and high mitochondrial density. [ 163 ] HF is accompanied by metabolic reprogramming and derangements, including altered substrate utilization, diminished oxidative metabolism, and lipid accumulation. [ 163 ] Cholesterol exacerbates lipotoxicity in cardiomyocytes via various regulatory mechanisms involved in cholesterol homeostasis. [ 164 ] Enhancing bile acid synthesis and excretion is a key part of cholesterol metabolism. Bile acid intermediates can trigger mtDNA release and activate the cGAS–STING signaling pathway, thus promoting HF via the myocardial inflammation response. Overall, the activation of the cGAS–STING signaling pathway and downstream inflammatory cascades may represent a promising therapeutic strategy for preventing myocardial remodeling in HF [Figure 8 ].
Cardiomyopathies are a heterogeneous group of myocardial diseases characterized by mechanical and/or electrical dysfunction. [ 165 ] Recently, emerging studies have revealed an association between the cGAS–STING signaling pathway and cardiomyopathy progression, with a particular focus on diabetic cardiomyopathy (DCM). Lipotoxicity is a pivotal mechanism underlying DCM development due to cardiac metabolic abnormalities. The diabetic heart is characterized by a metabolic preference for fatty acids (FAs) as substrates, driven by elevated circulating free FA levels, increased FA uptake, and disrupted glucose utilization. [ 166 ] The cGAS–STING signaling pathway provides evidence linking lipotoxicity, mitochondrial damage, inflammatory responses, and DCM progression [Figure 8 ]. The activation of the cGAS–STING signaling pathway is triggered by mitochondrial dysfunction and mtDNA leakage, with IRF3 and NF-κB acting as key downstream promoters of sterile inflammation in DCM [ 167 , 168 ] [Figure 8 ]. Similarly, decreased mitochondrial fusion, particularly due to reduced mitofusin 2, can exacerbate myocardial injury during diabetic myocardial I/R via the cGAS–STING signaling pathway. [ 169 ] Preserving mitochondrial function and inhibiting the cGAS–STING activation could attenuate DCM progression. [ 170 , 171 ] Pyroptosis, typically mediated by inflammasome activation, is implicated in DCM through signaling pathways such as the NF-κB, mtROS, and adenosine 5′-monophosphate-activated protein kinase [ 172 ] [Figure 8 ]. Free FAs can cause NLRP3 inflammasome activation and pyroptosis in cardiomyocytes via a cGAS–STING-dependent signaling pathway, resulting in mitochondrial dynamics and structural and functional cardiac impairments in DCM [ 168 ] [Figure 8 ]. These findings collectively highlight that direct inhibition of the cGAS–STING signaling pathway or upstream signaling axes may represent an effective therapeutic strategy for DCM [Figure 8 ].
Overall, recent studies have increasingly highlighted the role of the cGAS–STING pathway in cardiovascular diseases, including MI, cardiomyopathy, and HF. Dysregulated activation of the cGAS–STING pathway is associated with inflammatory responses and abnormalities in cellular homeostasis. Targeting cGAS–STING signaling has shown promise in mitigating inflammatory infiltration, adverse remodeling, and cardiac dysfunction, highlighting its potential as a novel therapeutic strategy in cardiovascular pathology.
Leukemia is defined by the presence of circulating malignant white blood cells. It is clinically classified into four primary subtypes: acute myeloid leukemia (AML), acute lymphoblastic leukemia/lymphoma (ALL), chronic lymphocytic leukemia/small lymphocytic lymphoma (CLL/SLL), and chronic myeloid leukemia (CML). [ 173 ] During hematopoietic stem cell transplantation in murine myeloid leukemia models, leukemia cells secrete dsDNA via extracellular vesicles, which impairs the hematopoietic functions of donor cells. Cytoplasmic DNA accumulation activates the cGAS–STING signaling pathway, reducing leukemia cell viability through ROS generation [ 174 ] [Figure 3 ]. Bone marrow macrophages suppress leukemia expansion via LC3-associated phagocytosis, in which mtDNA activates STING, releasing inflammatory signals that promote phagocytosis and restrict leukemic cell proliferation. [ 175 , 176 ] Systemic immunotherapy via a lipid-based nanoparticle platform carrying Mn 2+ and the STING agonist c-di-AMP (CDA) exhibited robust antitumor efficacy in a disseminated AML mouse model. [ 177 ] . Controversially, recent studies have demonstrated that negative regulation of STING signaling can inhibit leukemia progression. [ 178 ] Surfeit 4, a multipass ER transmembrane protein involved in the ER-Golgi compartment, is frequently amplified and highly expressed in leukemic cells. Surfeit 4 suppresses myeloid differentiation and inhibits leukemia cell death by negatively regulating the STING–TBK1–STAT6 axis. [ 178 ]
AML with tumor protein p53 (TP53) mutation is associated with a highly lethal phenotype and poor prognosis. [ 179 ] In TP53-mutated AML, histone modifications and polyploidy activate the cGAS–STING signaling pathway, leading to cytokine and chemokine secretion and subsequent activation of macrophages and T cells upon coculture with AML cells. [ 179 , 180 ] In TP53-mutant blood cancers, STING agonists induce the expression of pro-apoptotic BH3-only protein in a p53-independent manner, leading to the death of AML cells. [ 181 ] Somatic loss-of-function mutations in the dioxygenase ten-eleven translocation-2 gene are frequent in AML patients. STING inhibition specifically reduces the proliferation of leukemia cells from dioxygenase ten-eleven translocation-2-mutated individuals in patient-derived xenograft models. [ 182 ] AML patients harboring a RUNX1:RUNX1T1 fusion present an approximately 50% relapse rate. Kasumi-1 cells expressing this fusion protein exhibit increased DNA damage signals, triggering cGAS–STING signaling pathway activation. STING deletion in a mouse primary RUNX1:RUNX1T1 leukemia model reduces leukemogenesis and extends survival. [ 183 ] . In addition, promyelocytic leukemia (PML) expresses SASP in senescent cells via the CCF–cGAS–STING–TBK1–NF-κB signaling pathway [ 184 ] [Figure 3 ]. In a Sting -deficient CLL mouse model, Sting -deficient CLL cells are more responsive to B-cell receptor activation, and both human and mouse malignant CLL cells downregulate STING to increase B-cell receptor signaling for survival. [ 185 ] Collectively, these studies indicate that the cGAS–STING signaling pathway plays various roles in different types of leukemia and that targeting STING may be beneficial for enhancing the antitumor effects of leukemia immunotherapy.
Diffuse large B-cell lymphoma (DLBCL) is the most prevalent form of non-Hodgkin lymphoma globally, with approximately 150,000 new cases reported annually. [ 186 ] Genomic instability is a significant driver of cancer progression. Extrachromosomal circular DNAs induced by DNA damage promote oncogenesis in DLBCL by activating STING signaling in a cGAS-independent manner. [ 187 ] Inhibition of STING and STAT3 signaling pathways hinders the proliferation of Epstein–Barr virus-infected B cells and the transformation of lymphoblastoid cell lines. [ 188 ] However, emerging evidence suggests that cGAS–STING activation may enhance the efficacy of radiochemotherapy in DLBCL. [ 189 – 191 ] Specifically, bendamustine-rituximab therapy has been shown to activate the cGAS–STING signaling pathway, resulting in the release of inflammatory cytokines, upregulation of major histocompatibility complex molecules, and the creation of an immunologically “hot” TME. This cascade of events ultimately induces pyroptosis in DLBCL cells. [ 189 ] Epigenetic priming has also been reported to increase the efficacy of salvage chemotherapy in DLBCL by activating the cGAS–STING signaling pathway via endogenous retroviruses. [ 190 ] Furthermore, the STING agonist DMXAA has been shown to increase the efficacy of PD-L1 inhibitors in DLBCL. [ 191 ]
Peripheral T-cell lymphoma (PTCL) represents a heterogeneous group of mature T-cell neoplasms. High expression of the cGAS–STING signaling pathway is closely linked to PTCL proliferation. Specifically, inhibition of cGAS suppresses tumor growth and disrupts DNA damage repair mechanisms [ 192 ] [Figure 3 ]. Notably, STING expression is predominantly confined to T- and NK-cell lymphomas and is downregulated in B-cell non-Hodgkin lymphoma. [ 193 ] Targeting cytidine triphosphate synthase 1 has been demonstrated to induce immune responses via the cGAS–STING signaling pathway in mantle cell lymphoma, which is pivotal for inhibiting tumor growth in mantle cell lymphoma patients. [ 194 ]
MM is a neoplastic disorder of the hematopoietic system characterized by the uncontrolled proliferation of neoplastic plasma cells within the bone marrow. This proliferation results in skeletal destruction, renal impairment, anemia, and hypercalcemia. [ 195 ] Myeloma-derived mtDNA alters the bone marrow niche by activating the cGAS–STING signaling pathway in tumor-associated macrophages, thereby promoting disease progression. [ 196 ] In MM, cGAS–STING signaling pathway activation induces cell death through the IRF3–NOXA–BAX/BCL-2 antagonist/killer 1 (BAK) axis and triggers M1 macrophage polarization [ 197 ] [Figure 3 ]. In addition, viral infections significantly contribute to morbidity and mortality in MM patients. Exosomes derived from MM cells are enriched in microRNAs that are transferred to host monocytes/macrophages, where they suppress the cGAS–STING signaling pathway, reduce IFN-I production, and impair the innate immune response to DNA viruses. [ 198 ]
The standard first-line therapy for MM patients typically includes a combination of an injectable proteasome inhibitor (e.g., bortezomib), an oral immunomodulatory drug (e.g., lenalidomide), and dexamethasone. [ 195 ] Bortezomib enhances the immunogenicity of MM cells by activating the cGAS–STING signaling pathway and inducing IFN-Is [Figure 3 ]. The coadministration of STING agonists with bortezomib elicits a robust tumor-specific immune response and improves clinical outcomes in MM patients. [ 199 ] The DNA-dependent protein kinase catalytic subunit (DNA-PKcs) is a DNA damage repair factor. Inhibition of DNA-PKcs enhances the anti-MM effects of doxorubicin by activating the cGAS–STING signaling pathway. [ 197 ] Collectively, these findings suggest that the combination of STING agonists with chemotherapeutic agents may offer therapeutic advantages for MM patients.
In summary, STING agonists demonstrate significant antitumor efficacy in hematologic malignancies. However, these cancers frequently harbor genetic mutations, and the cGAS–STING signaling pathway has divergent effects depending on the mutation sites. Therefore, future research targeting the cGAS–STING signaling pathway should focus on specific malignancy subtypes to achieve precision medicine.
In lung cancer, particularly metastatic lung adenocarcinoma, STING functions as a checkpoint to suppress the outgrowth of reawakened dormant cancer cells [Figure 3 ]. STING activity increases as metastatic progenitors exit dormancy, but its function can be suppressed through hypermethylation of regulatory regions or chromatin repression. Encouragingly, the activation of STING via agonists has demonstrated promise in eliminating dormant metastases and preventing disease relapse via T-cell- and NK cell-mediated mechanisms in lung adenocarcinoma [ 200 ] [Figure 3 ]. However, challenges emerge in KRAS-LKB1-mutant lung cancers, where intrinsic mitochondrial dysfunction silences STING, resulting in T-cell exclusion and resistance to PD-1/PD-L1 blockade. These cancers further avoid downstream STING and STAT1 activation by minimizing 2′3′-cGAMP accumulation. Notably, combining epigenetic reactivation of STING with transient monopolar spindle 1 kinase inhibition restores STING activity, enhances T-cell infiltration, and improves anti-PD-1 efficacy in vivo . [ 201 ] These findings underscore STING as a pivotal target for overcoming immune evasion and improving therapeutic outcomes in lung cancer.
In addition to its role in cancer, STING also significantly contributes to lung fibrosis through its involvement in the STING–PERK–eIF2α axis, a noncanonical cGAS–STING signaling pathway [Figure 3 ]. This mechanism links innate DNA sensing to cellular translation. Upon cGAMP binding, STING activates PERK in the ER, leading to eIF2α phosphorylation and a shift toward an inflammatory translation program [Figure 3 ]. The STING–PERK–eIF2α signaling pathway is critical in the development of lung fibrosis, and its targeting has been shown to attenuate lung fibrosis. [ 36 ] Similarly, in silica-induced lung inflammation and fibrosis, STING is activated by self-dsDNA released in the lungs following cell death. Degradation of extracellular dsDNA by DNase I inhibits STING activation and downstream IFN-I responses, highlighting DNase I as a potential therapy. Consistently, in silicosis patients, increased circulating dsDNA and STING activation are associated with inflammatory markers such as CXCL10, further supporting the role of STING-mediated DNA sensing in silica-induced lung inflammation. [ 202 ]
STING also contributes to the pathogenesis of severe asthma by driving neutrophilic lung inflammation. The activation of STING exacerbates airway hyperresponsiveness through cell death via PANoptosis, extracellular dsDNA release, and the activation of DNA sensors [Figure 3 ]. In asthma models, STING agonists such as diABZI enhance neutrophil recruitment, airway hyperresponsiveness, and a mixed Th1/Th2 inflammatory response. These effects include epithelial barrier damage, tight junction downregulation, and increased release of inflammatory markers, mirroring features of severe asthma. [ 203 ]
In summary, STING is a critical mediator of immune responses in respiratory diseases, including lung cancer, fibrosis, and asthma. Its activation or dysregulation underpins key pathological processes, making it a promising target for future therapeutic strategies.
In AKI, mitochondrial dysfunction and subsequent activation of the cGAS–STING signaling pathway drive inflammation and kidney damage. [ 204 ] Cisplatin-induced AKI leads to mtDNA leakage into the cytosol through BCL2-associated X (BAX) pores in the mitochondrial outer membrane, thereby triggering STING activation and inflammatory responses. Studies in STING-deficient mice and tubular cell models have shown reduced inflammation and improved outcomes, emphasizing the central role of the STING signaling pathway [ 205 ] [Figure 3 ]. Furthermore, elevated plasma mtDNA in patients receiving platinum-based chemotherapy suggests that STING activation contributes to AKI. Therapeutically, the STING antagonist H151 has demonstrated significant efficacy in improving renal function, reducing tubular apoptosis, and alleviating inflammation and mitochondrial injury in cisplatin-induced AKI models, highlighting its potential as a treatment option [ 206 ] [Figure 3 ].
In addition to AKI, STING also contributes to kidney fibrosis, a hallmark of CKD. In a Tfam knockout mouse model, mitochondrial defects caused mispackaging of mtDNA, leading to its cytosolic translocation and subsequent activation of the cGAS–STING signaling pathway. This activation results in cytokine expression, immune cell recruitment, and fibrosis progression [Figure 3 ]. Importantly, ablation of Sting significantly reduces fibrosis, further supporting its therapeutic potential in CKD. [ 207 ]
In bladder cancer, the cGAS–STING signaling pathway shapes the TME by driving the differentiation of a specific subpopulation of cancer-associated fibroblasts (CAFs) characterized by SLC14A1 overexpression. These SLC14A1 + CAFs are induced by interferon signaling via STING activation in tumor cells. Mechanically, these SLC14A1 + CAFs promote bladder cancer cell stemness through the wingless-type MMTV integration site family member 5A paracrine signaling pathway, leading to poor outcomes and resistance to chemotherapy and immunotherapy [ 208 ] [Figure 3 ].
In summary, the cGAS–STING signaling pathway plays diverse yet interconnected roles in urinary and renal diseases, mediating inflammation and mitochondrial dysfunction in AKI, driving fibrosis in CKD, and modulating the TME in bladder cancer. These findings establish STING as a promising target for therapeutic interventions across these conditions.
Endometriosis refers to a gynecological condition characterized by the presence of endometrial tissues (epithelium and/or stroma) outside the uterus. [ 209 ] Immunological, inflammatory, proangiogenic, and endocrine factors contribute to endometrial cell survival and proliferation outside the uterus. [ 210 ] Recent data have demonstrated elevated cGAS–STING expression and autophagy activity in the ectopic endometria of humans and mice compared with normal and eutopic endometria. [ 211 ] The expression of STING reflects the chronic inflammatory state within the tissue microenvironment, facilitating the establishment and maintenance of ectopic lesions. [ 212 , 213 ] As crucial immune cells, macrophages drive endometriosis development by sustaining a chronic pelvic inflammatory state and promoting ectopic endometriotic lesion proliferation. [ 214 ] Macrophage activation, associated with the cGAS–STING signaling pathway, contributes to ovarian dysfunction through inflammatory responses, apoptosis, and cellular senescence. [ 215 ] These findings may provide a theoretical basis for understanding infertility associated with ovarian endometriosis. In addition, autophagy activity and human endometrial stromal cell motility increased in a lentivirus-based model of STING overexpression [ 211 ] [Figure 3 ]. These findings collectively indicate that the cGAS–STING signaling pathway can enhance autophagy, thereby promoting the migration and invasion of ectopic endometrial cells. The application of STING inhibitors may attenuate downstream development and reduce endometriosis lesions. [ 211 , 215 ]
Adenomyosis is characterized by the growth of endometrial epithelial cells and stromal fibroblasts into the myometrium and was initially considered a variant of endometriosis. Hypoxia, inflammation, immune cell infiltration, and platelet activation can promote the differentiation of Schwann cells at the endometrial–myometrial interface into endometrial cells, thus inducing adenomyosis. [ 216 ] Hypoxia can lead to mitochondrial damage and mitophagy, processes implicated in various diseases, including adenomyosis. [ 217 , 218 ] Elevated mtDNA levels, resulting from mitochondrial damage, are observed in hypoxic endometrial stromal cells and can activate the cGAS–STING signaling pathway. Notably, inhibiting mtDNA replication can reverse hypoxia-induced STING expression. STING activation promotes an inflammatory state by producing the downstream cytokines IL-6 and TNF-α in adenomyosis and is correlated with abnormal cell proliferation and migration under hypoxic conditions [Figure 3 ]. [ 219 ] Furthermore, the expression of TBK-1 and TNF-α in adenomyotic lesion tissue is positively correlated with the severity of dysmenorrhea in patients, providing robust clinical evidence supporting the involvement of this signaling pathway in adenomyosis. [ 220 ]
Ovarian cancer is the most fatal gynecological malignancy, with a global 5-year survival rate of 30–40%. [ 221 ] Epithelial ovarian cancer is the most common subtype, with high-grade serous ovarian cancer being the primary contributor to patient mortality. The STING signaling pathway promotes resistance by modulating the cancer-immunity cycle [ 222 ] [Figure 3 ]. In ovarian cancer, the cGAS–STING deficiency impairs STING-dependent DNA sensing, a key immune evasion mechanism, [ 223 , 224 ] potentially driven by elevated USP35 deubiquitinase expression. [ 225 ] Furthermore, STING expression is correlated with tumor histology and clinical stage. [ 224 , 226 ] Numerous studies have proposed that modulating the STING signaling pathway may provide new insights into ovarian cancer chemotherapies, including strategies to overcome drug resistance. Despite these interventions, ovarian cancer is characterized by a high recurrence rate and drug resistance, prompting the integration of novel therapies such as poly ADP–ribose polymerase (PARP) inhibitors. [ 227 ] While the STING signaling pathway activation may elucidate the antitumor mechanisms of PARP inhibitors [ 228 ] [Figure 3 ], resistance is increasingly prevalent and associated with M2-like polarization of tumor-associated macrophages in the TME. STING agonists can alter myeloid cell function, potentially overcoming this resistance. [ 229 ] However, a recent study revealed that cisplatin resistance in ovarian cancer may be associated with cGAS–STING signaling pathway activation in CAFs, which can be reversed with STING inhibitors. [ 230 ] Hence, the role of STING as either a tumor suppressor or promoter remains context-dependent, necessitating caution in the therapeutic use of STING agonists for ovarian cancer. [ 231 ]
In summary, emerging evidence indicates a significant association between the cGAS–STING pathway and reproductive disorders, with its roles varying across different pathological contexts. Aberrant activation of the cGAS–STING pathway is associated with an excessive inflammatory state in reproductive dysfunction. Conversely, this pathway is crucial for promoting antitumor immunity. A deeper understanding of these signaling pathways may provide new insights into unexplained reproductive disorders, such as endometriosis and adenomyosis, while also addressing challenges related to tumor drug resistance.
SLE is a multisystemic autoimmune disease characterized by the production of antibodies against nuclear antigens, immune complex deposition, and chronic inflammation in target organs such as the skin, joints, and kidneys. [ 232 ] The pathogenesis of SLE is associated with dysregulated activation of the IFN-I signaling pathway and the presence of an IFN-stimulated gene signature [ 233 ] [Figure 3 ]. The IFN response is initiated by the engagement of oxidized DNA with the cytosolic DNA-sensing complex cGAS–STING. [ 234 ] A subset of SLE patients exhibits impaired function of hypoxia-inducible factor-regulated metabolic and proteasomal signaling pathways, leading to the accumulation of mitochondria-containing red blood cells (Mito + RBCs). When phagocytosed by macrophages, these Mito + RBCs trigger cGAS–STING-dependent inflammation. [ 235 ] Monocytes co-produce IFN-I and mature IL-1β in response to opsonized Mito + RBCs [ 236 ] [Figure 3 ]. The DNA repair enzyme 8-oxyguanine glycosylase 1, which corrects 8-oxo-2′-deoxyguanosine, modulates IFN-β expression via the cGAS–STING signaling pathway in a pristane-induced SLE mouse model. [ 234 ] These findings highlight the critical role of the cGAS–STING signaling axis in SLE pathogenesis and its potential as a therapeutic target for autoinflammation.
Deficiency or pharmacological inhibition of STING has been shown to ameliorate SLE in murine models. [ 237 , 238 ] Peripheral blood mononuclear cells (PBMCs) from SLE patients exhibit increased phosphorylation of IRF8 and enhanced STING activity. [ 239 ] The RNF115 protein can exacerbate STING-mediated inflammation and autoimmunity, and this effect can be mitigated by the RNF115 inhibitor disulfiram. Downregulation of RNF115 disrupts STING oligomerization and Golgi localization in various cell types, resulting in reduced expression of IFN-α, IFN-γ, and proinflammatory cytokines in PBMCs from SLE patients [ 240 ] [Figure 3 ]. Conversely, a study suggested that a deficiency in both cGAS and STING does not protect mice from tetramethylpentadecane-induced SLE and is associated with increased autoantibody production and proteinuria levels compared with those in cGAS- and STING-sufficient mice. [ 241 ] Thus, further investigation is necessary to clarify the mechanisms by which STING contributes to SLE and to assess the potential of STING as a therapeutic target in SLE and associated autoimmune diseases.
RA is a chronic systemic autoimmune disorder predominantly affecting joints and periarticular soft tissues. [ 242 ] In a mouse model of inflammatory arthritis, cGAS deficiency has been shown to block IFN responses, reduce inflammatory cell infiltration, and alleviate joint swelling [ 243 ] [Figure 3 ]. Similarly, inhibiting the STING signaling pathway ameliorates joint damage in mouse models of dsDNA-induced and collagen-induced arthritis. [ 244 ] Moreover, several studies have demonstrated that TBK1 recruitment to STING mediates autoinflammatory arthritis independently of IFN-I signaling [ 245 , 246 ] [Figure 3 ].
The cGAS–STING signaling pathway is central to regulating the aggressive behavior of rheumatoid synovial tissues. Fibroblast-like synoviocytes are key pathogenic players in RA. Fibroblast-like synoviocytes exhibit increased cGAS expression upon TNF-α stimulation, underscoring the role of TNF in RA progression via the cGAS–STING axis. [ 243 ] In addition, increased expression of fat mass and obesity-associated protein (FTO) in RA synovial cells promotes their proliferation and migration while inhibiting senescence and apoptosis. The FTO–CMPK2 signaling pathway is essential for modulating synovial inflammation through the mtDNA-mediated cGAS–STING signaling pathway, thereby influencing chondrocyte homeostasis. [ 247 ] DNA polymerase β (Pol β), a key enzyme in base excision repair, is significantly downregulated in PBMCs from active RA patients and collagen-induced arthritis mice. Pol β deficiency leads to DNA damage accumulation and cytosolic dsDNA leakage, activating the cGAS–STING–NF-κB signaling pathway and upregulating NLRP3, IL-1β, and IL-18 expression, ultimately inducing macrophage pyroptosis [ 248 ] [Figure 3 ]. These findings suggest that Pol β may serve as a potential therapeutic target for the prevention and treatment of RA and related autoimmune diseases.
In summary, the cGAS–STING signaling pathway, which detects mislocated self-DNA to trigger pathogenic IFN-I and cytokine production, is a crucial driver of inflammation in autoimmune diseases such as SLE and RA. Despite the therapeutic potential of STING inhibition demonstrated in numerous mouse models of autoimmune diseases, therapeutic strategies must precisely target pathological signaling while preserving essential host defenses.
The cGAS–STING signaling pathway is crucial in initiating host defense against microbial infections [Figure 3 ]. In Drosophila melanogaster , two cGAS-like receptors produce 3′2′-cGAMP and 2′3′-cGAMP to activate STING. Recent studies have shown that various CDNs, including 2′3′-c-di-GMP, are produced in a cGLR-dependent manner in response to viral infection [Figure 3 ]. Notably, 2′3′-c-di-GMP is a more potent STING agonist than cGAMP in D. melanogaster and induces a robust antiviral transcriptional response in D. serrata . [ 249 ] STING serves as the first line of defense against infections, primarily through IFN-I production. [ 250 , 251 ] However, for successful viral infection, immune evasion mechanisms must be used. Upon DNA virus infection, myb-like, swirm and mpn domain 1 (MYSM1) expression is induced. MYSM1 subsequently interacts with STING and cleaves K63-linked ubiquitinated STING to suppress cGAS–STING signaling. [ 252 ] In addition, the oncogenes E7 from human papillomavirus 18 and E1A from adenovirus inhibit the cGAS–STING signaling pathway. [ 253 ] The phase separation of cGAS–DNA is essential for the antiviral innate immune response. Viral tegument proteins restrict cGAS–DNA phase separation to overcome innate immunity. [ 254 ] Virus-like particles induce cGAS liquid-phase condensation and activate STING signaling, leading to the production of inflammatory cytokines and enhanced antitumor immunity. [ 255 ] These findings suggest that viruses suppress the cGAS–STING signaling pathway for immune evasion [Figure 3 ].
Herpes simplex virus 1 (HSV-1) effectively establishes acute and latent human infections by antagonizing host antiviral innate immune responses. Upon infection, viral capsids are transported along the cytoskeleton within the cytoplasm, followed by the injection of the viral genome into the nucleus via the nuclear pore complex. DNA sensor-mediated innate immune signaling pathways are important in restricting HSV-1 infection. [ 256 , 257 ] The HSV-1 γ(1)34.5 protein directly interacts with STING to prevent its transport from the ER to the Golgi apparatus, thereby inhibiting STING activation and downstream antiviral signaling pathways. [ 257 ] Preventing STING degradation enhances IFN production, reduces viral replication, and diminishes cellular infiltration. [ 251 ]
The cGAS–STING signaling pathway is essential for IFN-I induction during varicella-zoster virus (VZV) infection, and the recognition of VZV by cGAS inhibits viral replication [ 258 , 259 ] [Figure 3 ]. The VZV tegument protein ORF9 acts as a cGAS antagonist, reducing IFN-I responses. [ 258 ] VZV glycoprotein E facilitates PINK1/Parkin-mediated mitophagy to evade STING-mediated antiviral innate immunity. [ 259 ] In human cytomegalovirus (HCMV), the HCMV-encoded UL37 exon-1 protein inhibits the cGAS–STING signaling pathway through direct interaction with TBK1. [ 260 ] Despite its antiapoptotic function in enhancing immune signaling, the immunosuppressive activity of the HCMV-encoded UL37 exon-1 protein mitigates this potential side effect. [ 260 ] Moreover, cytomegalovirus infections can be effectively controlled by STING-mediated immune responses in hematopoietic and stromal cells. [ 250 ]
RNA viruses, such as parainfluenza virus and rhinovirus, are major pathogens responsible for respiratory infections. STING activation has been shown to exert significant antiviral effects against parainfluenza virus 3 and rhinovirus 16 [ 261 ] [Figure 3 ]. Dengue virus, an RNA virus without a DNA stage, manipulates cGAS–STING-mediated innate immunity through proteolytic degradation of STING. The overexpression of cGAS or DNA virus reactivation in cells leads to enhanced STING cleavage in neighboring cells containing dengue virus protease. [ 262 ] During foot-and-mouth disease virus infection in swine cells, the viral proteases leader and 3C protease cleave cGAS, attenuating the cGAS–STING-dependent antiviral response. [ 263 ] In the pseudorabies virus model, tegument protein US2 interacts with STING, recruiting the E3 ubiquitin ligase TRIM21 to facilitate K48-linked ubiquitination and subsequent STING degradation. [ 264 ] Collectively, these findings indicate that viruses can evade innate immunity by inhibiting cGAS–STING activity, suggesting that STING agonists may serve as potential targets for antiviral therapeutics.
The cGAS–STING signaling pathway constitutes a critical innate immune defense mechanism against pathogens, inducing IFN-I production and antiviral responses upon cytosolic DNA sensing. However, diverse viruses (e.g., HSV-1, VZV, HCMV, dengue virus, foot-and-mouth disease virus, and pseudorabies virus) use species-specific strategies to evade or suppress the cGAS–STING signaling pathway. Mechanisms include cleaving cGAS or STING, blocking STING trafficking, disrupting phase separation, or exploiting host processes such as mitophagy. This pervasive viral evasion underscores the fundamental role of the cGAS–STING signaling pathway while highlighting challenges for its therapeutic exploitation.
Aging is a complex, natural, and irreversible biological process. Cellular senescence, a stable state of proliferative arrest, is a major contributor to organismal aging. [ 265 ] It is characterized by permanent cell cycle arrest, changes in the cellular secretome, imbalances in macromolecules, and alterations in organelle structure and function. [ 266 ] One of the key hallmarks of senescent cells is the SASP, which involves various factors that exert autocrine and paracrine effects, reshaping the local microenvironment and promoting further senescence. SASP is a form of molecular inflammation, and chronic overproduction of these factors contributes to chronic low-grade inflammation known as inflammaging. [ 267 ] The cGAS–STING signaling pathway may serve as a central mediator linking age-induced cellular damage and SASP activation through the IFN signaling pathway [ 268 ] [Figure 3 ]. DNA damage, a significant trigger for the cGAS–STING signaling, may be associated with various molecular mechanisms of senescence, including genomic instability, epigenetic alterations, and mitochondrial dysfunction. [ 269 ]
The SASP is predominantly driven by CCFs in senescent cells. [ 270 ] These micronuclei-like structures, generated via nuclear membrane blebbing, contain genomic DNA and act as upstream activators of cGAS. [ 271 ] The topoisomerase 1-DNA covalent cleavage complex may enhance cGAS binding to CCFs, a crucial interaction for cGAS-mediated DNA sensing and subsequent SASP activation during the aging process [ 272 ] [Figure 3 ]. Key challenges lie in elucidating the mechanisms of CCF formation and ectopic DNA accumulation, which trigger sensor activation during senescence. Loss of lamin B1 in the nuclear lamina can compromise the integrity of the nuclear membrane. In mouse embryonic fibroblasts, siRNA-mediated knockdown of lamin B1 led to CCF formation and recognition by cGAS. [ 273 , 274 ] In addition, decreased activity of mechanosignaling genes yes-associated protein and tafazzin in stromal and contractile cells, mediated through Lamin B1 and actin-related protein 2, disrupts nuclear membrane integrity and facilitates SASP via the cGAS–STING signaling pathway. [ 275 ] Two major deoxyribonucleases responsible for cytoplasmic DNA degradation, deoxyribonuclease 2 and three prime repair exonuclease 1 (TREX1), are both downregulated during senescence. In fact, cytoplasmic DNA accumulation in the absence of functional DNase can also facilitate the DNA damage-cGAS–SASP axis in senescent cells. [ 276 , 277 ]
Loss of heterochromatin during aging can promote retrotransposon derepression in genomic instability, another potential mechanism of cGAS–STING activation. [ 278 ] LINE-1s elements, the most abundant retrotransposons, play crucial roles in senescence and inflammaging via the cGAS–STING signaling pathway. In aging mice, increased LINE-1 activity results in cDNA accumulation, thereby eliciting a type I interferon response via the cGAS–STING signaling pathway. [ 279 ] Modulating LINE-1 activity, such as through brain and muscle ARNT-like 1 (BMAL1, which inhibits the LINE-1–cGAS–SASP cascade) or paired box 5 (PAX5, which promotes LINE-1 activation), can influence cellular senescence [ 280 , 281 ] [Figure 3 ]. Interestingly, nuclear cGAS can suppress LINE-1s by affecting open reading frame 2 protein stability following DNA damage, highlighting the dual functions of cGAS in the nucleus and cytoplasm during aging, as well as the multifaceted regulation of LINE-1 activity. [ 282 ]
Mitochondrial dysfunction is also implicated in aging. The release of mtDNA from damaged mitochondria is a significant source of cytoplasmic DNA, activating the cGAS–STING signaling pathway. In microglia, mitochondrial dysfunction drives aging-related innate immune activation and neurodegeneration via the cGAS–STING signaling pathway, with TNF exerting downstream neurotoxic effects. [ 283 ] Mitochondrial outer membrane permeability (MOMP) is a key event in mtDNA leakage, which occurs in a BAK-dependent manner. [ 284 ] During aging, the formation of BAX and BAK pores also induces a phenomenon called “miMOMP”, where a small fraction of mitochondria exhibits increased MOMP and activates the cGAS–STING signaling pathway during aging. [ 285 ] However, unlike MOMP, which typically occurs during cellular apoptosis, miMOMP does not affect cyclin-dependent kinase inhibitors, thus mediating the progression of cellular senescence. Overall, impaired mitochondrial integrity drives cGAS–STING activation, contributing to inflammaging, but this process is mitigated by mitophagy. [ 286 , 287 ] With increasing age, the increase in mitophagy in multiple organs of mice may be a reaction to cGAS–STING activation. Drug-induced mitophagy has improved neurological and visual functions in aged mice, offering new insights for developing therapeutic strategies against aging-related diseases. [ 287 ]
In summary, cytosolic DNA accumulation recognized by cGAS can induce the SASP and drive inflammaging. Various upstream factors can modulate this process, including the compromised nuclear membrane integrity, DNase downregulation, retrotransposon derepression, and mitochondrial dysfunction. Serving as a pivotal connection between DNA damage and inflammation in senescence, the cGAS–STING pathway presents diverse therapeutic targets for aging-related diseases.
The immune-inflammatory response critically contributes to multifactorial ocular surface diseases such as dry eye, characterized by tear film hyperosmolarity, oxidative stress, and epithelial cell damage. [ 288 ] Mitochondrial homeostasis maintains corneal epithelial cell stability to defend against environmental stresses. Recently, researchers have provided evidence for the activation of the cGAS–STING signaling pathway in dry eye disease across both environmental and non-environmental models [ 289 , 290 ] [Figure 3 ], potentially initiated by mitochondrial permeability transition pore opening and the subsequent mtDNA leakage into the cytoplasm. Hyperosmotic conditions also induce ROS production, primarily due to mitochondrial dysfunction, exacerbating oxidative mtDNA damage. [ 291 , 292 ] The cGAS–STING signaling pathway responds by upregulating NF-κB and IFN-β [ 293 ] [Figure 3 ], with oxidized mtDNA detected by cGAS implicated as a trigger. [ 294 ] These results indicate mitochondrial impairment is a key precursor for cGAS–STING activation in dry eye disease. [ 295 ]
Glaucoma is characterized by retinal ganglion cell (RGC) degeneration and neuroinflammation of retinal glial cells. [ 296 ] A recent study [ 297 ] indicated that the cGAS–STING signaling pathway is activated within the microglia of RGCs at the early axonal debris stage, coinciding with mitochondrial dysfunction. Neuroinflammation-induced RGC ischemia may initiate the sensing process and exacerbate retinal damage by amplifying the inflammatory response. [ 298 ] Furthermore, microglial cGAS–STING activation contributes to macroglial reactivity, providing novel insights into the interactions between different glial cells in glaucoma. [ 299 ] Strategies targeting cGAS–STING–IFN signaling, including TBK1 inhibitors, IFNAR1 antibodies, and genetic deletion of STING, are beneficial for protecting RGC cells and preserving visual quality [Figure 3 ].
Ischemia, pathological angiogenesis, photoreceptor degeneration, and inflammation are common events in various retinopathies, such as diabetic retinopathy, age-related macular degeneration, and retinopathy of prematurity. An increasing number of studies are exploring the activation of the cGAS–STING signaling pathway in retinal damage and the corresponding therapeutic options. The cGAS–STING signaling pathway contributes to the activation of retinal myeloid cells, including microglia and macrophages, which can further promote neovascularization in the retina. [ 300 – 302 ] The preservation of mitochondrial function has been shown to reduce retinal damage, [ 301 , 303 ] reinforcing the central roles of mitochondria and the cGAS–STING signaling pathway in retinopathy. Modulating macrophage polarization to block this inflammatory response and alleviate angiogenesis may represent alternative options for anti-VEGF therapies. [ 300 ] Bromodomain and extraterminal domain (BET) protein inhibitors, such as dBET6 and JQ1, [ 304 , 305 ] can also attenuate cGAS–STING signaling pathway activation and protect photoreceptor cells.
Ocular diseases are closely associated with inflammation. The activation of the cGAS–STING, a key inflammatory signaling pathway, contributes to the progression of various ocular diseases, including dry eye disease, glaucoma, and retinal diseases. Targeting the excessive inflammatory responses mediated by the cGAS–STING pathway may present a novel therapeutic strategy for ocular diseases.
CRS is a common upper airway inflammatory disease with two major phenotypes: CRS with nasal polyps (CRSwNP) and CRS without nasal polyps. Eosinophilic CRS (eCRS) is driven by type 2 immune response and is characterized by eosinophil infiltration. [ 306 ] Pattern-recognition receptors such as Toll-like receptors are activated in the epithelial innate immune response, providing antiviral and antibacterial functions. [ 307 ] However, the role of the cGAS–STING signaling pathway in CRS, especially eCRS, requires more in-depth research. The STING signaling pathway exerts a dual role in modulating the innate immune response and type 2 inflammation in CRSwNP patients. [ 308 ] In the eosinophilic subtype, reduced STING expression and subsequent decreased IFN-I production indicate impaired antiviral resistance and exacerbated inflammation [Figure 3 ]. This observed reduction in STING expression may be attributed to the activity of IL-4 and IL-13 in type 2 inflammation. [ 308 ] Researchers have further reported that IL-13 is activated through suppressor of cytokine signaling 1 following defective STING expression in eosinophilic CRSwNP. [ 309 ] Given its involvement in both innate and type 2 immune responses, the STING pathway represents a promising therapeutic target for eosinophilic CRSwNP, a clinically challenging and severe subtype, despite the need for further research.
The cGAS–STING signaling pathway is correlated with oral cancer and inflammatory diseases, offering new insights for therapeutic interventions. Oral squamous cell carcinoma (OSCC) is a cancer that originates from the epithelium of the oral mucosa. It is classified as a type of head and neck squamous cell carcinoma (HNSCC), which ranks as the sixth most common cancer worldwide. [ 310 ] Most patients develop chemotherapy resistance, leading to a poor prognosis and posing significant challenges to treatment. [ 311 ] A recent study suggested targeting casein kinase 2-interacting protein 1 (CKIP-1) may be an effective therapeutic strategy. Silencing CKIP-1 can effectively inhibit various malignant behaviors of OSCC tumors by influencing mitochondrial homeostasis and activating the cGAS–STING signaling pathway. [ 312 ] Another study indicated that STING agonists can positively enhance both local and systemic antitumor immune effects [ 313 ] [Figure 3 ]. Intratumoral injection of STING agonists has been shown to augment checkpoint blockade in HNSCC. Specifically, in preclinical models of HPV-positive oral tumors, the STING agonist ML-RR-CDA can increase PD-1/PD-L1 expression, thereby improving the therapeutic effects of systemic α-PD-1. Apical periodontitis is a common destructive inflammatory oral disease caused primarily by microbial infection. During the dynamic regulation of immune responses, the innate immune system initiates the process through various pattern recognition receptors, including the cGAS. [ 314 , 315 ] Apical periodontitis is characterized by progressive alveolar bone disruption, [ 316 ] a process partly mediated by activated STING signaling [Figure 3 ]. STING inhibitors might provide an effective nonsurgical treatment option by inhibiting osteoclast differentiation and bone resorption, thus preventing bone loss. [ 317 ]