Molecular Population Genetics of theSRKandSCRSelf-Incompatibility Genes in the Wild Plant SpeciesBrassica cretica(Brassicaceae)

Edh, Kristina; Widén, Björn; Ceplitis, Alf

doi:10.1534/genetics.108.090829

Cited by 14 publications

(23 citation statements)

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“…Indeed, in the class II SCR tree, the clustering of interspecific triplets consisting of one haplotype from each of B. oleracea and B. rapa, together with one putatively functional B. cretica haplotype, is particularly evident (Figure 3). In fact, the entire reservoir of class II haplotypes in cultivated B. oleracea can be found within a single B. cretica population (Edh et al 2009) and, thus, we apparently have not found any functional class II haplotypes not previously known from Brassica in the wild B. cretica. Several closely related pairs of B. cretica/B.…”

Section: Discussionmentioning

confidence: 61%

“…Moreover, SRK lineages from the cultivated B. oleracea and B. rapa are widely dispersed among lineages from the wild B. cretica. Together with the observation of almost equal levels of SRK sequence polymorphism in wild and cultivated Brassica species (Edh et al 2009), this suggests that domestication has not entailed any severe bottleneck, with subsequent reduction in the number and diversity of lineages, at the Brassica S locus (cf. Igic et al 2004).…”

Section: Discussionmentioning

confidence: 80%

“…Since the B. cretica haplotypes form the same dominance class-specific clusters as the other Brassica species, we suggest that the dominance pattern is the same in wild B. cretica as in cultivated Brassica, with dominant class I and recessive class II haplotypes. In the absence of crossing data, we previously assigned B. cretica SRK haplotypes into putative groups of haplotypes with identical SI specificity on the basis of DNA sequence similarity (Edh et al 2009). As revealed by the ML SRK kinase domain tree, clusters of similar haplotypes assigned to the same functional group are, in all cases except one, monophyletic (Figure 1).…”

Section: Discussionmentioning

confidence: 99%

“…Approximately 100 mg leaf tissue was used for whole-genome DNA extraction with a DNeasy plant mini kit (Qiagen) according to the manufacturer's instructions. Exons 4-7 of the kinase domain of SRK and parts of exons 1 and 2 of SCR were amplified and sequenced as described in Edh et al (2009). As S-domainrelated regions are also found in S-locus genes other than SRK (e.g., SLG; Stein et al 1991), we chose to work with the SRK kinase domain instead of the S domain to avoid inadvertent PCR amplification of nonhomologous regions.…”

Section: Methodsmentioning

confidence: 99%

“…Haplotypes were identified on the basis of total sequence identity, including both introns and exons, in BioEdit version 7.0.5.3 (Hall 1999) after alignment using the Clustal W algorithm (Thompson et al 1994). For SRK, the 46 haplotypes identified in Edh et al (2009) were used in the phylogenetic analysis. For SCR, only class II haplotypes could be amplified, and six class II haplotypes were used in this study.…”

Section: Methodsmentioning

confidence: 99%

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The Evolution and Diversification ofS-Locus Haplotypes in the Brassicaceae Family

2009

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Self-incompatibility (SI) in the Brassicaceae plant family is controlled by the SRK and SCR genes situated at the S locus. A large number of S haplotypes have been identified, mainly in cultivated species of the Brassica and Raphanus genera, but recently also in wild Arabidopsis species. Here, we used DNA sequences from the SRK and SCR genes of the wild Brassica species Brassica cretica, together with publicly available sequence data from other Brassicaceae species, to investigate the evolutionary relationships among S haplotypes in the Brassicaceae family. The results reveal that wild and cultivated Brassica species have similar levels of SRK diversity, indicating that domestication has had but a minor effect on S-locus diversity in Brassica. Our results also show that a common set of S haplotypes was present in the ancestor of the Brassica and Arabidopsis genera, that only a small number of haplotypes survived in the Brassica lineage after its separation from Arabidopsis, and that diversification within the two Brassica dominance classes occurred after the split between the two lineages. We also found indications that recombination may have occurred between the kinase domain of SRK and the SCR gene in Brassica.T O avoid self-fertilization, different kinds of selfincompatibility (SI) mechanisms have evolved in many plant families (Richards 1997). In most cases, SI is controlled by a single locus, the S locus, which, even though it often contains several genes, is inherited as a single Mendelian locus (Silva and Goring 2001); for this reason, S alleles are often referred to as S haplotypes (Boyes and Nasrallah 1993). In the Brassicaceae, which has the sporophytic type of SI where the pollen SI phenotype is determined by the S-locus genotype of the diploid parent, two S-locus genes, SRK and SCR, encode the maternal (pistil) and paternal (pollen) specificities, respectively (Stein et al. 1991;Schopfer et al. 1999;Suzuki et al. 1999). The SRK receptor consists of three domains with different functions: an extracellular S domain (encoded by exon 1 in SRK), which is the center for recognition of SCR; a transmembrane domain (exon 2) that passes through the plasma membrane; and an intracellular kinase domain (exons 4-7), which initiates the signaling cascade in the stigma cells (see Takayama and Isogai 2005). The SCR gene product is a small soluble protein molecule present at the pollen surface where it interacts with the S domain of its cognate SRK protein (Takayama et al. 2001). Because of the strong frequency-dependent selection acting on the SI system, the S locus typically maintains a large number of haplotypes (Lawrence 2000), and levels of diversity at both synonymous and nonsynonymous sites are high in the S domain of SRK and in SCR (e.g., Awadalla and Charlesworth 1999;Charlesworth et al. 2003;Takuno et al. 2007). Furthermore, in both Brassica and Arabidopsis, synonymous diversity is elevated in a region encompassing several tens of kilobases beyond the actual targets of selection due to the low level...

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Section: Discussionmentioning

confidence: 61%

Section: Discussionmentioning

confidence: 80%

Section: Discussionmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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The Evolution and Diversification ofS-Locus Haplotypes in the Brassicaceae Family

2009

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Progress on characterization of self-incompatibility in Brassica napus L.

et al. 2011

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Self-incompatibility (SI) is a widespread mechanism in flowering plants that promotes outbreeding and thereby increases genetic diversity. Recognition specificity in Brassica is achieved by the interaction of the female determinant S-receptor kinase (SRK) and its ligand, the male determinant S-locus protein 11 (SP11). The interaction between SP11 and SRK triggers the signaling cascade in an S-haplotype-specific manner and results in the rejection of self-pollen, but the signal components involved are still not well characterized. S haplotypes are widespread in self-compatible amphidiploid B. napus, and the interaction of heterozygous S haplotypes causes the loss of SI. This review highlights the recent advances made towards understanding the genetic analysis, distribution, and evolution of S haplotypes, the signal factors, and the potential of SI in B. napus hybrid breeding program.

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Linkage disequilibrium in French wild cherry germplasm and worldwide sweet cherry germplasm

Arunyawat

Capdeville

Decroocq

et al. 2012

Tree Genetics & Genomes

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Molecular Population Genetics of theSRKandSCRSelf-Incompatibility Genes in the Wild Plant SpeciesBrassica cretica(Brassicaceae)

Cited by 14 publications

References 85 publications

The Evolution and Diversification ofS-Locus Haplotypes in the Brassicaceae Family

The Evolution and Diversification ofS-Locus Haplotypes in the Brassicaceae Family

Progress on characterization of self-incompatibility in Brassica napus L.

Linkage disequilibrium in French wild cherry germplasm and worldwide sweet cherry germplasm

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