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For a population to acquire a complex adaptation requiring multiple individually neutral mutations, it must cross a plateau in the fitness landscape. We consider plateaus involving three mutations, and show that large populations can cross them rapidly via lineages that acquire multiple mutations while remaining at low frequency, much faster than the ∝μ3 rate for simultaneous triple mutations. Plateau-crossing is fastest for very large populations. At intermediate population sizes, recombination can greatly accelerate adaptation by combining independent mutant lineages to form triple-mutants. For more frequent recombination, such that the population is kept near linkage equilibrium, we extend our analysis to find simple expressions for the expected time to cross plateaus of arbitrary width.

Original publication

DOI

10.1016/j.tpb.2019.03.008

Type

Conference paper

Publication Date

10/2019

Volume

129

Pages

54 - 67

Addresses

Department of Physics, Emory University, Atlanta, GA 30322, USA; Department of Genetics, University of Cambridge, UK.

Keywords

Humans, Models, Statistical, Germ-Line Mutation, Time Factors, Genetic Fitness