TY - JOUR
T1 - Mean mass-specific metabolic rates are strikingly similar across life's major domains
T2 - Evidence for life's metabolic optimum
AU - Makarieva, Anastassia M.
AU - Gorshkov, Victor G.
AU - Li, Bai An
AU - Chown, Steven L.
AU - Reich, Peter B.
AU - Gavrilov, Valery M.
PY - 2008/11/4
Y1 - 2008/11/4
N2 - A fundamental but unanswered biological question asks how much energy, on average, Earth's different life forms spend per unit mass per unit time to remain alive. Here, using the largest database to date, for 3,006 species that includes most of the range of biological diversity on the planet - from bacteria to elephants, and algae to sapling trees - we show that metabolism displays a striking degree of homeostasis across all of life. We demonstrate that, despite the enormous biochemical, physiological, and ecological differences between the surveyed species that vary over 1020-fold in body mass, mean metabolic rates of major taxonomic groups displayed at physiological rest converge on a narrow range from 0.3 to 9 W kg-1. This 30-fold variation among life's disparate forms represents a remarkably small range compared with the 4,000- to 65,000-fold difference between the mean metabolic rates of the smallest and largest organisms that would be observed if life as a whole conformed to universal quarter-power or third-power allometric scaling laws. The observed broad convergence on a narrow range of basal metabolic rates suggests that organismal designs that fit in this physiological window have been favored by natural selection across all of life's major kingdoms, and that this range might therefore be considered as optimal for living matter as a whole.
AB - A fundamental but unanswered biological question asks how much energy, on average, Earth's different life forms spend per unit mass per unit time to remain alive. Here, using the largest database to date, for 3,006 species that includes most of the range of biological diversity on the planet - from bacteria to elephants, and algae to sapling trees - we show that metabolism displays a striking degree of homeostasis across all of life. We demonstrate that, despite the enormous biochemical, physiological, and ecological differences between the surveyed species that vary over 1020-fold in body mass, mean metabolic rates of major taxonomic groups displayed at physiological rest converge on a narrow range from 0.3 to 9 W kg-1. This 30-fold variation among life's disparate forms represents a remarkably small range compared with the 4,000- to 65,000-fold difference between the mean metabolic rates of the smallest and largest organisms that would be observed if life as a whole conformed to universal quarter-power or third-power allometric scaling laws. The observed broad convergence on a narrow range of basal metabolic rates suggests that organismal designs that fit in this physiological window have been favored by natural selection across all of life's major kingdoms, and that this range might therefore be considered as optimal for living matter as a whole.
KW - Allometry
KW - Body size
KW - Breathing
KW - Energy consumption
KW - Scaling
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U2 - 10.1073/pnas.0802148105
DO - 10.1073/pnas.0802148105
M3 - Article
C2 - 18952839
AN - SCOPUS:55949118803
SN - 0027-8424
VL - 105
SP - 16994
EP - 16999
JO - Proceedings of the National Academy of Sciences of the United States of America
JF - Proceedings of the National Academy of Sciences of the United States of America
IS - 44
ER -