Loss Of The Smooth- muscle-cell-angiotensin Ii-sensitive Lncrna Leads To Smc Hypertrophic And Hypertensive Remodeling Due To Cell Cycle Dysregulation

Vascular smooth muscle cells (SMC) responses to increased levels of Ang II during hypertensive remodeling included enhanced vasoconstriction and hypertrophy due to the enlargement of the SMC on the vessel wall. Hypertrophic SMC usually present defects in cell division and cell polyploidy. However, the molecular mechanisms controlling SMC hypertrophy and polyploidy vs. hyperplasia are still not fully understood. Long-non-coding-RNAs (LncRNAs) are epigenetic regulators of gene expression influencing biological processes, including cell division fidelity. We discovered a novel lncRNA decreased in dedifferentiated SMC, the SMC-Ang II-Sensitive (SAS) lncRNA, which expression is reduced in response to Ang-II in cultured SMC and the aorta of hypertensive mice, suggesting a role in mediating hypertension-induced SMC hypertrophy. Publicly available transcriptional datasets revealed that SAS is preferentially expressed in SMC-rich tissues, including the aorta and renal artery, in humans and mice. Yet, the functional relevance of SAS in SMC has never been investigated. Knockdown of SAS reduces proliferation and migration in SMC treated with Platelet-Derived Growth Factor (PDGF-BB). SAS knockdown was also associated with distinct SMC hypertrophic morphological changes, including enlargement in cell size and polynucleation in vitro. We have generated a SAS KO mouse, and aortas from these mice present a higher number of polynucleated medial SMC than their WT littermates. These data correlate with a cell cycle arrest in G1 and senescence phenotype that SAS deficient SMC present due to dysregulation in cyclins expression. Furthermore, SAS defective cells show mitochondria hyperfusion and increased oxygen consumption that correlates with the observed senescence and arrest on the G1/S checkpoint, and it is exacerbated by treatment with Ang-II. Interestingly, treatment with Losartan, an Ang-II receptor inhibitor, rescues SAS expression on Ang-II treated SMC and diminishes SMC hypertrophy. Together, these observations suggest that a decrease in SAS causes SMC hypertrophy due to defects in cell cycle completion. SAS is a potent regulator of SMC morphology and is required for proper cell division and mitochondria organization.