The effective population size modulates the strength of GC biased gene conversion in two passerines

Hj, Barton; Zeng, Kai

doi:10.1101/2021.04.20.440602

Cited by 2 publications

(2 citation statements)

References 67 publications

(136 reference statements)

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“…In mammals, there is a (weak) correlation between effective population size N e and the population-scaled gBGC coefficient (B = 4N e b) (Lartillot, 2013;Galtier, 2021). This correlation is also observed among human populations (Glémin et al, 2015;Subramanian, 2019), and effective population size seems to explain the difference in B between two passerine species (Barton and Zeng, 2021). However, in Leptidea butterflies there is no relationship between B and genetic diversity, suggesting that the transmission bias b is lower in species/populations of higher effective population size (Boman et al, 2021).…”

Section: Gbgc and Effective Population Sizementioning

confidence: 94%

The evolution of GC-biased gene conversion by means of natural selection

Clessin,

Joseph,

Lartillot

2024

Preprint

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GC-biased gene conversion (gBGC) is a recombination-associated evolutionary process that biases the segregation ratio of AT:GC polymorphisms in the gametes of heterozygotes, in favour of GC alleles. This process is the major determinant of variation in base composition across the human genome and can be the cause of a substantial burden of GC deleterious alleles. While the importance of GC-biased gene conversion in molecular evolution is increasingly recognised, the reasons for its existence and its variation between species remain largely unknown. Using simulations and semi-analytical approximations, we investigated the evolution of gBGC as a quantitative trait evolving by mutation, drift and natural selection. We show that in a finite population where most mutations are deleterious, gBGC is under weak stabilising selection around a positive value that mainly depends on the intensity of the mutation bias and on the intensity of selective constraints exerted on the genome. Importantly, the levels of gBGC that evolve by natural selection do not minimize the load in the population, and even increase it substantially in regions of high recombination rate. Therefore, despite reducing the population’s fitness, levels of gBGC that are currently observed in humans could in fact have been (weakly) positively selected.

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Section: Gbgc and Effective Population Sizementioning

confidence: 94%

The evolution of GC-biased gene conversion by means of natural selection

Clessin,

Joseph,

Lartillot

2024

Preprint

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“…The presence of a moderate fixation bias of synonymous substitutions towards an increase in GC-content has been identified in population studies in Lepidoptera ( Galtier et al 2018 ; Boman et al 2021 ). Although the impact of gBGC appears to be lower in Lepidoptera compared to for example birds ( Glémin et al 2015 ; Bolívar et al 2018 ; Barton and Zeng 2021 ), such a fixation bias in combination with codon usage preferences can have considerable effects on evolutionary rate estimates. So far, studies of codon usage preferences have been limited in Lepidoptera, and they have only covered specific genes in Bombyx mori and a single pair of other moth species ( Frohlich and Wells 1994 ; Sharma et al 2012 ).…”

Section: Introductionmentioning

confidence: 99%

Base Composition, Codon Usage, and Patterns of Gene Sequence Evolution in Butterflies

Näsvall

Boman

Talla

et al. 2023

Genome Biology and Evolution

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Coding sequence evolution is influenced by both natural selection and neutral evolutionary forces. In many species, the effects of mutation bias, codon usage and GC-biased gene conversion (gBGC) on gene sequence evolution have not been detailed. Quantification of how these forces shape substitution patterns is therefore necessary to understand the strength and direction of natural selection. Here, we used comparative genomics to investigate the association between base composition and codon usage bias on gene sequence evolution in butterflies and moths (Lepidoptera), including an in-depth analysis of underlying patterns and processes in one species, Leptidea sinapis. The data revealed significant G/C to A/T substitution bias at third codon position with some variation in the strength among different butterfly lineages. However, the substitution bias was lower than expected from previously estimated mutation rate ratios, partly due to the influence of gBGC. We found that A/T-ending codons were overrepresented in most species, but there was a positive association between the magnitude of codon usage bias and GC-content in third codon positions. In addition, the tRNA-gene population in L. sinapis showed higher GC-content at third codon positions compared to coding sequences in general and less overrepresentation of A/T-ending codons. There was an inverse relationship between synonymous substitutions and codon usage bias indicating selection on synonymous sites. We conclude that the evolutionary rate in Lepidoptera is affected by a complex interaction between underlying G/C -> A/T mutation bias and partly counteracting fixation biases, predominantly conferred by overall purifying selection, gBGC and selection on codon usage.

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The effective population size modulates the strength of GC biased gene conversion in two passerines

Cited by 2 publications

References 67 publications

The evolution of GC-biased gene conversion by means of natural selection

The evolution of GC-biased gene conversion by means of natural selection

Base Composition, Codon Usage, and Patterns of Gene Sequence Evolution in Butterflies

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