{"paper_id":"e1f42590-61df-47e1-a48c-fbfcebcd17a3","body_text":"As the basic functional unit of ovaries [ 1 ], the normal growth, development and ovulation of follicles are necessary for the generations of mammals [ 2 ]. In  humans , a series of female reproductive diseases such as polycystic ovary syndrome (PCOS) [ 3 , 4 ], endometriosis [ 5 ], and dysfunction of ovarian reserve [ 6 ] present the clinical feature of abnormal follicular growth. However, no effective therapy treats and cures these devastating diseases. Follicular growth is a complex multicellular process, and the granulosa cells (GCs) have been shown to be the main supporting and regulating cells in follicles [ 7 , 8 ]. Previous studies have proved that the proliferation of GCs ensures the follicular development and ovulation [ 2 , 9 , 10 ], while the excessive apoptosis of GCs leads to follicular atresia [ 7 , 11 , 12 ]. Numerous studies have indicated that the DNA methylation catalyzed by DNA methyltransferases (DNMTs) regulates the transcription of genes via altering the chromatin structure to be involved in follicular growth [ 13 ]. DNA hypermethylation is often thought to be associated with gene silencing, whereas DNA demethylation is associated with gene activation [ 14 , 15 ]. Interestingly, previous studies have found that DNA methylation plays an important role in follicular growth [ 16 , 17 ]. The knockdown of  DNMT1  increases the expression of  RSPO2 , thereby inducing follicular growth [ 18 ]. The knockdown of  DNMTs  inhibits the methylation status of  H19 / Igf2  to decrease the apoptosis of ovarian cells [ 19 ].  DNMT1  prevents follicular growth by mediating lncRNA  IFFD  inhibition proliferation and promoting the apoptosis of GCs [ 20 ]. These results suggest that DNMTs may regulate GCs function to modulate follicular growth by directly targeting genes, but the molecular mechanism behind this process is still not fully understood.\nThe solute carrier organic anion transporter family member 3A1 ( SLCO3A1 ) is one of the uptake transporters that belongs to the solute carrier family [ 21 ]. Research revealed that a lower expression of  SLCO3A1  inhibits the transmembrane transport of E1S to decrease the proliferation of breast cancer cells [ 22 ]. Notably, the  SLCO3A1  has been demonstrated to regulate the proliferation and apoptosis of ovarian GCs in rats with PCOS [ 23 ], indicating the potential function of  SLCO3A1  in follicular growth. Unfortunately, the specific mechanisms by which  SLCO3A1  is medicated by DNMTs involve the follicular growth via regulating the proliferation and apoptosis of GCs, which remains to be further explored.\nHence, we aimed to investigate how DNMTs regulate the expression of  SLCO3A1  to modulate the biological function of GCs and the growth of follicles. In this study, we found that the knockdown of  DNMT1  could regulate chromatin accessibility, increase the level of  SLCO3A1  to inhibit the apoptosis of GCs, and it could also induce proliferation by promoting the cycle progression of GCs. Moreover,  SLCO3A1  facilitated E2 secretion to regulate follicular growth. These results might provide a therapeutic strategy for treating female reproductive disorders.\n\nTo investigate the impact of  SLCO3A1  on the proliferation of GCs, empty plasmids (named OE-NC), overexpression plasmids of  SLCO3A1  (named OE-SLCO3A1), small interfering RNA (siRNA) of NC (named KD-NC) and siRNAs of  SLCO3A1  (named KD-SLCO3A1) were transfected into COV434 cells. The mRNA and protein levels of  SLCO3A1  were significantly upregulated by OE-SLCO3A1 treatment compared to OE-NC ( Figure 1 A,B), and 0.5 ng/μL of OE-SLCO3A1 was chosen for subsequent experiments. We found that the mRNA and protein levels of  SLCO3A1  were significantly reduced by KD-SLCO3A1 (siRNA#1, siRNA#2, siRNA#3) treatment compared to KD-NC ( Figure 1 C,D) in the GCs. And we used 50 nM of siRNA#3 for subsequent experiments. The 5-Ethynyl-2′-deoxyuridine (EdU) results showed that the proliferation rate of GCs was significantly increased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 1 E), but it was significantly decreased by KD-SLCO3A1 treatment compared to KD-NC ( Figure 1 F). The mRNA and protein levels of proliferation-related genes (e.g.,  MCL1 ,  PCNA , and  STAR ) were increased by OE-SLCO3A1 treatment compared to OE-NC. ( Figure 1 G,H). Meanwhile, the mRNA and protein levels of  MCL1 ,  PCNA , and  STAR  were decreased by KD-SLCO3A1 treatment compared to KD-NC ( Figure 1 I,J). Moreover, the mRNA and protein levels of  FSHR  were significantly increased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 1 K,L), while the opposite result was found by KD-SLCO3A1 treatment ( Figure 1 M,N). These results suggested that  SLCO3A1  promoted the proliferation of GCs.\nWe next investigated the effects of  SLCO3A1  on the cell cycle distribution and apoptosis of GCs. Flow cytometry results showed that the rate of G0-G1 phase cells was decreased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 2 A), but it was increased by KD-SLCO3A1 treatment compared to KD-NC ( Figure 2 B) in the COV434 cells. The mRNA and protein levels of maker genes involved in the transition from G1 phase to S phase (e.g.,  CCNE1 ,  CDK2 , and  CCND1 ) were increased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 3 C,D), but the opposite results were found for KD-SLCO3A1 treatment ( Figure 2 E,F). The apoptosis rate of GCs was significantly decreased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 2 G), while it was significantly increased by KD-SLCO3A1 treatment compared to KD-NC ( Figure 2 H). Furthermore, the mRNA and protein levels of pro-apoptotic genes (e.g.,  CASP3  and  CASP8 ) were decreased by OE-SLCO3A1 treatment compared to OE-NC ( Figure 2 I,J). The mRNA and protein levels of  CASP3  and  CASP8  increased by KD-SLCO3A1 treatment compared to KD-NC ( Figure 2 K,L). Thus, it was concluded that  SLCO3A1  facilitated the cell cycle-related processes and suppressed the apoptosis of GCs.\nTo further investigate the function of  SLCO3A1  in follicular growth, the ovarian follicles of pigs were subjected to lentiviral-mediated treatments including control for overexpression (LV-NC), overexpression of  SLCO3A1  (LV-SLCO3A1), control for knockdown (sh-NC), and knockdown of  SLCO3A1  (sh-SLCO3A1). It was found that the mRNA and protein levels of  SLCO3A1  were increased by LV-SLCO3A1 treatment compared to LV-NC ( Figure 3 A), but they were decreased by sh-SLCO3A1 treatment compared to sh-NC ( Figure 3 B). The mRNA and protein levels of  CDK4  and  P65  were significantly upregulated by LV-SLCO3A1 treatment compared to LV-NC ( Figure 3 C,D), while the opposite results were observed by sh-SLCO3A1 treatment ( Figure 3 E,F). Together, these data indicated that  SLCO3A1  promoted follicular growth by promoting the proliferation of GCs.\nTo further validate the role of  SLCO3A1  in ovarian follicular growth, LV-NC, LV-SLCO3A1, sh-NC, or sh-SLCO3A1 were injected into the mice. Compared to LV-NC, the mRNA and protein levels of  SLCO3A1  were elevated by LV-SLCO3A1 treatment ( Figure 4 A), while they decreased by sh-SLCO3A1 ( Figure 4 B). The terminal deoxynucleotidyl transferase mediated dUTP nick-end labeling (TUNEL) showed lower green fluorescence intensity with LV-SLCO3A1 treatment compared to LV-NC, but the fluorescence was higher with sh-SLCO3A1 treatment ( Figure 4 C). The hematoxylin and eosin (HE) staining showed that the number of antral follicles and corpus luteum were increased by LV-SLCO3A1 treatment compared to LV-NC, while this number was decreased by sh-SLCO3A1 treatment compared to sh-NC ( Figure 4 D). A previous study shows that the vaginal opening indicates that mice are in the estrus stage [ 24 ], and the age of mice at vaginal opening was earlier by LV-SLCO3A1 treatment compared to LV-NC, but it was significantly delayed by sh-SLCO3A1 treatment compared to sh-NC ( Figure 4 E). The E2 level was significantly elevated by LV-SLCO3A1 treatment compared to LV-NC, while it was significant inhibited by sh-SLCO3A1 treatment compared to sh-NC in serum ( Figure 4 F). The mRNA and protein levels of  CCNB2  and  CDK1  were increased by LV-SLCO3A1 treatment compared to LV-NC ( Figure 4 G,H), while they declined by sh-SLCO3A1 treatment ( Figure 4 I,J). These results suggested that  SLCO3A1  promoted the follicular maturation and eventually facilitated the ovulation and luteinization by inhibiting the apoptosis of GCs and promoting the secretion of E2 in mice.\nTo investigate the regulation of  SLCO3A1  by DNMTs in follicular growth, the expression of  SLCO3A1  in the small (<3 mm in diameter) and large (>3 mm in diameter) follicles of pigs was detected. We found that the mRNA and protein levels of  SLCO3A1  in the large follicles were significantly higher than that in the small follicles ( Figure 5 A,B). Moreover, the mRNA and protein levels of  SLCO3A1  were increased by 5-Aza-CdR treatment compared to DMSO ( Figure 5 C,D). We found that the chromatin accessibilities of region-1, region-2, and region-3 were significantly reduced in the 5-Aza-CdR treated-cells ( Figure 5 E). The siRNAs of  DNMT1 ,  DNMT3A , or  DNMT3B  (named KD-DNMT1, KD-DNMT3A, and KD-DNMT3B, respectively) were transfected into GCs. Both mRNA and protein levels of  SLCO3A1  displayed insignificant changes by KD-DNMT3A or KD-DNMT3B treatment ( Figure 5 F,H,I). But the mRNA and protein levels of  SLCO3A1  increased by KD-DNMT1 treatment ( Figure 5 F,G). These results demonstrated that the knockdown of  DNMT1  likely enhanced the mRNA and protein levels of  SLCO3A1  by regulating the chromatin accessibility.\n\nIn recent years, the incidence of female reproductive disorders, such as PCOS, endometriosis, and diminished ovarian reserve, have been increasing, which is a serious threat to women’s health and fertility [ 25 ]. Follicular growth can be delayed due to a decreased proliferation of GCs and increased apoptosis of GCs, which are thought to play essential roles in the pathogenesis of female reproductive diseases [ 5 , 26 , 27 ]. However, there is no effective therapy for these disorders, and the specific mechanisms regulating follicular growth remain to be further explored. In the present study, we confirmed that the knockdown of  DNMT1  upregulated the level of  SLCO3A1 , resulted in an enhanced proliferation of GCs, increased E2 secretion, and inhibited the apoptosis of GCs, ultimately promoting follicular growth. Targeting  SLCO3A1  may be a new strategy for the clinical management of female reproductive disorders.\nTo explore the biological functions of  SLCO3A1  on the survival of GCs, the overexpression ( Figure 1 A,B) or knockdown ( Figure 1 C,D) of  SLCO3A1  was achieved in GCs. Accumulating studies have shown that the proliferation of GCs is an essential condition that must be present to ensure proper follicular growth [ 28 , 29 , 30 ]. The findings in the present study suggested that  SLCO3A1  promoted GCs proliferation by upregulating  PCNA ,  MCL1 , and  STAR  at the mRNA and protein levels ( Figure 1 E–J).  PCNA  promotes the proliferation of GCs and improves follicular growth in PCOS rats [ 31 ]. In general, cell proliferation and the cell cycle are closely connected [ 32 ].  SLCO3A1  upregulated the expression of  CCND1 ,  CCNE1 , and  CDK2 , which indicated that  SLCO3A1  could promote proliferation by facilitating cell cycle progression ( Figure 2 A–F).  CCND1  and  CCNE1  are crucial regulators of the cell cycle, controlling the G1/S transition [ 33 ], which could promote the proliferation of GCs [ 18 ]. Excessive apoptosis of GCs contributes to follicular atresia [ 34 ]. Our results indicated that  SLCO3A1  inhibited apoptosis by downregulating the mRNA and protein levels of  CASP3  and  CASP8  ( Figure 2 G–L).  CASP3  and  CASP8  are known pro-apoptotic genes that have been reported to promote the apoptosis of GCs in patients with PCOS [ 35 , 36 ]. We found that the expression of  SLCO3A1  in the large follicles was significantly higher than that in the small follicles ( Figure 5 A,B). These suggested that  SLCO3A1  might play a pivotal role as a promoting gene during follicular growth.\nTo further investigate the function of  SLCO3A1 , we successfully achieved the overexpression ( Figure 3 A) or knockdown ( Figure 3 B) of  SLCO3A1  by lentiviral infection using porcine follicles as a model. Our results indicated that  SLCO3A1  promoted proliferation by upregulating the mRNA and protein levels of  P65  and  CDK4  ( Figure 3 C–F).  P65  and  CDK4  were reported to promote the cell proliferation of GCs [ 37 ].\nReferring to previous research methods [ 20 , 38 ], we altered the expression of  SLCO3A1  by an intraperitoneal injection of lentivirus in the ovaries of mice ( Figure 4 A,B). Our findings indicated that  SLCO3A1  upregulated the expression of  ESR1 ,  ESR2  and  FSHR  ( Figure 1 K–N) as well as promoted E2 secretion ( Figure 4 F). Moreover, we found that  SLCO3A1  inhibited the apoptosis of GCs ( Figure 4 C), promoted the formation of antral follicles and corpora lutea ( Figure 4 D), and accelerated vaginal opening in mice ( Figure 4 E). Previous studies have demonstrated that  SLCO3A1  mediates the transport of steroid hormones [ 39 ]. Based on these results, we speculated that  SLCO3A1  regulated follicular growth through the transport of estrogen. Additionally,  SLCO3A1  could promote the proliferation of GCs by upregulating  CCNB2  and  CDK1  at the mRNA and protein levels ( Figure 4 G–J). Our study has several limitations that should be considered. Firstly, the use of five mice per treatment group in the current study may limit the generalizability of our findings. Increasing the number of mice in future studies could enhance the robustness of conclusions. Secondly, the intraperitoneal injection of LV-SLCO3A1 and sh-SLCO3A1 might impact the function of other organs, which could influence the observed changes in the mouse ovaries. Future research could use the tissue-specific gene editing mouse models to more precisely investigate the role of  SLCO3A1  in reproductive disorders. Thirdly, due to limitations in our experimental materials and methods, the number of atretic follicles was not quantified. It is better to count the number of atretic follicles to describe follicular growth.\nDNMTs have been reported as a key regulator of follicular growth [ 40 , 41 , 42 ]. We found that the expression of  SLCO3A1  was significantly increased in the GCs treated with 5-Aza-CdR ( Figure 5 C,D) [ 43 , 44 , 45 ]. But after 5-Aza-CdR treatment, a significant reduction in chromatin accessibility was observed in the promoter region of  SLCO3A1  ( Figure 5 E), suggesting that changes of DNA methylation might be not in line with the changes of chromatin accessibility, and this appearance was consistent with previous findings [ 46 ]. This indicated that the process of modifying chromatin status through DNA demethylation for epigenetic regulation is intricate and merits further investigation. Moreover, our findings suggested that the mRNA and protein levels of  SLCO3A1  were upregulated by KD-DNMT1 treatment ( Figure 5 G). This was in line with previous studies indicating that  DNMT1  may alter the expression of genes in the GCs to affect follicular growth [ 18 ].\nOur results showed that the knockdown of  DNMT1  upregulated the level of  SLCO3A1 , promoted the proliferation of GCs, and inhibited the apoptosis of GCs, ultimately fostering follicular growth. These results suggested that  DNMT1 -mediated  SLCO3A1  might serve as a potential therapeutic strategy for the diseases of follicular disorders.\n\nThe human ovarian granulosa cell line (COV434 cells) utilized in this study was obtained from the cell bank of the Guangdong Provincial Key Laboratory of Agricultural Animal Genome and Molecular Breeding (Guangzhou, China). GCs were cultured with Dulbecco’s modified Eagle’s medium (DMEM, Hyclone, Logan, UT, USA) basal medium containing 10% fetal bovine serum (FBS, Hyclone, Logan, UT, USA) and 1% penicillin–streptomycin (Hyclone, Logan, UT, USA), and they were incubated at 37 °C and 5% CO 2 . When the confluence of GCs reached 70–80%, the transient transfections of plasmids and oligonucleotides were performed using Lipofectamine ™ 3000 reagent (Invitrogen, Waltham, MA, USA). The plasmids included pcDNA3.1 (named OE-NC) and an overexpression plasmid of  SLCO3A1  with pcDNA3.1 as the vector backbone (named OE-SLCO3A1). Oligonucleotides were sourced from Guangzhou Ruibo (Guangzhou, China), and the sequences are shown in  Table 1 . The RT-qPCR, WB, EdU and flow cytometry assays were performed at 48 h after cell transfection.\nThe vivo experiments were performed on C57BL/6J mice. The 3-week-old female C57BL/6J mice were bought from the Southern Medical University Laboratory Animal Center (Guangzhou, China). We randomly divided the mice into four groups (LV-NC, LV-SLCO3A1, sh-NC, sh-SLCO3A1) with 5 individuals in each group. The lentiviral vectors for the overexpression or knockdown of  SLCO3A1  (LV-SLCO3A1 or sh-SLCO3A1) were synthesized by Guangzhou Dongze (Guangzhou, China). Mice were injected with lentiviral vectors at a dosage of 1 × 10 7  TU through intraperitoneal injection after 3 days of adaptive feeding. Injections of lentiviral vectors were given once weekly for three weeks. Mice were sacrificed at 42 days of age.\nOvaries collected from commercial sows at local slaughterhouses were washed twice with phosphate-buffered saline (PBS) containing 1% penicillin–streptomycin, immersed in PBS, and transported back to the laboratory while maintaining a cold environment. After washing the ovaries with PBS in a sterile laboratory, follicles measuring 3–5 mm in diameter were removed from the ovaries using forceps and scalpels. The follicles were washed twice with medium (DMEM/F12 containing 1% penicillin-streptomycin), then individually placed into twenty-four-well plates with an appropriate volume of medium, and cultured in an incubator at 38.5 °C with 5% CO 2 .\nTotal RNA from tissues and cells was extracted following the instructions provided in the RNAfast200 Total RNA Extraction Kit manual (Feijie, Shanghai, China). The purity and integrity of total RNA were detected using UV spectrophotometer (Thermo Fisher Scientific, Waltham, MA, USA). Afterwards, high-quality RNA was used for cDNA reverse transcription. The reaction system comprised 2 μL of 5× PrimeScript RT premix (TaKaRa, Tokyo, Japan) and ≤500 ng of total RNA, which was adjusted to a final volume of 10 μL with RNase-free H 2 O. Hieff  ®  qPCR SYBR Green Master Mix (2×) (YEASEN, Shanghai, China) and a CFX96 Touch Real-Time PCR system (Bio-Rad, Berkeley, CA, USA) were used to quantify the relative levels of mRNAs.  GAPDH  was selected as endogenous control, and the 2 −ΔΔct  method was applied for the analysis of expression level. All primers for RT-qPCR are listed in  Table 2 ,  Table 3  and  Table 4 . The reactions were performed in a total volume of 20 μL per sample, which included 10 μL of SYBR Green Master Mix, 0.6 μL of forward/reverse primer, 1 μL of diluted cDNA template and 7.8 μL of RNA-free water. The cycling conditions were as follows: a holding step at 95 °C for 10 min followed by 40 cycles of 15 s at 95 °C and 1 min at 60 °C.\nCells and tissues were lysed using RIPA (Bestbio, Shanghai, China) containing 1% Protease Inhibitor (Biosharp, Beijing, China) to obtain protein samples. The total protein concentration was determined using the BCA Protein Assay Kit (Biosharp, Beijing, China). Protein separation was performed by electrophoresis using Future PAGE TM  protein precast gels. The separated proteins were transferred to a polyvinylidene fluoride (PVDF) membrane using the eBlot™ L1 membrane converter (GenScript, Nanjing, China). The PVDF membranes were blocked with 5% skim milk powder for 2 h, which was followed by incubation in primary antibody diluent for 12 h. The primary antibodies used were anti-SLCO3A1 (A14276, ABclonal, 1:1000), anti-DNMT1 (DF7376, Affinity, 1:1000), anti-DNMT3A (DF7226, Affinity, 1:1000), anti-DNMT3B (AF5493, Affinity, 1:1000), anti-MCL1 (38113, Signalway, 1:1000), anti-PCNA (60097-1-Ig, Proteintech, 1:10,000), anti-STAR (bs-20387R, Bioss, 1:1000), anti-FSHR (22665-1-AP, Proteintech, 1:1000), anti-CCNE1 (AF4713, Affinity, 1:1000), anti-CDK2 (AF6237, Affinity, 1:1000), anti-CCND1 (AF0931, Affinity, 1:1000), anti-CASP3 (AF6311, Affinity, 1:1000), anti-CASP8 (AF6442, Affinity, 1:1000), anti-CASP9 (AF6348, Affinity, 1:1000), anti-β-Tubulin (10068-1-Ap, Proteintech, 1:1000), anti-GAPDH (YN5585, Immunowau, 1:5000), anti-P65 (10745-1-AP, Proteintech, 1:1000), anti-CDK4 (DF6102, Affinity, 1:1000), anti-CCNB2 (bs-6656R, Bioss, 1:1000), and anti-CDK1 (A0220, Abclonal, 1:1000). The horseradish peroxidase-conjugated goat anti-rabbit immunoglobulin G (IgG) (ab205718, abcam, 1:5000) and goat anti-mouse IgG (L3032-1, Signalway, 1:20,000) were used as the secondary antibodies. The PVDF membranes were incubated in the secondary antibody dilution for 1.5–2 h at room temperature. ECL development solution was added dropwise to the PVDF membrane, and on-line development was performed using a fully automated chemiluminescence image analysis system.\nThe cell proliferation analysis was conducted using the Cell-Light™ EdU Apollo 567 In Vitro Kit (RiboBio, Guangzhou China). Cells were incubated with 50 μM EdU medium for 2 h, after which the medium was discarded. The cells were then washed twice with PBS for 5 min each time. Following this, cell fixative was added to each well, and the cells were incubated at room temperature for 15–30 min before being washed with PBS for 5 min. Osmolyte was added to each well, and permeabilization was performed for 8 min. Subsequently, the cells were washed with PBS for 5 min. Next, 1 × Apollo staining reaction solution was added to each well, and the cells were incubated for 30 min at room temperature with external foil covering. The cells were then washed with PBS for 5 min, and another round of permeabilization was conducted. DAPI reaction solution was added to each well, which was followed by a 30-min incubation at room temperature with foil covering. Finally, three randomly selected fields of view in each well were observed under a Nikon ECLIPSE Ti2 fluorescence microscope (Nikon, Tokyo, Japan), and images were captured.\nThe apoptosis rate was detected using an Annexin V-FITC/PI Apoptosis Detection Kit (BD, USA). The cells were collected and washed twice with PBS (Biosharp, Beijing, China), which was followed by gentle suspension in 500 μL of 1× Annexin V Buffer. Subsequently, 5 μL of Annexin V-FITC and 5 μL of propidium iodide staining solution was added to the cells, which were then incubated at 24 °C for 15 min while protected from light. The cell cycle distribution of granulosa cells (GCs) was determined using a cell cycle assay kit (KeyGEN, Nanjing, China). After collection and two washes with PBS, 500 μL of PI/RNase staining buffer was added to each tube of cell samples. The cells were gently resuspended and incubated for 15 min at 37 °C in the absence of light. Finally, the apoptosis rate and cell cycle distribution were analyzed by flow cytometry (BD, Franklin Lakes, NJ, USA) and Flowjo software (version 7.6).\nThe number of follicles and corpus luteum were detected by HE staining. The largest cross-section cut along the suspensory ligament of the ovary was stained with hematoxylin–eosin, and images were observed and acquired under a Nikon ECLIPSE Ti2 microscope (Nikon, Tokyo, Japan).\nThe TUNEL method was used to detect apoptosis in mouse ovarian GCs. The sections were deparaffinized using xylene and dehydrated with anhydrous ethanol, which was followed by repair using DNase-free proteinase K. Subsequently, the sections were incubated with 50 μL of the TUNEL assay solution for 60 min at 37 °C while protected from light. After incubation, the sections were washed three times with PBS and then sealed using an anti-fluorescence quenching sealer before observation under a Nikon ECLIPSE Ti2 fluorescence microscope (Nikon, Tokyo, Japan).\nThe Mouse E2 ELISA kit (JM-02849 M2) from Jingmai Biotechnology Co., Ltd. (Jiangsu, China) was employed to determine the concentration of E2 in mouse serum. Specific operational instructions were followed as per the kit manual. The relevant reagents were equilibrated at room temperature for 20 min. Fifty microliters of different standard concentrations was added to the standard wells in the ELISA plate, while 50 μL of 5-fold diluted samples to be tested was added to the sample wells. Subsequently, 100 μL of horseradish peroxidase (HRP)-labeled detection antibody was added to each well, and the reaction wells were sealed with a membrane and incubated at 37 °C for 1 h. After discarding the liquid, each well was filled with washing solution and left to stand for 1 min with the washing step repeated 5 times. Chromogen solution A (50 μL) and chromogen solution B (50 μL) were added to each well, which was followed by incubation at 37 °C away from light for 15 min. Finally, 50 μL of stop solution was added to each well, and the optical density (OD) was read at 450 nm using a microtiter plate reader within 15 min.\nThe chromatin accessibility assay in this study was conducted using the EpiQuik™ Chromatin Accessibility Assay Kit (EPIGENTEK, Farmingdale, NY, USA) following the manufacturer’s instructions. Granulosa cells (GCs) were collected and suspended in 1 × lysis buffer. The cell suspension was divided into sample and No-Nse control groups. Both groups were incubated on ice, which was followed by vortexing and centrifugation to remove the supernatant. The chromatin was washed with 1 mL 1 × wash buffer at 4 °C and centrifuged to discard the supernatant. Subsequently, NDB and Nse were added to the sample group, while the No-Nse control group was treated with NDB only. The Nse reaction mixture was added, which was followed by incubation of the chromatin pellet under specified conditions. DNA was eluted from the binding columns using elution solution (ES) and centrifugation. We designed three primer pairs in the promoter region of  SLOC3A1  (region-1, 282 bp, +971/+1252 bp, region-2, 125 bp, +1433/+1557 bp, and region-3, 209 bp, +1623/+1831 bp, transcription start site = +2000,  Table 5 ). Hieff  ®  qPCR SYBR Green Master Mix and a CFX96 Touch Real-Time PCR system were used to measure the amplification efficiency. The reaction volume was consistent with that of the RT-qPCR reaction. Amplification programs were performed using a two-step method: pre-denaturation at 95 °C for 10 min, which was followed by 40 cycles including denaturation at 95 °C for 15 s and annealing/extension at 60 °C for 1 min. The fold enrichment (FE) in the  SLCO3A1  promoter region was calculated using the formula  FE  = 2 (Nse CT − no-Nse CT)  × 100%.\nAll statistical analyses were performed with GraphPad Prism software (version 9.0, Boston, MA, USA). The data were expressed as the mean ± SD from at least three independent experiments, and an independent samples  t -test was used for numerical data. In all cases, *  p  < 0.05, **  p  < 0.01, ***  p  < 0.001,  ns   p  > 0.05.\n\nTaken together, we found that the knockdown of  DNMT1  upregulated the level of  SLCO3A1 , leading to a promoted proliferation of GCs, increased E2 secretion, and inhibited apoptosis of GCs, ultimately fostering follicular growth. This suggested that targeting  SLCO3A1  could be a potential strategy for treating female reproductive diseases.","source_license":"CC-BY-4.0","license_restricted":false}