Enhanced energy metabolism contributes to the extended life span of calorie-restricted Caenorhabditis elegans
Enhanced energy metabolism contributes to the extended life span of calorie-restricted Caenorhabditis elegans
Caloric restriction (CR) markedly extends life span and improves the health of a broad number of species. Energy metabolism fundamentally contributes to the beneficial effects of CR, but the underlying mechanisms that are responsible for this effect remain enigmatic. A multidisciplinary approach that involves quantitative proteomics, immunochemistry, metabolic quantification, and life span analysis was used to determine how CR, which occurs in the Caenorhabditis elegans eat-2 mutants, modifies energy metabolism of the worm, and whether the observed modifications contribute to the CR-mediated physiological responses. A switch to fatty acid metabolism as an energy source and an enhanced rate of energy metabolism by eat-2 mutant nematodes were detected. Life span analyses validated the important role of these previously unknown alterations of energy metabolism in the CR-mediated longevity of nematodes. As observed in mice, the overexpression of the gene for the nematode analog of the cytosolic form of phosphoenolpyruvate carboxykinase caused a marked extension of the life span in C. elegans, presumably by enhancing energy metabolism via an altered rate of cataplerosis of tricarboxylic acid cycle anions. We conclude that an increase, not a decrease in fuel consumption, via an accelerated oxidation of fuels in the TCA cycle is involved in life span regulation; this mechanism may be conserved across phylogeny.
31414-31426
Yuan, Yiyuan
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Kadiyala, Chandra S.
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Ching, Tsui-Ting
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Hakimi, Parvin
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Saha, Sudipto
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Xu, Hua
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Yuan, Chao
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Mullangi, Vennela
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Wang, Liwen
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Fivenson, Elayne
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Hanson, Richard W.
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Ewing, Rob
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Hsu, Ao-Lin
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Miyagi, Masaru
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Feng, Zhaoyang
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7 September 2012
Yuan, Yiyuan
df9ec813-2a1e-43d7-9996-0a81c4fe34e4
Kadiyala, Chandra S.
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Ching, Tsui-Ting
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Hakimi, Parvin
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Saha, Sudipto
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Xu, Hua
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Yuan, Chao
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Mullangi, Vennela
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Wang, Liwen
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Fivenson, Elayne
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Hanson, Richard W.
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Ewing, Rob
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Hsu, Ao-Lin
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Miyagi, Masaru
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Feng, Zhaoyang
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Yuan, Yiyuan, Kadiyala, Chandra S., Ching, Tsui-Ting, Hakimi, Parvin, Saha, Sudipto, Xu, Hua, Yuan, Chao, Mullangi, Vennela, Wang, Liwen, Fivenson, Elayne, Hanson, Richard W., Ewing, Rob, Hsu, Ao-Lin, Miyagi, Masaru and Feng, Zhaoyang
(2012)
Enhanced energy metabolism contributes to the extended life span of calorie-restricted Caenorhabditis elegans.
The Journal of Biological Chemistry, 287 (37), .
(doi:10.1074/jbc.M112.377275).
(PMID:22810224)
Abstract
Caloric restriction (CR) markedly extends life span and improves the health of a broad number of species. Energy metabolism fundamentally contributes to the beneficial effects of CR, but the underlying mechanisms that are responsible for this effect remain enigmatic. A multidisciplinary approach that involves quantitative proteomics, immunochemistry, metabolic quantification, and life span analysis was used to determine how CR, which occurs in the Caenorhabditis elegans eat-2 mutants, modifies energy metabolism of the worm, and whether the observed modifications contribute to the CR-mediated physiological responses. A switch to fatty acid metabolism as an energy source and an enhanced rate of energy metabolism by eat-2 mutant nematodes were detected. Life span analyses validated the important role of these previously unknown alterations of energy metabolism in the CR-mediated longevity of nematodes. As observed in mice, the overexpression of the gene for the nematode analog of the cytosolic form of phosphoenolpyruvate carboxykinase caused a marked extension of the life span in C. elegans, presumably by enhancing energy metabolism via an altered rate of cataplerosis of tricarboxylic acid cycle anions. We conclude that an increase, not a decrease in fuel consumption, via an accelerated oxidation of fuels in the TCA cycle is involved in life span regulation; this mechanism may be conserved across phylogeny.
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Published date: 7 September 2012
Organisations:
Molecular and Cellular
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Local EPrints ID: 355401
URI: http://eprints.soton.ac.uk/id/eprint/355401
ISSN: 0021-9258
PURE UUID: 96a0ec96-6449-4f93-84ad-f7ab75bc9912
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Date deposited: 20 Aug 2013 13:43
Last modified: 15 Mar 2024 03:44
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Author:
Yiyuan Yuan
Author:
Chandra S. Kadiyala
Author:
Tsui-Ting Ching
Author:
Parvin Hakimi
Author:
Sudipto Saha
Author:
Hua Xu
Author:
Chao Yuan
Author:
Vennela Mullangi
Author:
Liwen Wang
Author:
Elayne Fivenson
Author:
Richard W. Hanson
Author:
Ao-Lin Hsu
Author:
Masaru Miyagi
Author:
Zhaoyang Feng
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