The Capsella rubella genome and the genomic consequences of rapid mating system evolution

Slotte, Tanja; Hazzouri, Khaled M.; Ågren, J. Arvid; Koenig, Daniel; Maumus, Florian; Guo, Ya‐Long; Steige, Kim A.; Platts, Adrian E.; Escobar, Juan S.; Newman, Leorra; Wang, Wei; Mandáková, Terezie; Vello, Emilio; Smith, Lisa M.; Henz, Stefan R.; Steffen, Joshua G.; Takuno, Shohei; Brandvain, Yaniv; Coop, Graham; Andolfatto, Peter; Hu, Tina T.; Blanchette, Mathieu; Clark, Richard M.; Quesneville, Hadi; Nordborg, Magnus; Gaut, Brandon S.; Lysák, Martin; Jenkins, Jerry; Grimwood, Jane; Chapman, Jarrod; Prochnik, Simon; Shu, Shengqiang; Rokhsar, Daniel S.; Schmutz, Jeremy; Weigel, Detlef; Wright, Stephen I.

doi:10.1038/ng.2669

Cited by 362 publications

(417 citation statements)

References 41 publications

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“…Two were consistent with rearrangement between the A. lyrata and A. arenosa genomes. One of these was also confirmed by the karyotypes of several of our dosage variants ( Figure 7B, inset) and was also detected in a population of Capsella rubella (Slotte et al, 2013). Taken together, these results suggest that it might originate from erroneous assembly of that particular segment of the A. lyrata genome (Slotte et al, 2013).…”

Section: Genomic Structure Of the A Suecica Genomesupporting

confidence: 68%

“…One of these was also confirmed by the karyotypes of several of our dosage variants ( Figure 7B, inset) and was also detected in a population of Capsella rubella (Slotte et al, 2013). Taken together, these results suggest that it might originate from erroneous assembly of that particular segment of the A. lyrata genome (Slotte et al, 2013). Only the third rearrangement was consistent with an inversion between the two parental genomes (A. arenosa Care-1 and A. suecica Sue-1).…”

Section: Genomic Structure Of the A Suecica Genomesupporting

confidence: 67%

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The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

et al. 2014

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Whole-genome duplication resulting from polyploidy is ubiquitous in the evolutionary history of plant species. Yet, polyploids must overcome the meiotic challenge of pairing, recombining, and segregating more than two sets of chromosomes. Using genomic sequencing of synthetic and natural allopolyploids of Arabidopsis thaliana and Arabidopsis arenosa, we determined that dosage variation and chromosomal translocations consistent with homoeologous pairing were more frequent in the synthetic allopolyploids. To test the role of structural chromosomal differentiation versus genetic regulation of meiotic pairing, we performed sequenced-based, high-density genetic mapping in F2 hybrids between synthetic and natural lines. This F2 population displayed frequent dosage variation and deleterious homoeologous recombination. The genetic map derived from this population provided no indication of structural evolution of the genome of the natural allopolyploid Arabidopsis suecica, compared with its predicted parents. The F2 population displayed variation in meiotic regularity and pollen viability that correlated with a single quantitative trait locus, which we named BOY NAMED SUE, and whose beneficial allele was contributed by A. suecica. This demonstrates that an additive, gain-of-function allele contributes to meiotic stability and fertility in a recently established allopolyploid and provides an Arabidopsis system to decipher evolutionary and molecular mechanisms of meiotic regularity in polyploids.

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Section: Genomic Structure Of the A Suecica Genomesupporting

confidence: 68%

Section: Genomic Structure Of the A Suecica Genomesupporting

confidence: 67%

The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

et al. 2014

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“…We used nucleotidenucleotide BLAST 2.2.29 þ 58 , specifically the megablast algorithm 38 , to search ARTICLE NATURE COMMUNICATIONS | DOI: 10.1038/ncomms7338 the predicted coding sequence databases from A. lyrata 39 , C. rubella 40 and B. rapa 41 with the A. thaliana Col-0-coding sequences of RRS1, RPS4, RRS1B and RPS4B. Following the identification of putatively orthologous genes, MUSCLE 59 and CLUSTAL W 60 nucleotide and protein sequence alignments were used to generate phylogenetic trees using the Neighbour-Joining and Maximum Likelihood (Tamura-Nei model) methods, each with 1,000 bootstraps.…”

Section: Methodsmentioning

confidence: 99%

“…NATURE COMMUNICATIONS | DOI: 10.1038/ncomms7338 ARTICLE A. thaliana. Using the nucleotide sequences of each gene from each pair in megablast searches 38 , we found that in the genomes of the sister species Arabidopsis lyrata 39 , and the closely related species Capsella rubella 40 , there are distinct putatively orthologous pairs matching both the 'A' pair (RRS1/RPS4) and 'B' pair (RRS1B/RPS4B). In A. lyrata, we also found an apparent duplication of the 'B' pair, resulting in a paralogous 'C' pair with a high level of identity to the 'B' pair (Fig.…”

Section: Avrrps4mentioning

confidence: 99%

Two linked pairs of Arabidopsis TNL resistance genes independently confer recognition of bacterial effector AvrRps4

et al. 2015

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Plant immunity requires recognition of pathogen effectors by intracellular NB-LRR immune receptors encoded by Resistance (R) genes. Most R proteins recognize a specific effector, but some function in pairs that recognize multiple effectors. Arabidopsis thaliana TIR-NB-LRR proteins RRS1-R and RPS4 together recognize two bacterial effectors, AvrRps4 from Pseudomonas syringae and PopP2 from Ralstonia solanacearum. However, AvrRps4, but not PopP2, is recognized in rrs1/rps4 mutants. We reveal an R gene pair that resembles and is linked to RRS1/RPS4, designated as RRS1B/RPS4B, which confers recognition of AvrRps4 but not PopP2. Like RRS1/RPS4, RRS1B/RPS4B proteins associate and activate defence genes upon AvrRps4 recognition. Inappropriate combinations (RRS1/RPS4B or RRS1B/RPS4) are non-functional and this specificity is not TIR domain dependent. Distinct putative orthologues of both pairs are maintained in the genomes of Arabidopsis thaliana relatives and are likely derived from a common ancestor pair. Our results provide novel insights into paired R gene function and evolution.

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“…An example script with all program versions and flags used for bioinformatic analyses, filtered vcf files, and a collated dataset and scripts used to identify genomic predictors of ASE are available on Figshare: https://doi.org/10.17045/sthlmuni.c.3654650. structure (20) and a large, stable effective population size (21,22). Indeed, selection on both protein-coding (23) and regulatory regions (18) is highly efficient in C. grandiflora, and high levels of polymorphism enhance the power to detect cis-regulatory variation and quantify selection.…”

Section: Significancementioning

confidence: 99%

Genomic analysis reveals major determinants ofcis-regulatory variation inCapsella grandiflora

Steige

Laenen

Reimegård

et al. 2017

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

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Understanding the causes of cis-regulatory variation is a long-standing aim in evolutionary biology. Although cis-regulatory variation has long been considered important for adaptation, we still have a limited understanding of the selective importance and genomic determinants of standing cis-regulatory variation. To address these questions, we studied the prevalence, genomic determinants, and selective forces shaping cis-regulatory variation in the outcrossing plant Capsella grandiflora. We first identified a set of 1,010 genes with common cis-regulatory variation using analyses of allele-specific expression (ASE). Population genomic analyses of whole-genome sequences from 32 individuals showed that genes with common cis-regulatory variation (i) are under weaker purifying selection and (ii) undergo less frequent positive selection than other genes. We further identified genomic determinants of cis-regulatory variation. Gene body methylation (gbM) was a major factor constraining cis-regulatory variation, whereas presence of nearby transposable elements (TEs) and tissue specificity of expression increased the odds of ASE. Our results suggest that most common cis-regulatory variation in C. grandiflora is under weak purifying selection, and that gene-specific functional constraints are more important for the maintenance of cis-regulatory variation than genome-scale variation in the intensity of selection. Our results agree with previous findings that suggest TE silencing affects nearby gene expression, and provide evidence for a link between gbM and cis-regulatory constraint, possibly reflecting greater dosage sensitivity of body-methylated genes. Given the extensive conservation of gbM in flowering plants, this suggests that gbM could be an important predictor of cis-regulatory variation in a wide range of plant species.allele-specific expression | fitness effects | purifying selection | positive selection | gene body methylation U nderstanding the causes of regulatory variation is of major importance for many areas of biology and medicine (1). Much interest has centered on cis-regulatory variation, which has long been thought to be particularly important for adaptation (2-5). Like other quantitative traits, cis-regulatory variation is expected to be shaped by the interplay of mutation, selection, and drift. However, the relative importance of these forces remains unclear in most species.Recently, prospects for quantifying cis-regulatory variation have greatly improved, and, as a result, ample heritable cis-regulatory variation has been identified in many species (6); this is resulting in a growing consensus that a large amount of standing cis-regulatory variation is under weak purifying selection (7-9). Clarifying why the impact of purifying selection varies across the genome is therefore important to understand the maintenance of cis-regulatory variation.Variation in the intensity of purifying selection across the genome can result from differences in selective constraint that are due to the specific functions of...

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The Capsella rubella genome and the genomic consequences of rapid mating system evolution

Cited by 362 publications

References 41 publications

The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

The BOY NAMED SUE Quantitative Trait Locus Confers Increased Meiotic Stability to an Adapted Natural Allopolyploid of Arabidopsis

Two linked pairs of Arabidopsis TNL resistance genes independently confer recognition of bacterial effector AvrRps4

Genomic analysis reveals major determinants ofcis-regulatory variation inCapsella grandiflora

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