Variation in the intensity of selection on codon bias over time causes contrasting patterns of base composition evolution in
            <i>Drosophila</i>

Jackson, Benjamin C.; Campos, José Luis; Haddrill, Penelope R.; Charlesworth, Brian; Zeng, Kai

doi:10.1093/gbe/evw291

Cited by 40 publications

(115 citation statements)

References 104 publications

(153 reference statements)

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“…This is unexpected, because selection on codon use reduces synonymous site diversity (44), so that a negative relation between Fop and π S would be expected. However, there is little evidence for ongoing selection on codon use at polymorphic synonymous sites in D. melanogaster, in contrast to D. simulans, except for genes with very high codon use bias (45), so that the expected direct effect of selection on codon use on π S in our data is probably negligible. A plausible explanation is that both SSWs and BGS affect π S and Fop in a similar way by reducing the N e for a gene (27,46).…”

Section: Discussioncontrasting

confidence: 65%

Estimating the parameters of background selection and selective sweeps in Drosophila in the presence of gene conversion

Campos

Zhao

Charlesworth

2017

Proc. Natl. Acad. Sci. U.S.A.

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117

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We used whole-genome resequencing data from a population of Drosophila melanogaster to investigate the causes of the negative correlation between the within-population synonymous nucleotide site diversity (π S ) of a gene and its degree of divergence from related species at nonsynonymous nucleotide sites (K A ). By using the estimated distributions of mutational effects on fitness at nonsynonymous and UTR sites, we predicted the effects of background selection at sites within a gene on π S and found that these could account for only part of the observed correlation between π S and K A . We developed a model of the effects of selective sweeps that included gene conversion as well as crossing over. We used this model to estimate the average strength of selection on positively selected mutations in coding sequences and in UTRs, as well as the proportions of new mutations that are selectively advantageous. Genes with high levels of selective constraint on nonsynonymous sites were found to have lower strengths of positive selection and lower proportions of advantageous mutations than genes with low levels of constraint. Overall, background selection and selective sweeps within a typical gene reduce its synonymous diversity to ∼75% of its value in the absence of selection, with larger reductions for genes with high K A . Gene conversion has a major effect on the estimates of the parameters of positive selection, such that the estimated strength of selection on favorable mutations is greatly reduced if it is ignored. background selection | selective sweeps | sequence diversity | gene conversion | Drosophila melanogaster

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Section: Discussioncontrasting

confidence: 65%

Estimating the parameters of background selection and selective sweeps in Drosophila in the presence of gene conversion

Campos

Zhao

Charlesworth

2017

Proc. Natl. Acad. Sci. U.S.A.

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117

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“…We first discuss the question of how to obtain data on nearly neutral DNA sequence variants. A recent analysis of selection on GC versus AT variants at third codon positions in a Rwandan population of D. melanogaster, using genomewide polymorphism data from the Drosophila Population Genomics Project (Pool et al., ), suggested that only autosomal genes with a high GC content currently experience selection in favour of GC base pairs (Jackson, Campos, Haddrill, Charlesworth, & Zeng, ); there was no statistically significant evidence for such selection on the X chromosome. (Note that the presence of GC vs. AT base pairs at the 3 rd codon position was used as a proxy for preferred versus unpreferred codons, since D. melanogaster preferred codons end in GC (Akashi, ; Zeng, )).…”

Section: Empirical Findingsmentioning

confidence: 99%

“…However, Jackson et al. () found that short intron (SI) sequences, which are thought to evolve nearly neutrally (Clemente & Vogl, ; Parsch, Novozhilov, Saminadin‐Peter, Wong, & Andolfatto, ), showed statistically significant evidence for a departure from neutrality, favouring GC over AT base pairs on the autosomes in both D. simulans and D. melanogaster , and on the X in D. simulans but not D. melanogaster .…”

Section: Empirical Findingsmentioning

confidence: 99%

“…melanogaster , which is thought to be closely related to the ancestral population of the species (Pool et al., ), the data in Table of Jackson et al. () give X/A ratios of diversity as 1.10 for SI sites and 1.08 for fourfold sites, averaged over regions of the X and A that have nonzero rates of crossing over. This finding is consistent with previous studies that indicated that the mean silent site diversity for the X in African populations of D. melanogaster is similar to, or slightly greater, than that for A (Andolfatto & Przeworski, ; Campos et al., ; Glinka, Ometto, Mousset, Stephan, & De Lorenzo, ; Hutter et al., ; Kauer, Zangerl, Dieringer, & Schloetterer, ; Singh, Macpherson, Jensen, & Petrov, ).…”

Section: Empirical Findingsmentioning

confidence: 99%

“…This departure complicates the interpretation of the results. In contrast, SI sites seem to be approximately in equilibrium with respect to base composition on the D. simulans branch, but not on the D. melanogaster branch (Jackson et al., ).…”

Section: Empirical Findingsmentioning

confidence: 99%

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Faster‐X evolution: Theory and evidence from Drosophila

2018

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A faster rate of adaptive evolution of X-linked genes compared with autosomal genes can be caused by the fixation of recessive or partially recessive advantageous mutations, due to the full expression of X-linked mutations in hemizygous males. Other processes, including recombination rate and mutation rate differences between X chromosomes and autosomes, may also cause faster evolution of X-linked genes. We review population genetics theory concerning the expected relative values of variability and rates of evolution of X-linked and autosomal DNA sequences. The theoretical predictions are compared with data from population genomic studies of several species of Drosophila. We conclude that there is evidence for adaptive faster-X evolution of several classes of functionally significant nucleotides. We also find evidence for potential differences in mutation rates between X-linked and autosomal genes, due to differences in mutational bias towards GC to AT mutations. Many aspects of the data are consistent with the male hemizygosity model, although not all possible confounding factors can be excluded.

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Transposable elements in individual genotypes of Drosophila simulans

Signor

2020

Ecology and Evolution

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Transposable elements are abundant, dynamic components of the genome that affect organismal phenotypes and fitness. In Drosophila melanogaster, they have increased in abundance as the species spread out of Africa, and different populations differ in their transposable element content. However, very little is currently known about how transposable elements differ between individual genotypes, and how that relates to the population dynamics of transposable elements overall. The sister species of D. melanogaster, D. simulans, has also recently become cosmopolitan, and panels of inbred genotypes exist from cosmopolitan and African flies. Therefore, we can determine whether the differences in colonizing populations are repeated in D. simulans, what the dynamics of transposable elements are in individual genotypes, and how that compares to wild flies. After estimating copy number in cosmopolitan and African D. simulans, I find that transposable element load is higher in flies from cosmopolitan populations. In addition, transposable element load varies considerably between populations, between genotypes, but not overall between wild and inbred lines. Certain genotypes either contain active transposable elements or are more permissive of transposition and accumulate copies of particular transposable elements. Overall, it is important to quantify genotype‐specific transposable element dynamics as well as population averages to understand the dynamics of transposable element accumulation over time.

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Variation in the intensity of selection on codon bias over time causes contrasting patterns of base composition evolution in Drosophila

Cited by 40 publications

References 104 publications

Estimating the parameters of background selection and selective sweeps in Drosophila in the presence of gene conversion

Estimating the parameters of background selection and selective sweeps in Drosophila in the presence of gene conversion

Faster‐X evolution: Theory and evidence from Drosophila

Transposable elements in individual genotypes of Drosophila simulans

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