<i>S</i>Locus Genes and the Evolution of Self-Fertility in<i>Arabidopsis thaliana</i>

Sherman-Broyles, Sue; Boggs, Nathan A.; Farkas, Ágnes; Liu, Pei; Vrebalov, Julia; Nasrallah, Mikhail E.; Nasrallah, June B.

doi:10.1105/tpc.106.048199

Cited by 110 publications

(128 citation statements)

References 42 publications

Supporting

Mentioning

115

Contrasting

Unclassified

Order By: Relevance

“…Previous studies had shown that in some accessions, such as C24, the SRK and SCR sequences are highly decayed or deleted, and only partial remnants of these sequences have been retained . In other accessions, SRK sequences are relatively well preserved while SCR sequences are very much degraded or entirely absent (Nasrallah et al 2004;Sherman-Broyles et al 2007). For example, in SA-containing accessions, SCRA sequences are nonfunctional and may be repeated, truncated, or rearranged (Nasrallah et al 2004;Sherman-Broyles et al 2007;Boggs et al 2009a), while the SRKA gene has remained much more intact, being transcribed but encoding a truncated open reading frame due to splice site usage as in the Col-0 accession (Kusaba et al 2001;Shimizu et al 2004;Tang et al 2007), or even remaining functional as in the Wei-0 accession (Tsuchimatsu et al 2010).…”

Section: Discussionmentioning

confidence: 99%

“…The structure of the Lz-0 SC haplotype was compared to that of the previously characterized C24 SA-SC recombinant haplotype ( Figure 1B; Sherman-Broyles et al 2007), the Col-0 SA haplotype ( Figure 1C; Kusaba et al 2001), and the Cvi-0 SB haplotype ( Figure 1D; Tang et al 2007). Among these S haplotypes, the Lz-0 S haplotype has the longest PUB8-ARK3 region (.44 kb).…”

Section: Resultsmentioning

confidence: 99%

“…By contrast, for the SC haplotype, only SRK sequences, some of them encoding full-length open reading frames, are available, and neither SCRC sequences nor the corresponding A. lyrata SCR36 sequences have been isolated to date. Thus, although there is clear evidence that the SC haplotype is nonfunctional, at least in some accessions (Boggs et al 2009a), it is not known what mutations were associated with inactivation of this locus in the 11 A. thaliana accessions known to harbor the SC haplotype (Shimizu et al 2004;Sherman-Broyles et al 2007), how these mutations compare with those that inactivated the SA and SB haplotypes, and if SA-SC recombinant haplotypes have retained SCRC sequences. Thus, our view of the events that remodeled the A. thaliana S locus is incomplete.…”

mentioning

confidence: 99%

“…The SRK and SCR proteins are highly polymorphic and co-evolving proteins (Sato et al 2002) and their haplotype-specific interaction is responsible for the specific recognition and inhibition by the stigma epidermis of self-related pollen (i.e., pollen derived from the same flower, other flowers on the same plant, or plants expressing the same S haplotype) (reviewed in Rea and Nasrallah 2008). Consequently, an understanding of the genetic events associated with the switch to self-fertility in the A. thaliana lineage was sought through analysis of SRK and SCR sequences harbored by various A. thaliana geographical accessions (Kusaba et al 2001;Shimizu et al 2004Shimizu et al , 2008Sherman-Broyles et al 2007;Tang et al 2007; Boggs et al 2009a,b;Tsuchimatsu et al 2010) and comparisons to orthologous sequences from A. thaliana's close self-incompatible relatives A. lyrata and A. halleri (Bechsgaard et al 2006). These comparisons have suggested that A. thaliana has retained only three of the many S haplotypes that must have Liu et al 2007;Boggs et al 2009b).…”

mentioning

confidence: 99%

See 3 more Smart Citations

Molecular Characterization and Evolution of Self-Incompatibility Genes inArabidopsis thaliana:The Case of theScHaplotype

et al. 2013

View full text Add to dashboard Cite

The switch from an outcrossing mode of mating enforced by self-incompatibility to self-fertility in the Arabidopsis thaliana lineage was associated with mutations that inactivated one or both of the two genes that comprise the self-incompatibility (SI) specificity-determining S-locus haplotype, the S-locus receptor kinase (SRK) and the S-locus cysteine-rich (SCR) genes, as well as unlinked modifier loci required for SI. All analyzed A. thaliana S-locus haplotypes belong to the SA, SB, or SC haplotypic groups. Of these three, the SC haplotype is the least well characterized. Its SRKC gene can encode a complete open-reading frame, although no functional data are available, while its SCRC sequences have not been isolated. As a result, it is not known what mutations were associated with inactivation of this haplotype. Here, we report on our analysis of the Lz-0 accession and the characterization of its highly rearranged SC haplotype. We describe the isolation of its SCRC gene as well as the subsequent isolation of SCRC sequences from other SC-containing accessions and from the A. lyrata S36 haplotype, which is the functional equivalent of the A. thaliana SC haplotype. By performing transformation experiments using chimeric SRK and SCR genes constructed with SC-and S36-derived sequences, we show that the SRKC and SCRC genes of Lz-0 and at least a few other SC-containing accessions are nonfunctional, despite SCRC encoding a functional full-length protein. We identify the probable mutations that caused the inactivation of these genes and discuss our results in the context of mechanisms of S-locus inactivation in A. thaliana.T HE switch from an outcrossing mode of mating to selffertility was a major transition in the evolutionary history of Arabidopsis thaliana. Recent studies have shown that this switch was accompanied by multiple independent losses of self-incompatibility (SI), the major mechanism that promotes outcrossing in the Brassicaceae Shimizu et al. 2008; Boggs et al. 2009a). In this family, SI is controlled by numerous haplotypes of the S locus. Within each S-locus haplotype (hereafter S haplotype), are two genes that determine specificity in the SI response: one gene encodes the stigma-expressed S-locus receptor kinase (SRK) and the other encodes the pollen coat-localized ligand for SRK, the S-locus cysteine-rich (SCR) protein. The SRK and SCR proteins are highly polymorphic and co-evolving proteins (Sato et al. 2002) and their haplotype-specific interaction is responsible for the specific recognition and inhibition by the stigma epidermis of self-related pollen (i.e., pollen derived from the same flower, other flowers on the same plant, or plants expressing the same S haplotype) (reviewed in Rea and Nasrallah 2008). Consequently, an understanding of the genetic events associated with the switch to self-fertility in the A. thaliana lineage was sought through analysis of SRK and SCR sequences harbored by various A. thaliana geographical accessions (Kusaba et al. 2001;Shimizu et al. 2004Shimizu et al....

show abstract

Section: Discussionmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

mentioning

confidence: 99%

mentioning

confidence: 99%

See 2 more Smart Citations

Molecular Characterization and Evolution of Self-Incompatibility Genes inArabidopsis thaliana:The Case of theScHaplotype

et al. 2013

View full text Add to dashboard Cite

show abstract

“…S locus (Sherman-Broyles et al 2007), suggesting that this element might have a widespread role in the evolution of self-compatibility.…”

Section: Discussionmentioning

confidence: 99%

Molecular and Genetic Analyses of Four Nonfunctional S Haplotype Variants Derived from a Common Ancestral S Haplotype Identified in Sour Cherry (Prunus cerasus L.)

et al. 2010

View full text Add to dashboard Cite

Tetraploid sour cherry (Prunus cerasus) has an S-RNase-based gametophytic self-incompatibility (GSI) system; however, individuals can be either self-incompatible (SI) or self-compatible (SC). Unlike the situation in the Solanaceae, where self-compatibility accompanying polyploidization is often due to the compatibility of heteroallelic pollen, the genotype-dependent loss of SI in sour cherry is due to the compatibility of pollen containing two nonfunctional S haplotypes. Sour cherry individuals with the S 4 S 6 S 36a S 36b genotype are predicted to be SC, as only pollen containing both nonfunctional S 36a and S 36b haplotypes would be SC. However, we previously found that individuals of this genotype were SI. Here we describe four nonfunctional S 36 variants. Our molecular analyses identified a mutation that would confer loss of stylar S function for one of the variants, and two alterations that might cause loss of pollen S function for all four variants. Genetic crosses showed that individuals possessing two nonfunctional S 36 haplotypes and two functional S haplotypes have reduced self-fertilization due to a very low frequency of transmission of the one pollen type that would be SC. Our finding that the underlying mechanism limiting successful transmission of genetically compatible gametes does not involve GSI is consistent with our previous genetic model for Prunus in which heteroallelic pollen is incompatible. This provides a unique case in which breakdown of SI does not occur despite the potential to generate SC pollen genotypes.

show abstract