Abstract
Background/Objectives: The INK4 locus at chromosome 9p21.3, encoding CDKN2A, CDKN2B and the long non-coding RNA CDKN2B-AS1 (ANRIL), has been implicated in multiple diseases, including glaucoma and cardiovascular disease. ANRIL plays a critical role in gene regulation, inflammation and cell proliferation, contributing to disease susceptibility through shared molecular mechanisms. This study aims to identify SNPs within the INK4 locus associated with both glaucoma and CVD using the Open Targets Genetics platform and assess their pleiotropic effects. Methods: We utilised the Open Targets Genetics platform to identify SNPs at the INK4 locus associated with glaucoma and CVD. For each SNP, we recorded its genomic location, statistical significance and associated phenotypes. We further analysed the SNPs using the Genome Aggregation Database (gnomAD) to confirm their genomic position. Phenotypic associations were assessed using PheWAS data. Results: We identified 20 GWAS SNPs significantly associated with both glaucoma and CVD. All SNPs were located within intronic regions of the long non-coding RNA ANRIL. Certain SNPs such as rs4977756, rs1333037 and rs1063192 have known pleiotropic effects, influencing retinal ganglion cell survival in glaucoma and vascular smooth muscle cell proliferation in CVD. These SNPs influence shared biological pathways, including inflammation, oxidative stress and epigenetic regulation, and may exert either protective or pathogenic effects. Certain SNPs such as rs7853090 and rs1434537531 remain underexplored, emphasising the need for further research. Conclusions: This study highlights the pleiotropic role of ANRIL in glaucoma and CVD, driven by shared genetic and molecular pathways. While SNPs within ANRIL provide valuable insights into disease mechanisms, these conditions remain complex, influenced by multiple genetic and environmental factors. Targeting ANRIL therapeutically poses challenges due to its non-coding nature, but emerging RNA-based therapies, including antisense oligonucleotides and small-molecule modulators, hold promise. Further research into underexplored SNPs and ANRIL's regulatory mechanisms is essential for advancing therapeutic development and understanding these multifactorial diseases.