Breakdown of Self-Incompatibility in a Natural Population of<i>Petunia axillaris</i> Caused by Loss of Pollen Function

Tsukamoto, Tatsuya; Ando, Toshio; Takahashi, Koichi; Omori, Takahiro; Watanabe, Hitoshi; Kokubun, Hisashi; Marchesi, Eduardo; Kao, Teh Hui

doi:10.1104/pp.102.018069

Cited by 54 publications

(48 citation statements)

References 26 publications

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“…In Campanula rapunculoides, analyses of 31 parental families suggested the presence of 3-5 unlinked, mostly recessive genetic modifiers affecting the strength of the SI response (GoodAvila and Stephenson 2002). In P. axillaris, the presence of self-compatible plants has been shown to be due to three different mechanisms: a linked gene that suppresses the expression of a specific S-RNase gene (Tsukamoto et al 2003a), a loss of function on the pollen component of SI (Tsukamoto et al 2003b), and the presence of unlinked modifiers (Tsukamoto et al 1999). The variable strength of SI has been shown in most cases in species with small patchy populations such as weeds (Baker 1965), island colonizers (Bateman 1952;Burd 1994), and populations growing in peripheral habitats (Busch 2005); these populations typically undergo repeated events of colonization and local extinction and usually consist of a small number of individuals and are likely to experience reduced pollinator and mate availability.…”

Section: Discussionmentioning

confidence: 99%

“…One possible target may lie on the flanking regions surrounding different S-alleles. These sequences are known to be highly divergent (Coleman and Kao 1992); therefore, it could be possible for specific regulatory proteins to be either required for the appropriate transcription of different S-alleles or involved in the turnover of specific RNA transcripts (Tsukamoto et al 2003a).…”

Section: Discussionmentioning

confidence: 99%

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Segregation Analyses of Partial Self-Incompatibility in Self and Cross Progeny of Solanum carolinense Reveal a Leaky S-Allele

Mena‐Alí

Stephenson

2007

Genetics

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Natural populations of self-incompatible species often exhibit marked phenotypic variation among individuals in the strength of self-incompatibility (SI). In previous studies, we found that the strength of the SI response in Solanum carolinense, a weedy invasive with RNase-mediated SI, is a plastic trait. Selfing can be particularly important for weeds and other successional species that typically undergo repeated colonization and local extinction events and whose population sizes are often small. We applied a PCRbased protocol to identify the S-alleles present in 16 maternal genotypes and their offspring and performed a two-generation greenhouse study to determine whether variation in the strength of SI is due to the existence of weak and strong S-alleles differing in their ability to recognize and reject self-pollen. We found that allele S 9 sets significantly more self seed than the other S-alleles in the population we sampled and that its ability to self is not dependent on interactions with other S-alleles. Our data suggest that the observed variations in self-fertility are likely due to factors that directly influence the expression of SI by altering the translation, turnover, or activity of the S-RNase. The variability in the strength of SI among individuals that we have observed in this and our previous studies raises the possibility that plasticity in the strength of SI in S. carolinense may play a role in the colonization and establishment of this weedy species.

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Section: Discussionmentioning

confidence: 99%

Section: Discussionmentioning

confidence: 99%

Segregation Analyses of Partial Self-Incompatibility in Self and Cross Progeny of Solanum carolinense Reveal a Leaky S-Allele

Mena‐Alí

Stephenson

2007

Genetics

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“…One possible role of the modifier genes is to regulate the expression of the S-locus genes. For example, Tsukamoto et al (1999Tsukamoto et al ( , 2003 found that several pistil-part self-compatible plants identified from a natural population of self-incompatible Petunia axillaris carried a defective S 13 -haplotype (designated S 13 sps ), which did not produce any transcript of the S 13 -RNase gene. They further showed that self-incompatible progeny homozygous or heterozygous for the functional S 13 -haplotype were obtained from self-pollination of the self-compatible plants that carried the S 13 sps S 15 genotype.…”

Section: Other Genes That Modulate the Si Responsementioning

confidence: 99%

The Molecular and Genetic Bases of S-RNase-Based Self-Incompatibility

Kao

Tsukamoto

2004

THE PLANT CELL ONLINE

248

185

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“…The system can be lost secondarily, resulting in transition to self-compatibility (SC) by mutations linked to the Slocus (Broothaerts et al, 2004;de Nettancourt, 2001), by the presence of pollen heteroallelic for the Sgenotype, which may be the result of polyploidization (Entani et al, 1999), or by modifier gene(s) unlinked to the S-locus (Tsukamoto et al, 2003).…”

Section: Introductionmentioning

confidence: 99%

Phylogenetic Relationship between Degree of Self-compatibility and Floral Traits in Lilium longiflorum Thunb. (Liliaceae)

Sakazono

Hiramatsu

Huang

et al. 2012

J. Japan. Soc. Hort. Sci.

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Lilium longiflorum is endemic to the islands of the Ryukyu Archipelago in Japan and to the eastern seacoasts and satellite islands of the mainland of Taiwan. The species is an important ornamental plant, and is cultivated throughout the world. Lilium longiflorum has long been regarded as a self-incompatible species but the existence of selfing in some natural populations was suggested by isozyme analysis in a previous study. To confirm the occurrence of self-compatible individuals and to clarify the evolutionary shift of floral traits associated with degree of self-compatibility in L. longiflorum by comparative analysis, we used 17 populations of L. longiflorum, and two populations of L. formosanum, the genetically closest species of L. longiflorum, covering the entire species distribution. Artificial self-pollination revealed that not all L. longiflorum individuals are self-incompatible and there is substantial quantitative variation of self-incompatibility among L. longiflorum individuals and populations. Self-compatible dominant populations allopatrically and independently evolved at the periphery of the species distribution area, the northern Ryukyu Archipelago and Taiwan. Increasing degree of selfcompatibility in L. longiflorum correlated with reduced corolla length, corolla width, corolla volume, and anther length for the Ryukyu Archipelago, in contrast to only reduced corolla width and volume for Taiwan. Approach between anther and stigma was not observed in any populations. Our data indicate that in the Ryukyu Archipelago increasing degree of self-compatibility evolved floral traits related to mating system evolution, to selfing, that does not depend on adjacency between anther and stigma position, but not in Taiwan.

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Breakdown of Self-Incompatibility in a Natural Population ofPetunia axillaris Caused by Loss of Pollen Function

Cited by 54 publications

References 26 publications

Segregation Analyses of Partial Self-Incompatibility in Self and Cross Progeny of Solanum carolinense Reveal a Leaky S-Allele

Segregation Analyses of Partial Self-Incompatibility in Self and Cross Progeny of Solanum carolinense Reveal a Leaky S-Allele

The Molecular and Genetic Bases of S-RNase-Based Self-Incompatibility

Phylogenetic Relationship between Degree of Self-compatibility and Floral Traits in Lilium longiflorum Thunb. (Liliaceae)

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