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Fitness landscapes and coevolution: from physics to biology. Frances Taschuk March 24, 2008. Fitness landscapes. Peaks represent local fitness maxima Here: fitness relates to feeding efficiency of crossbills on different conifers. Kauffman and Johnsen. Rugged multipeaked fitness landscapes
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Fitness landscapes and coevolution: from physics to biology Frances Taschuk March 24, 2008
Fitness landscapes • Peaks represent local fitness maxima • Here: fitness relates to feeding efficiency of crossbills on different conifers
Kauffman and Johnsen • Rugged multipeaked fitness landscapes • NK model: N=number of traits K=interacting traits within species C=interacting traits in other species • In trying to maximize their own fitness, coevolutionary species change one another’s fitness landscapes
Parameters can be adjusted so that coevolving species reach steady state (“analogue of Nash equilibrium”) More rugged landscapes (high K/C ratio) take less time to reach equilibrium because more local maxima Tuning
Coevolution Presence of more interconnected species in model makes it take longer to reach equilibrium
Avalanches • When optimized for maximum sustained fitness, model ecosystem is subject to changes that propagate throughout When K is close to optimal value of 10, log-log plot shows straight line, suggesting a power law relationship
Adaptive surfaces in biology • Idea of adaptive landscape has been around in biology since 1932 • Originally used to describe genetic fine-tuning, but has also been used to visualize larger-scale phenotypic evolution • Little information is available about people trying to fit real data to landscapes
Poelwijk et al in Nature (2007) • '...why, if species have descended from other species by insensibly fine gradations, do we not everywhere see innumerable transitional forms?' (Darwin) • Looks at molecular function to address question of evolutionary intermediates
Modeling adaptation of bacterial β-lactamase to the antibiotic cefotaxime • Know resistance phenotype, so can reconstruct intermediates (5 mutations needed) • 5! different possible trajectories • Fitness result of a given mutation depends on order – “balance of structural and functional benefits • b, c, d unlikely to happen • Found18 paths of type a
2. Evolution of isopropylmalate dehydrogenase • Studied mutational intermediates affecting binding of cofactors (NADP less optimal than NAD) • In vitro measurements revealed single-peaked landscape; mutations not order-dependent • In vivo measurements found a valley on fitness landscape, making some routes from NADP to NAD inaccessible NADP NAD
3. Evolution of regulatory interactions • In hormone/receptor model, function could continue while receptors diverged because there was a ligand that could activate both • In the case of lac, new interaction offset deteriorations - robust network allows evolvability
Decaestecker et al in Nature (2007) • Observation of “Red Queen” dynamics between Daphnia and Pasteuria ramosa (parasite) • Reasons to expect coevolution: • Genetic variation in Daphnia resistance • Genotype-specific interactions • Daphnia population genetics change during parasite epidemics
Methods • Collected dormant Daphnia eggs and parasite samples from different depths— “snapshot in the arms race” • Exposed Daphnia to parasites from previous, contemporary, and subsequent growing seasons
References Kauffman and Johnsen. 1991. Coevolution to the edge of chaos: coupled fitness landscapes, poised states, and coevolutionary avalanches. Journal of Theoretical Biology, 149. Poelwijk et al. 2007. Empirical fitness landscapes reveal accessible evolutionary paths. Nature, vol. 445. Decaestecker et al. 2007. Host-parasite “Red Queen” dynamics archived in pond sediment. Nature, vol 450. Also: Benkman. 2003. Divergent selection drives the adaptive radiation of crossbills. Evolution. A simple model of the evolution of simple models of evolution http://daphnia.cgb.indiana.edu/images/Daphnia_DGC.png