Fluctuating natural selection accounts for the evolution of diversification bet hedging

Natural environments are characterized by unpredictability over all time scales. This stochasticity is expected on theoretical grounds to result in the evolution of ‘bet-hedging’ traits that maximize the long term, or geometric mean fitness even though such traits do not maximize fitness over shorter time scales. The geometric mean principle is thus central to our interpretation of optimality and adaptation; however, quantitative empirical support for bet hedging is lacking. Here, I report a quantitative test using the timing of seed germination—a model diversification bet-hedging trait—in Lobelia inflata under field conditions. In a phenotypic manipulation study, I find the magnitude of fluctuating selection acting on seed germination timing—across 70 intervals throughout five seasons—to be extreme: fitness functions for survival are complex and multimodal within seasons and significantly dissimilar among seasons. I confirm that the observed magnitude of fluctuating selection is sufficient to account for the degree of diversification behaviour characteristic of individuals of this species. The geometric mean principle has been known to economic theory for over two centuries; this study now provides a quantitative test of optimality of a bet-hedging trait in nature.

[1]  E. Dempster Maintenance of genetic heterogeneity. , 1955, Cold Spring Harbor symposia on quantitative biology.

[2]  D. Cohen Optimizing reproduction in a randomly varying environment. , 1966, Journal of theoretical biology.

[3]  M. Slatkin Hedging one's evolutionary bets , 1974, Nature.

[4]  J H Gillespie,et al.  Nautural selection for within-generation variance in offspring number. , 1974, Genetics.

[5]  J. Gillespie Natural selection for within-generation variance in offspring number II. Discrite haploid models. , 1975, Genetics.

[6]  Joel P. Brockman,et al.  What is Bet-Hedging , 1987 .

[7]  J. Bull EVOLUTION OF PHENOTYPIC VARIANCE , 1987, Evolution; international journal of organic evolution.

[8]  Dolph Schluter,et al.  ESTIMATING THE FORM OF NATURAL SELECTION ON A QUANTITATIVE TRAIT , 1988, Evolution; international journal of organic evolution.

[9]  D. Roff The evolution of life histories : theory and analysis , 1992 .

[10]  M. Lynch Evolution and extinction in response to environ mental change. , 1993 .

[11]  T. Philippi Bet-Hedging Germination of Desert Annuals: Beyond the First Year , 1993, The American Naturalist.

[12]  Elliott Sober,et al.  Optimality Models and the Test of Adaptationism , 1994, The American Naturalist.

[13]  M. Lynch,et al.  EVOLUTION AND EXTINCTION IN A CHANGING ENVIRONMENT: A QUANTITATIVE‐GENETIC ANALYSIS , 1995, Evolution; international journal of organic evolution.

[14]  J. Halley Ecology, evolution and 1 f -noise. , 1996, Trends in ecology & evolution.

[15]  M. Mckinney,et al.  Species–time curves and population extremes: Ecological patterns in the fossil record , 1999 .

[16]  M. Pigliucci,et al.  Manipulative Approaches to Testing Adaptive Plasticity: Phytochrome‐Mediated Shade‐Avoidance Responses in Plants , 1999, The American Naturalist.

[17]  D. L. Venable,et al.  Seed Germination in Desert Annuals: An Empirical Test of Adaptive Bet Hedging , 2000, The American Naturalist.

[18]  M. Johnston,et al.  Variation in seed traits of Lobelia inflata (Campanulaceae): sources and fitness consequences. , 2000, American journal of botany.

[19]  B. Grant,et al.  Unpredictable Evolution in a 30-Year Study of Darwin's Finches , 2002, Science.

[20]  Andrew M. Simons,et al.  The continuity of microevolution and macroevolution , 2002 .

[21]  M. Johnston,et al.  Suboptimal timing of reproduction in Lobelia inflata may be a conservative bet‐hedging strategy , 2003, Journal of evolutionary biology.

[22]  Michael S. Y. Lee,et al.  The geometric meaning of macroevolution , 2003 .

[23]  THE EVOLUTIONARY ECOLOGY OF SEED GERMINATION OF ARABIDOPSIS THALIANA: VARIABLE NATURAL SELECTION ON GERMINATION TIMING , 2005, Evolution; international journal of organic evolution.

[24]  Arturo H. Ariño,et al.  On the nature of population extremes , 1995, Evolutionary Ecology.

[25]  J. Schmitt,et al.  Environmental and genetic influences on the germination of Arabidopsis thaliana in the field. , 2005 .

[26]  R. O’Hara Comparing the effects of genetic drift and fluctuating selection on genotype frequency changes in the scarlet tiger moth , 2005, Proceedings of the Royal Society B: Biological Sciences.

[27]  M. Johnston,et al.  ENVIRONMENTAL AND GENETIC SOURCES OF DIVERSIFICATION IN THE TIMING OF SEED GERMINATION: IMPLICATIONS FOR THE EVOLUTION OF BET HEDGING , 2006, Evolution; international journal of organic evolution.

[28]  Derek A. Roff,et al.  Introduction to Computer-Intensive Methods of Data Analysis in Biology: Preface , 2006 .

[29]  R. Ferrière,et al.  Bet Hedging via Seed Banking in Desert Evening Primroses (Oenothera, Onagraceae): Demographic Evidence from Natural Populations , 2006, The American Naturalist.

[30]  A. Simons,et al.  Selection for increased allocation to offspring number under environmental unpredictability , 2007, Journal of evolutionary biology.

[31]  S. Stearns Daniel Bernoulli (1738): evolution and economics under risk , 2000, Journal of Biosciences.

[32]  D. L. Venable Bet hedging in a guild of desert annuals. , 2007, Ecology.

[33]  G. Bell,et al.  Adaptation, extinction and global change , 2008, Evolutionary applications.