Dietary restriction (DR) is the most potent method for promoting healthy aging and age-onset disease resistance in animal models. However, DR's therapeutic potential is limited by associated negative physiological effects, including impaired growth, immunity and reproductive capacity. Although nutrient- sensing mediators of DR have been identified, such as mTOR, FOXO/As and the sirtuins, these central nodes recapitulate the entirety of the response, making them sub-optimal therapeutic targets. Our long-term objective is to uncover molecular mechanisms that specifically mediate only the pro-longevity effects of DR to develop optimal therapeutics. A key mediator of DR is AMP-activated protein kinase (AMPK), a cellular fuel gauge activated when energy levels are low. However, like DR, AMPK increases lifespan at the cost of impaired growth and reproduction. The objective in this application is to use the genetically tractable model system C. elegans to identify mechanisms by which AMPK specifically mediates longevity, in order to elucidate the first molecular targets that recapitulate only the pro-health effects of DR. The central hypothesis is that beneficial and detrimental effects of DR can be uncoupled. In support of this hypothesis, specific amino acid combinations in the diet have recently been shown to increase lifespan while maintaining normal reproduction, establishing that the positive effects of DR on lifespan do not require obligate detrimental side effects. However, the molecular mechanisms that uncouple longevity from associated negative effects are unknown. We have uncovered a longevity-specific target of AMPK, the 'CREB regulated transcriptional coactivator (CRTC)-1', that uncouples the longevity effects of AMPK from side effects. We now seek to identify the mechanisms by which CRTC-1 specifically mediates longevity. The rationale for this project is that, before we can generate viable therapies from DR for clinical application we must first identify mechanisms that 1) recapitulate only the positive effects of DR and 2) are effective when applied late in life, post-diagnosis of age- related disease. Based upon strong preliminary data we will test three specific aims. 1) We will examine the role of CRTC-1 in promoting healthy aging via increases to protein fidelity checkpoints. 2) We will utilize a novel inducible system to identify DR mediators with acute, late-onset beneficial effects and 3) We will define the longevity-specific transcriptome regulated by CRTC-1, to determine molecular targets that specifically promote healthy aging without physiological side effects. Collectively, we expect this work to provide the first example of molecular pathways that uncouple the positive and negative effects of DR, a critical step in transitioning DR research to the promotion of healthy human aging.

Public Health Relevance

This proposed research is relevant to the mission of the NIH because uncovering the underlying mechanisms linking energy/nutritional intake and pathology will provide novel therapeutics to both prevent and cure multiple age-onset diseases, which represent ever growing burdens to public health.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Research Project (R01)
Project #
5R01AG044346-05
Application #
9283296
Study Section
Cellular Mechanisms in Aging and Development Study Section (CMAD)
Program Officer
Fridell, Yih-Woei
Project Start
2013-09-30
Project End
2019-05-31
Budget Start
2017-07-01
Budget End
2019-05-31
Support Year
5
Fiscal Year
2017
Total Cost
Indirect Cost
Name
Harvard University
Department
Genetics
Type
Schools of Public Health
DUNS #
149617367
City
Boston
State
MA
Country
United States
Zip Code
02115
Escoubas, Caroline C; Silva-García, Carlos G; Mair, William B (2017) Deregulation of CRTCs in Aging and Age-Related Disease Risk. Trends Genet 33:303-321
Heintz, Caroline; Doktor, Thomas Koed; Lanjuin, Anne et al. (2017) Splicing factor 1 modulates dietary restriction and TORC1 pathway longevity in C. elegans. Nature 541:102-106
Han, Shuo; Schroeder, Elizabeth A; Silva-García, Carlos G et al. (2017) Mono-unsaturated fatty acids link H3K4me3 modifiers to C. elegans lifespan. Nature 544:185-190
Weir, Heather J; Yao, Pallas; Huynh, Frank K et al. (2017) Dietary Restriction and AMPK Increase Lifespan via Mitochondrial Network and Peroxisome Remodeling. Cell Metab 26:884-896.e5
Burkewitz, Kristopher; Weir, Heather J M; Mair, William B (2016) AMPK as a Pro-longevity Target. Exp Suppl 107:227-256
Reis Rodrigues, Pedro; Kaul, Tiffany K; Ho, Jo-Hao et al. (2016) Synthetic Ligands of Cannabinoid Receptors Affect Dauer Formation in the Nematode Caenorhabditis elegans. G3 (Bethesda) 6:1695-705
Hou, Lei; Wang, Dan; Chen, Di et al. (2016) A Systems Approach to Reverse Engineer Lifespan Extension by Dietary Restriction. Cell Metab 23:529-40
Weir, Heather J; Mair, William B (2016) SnapShot: Neuronal Regulation of Aging. Cell 166:784-784.e1
Burkewitz, Kristopher; Morantte, Ianessa; Weir, Heather J M et al. (2015) Neuronal CRTC-1 governs systemic mitochondrial metabolism and lifespan via a catecholamine signal. Cell 160:842-855
Jacobi, David; Liu, Sihao; Burkewitz, Kristopher et al. (2015) Hepatic Bmal1 Regulates Rhythmic Mitochondrial Dynamics and Promotes Metabolic Fitness. Cell Metab 22:709-20

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