Abstract
BackgroundEndothelial cell senescence is the state of permanent cell cycle arrest and plays a critical role in the pathogenesis of age-related diseases. However, a comprehensive understanding of the gene regulatory network, including genome-wide alternative splicing machinery, involved in endothelial cell senescence is lacking.ResultsWe thoroughly described the transcriptome landscape of replicative senescent human umbilical vein endothelial cells. Genes with high connectivity showing a monotonic expression increase or decrease with the culture period were defined as hub genes in the co-expression network. Computational network analysis of these genes led to the identification of canonical and non-canonical senescence pathways, such as E2F and SIRT2 signaling, which were down-regulated in lipid metabolism, and chromosome organization processes pathways. Additionally, we showed that endothelial cell senescence involves alternative splicing. Importantly, the first and last exon types of splicing, as observed in FLT1 and ACACA, were preferentially altered among the alternatively spliced genes during endothelial senescence. We further identified novel microexons in PRUNE2 and PSAP, each containing 9 nt, which were altered within the specific domain during endothelial senescence.ConclusionsThese findings unveil the comprehensive transcriptome pathway and novel signaling regulated by RNA processing, including gene expression and splicing, in replicative endothelial senescence.
Highlights
Cellular senescence is a permanent state of cell cycle arrest caused by the interruption of cell division with limited replicative capacity, referred to as replicative senescence [1, 2]
Our results showed that alternative first exon (AFE) and alternative last exon (ALE) types of splicing were predominantly induced by Human umbilical vein endothelial cell (HUVEC) senescence
After 60 days of culture, four independent HUVECs (C1–4) stopped dividing, which showed that the population doubling (PD) rate was
Summary
Cellular senescence is a permanent state of cell cycle arrest caused by the interruption of cell division with limited replicative capacity, referred to as replicative senescence [1, 2]. Senescent cells exhibit morphological changes including the formation. Global transcriptome analysis enables a comprehensive understanding of complex biological processes. This technique has been used in several studies to identify senescence-related gene expression changes in inflammatory and mitochondrial pathways in fibroblasts [11,12,13]. Our current knowledge of the gene regulatory network including genome-wide splicing involved in replicative endothelial cell senescence is limited. Endothelial cell senescence is the state of permanent cell cycle arrest and plays a critical role in the pathogenesis of age-related diseases. A comprehensive understanding of the gene regulatory network, including genome-wide alternative splicing machinery, involved in endothelial cell senescence is lacking
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