The Distribution of Fitness Effects of New Deleterious Amino Acid Mutations in Humans

doi:10.1534/genetics.106.057570

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Genetics. Published Articles Ahead of Print: March 17, 2006, Copyright © 2006
doi:10.1534/genetics.106.057570

A more recent version of this article appeared on June 1, 2006.

REGULAR RESEARCH PAPERS

The Distribution of Fitness Effects of New Deleterious Amino Acid Mutations in Humans

Adam Eyre-Walker ¹^*, Meg Woolfit ² and Ted Phelps ¹

¹ University of Sussex
² University of Sussex

^* To whom correspondence should be addressed. E-mail: a.c.eyre-walker{at}sussex.ac.uk.

Submitted on February 23, 2006
Revised on March 7, 2006
Accepted on 8 March 2006

Abstract

The distribution of fitness effects of new mutations is a fundamentalparameter in genetics. Here we present a new method by whichthe distribution can be estimated. The method is fairly robustto changes in population size and admixture, and it can be correctedfor any residual effects if a model of the demography is available. We apply the method to extensively sampled single nucleotidepolymorphism data from humans and estimate the distributionof fitness effects for amino acid changing mutations. We showthat a gamma distribution with a shape parameter of 0.23 providesa good fit to the data and we estimate that more than 50% ofmutations are likely to have mild effects, such that they reducefitness by between 1/1000 and 1/10. We also infer that fewerthan 15% of new mutations are likely to have strongly deleteriouseffects. We estimate that on average a non-synonymous mutationreduces fitness by ~4.3% and that the average strength of selectionacting against a non-synonymous polymorphism is ~9 x 10-5. Weargue that the relaxation of natural selection due to modernmedicine and reduced variance in family size is not likely tolead to a rapid decline in genetic quality, but that it willbe very difficult to locate most of the genes involved in complexgenetic diseases.

Key Words: SNP, fitness, selection

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REGULAR RESEARCH PAPERS

The Distribution of Fitness Effects of New Deleterious Amino Acid Mutations in Humans

Adam Eyre-Walker 1*, Meg Woolfit 2 and Ted Phelps 1

Adam Eyre-Walker ¹^*, Meg Woolfit ² and Ted Phelps ¹