Early or Late-Life Treatment With Acarbose or Rapamycin Improves Physical Performance and Affects Cardiac Structure in Aging Mice.

Pharmacological treatments can extend the life span of mice. For optimal translation in humans, treatments should improve health during aging, and demonstrate efficacy when started later in life. Acarbose (ACA) and rapamycin (RAP) extend life span in mice when treatment is started early or later in life. Both drugs can also improve some indices of healthy aging, although there has been little systematic study of whether health benefits accrue differently depending on the age at which treatment is started. Here we compare the effects of early (4 months) versus late (16 months) onset ACA or RAP treatment on physical function and cardiac structure in genetically heterogeneous aged mice. ACA or RAP treatment improve rotarod acceleration and endurance capacity compared to controls, with effects that are largely similar in mice starting treatment from early or late in life. Compared to controls, cardiac hypertrophy is reduced by ACA or RAP in both sexes regardless of age at treatment onset. ACA has a greater effect on the cardiac lipidome than RAP, and the effects of early-life treatment are recapitulated by late-life treatment. These results indicate that late-life treatment with these drugs provide at least some of the benefits of life long treatment, although some of the benefits occur only in males, which could lead to sex differences in health outcomes later in life.

Parvalbumin corrects slowed relaxation in adult cardiac myocytes expressing hypertrophic cardiomyopathy-linked alpha-tropomyosin mutations.

Hypertrophic cardiomyopathy mutations A63V and E180G in alpha-tropomyosin (alpha-Tm) have been shown to cause slow cardiac muscle relaxation. In this study, we used two complementary genetic strategies, gene transfer in isolated rat myocytes and transgenesis in mice, to ascertain whether parvalbumin (Parv), a myoplasmic calcium buffer, could correct the diastolic dysfunction caused by these mutations. Sarcomere shortening measurements in rat cardiac myocytes expressing the alpha-Tm A63V mutant revealed a slower time to 50% relengthening (T50R: 44.2+/-1.4 ms in A63V, 36.8+/-1.0 ms in controls; n=96 to 108; P<0.001) when compared with controls. Dual gene transfer of alpha-Tm A63V and Parv caused a marked decrease in T50R (29.8+/-1.0 ms). However, this increase in relaxation rate was accompanied with a decrease in shortening amplitude (114.6+/-4.4 nm in A63+Parv, 137.8+/-5.3 nm in controls). Using an asynchronous gene transfer strategy, Parv expression was reduced (from approximately 0.12 to approximately 0.016 mmol/L), slow relaxation redressed, and shortening amplitude maintained (T50R=33.9+/-1.6 ms, sarcomere shortening amplitude=132.2+/-7.0 nm in A63V+PVdelayed; n=56). Transgenic mice expressing the E180G alpha-Tm mutation and mice expressing Parv in the heart were crossed. In isolated adult myocytes, the alpha-Tm mutation alone (E180G+/PV-) had slower sarcomere relengthening kinetics than the controls (T90R: 199+/-7 ms in E180G+/PV-, 130+/-4 ms in E180G-/PV-; n=71 to 72), but when coexpressed with Parv, cellular relaxation was faster (T90R: 36+/-4 ms in E180G+/PV+). Collectively, these findings show that slow relaxation caused by alpha-Tm mutants can be corrected by modifying calcium handling with Parv.