Decreased Recent Adaptation at Human Mendelian Disease Genes As a Possible Consequence of Interference Between Advantageous and Deleterious Variants

Overview

Journal Elife

Specialty Biology

Date 2021 Oct 12

PMID 34636724

Citations 7

Authors

Chenlu Di

Jesus Murga Moreno

Diego F Salazar-Tortosa

M Elise Lauterbur

David Enard

Affiliations

Soon will be listed here.

Abstract

Advances in genome sequencing have improved our understanding of the genetic basis of human diseases, and thousands of human genes have been associated with different diseases. Recent genomic adaptation at disease genes has not been well characterized. Here, we compare the rate of strong recent adaptation in the form of selective sweeps between mendelian, non-infectious disease genes and non-disease genes across distinct human populations from the 1000 Genomes Project. We find that mendelian disease genes have experienced far less selective sweeps compared to non-disease genes especially in Africa. Investigating further the possible causes of the sweep deficit at disease genes, we find that this deficit is very strong at disease genes with both low recombination rates and with high numbers of associated disease variants, but is almost non-existent at disease genes with higher recombination rates or lower numbers of associated disease variants. Because segregating recessive deleterious variants have the ability to interfere with adaptive ones, these observations strongly suggest that adaptation has been slowed down by the presence of interfering recessive deleterious variants at disease genes. These results suggest that disease genes suffer from a transient inability to adapt as fast as the rest of the genome.

Citing Articles

Adaptation in human immune cells residing in tissues at the frontline of infections.

Salvador-Martinez I, Murga-Moreno J, Nieto J, Alsinet C, Enard D, Heyn H Nat Commun. 2024; 15(1):10329.

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Analysis of Evolutionary Conservation, Expression Level, and Genetic Association at a Genome-wide Scale Reveals Heterogeneity Across Polygenic Phenotypes.

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An efficient and robust ABC approach to infer the rate and strength of adaptation.

Murga-Moreno J, Casillas S, Barbadilla A, Uricchio L, Enard D G3 (Bethesda). 2024; 14(4).

PMID: 38365205 PMC: 11090462. DOI: 10.1093/g3journal/jkae031.

Assessing the Presence of Recent Adaptation in the Human Genome With Mixture Density Regression.

Salazar-Tortosa D, Huang Y, Enard D Genome Biol Evol. 2023; 15(10).

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Versatile Detection of Diverse Selective Sweeps with Flex-Sweep.

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