BackgroundSince the discovery of the Proprotein Convertase Subtilisin/Kexin Type 9(PCSK9) gene has been involved in regulating low-density lipoprotein metabolism and cardiovascular disease (CVD), many therapeutic strategies directly targeting PCSK9 have been introduced. PCSK9 gain of function (GoF) mutations are associated with autosomal dominant hypercholesterolemia (ADH) and premature atherosclerosis. In contrast, PCSK9 loss of function (LOF) mutations have cardioprotective effects and can lead to familial hypo cholesterol in some instances. However, its potential impacts beyond the typical effects on lipid metabolism have not been elucidated. Therefore the study aimed to identify and verify PCSK9′s possible effects beyond its traditional role in lipid metabolism. MethodsThe S127R is a PCSK9 gain of function mutation. Firstly, We used the data of the gene expression Omnibus(GEO) database to identify the differentially expressed genes between S127R mutation carriers and ordinary people. Secondly, the identification and analysis of significant genes were performed with various bioinformatics programs. Thirdly, to verify the possible effect and the potential pathways of PCSK9 on angiogenesis, we constructed PCSK9 low and high expression models by transfecting PCSK9-siRNA (small interfering RNA) and PCSK9-plasmid complex into human umbilical vein endothelial cells (HUVECs), respectively. Furthermore, Wound-Healing Assay and Capillary tube formation assay were applied to measure the effect of PCSK9 on angiogenesis. Fourthly, the expression level of VEGFR2 and the significant genes between PCSK9 low and high expression models were verified by quantitative real-time PCR. All data were analysed by GraphPad Prism 8 software. Results88 DEGs were identified, including 45 up-regulated and 43 down-regulated DEGs. Furthermore, we identified the six genes (MMP9, CASP3, EGR1, NGFR, LEFTY1 and NODAL) as significantly different genes between PCSK9-S127R and Control hiPSC. Further, we found that these significant difference genes were mainly associated with angiogenesis after enrichment analysis. To verify the possible effect of PCSK9 on angiogenesis, we constructed low and high-expression PCSK9 models by transfecting siRNA and PCSK9-plasmid complex into human umbilical vein endothelial cells (HUVECs), respectively. The tubule formation test and Wound healing assays showed that overexpression of PCSK9 had an inhibitory effect on angiogenesis, which could be reversed by decreasing the expression of PCSK9. Moreover, bioinformatics analysis indicated that the six hub genes (MMP9, CASP3, EGR1, NGFR, LEFTY1 and NODAL) might play a vital role in the biological function of PCSK9 in angiogenesis. Real-time quantitative PCR was applied to clarify the expression profiles of these critical genes in overexpression/knockdown PCSK9. Finally, the expression levels of MMP9, Caspase3, LEFTY1, and NODAL were suppressed by overexpression of PCSK9 and could be alleviated by PCSK9 knockdown. Otherwise, EGR1 had the opposite expression trend, and there was no specific trend of NGFR after repeated experiments. ConclusionPCSK9 might play an essential role in angiogenesis, unlike its typical role in lipid metabolism, and MMP9, Caspase3, LEFTY1, NODAL, and EGR1 may be involved in the regulation of angiogenesis as critical genes.