Endothelial-specific telomerase inactivation causes telomere-independent cell senescence and multi-organ dysfunction characteristic of aging.
Zhanguo GaoRafael Bravo SantosJoseph RupertRachel Van DrunenYongmei YuKristin Eckel-MahanMikhail G KoloninPublished in: Aging cell (2024)
It has remained unclear how aging of endothelial cells (EC) contributes to pathophysiology of individual organs. Cell senescence results in part from inactivation of telomerase (TERT). Here, we analyzed mice with Tert knockout specifically in EC. Tert loss in EC induced transcriptional changes indicative of senescence and tissue hypoxia in EC and in other cells. We demonstrate that EC-Tert-KO mice have leaky blood vessels. The blood-brain barrier of EC-Tert-KO mice is compromised, and their cognitive function is impaired. EC-Tert-KO mice display reduced muscle endurance and decreased expression of enzymes responsible for oxidative metabolism. Our data indicate that Tert-KO EC have reduced mitochondrial content and function, which results in increased dependence on glycolysis. Consistent with this, EC-Tert-KO mice have metabolism changes indicative of increased glucose utilization. In EC-Tert-KO mice, expedited telomere attrition is observed for EC of adipose tissue (AT), while brain and skeletal muscle EC have normal telomere length but still display features of senescence. Our data indicate that the loss of Tert causes EC senescence in part through a telomere length-independent mechanism undermining mitochondrial function. We conclude that EC-Tert-KO mice is a model of expedited vascular senescence recapitulating the hallmarks aging, which can be useful for developing revitalization therapies.
Keyphrases
- endothelial cells
- skeletal muscle
- high fat diet induced
- dna damage
- adipose tissue
- high glucose
- oxidative stress
- wild type
- single cell
- metabolic syndrome
- cell therapy
- induced apoptosis
- poor prognosis
- mesenchymal stem cells
- type diabetes
- machine learning
- high fat diet
- vascular endothelial growth factor
- endoplasmic reticulum stress
- bone marrow
- cell death
- transcription factor
- binding protein
- big data