Abstract

Calcific aortic valve disease (CAVD) is the leading heart valve disorder in the US. It is characterized by an active accumulation of calcium nodules on the aortic valve leaflets which lead to stiffening and remodeling of the valve leaflets causing valve dysfunction, cardiac failure and increased stroke risk. Inflammation and mechanical stresses contribute to CAVD pathogenesis. However, the mechanisms driving the fibrocalcific remodeling of the aortic valve are currently ill-defined. Multiple studies have revealed that the catalytic subunit of telomerase reverse transcriptase (TERT) can induce gene transcription and its overexpression primes mesenchymal stem cells to differentiate into osteoblasts, suggesting that TERT has a role in the activation of osteogenic transcriptional programs. We hypothesized that TERT contributes to early events leading to calcification of the valve leaflet. In human calcified valve tissue, we found that TERT protein is highly expressed in areas of calcification compared to control valve tissue, with no effect on telomere length. Alpha-SMA, a VIC activation marker, and RUNX2, a key transcription factor involved in the osteogenic differentiation of osteoblast, were also elevated in CAVD tissue. Under osteogenic differentiation conditions, human valve interstitial cells (VICs) upregulated TERT, RUNX2, and alpha-SMA protein levels and calcified, while CAVD VICs calcified de novo. Inflammatory stimuli intensified in vitro calcification, and induced TERT, RUNX2, and alpha-SMA protein expression. PLA and ChIP analysis showed that TERT interacts with interacted with Signal Transducer and Activator of Transcription 5A/B (STAT5) and together bind to RUNX2 promoter, respectively. shRNA-mediated TERT downregulation reduced expression of RUNX2 and alpha-SMA and genetic deletion of Tert in murine mesenchymal stem cells and vascular smooth muscle cells prevented calcification. These data provide evidence that TERT is required for calcification, regulates the transition of quiescent VICs into calcifying VICs, and that STAT5 functions as a TERT-interacting partner for DNA binding.

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