Calorie restriction is known to prolong average and maximum life spans in many species. One of the most widely accepted theories of aging is the oxidative stress theory which hypothesizes that oxidative damage produced by reactive oxygen species (ROS) accumulates over time leading to the development of diseases of aging such as cancer, cardiovascular disease, frailty and eventually death. Since ROS is a byproduct of energy metabolism, we hypothesize that calorie restriction will cause a metabolic adaptation (decrease in energy expenditure larger than accounted for by the decrease in metabolic body size) associated with a decrease in ROS-mediated oxidative damage. More specifically, we hypothesize that the decrease in energy expenditure (24-hour sedentary and sleeping) measured in a respiratory chamber will be larger than that expected on the basis of the changes in fat-free mass and fat mass and that this adaptation is associated with reduced activities of the sympathetic and thyroid systems. Furthermore, we will determine whether the magnitude of this metabolic adaptation is related to the calorie restriction-induced decrease in markers of oxidative stress to lipids (urinary isoprostanes), proteins (in blood) and DNA (nucleated blood cells). We will determine for the first time whether the metabolic adaptation is long lasting and dependent on the state of energy balance since studies will be performed after 1 year (probably still in negative energy balance) and after 2 years (now in energy balance) of 25% calorie restriction. The proposed study will be conducted as an ancillary study of a randomized clinical trial of calorie restriction (CALERIE). Importantly, our data will be compared to those obtained on mitochondrial function measured in vitro and in vivo in another ancillary study (PI, SR Smith).

Public Health Relevance

The proposed studies have been designed to test one of the major hypotheses explaining why caloric restriction increases lifespan in almost all animal species. This hypothesis """"""""rate of living theory"""""""" states that life expectancy of an animal is inversely related to its metabolic rate per unit of weight. We propose to test whether a lowering of the """"""""rate of living"""""""" (energy metabolism) is associated with an accompanying decrease in body temperature and oxidative stress in 50 volunteers consuming 25% less calories per day for 2 years. Both low body temperature and low oxidative stress are predictive of longer life.

Agency
National Institute of Health (NIH)
Institute
National Institute on Aging (NIA)
Type
Research Project (R01)
Project #
5R01AG029914-04
Application #
8092707
Study Section
Aging Systems and Geriatrics Study Section (ASG)
Program Officer
Romashkan, Sergei
Project Start
2008-08-15
Project End
2013-06-30
Budget Start
2011-07-15
Budget End
2012-06-30
Support Year
4
Fiscal Year
2011
Total Cost
$200,733
Indirect Cost
Name
Lsu Pennington Biomedical Research Center
Department
Type
Organized Research Units
DUNS #
611012324
City
Baton Rouge
State
LA
Country
United States
Zip Code
70808
Redman, Leanne M; Smith, Steven R; Burton, Jeffrey H et al. (2018) Metabolic Slowing and Reduced Oxidative Damage with Sustained Caloric Restriction Support the Rate of Living and Oxidative Damage Theories of Aging. Cell Metab 27:805-815.e4
Marlatt, Kara L; Redman, Leanne M; Burton, Jeff H et al. (2017) Persistence of weight loss and acquired behaviors 2 y after stopping a 2-y calorie restriction intervention. Am J Clin Nutr 105:928-935
Most, Jasper; Tosti, Valeria; Redman, Leanne M et al. (2017) Calorie restriction in humans: An update. Ageing Res Rev 39:36-45
Sparks, Lauren M; Redman, Leanne M; Conley, Kevin E et al. (2016) Differences in Mitochondrial Coupling Reveal a Novel Signature of Mitohormesis in Muscle of Healthy Individuals. J Clin Endocrinol Metab 101:4994-5003