Peter Lenart1,2, Julie Bienertová-Vašků1, Luděk Berec3,4. 1. Research Centre for Toxic Compounds in the Environment, Faculty of Science, Masaryk University, Kamenice 5, Building A29, 62500, Brno, Czech Republic. 2. Department of Experimental Biology, Faculty of Science, Masaryk University, Kamenice 5, 62500, Brno, Czech Republic. 3. Centre for Mathematical Biology, Institute of Mathematics, Faculty of Science, University of South Bohemia, Branišovská 1760, 37005, Ceske Budejovice, Czech Republic. lberec@prf.jcu.cz. 4. Department of Ecology, Biology Centre, Institute of Entomology, Czech Academy of Sciences, Branišovská 31, 37005, Ceske Budejovice, Czech Republic. lberec@prf.jcu.cz.
Abstract
BACKGROUND: The pace of aging varies considerably in nature. The best-known explanation of the evolution of specific rates of aging is the Williams' hypothesis suggesting that the aging rate should correlate with the level of extrinsic mortality. However, the current evidence is inconclusive with various examples where the Williams' hypothesis seems to be correct and where it doesn't. Here we explore the relationship between extrinsic mortality and aging rate by developing a simulation model of the evolution of aging rate in prey subject to predation. RESULTS: Our results suggest that more intense predation leads to the evolution of faster pace of aging in prey. However, this effect slowly vanishes when the predator diet breadth is allowed to evolve, too. Furthermore, in our model, the evolution of a specific aging rate is driven mainly by a single parameter, the strength of a trade-off between aging and fecundity. Indeed, in the absence of this trade-off the evolutionary impacts of predation on the prey aging rate appear random. CONCLUSIONS: We show that the William's hypothesis appears valid when there is a trade-off between aging and fecundity and predators and prey do not coevolve. However, we also show that when the prey and predators coevolve or if there is no trade-off between aging and fecundity the William`s hypothesis is no longer applicable.
BACKGROUND: The pace of aging varies considerably in nature. The best-known explanation of the evolution of specific rates of aging is the Williams' hypothesis suggesting that the aging rate should correlate with the level of extrinsic mortality. However, the current evidence is inconclusive with various examples where the Williams' hypothesis seems to be correct and where it doesn't. Here we explore the relationship between extrinsic mortality and aging rate by developing a simulation model of the evolution of aging rate in prey subject to predation. RESULTS: Our results suggest that more intense predation leads to the evolution of faster pace of aging in prey. However, this effect slowly vanishes when the predator diet breadth is allowed to evolve, too. Furthermore, in our model, the evolution of a specific aging rate is driven mainly by a single parameter, the strength of a trade-off between aging and fecundity. Indeed, in the absence of this trade-off the evolutionary impacts of predation on the prey aging rate appear random. CONCLUSIONS: We show that the William's hypothesis appears valid when there is a trade-off between aging and fecundity and predators and prey do not coevolve. However, we also show that when the prey and predators coevolve or if there is no trade-off between aging and fecundity the William`s hypothesis is no longer applicable.
Authors: Ralf Schaible; Alexander Scheuerlein; Maciej J Dańko; Jutta Gampe; Daniel E Martínez; James W Vaupel Journal: Proc Natl Acad Sci U S A Date: 2015-12-07 Impact factor: 11.205
Authors: Owen R Jones; Alexander Scheuerlein; Roberto Salguero-Gómez; Carlo Giovanni Camarda; Ralf Schaible; Brenda B Casper; Johan P Dahlgren; Johan Ehrlén; María B García; Eric S Menges; Pedro F Quintana-Ascencio; Hal Caswell; Annette Baudisch; James W Vaupel Journal: Nature Date: 2013-12-08 Impact factor: 49.962