Evolutionary forces affecting synonymous variations in plant genomes

Clément, Yves; Sarah, Gautier; Homa, Félix; Pointet, Stéphanie; Contreras, Sandy; Sabot, François; Sauné, Laure; Ardisson, Morgane; Baciliéri, Roberto; Besnard, Guillaume; Berger, Angélique; Cardi, Céline; Bellis, Fabien De; Fouet, Olivier; Jourda, Cyril; Khadari, Bouchaïb; Lanaud, Claire; Leroy, Thierry; Pot, David; Sauvage, Christopher; Sarcelli, Nora; Tregear, James; Vigouroux, Yves; Yahiaoui, Nabila; Ruiz, Manuel; Santoni, Sylvain; Labouisse, Jean-Pierre; Pham, Jean‐Louis; David, Jacques; Glémin, Sylvain

doi:10.1101/086231

Cited by 6 publications

(16 citation statements)

References 70 publications

(77 reference statements)

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“…Another common feature of plant genomes is a correlation of recombination rate with GC content. In most plant genomes, recombination rates are positively correlated with GC content but exceptions with negative or no correlation are known, especially in frequent selfers (Marais et al, 2004;Paape et al, 2012;Pessia et al, 2012;Cl ement et al, 2017). The significant relationship between recombination rate and GC content is thought to be maintained by GC-biased gene conversion after cross-overs (Cl ement et al, 2017).…”

Section: Correlation Between Genomic Featuresmentioning

confidence: 99%

“…In most plant genomes, recombination rates are positively correlated with GC content but exceptions with negative or no correlation are known, especially in frequent selfers (Marais et al, 2004;Paape et al, 2012;Pessia et al, 2012;Cl ement et al, 2017). The significant relationship between recombination rate and GC content is thought to be maintained by GC-biased gene conversion after cross-overs (Cl ement et al, 2017). Alternatively, the correlation could also be maintained by selection for higher GC content or by a recombination-inducing effect of GC-rich genomic regions (Liu et al, 2018).…”

Section: Correlation Between Genomic Featuresmentioning

confidence: 99%

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A pseudomolecule‐scale genome assembly of the liverwort Marchantia polymorpha

et al. 2019

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Summary Marchantia polymorpha has recently become a prime model for cellular, evo‐devo, synthetic biological, and evolutionary investigations. We present a pseudomolecule‐scale assembly of the M. polymorpha genome, making comparative genome structure analysis and classical genetic mapping approaches feasible. We anchored 88% of the M. polymorpha draft genome to a high‐density linkage map resulting in eight pseudomolecules. We found that the overall genome structure of M. polymorpha is in some respects different from that of the model moss Physcomitrella patens. Specifically, genome collinearity between the two bryophyte genomes and vascular plants is limited, suggesting extensive rearrangements since divergence. Furthermore, recombination rates are greatest in the middle of the chromosome arms in M. polymorpha like in most vascular plant genomes, which is in contrast with P. patens where recombination rates are evenly distributed along the chromosomes. Nevertheless, some other properties of the genome are shared with P. patens. As in P. patens, DNA methylation in M. polymorpha is spread evenly along the chromosomes, which is in stark contrast with the angiosperm model Arabidopsis thaliana, where DNA methylation is strongly enriched at the centromeres. Nevertheless, DNA methylation and recombination rate are anticorrelated in all three species. Finally, M. polymorpha and P. patens centromeres are of similar structure and marked by high abundance of retroelements unlike in vascular plants. Taken together, the highly contiguous genome assembly we present opens unexplored avenues for M. polymorpha research by linking the physical and genetic maps, making novel genomic and genetic analyses, including map‐based cloning, feasible.

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Section: Correlation Between Genomic Featuresmentioning

confidence: 99%

Section: Correlation Between Genomic Featuresmentioning

confidence: 99%

A pseudomolecule‐scale genome assembly of the liverwort Marchantia polymorpha

et al. 2019

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“…Hence, gBGC is considered a neutral process as it does not rely on the fitness effect of alleles of the individuals. For the last 10 years a plethora of evidence has been accumulated for gBGC as a major evolutionary force affecting codon usage and base composition in humans (reviewed by Galtier, 2009, Glémin et al, 2015), yeast (Lesecque et al, 2013) and plants (Muyle et al, 2011;Pessia et al, 2012;Wu et al, 2015;Rodgers-Melnick et al, 2016;Clément et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

Codon usage and codon pair patterns in non-grass monocot genomes

et al. 2017

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“…The GC content is determined by the relative fixation of S→W and W→S mutations (Sueoka 1962), which is governed by the balance of a mutation bias from S→W over W→S, and a fixation bias from W→S over S→W. The latter may be caused by gBGC only, but may also be observed at synonymous sites due to selection for preferred codons (Duret and Mouchiroud 1999; Clément, et al 2017; Galtier, et al 2018). Protein coding genes make up only 3.7 % of the L. sinapis genome (Talla, Soler, et al 2019) and potential selection on codon usage will hence only affect genome-wide base composition marginally in this species.…”

Section: Resultsmentioning

confidence: 99%

The effects of GC-biased gene conversion on patterns of genetic diversity among and across butterfly genomes

Boman

Mugal

Backström

2020

Preprint

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Recombination reshuffles the alleles of a population through crossover and gene conversion. These mechanisms have considerable consequences on the evolution and maintenance of genetic diversity. Crossover, for example, can increase genetic diversity by breaking the linkage between selected and nearby neutral variants. Bias in favor of G or C alleles during gene conversion may instead promote the fixation of one allele over the other, thus decreasing diversity. Mutation bias from G or C to A and T opposes GC-biased gene conversion (gBGC). Less recognized is that these two processes may –when balanced– promote genetic diversity. Here we investigate how gBGC and mutation bias shape genetic diversity patterns in wood white butterflies (Leptidea sp.). This constitutes the first in-depth investigation of gBGC in butterflies. Using 60 re-sequenced genomes from six populations of three species, we find substantial variation in the strength of gBGC across lineages. When modeling the balance of gBGC and mutation bias and comparing analytical results with empirical data, we reject gBGC as the main determinant of genetic diversity in these butterfly species. As alternatives, we consider linked selection and GC content. We find evidence that high values of both reduce diversity. We also show that the joint effects of gBGC and mutation bias can give rise to a diversity pattern which resembles the signature of linked selection. Consequently, gBGC should be considered when interpreting the effects of linked selection on levels of genetic diversity.

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Evolutionary forces affecting synonymous variations in plant genomes

Cited by 6 publications

References 70 publications

A pseudomolecule‐scale genome assembly of the liverwort Marchantia polymorpha

A pseudomolecule‐scale genome assembly of the liverwort Marchantia polymorpha

Codon usage and codon pair patterns in non-grass monocot genomes

The effects of GC-biased gene conversion on patterns of genetic diversity among and across butterfly genomes

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