Abstract
BACKGROUND: Polycystic ovary syndrome (PCOS) is a common endocrine disorders in women of reproductive age with limited targeted therapies. This study aimed to identify and prioritize potential druggable genes for PCOS through a purely computational, multi-omics approach. METHOD: We conducted an integrated in silico analysis leveraging publicly available datasets. A multi-omics Mendelian randomization (MR) framework was applied to 2,888 druggable genes. Our workflow incorporated two-sample MR for initial discovery of gene-PCOS associations with false discovery rate (FDR) correction, followed by validation using summary-data-based MR (SMR) and colocalization. Tissue-specific effects were assessed via cis-expression quantitative trait loci (cis-eQTL) MR in ovary, uterus, and blood, and epigenetic regulation via methylation QTL (mQTL) MR. The ovarian microenvironment was characterized using CIBERSORT and single-cell RNA sequencing (scRNA-seq). We also assessed whether immune cell traits mediate the causal pathway between cis-eQTLs and PCOS. Finally, we predicted potential drug targets using the Comparative Toxicogenomics Database and thereby performed molecular docking simulations. RESULTS: We identified seven FDR-significant druggable genes associated with PCOS risk: NRBP1, LGR6, GHRL, and IPP as risk-enhancing genes, and CBLN3, VIPR1, and TFRC as protective. SMR analysis confirmed that genetically predicted NRBP1 (OR = 1.5383, p = 8.67E-04), LGR6 (OR = 1.3442, p = 0.0107), GHRL (OR = 1.3391, p = 0.0413) increased PCOS risk, while CBLN3 (OR = 0.8605, p = 4.09E-04) decreased PCOS risk. Colocalization analysis prioritized CBLN3 (PP.H4 = 86.65%) and NRBP1 (PP.H4 = 78.46%) as high-confidence targets. CBLN3 expression was protective across tissues (blood: OR = 0.8586; ovary: OR = 0.8926; uterus: OR = 0.8713), while blood NRBP1 expression increased PCOS risk (OR = 2.1003). mQTL MR analysis revealed significant locus-specific causal effects for CBLN3 and NRBP1. Immune infiltration analysis revealed CBLN3 correlated positively with resting dendritic cells (r = 0.80), and inversely with eosinophils (r=-0.72) and neutrophils (r=-0.66), while NRBP1 associated positively with activated dendritic cells (r = 0.67) and inversely with resting CD4 T cells (r=-0.77). scRNA-seq identified four subtypes of PCOS theca cells, and the expression levels of CBLN3 and NRBP1 in four subtypes were explored. Mediation analysis suggested that the protective effect of CBLN3 may be partially mediated through NKT %lymphocytes. Primary compound screening identified nine high-affinity compounds binding both CBLN3 and NRBP1 (ΔG≤-5 kcal/mol). CONCLUSIONS: Using a comprehensive bioinformatic framework, we prioritize CBLN3 as a novel protective target and NRBP1 as a risk-associated target with multi-omics validation, thus providing mechanistically informed candidates for the development of urgently needed PCOS therapeutics. SUPPLEMENTARY INFORMATION: The online version contains supplementary material available at 10.1186/s13048-025-01889-8.