Abstract 634: Partial Genetic Disruption of mTOR Signaling Does Not Improve Vascular Endothelial Function in Hypercholesterolemic Mice

Abstract

Endothelial cell senescence promotes inflammation and impairs endothelium-dependent vasodilation. While aging, hypercholesterolemia, and caloric excess are known to drive cellular senescence in part through activation of mTOR, it is unknown whether reducing mTOR signaling can improve vasomotor function in aging mice. Here, we used hypercholesterolemic mice (Ldlr -/- /apoB 100/100 , or LA) carrying intact copies of mTOR (LA-mTOR +/+ ) or were deficient in one copy of mTOR (LA- mTOR +/- ). Mice were fed Western Diet for 6 or 12 months, and vasomotor function in aorta was evaluated using isolated organ chamber baths. Maximum relaxation to acetylcholine (MR ACH ) was progressively impaired from 6 months to 12 months in LA-mTOR +/+ mice (55±4% and 30±4%, respectively). In contrast to our hypothesis, however, MR ACH was not significantly improved in LA-mTOR +/- mice at either time point (62±3% and 35±5%, respectively). Interestingly, a subgroup analysis showed significant improvement in MR ACH in male mice at the 6-month point (male LA-mTOR +/+ mice = 30 ± 9% vs male LA-mTOR +/- mice = 55±4%; p < 0.01), whereas vasomotor function in female mice was nearly identical across groups. There was no significant difference at the 12-month point (male LA-mTOR +/+ mice = 19 ± 3% vs male LA-mTOR +/- mice = 22 ± 5%). Relaxation to acetylcholine was attenuated by L-NAME at 6 months and 12 months (but identical between genotypes) and relaxation to nitroprusside was identical between strains at each time point, suggesting that changes in endothelial function were not masked by compensatory mechanisms (e.g., endothelium-derived hyperpolarizing factors). Furthermore, reduction of mTOR did not elicit changes in maximal tension generated in response to Prostaglandin F 2 α at either time point. Collectively, despite compelling evidence from in vitro model systems, genetic reduction of mTOR signaling in vivo does not appear to be sufficient to improve vasomotor function in our model of aging hypercholesterolemic mice. Our data do, however, shed light on a potential role of sex in dictating phenotypic changes in early to moderate stages of disease, which warrants further investigation.