Ying Ann Chiao scite author profile

Chronic caloric restriction (CR) and rapamycin inhibit the mechanistic target of rapamycin (mTOR) signaling, thereby regulating metabolism and suppressing protein synthesis. Caloric restriction or rapamycin extends murine lifespan and ameliorates many aging-associated disorders; however, the beneficial effects of shorter treatment on cardiac aging are not as well understood. Using a recently developed deuterated-leucine labeling method, we investigated the effect of short-term (10 weeks) CR or rapamycin on the proteomics turnover and remodeling of the aging mouse heart. Functionally, we observed that short-term CR and rapamycin both reversed the pre-existing age-dependent cardiac hypertrophy and diastolic dysfunction. There was no significant change in the cardiac global proteome (823 proteins) turnover with age, with a median half-life 9.1 days in the 5-month-old hearts and 8.8 days in the 27-month-old hearts. However, proteome half-lives of old hearts significantly increased after short-term CR (30%) or rapamycin (12%). This was accompanied by attenuation of age-dependent protein oxidative damage and ubiquitination. Quantitative proteomics and pathway analysis revealed an age-dependent decreased abundance of proteins involved in mitochondrial function, electron transport chain, citric acid cycle, and fatty acid metabolism as well as increased abundance of proteins involved in glycolysis and oxidative stress response. This age-dependent cardiac proteome remodeling was significantly reversed by short-term CR or rapamycin, demonstrating a concordance with the beneficial effect on cardiac physiology. The metabolic shift induced by rapamycin was confirmed by metabolomic analysis.

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Normalization of NAD ⁺ Redox Balance as a Therapy for Heart Failure

Lee

et al. 2016

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Background heart failure has become increasingly prevalent along with the aging population and the increased survival of acute ischemic heart events. Impairments of mitochondrial function in the heart are intricately linked to the development of heart failure but there is no therapy for mitochondrial dysfunction in the clinic. Methods and Results we report that NAD+ redox imbalance (increased NADH/NAD+) and protein hyperacetylation, previously observed in genetic models of defective mitochondrial function, are also present in human failing hearts as well as in mouse hearts with pathological hypertrophy. Elevation of NAD+ levels by stimulating the NAD+ salvage pathway suppressed mitochondrial protein hyperacetylation and cardiac hypertrophy, and improved cardiac function in responses to stresses. Acetylome analysis identified a subpopulation of mitochondrial proteins that was sensitive to changes in the NADH/NAD+ ratio. Hyperacetylation of mitochondrial malate-aspartate shuttle proteins impaired the transport and oxidation of cytosolic NADH in the mitochondria, resulting in altered cytosolic redox state and energy deficiency. Furthermore, acetylation of oligomycin-sensitive conferring protein at lysine-70 in ATP synthase complex promoted its interaction with cyclophilin D, and sensitized the opening of mitochondrial permeability transition pore. Both could be alleviated by normalizing the NAD+ redox balance either genetically or pharmacologically. Conclusions we show that mitochondrial protein hyperacetylation due to NAD+ redox imbalance contributes to the pathological remodeling of the heart via two distinct mechanisms. Our preclinical data demonstrate a clear benefit of normalizing NADH/NAD+ imbalance in the failing hearts. These findings have a high translational potential as the pharmacological strategy of increasing NAD+ precursors are feasible in human.

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Mitochondrial oxidative stress in aging and healthspan

et al. 2014

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The free radical theory of aging proposes that reactive oxygen species (ROS)-induced accumulation of damage to cellular macromolecules is a primary driving force of aging and a major determinant of lifespan. Although this theory is one of the most popular explanations for the cause of aging, several experimental rodent models of antioxidant manipulation have failed to affect lifespan. Moreover, antioxidant supplementation clinical trials have been largely disappointing. The mitochondrial theory of aging specifies more particularly that mitochondria are both the primary sources of ROS and the primary targets of ROS damage. In addition to effects on lifespan and aging, mitochondrial ROS have been shown to play a central role in healthspan of many vital organ systems. In this article we review the evidence supporting the role of mitochondrial oxidative stress, mitochondrial damage and dysfunction in aging and healthspan, including cardiac aging, age-dependent cardiovascular diseases, skeletal muscle aging, neurodegenerative diseases, insulin resistance and diabetes as well as age-related cancers. The crosstalk of mitochondrial ROS, redox, and other cellular signaling is briefly presented. Potential therapeutic strategies to improve mitochondrial function in aging and healthspan are reviewed, with a focus on mitochondrial protective drugs, such as the mitochondrial antioxidants MitoQ, SkQ1, and the mitochondrial protective peptide SS-31.

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Matrix metalloproteinase-9 deletion attenuates myocardial fibrosis and diastolic dysfunction in ageing mice

et al. 2012

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Ying Ann Chiao

Altered proteome turnover and remodeling by short‐term caloric restriction or rapamycin rejuvenate the aging heart

Normalization of NAD ⁺ Redox Balance as a Therapy for Heart Failure

Mitochondrial oxidative stress in aging and healthspan

Matrix metalloproteinase-9 deletion attenuates myocardial fibrosis and diastolic dysfunction in ageing mice

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Ying Ann Chiao

Altered proteome turnover and remodeling by short‐term caloric restriction or rapamycin rejuvenate the aging heart

Normalization of NAD + Redox Balance as a Therapy for Heart Failure

Mitochondrial oxidative stress in aging and healthspan

Matrix metalloproteinase-9 deletion attenuates myocardial fibrosis and diastolic dysfunction in ageing mice

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Normalization of NAD ⁺ Redox Balance as a Therapy for Heart Failure