Molecular aspects of self-incompatibility in Brassica species.

Many flowering plants possess self-incompatibility (SI) systems to prevent inbreeding. SI in Brassica species is controlled by a single S locus with multiple alleles. In recent years, much progress has been made in determining the male and female S determinant in Brassica species. In the female, a gain-of-function experiment clearly demonstrated that SRK was the sole S determinant, and that SLG enhanced the SI recognition process. By contrast, the male S determinant (termed SP11/SCR) was identified in the course of genome analysis of S locus to be a small cysteine-rich protein, which was classified as a pollen coat protein. This SP11/SCR may function as a ligand for the S domain of SRK in the SI recognition reaction of Brassica species.     

A pollen coat protein, SP11/SCR, determines the pollen S-specificity in the self-incompatibility of Brassica species

Many flowering plants have evolved self-incompatibility (SI) systems to prevent inbreeding. In the Brassicaceae, SI is genetically controlled by a single polymorphic locus, termed the S-locus. Pollen rejection occurs when stigma and pollen share the same S-haplotype. Recognition of S-haplotype specificity has recently been shown to involve at least two S-locus genes, S-receptor kinase (SRK) and S-locus protein 11 or S-locus Cys-rich (SP11/SCR). SRK encodes a polymorphic membrane-spanning protein kinase, which is the sole female determinant of the S-haplotype specificity. SP11/SCR encodes a highly polymorphic Cys-rich small basic protein specifically expressed in the anther tapetum and in pollen. In cauliflower (B. oleracea), the gain-of-function approach has demonstrated that an allele of SP11/SCR encodes the male determinant of S-specificity. Here we examined the function of two alleles of SP11/SCR of B. rapa by the same approach and further established that SP11/SCR is the sole male determinant of SI in the genus Brassica sp. Our results also suggested that the 522-bp 5'-upstream region of the S9-SP11 gene used to drive the transgene contained all the regulatory elements required for the unique sporophytic/gametophytic expression observed for the native SP11 gene. Promoter deletion analyses suggested that the highly conserved 192-bp upstream region was sufficient for driving this unique expression. Furthermore, immunohistochemical analyses revealed that the protein product of the SP11 transgene was present in the tapetum and pollen, and that in pollen of late developmental stages, the SP11 protein was mainly localized in the pollen coat, a finding consistent with its expected biological role.     

Coevolution of the S-locus genes SRK,SLG and SP11/SCR in Brassica oleracea and B. rapa

Brassica self-incompatibility (SI) is controlled by SLG and SRK expressed in the stigma and by SP11/SCR expressed in the anther. We determined the sequences of the S domains of 36 SRK alleles, 13 SLG alleles, and 14 SP11 alleles from Brassica oleracea and B. rapa. We found three S haplotypes lacking SLG genes in B. rapa, confirming that SLG is not essential for the SI recognition system. Together with reported sequences, the nucleotide diversities per synonymous and nonsynonymous site (pi(S) and pi(N)) at the SRK, SLG, and SP11 loci within B. oleracea were computed. The ratios of pi(N):pi(S) for SP11 and the hypervariable region of SRK were significantly >1, suggesting operation of diversifying selection to maintain the diversity of these regions. In the phylogenetic trees of 12 SP11 sequences and their linked SRK alleles, the tree topology was not significantly different between SP11 and SRK, suggesting a tight linkage of male and female SI determinants during the evolutionary course of these haplotypes. Genetic exchanges between SLG and SRK seem to be frequent; three such recent exchanges were detected. The evolution of S haplotypes and the effect of gene conversion on self-incompatibility are discussed.     

Linear dominance relationship among four class-II S haplotypes in pollen is determined by the expression of SP11 in Brassica self-incompatibility

Self-incompatibility (SI) prevents self-fertilization by rejecting pollen from plants with the same S phenotype. The Brassica SI system is controlled sporophytically by multiple alleles at the single locus, S, and dominance relationships among S haplotypes are observed in both stigma and pollen. We have identified previously five different class-II S haplotypes in Brassica campestris. Here, we performed test-crosses between S heterozygotes and their respective parental S homozygotes for four of these class-II S haplotypes, and observed a linear dominance relationship on the pollen side. To determine how this relationship is controlled, we performed RNA gel blot analyses for six S heterozygotes and their respective parental S homozygotes using the corresponding SP11 clone as a probe. In all six S heterozygotes, SP11 derived from a dominant haplotype was predominantly expressed, and SP11 derived from a recessive haplotype was repressed. Thus, the linear dominance relationship of the SI phenotype on the pollen side is regulated by the expression of SP11.     

Characterization of Brassica S-haplotypes lacking S-locus glycoprotein

Self-incompatibility (SI) in Brassica is regulated by a single multi-allelic locus, S, which contains highly polymorphic stigma-expressed genes, SLG and SRK. While SRK is shown to be the determinant of female SI specificity, SLG is thought to assist the function of SRK. Here we report that the SLG genes of self-incompatible S(18) and S(60) homozygotes of Brassica oleracea have an in-frame stop codon and a 23 bp deletion resulting in a frame-shift, respectively. The finding that these SLG genes do not encode functional SLG proteins suggests that SLG is not essential for SI. The possible role of SLG in SI was discussed.     

Comparison of the genome structure of the self-incompatibility (S) locus in interspecific pairs of S haplotypes

The determinants of recognition specificity of self-incompatibility in Brassica are SRK in the stigma and SP11/SCR in the pollen, both of which are encoded in the S locus. The nucleotide sequence analyses of many SRK and SP11/SCR alleles have identified several interspecific pairs of S haplotypes having highly similar sequences between B. oleracea and B. rapa. These interspecific pairs of S haplotypes are considered to be derived from common ancestors and to have maintained the same recognition specificity after speciation. In this study, the genome structures of three interspecific pairs of S haplotypes were compared by sequencing SRK, SP11/SCR, and their flanking regions. Regions between SRK and SP11/SCR in B. oleracea were demonstrated to be much longer than those of B. rapa and several retrotransposon-like sequences were identified in the S locus in B. oleracea. Among the seven retrotransposon-like sequences, six sequences were found to belong to the ty3 gypsy group. The gag sequences of the retrotransposon-like sequences were phylogenetically different from each other. In Southern blot analysis using retrotransposon-like sequences as probes, the B. oleracea genome showed more signals than the B. rapa genome did. These findings suggest a role for the S locus and genome evolution in self-incompatible plant species.     

Just how complex is the Brassica S-receptor complex?

Of the plant self-incompatibility (SI) systems investigated to date, that possessed by members of the Brassicaceae is currently the best understood. Whilst the recent demonstrations of interactions between the male determinant (S-locus cysteine rich protein, SCR) and the female determinant (S-locus receptor kinase, SRK) indicate the minimal requirement for SI in Brassica, no consensus exists as to the nature of these molecules in vivo and the potential involvement of accessory molecules in establishing the active S-receptor complex. Variation between S haplotypes appears to be present in the molecular composition of the receptor complex, the regulation of downstream signalling and the requirement for accessory molecules. This review discusses what constitutes an active receptor complex and highlights potential differences between haplotypes. The role of accessory molecules, in particular SLG (S-locus glycoprotein) and low molecular weight pollen coat proteins (PCPs), in pollination are discussed, as is the link between SI and unilateral incompatibility (UI).     

A Rewarding Fifteen Years: From SLG to SCR/SP11

Selfincompatibility (SI) is a major genetic mechanism to prevent selffertilization in flowering plants and, in most cases, controlled by a single multiallelic locus, known as the S locus. In Brassica, the genes mediating both stylar (SRK, S receptor kinase) and pollen (SCR/SP11, S locus cystein rich protein/S locus protein 11) expression of selfincompatible reaction have been characterized though the first S locus-encoded gene, SLG (S locus glycoprotein), was isolated nearly fifteen years ago. These findings have finally unveiled the molecular partners in pollen recognition during selfincompatible reaction in Brassica.     

值得的十五年——从SLG到SCR/SP11

Self_incompatibility (SI) is a major genetic mechanism to prevent self_fertilization in flowering plants and, in most cases, controlled by a single multiallelic locus, known as the S locus. In Brassica, the genes mediating both stylar (SRK, S receptor kinase) and pollen (SCR/SP11, S locus cystein rich protein/S locus protein 11) expression of self_incompatible reaction have been characterized though the first S locus_encoded gene, SLG (S locus glycoprotein), was isolated nearly fifteen years ago. These findings have finally unveiled the molecular partners in pollen recognition during self_incompatible reaction in Brassica.     

Diversification and alteration of recognition specificity of the pollen ligand SP11/SCR in self-incompatibility of Brassica and Raphanus

The recognition specificity of the pollen ligand of self-incompatibility (SP11/SCR) was investigated using Brassica rapa transgenic plants expressing SP11 transgenes, and SP11 of Raphanus sativus S-21 was found to have the same recognition specificity as that of B. rapa S-9. In a set of three S haplotypes, whose sequence identities of SP11 and SRK are fairly high, R. sativus S-6 showed the same recognition specificity as Brassica oleracea S-18 and a slightly different specificity from B. rapa S-52. B. oleracea S-18, however, showed a different specificity from B. rapa S-52. Using these similar S haplotypes, chimeric SP11 proteins were produced by domain swapping. Bioassay using the chimeric SP11 proteins revealed that the incompatibility response induction activity was altered by the replacement of Region III and Region V. Pollen grains of Brassica transgenic plants expressing chimeric SP11 of the B. oleracea SP11-18 sequence with Region III and Region V from B. rapa SP11-52 (chimeric BoSP11-18[52]) were partially incompatible with the B. rapa S-52 stigmas, and those expressing the R. sativus SP11-6 sequence with Region III and Region V from B. rapa SP11-52 (chimeric RsSP11-6[52]) were completely incompatible with the stigmas having B. rapa S-52. However, the transgenic plant expressing chimeric RsSP11-6(52) also showed incompatibility with B. oleracea S-18 stigmas. These results suggest that Regions III and Region V of SP11 are important for determining the recognition specificity, but not the sole determinant. A possible process of the generation of a new S haplotype is herein discussed.     

Genomic organization of the S core region and the S flanking regions of a class-II S haplotype in Brassica rapa

The nucleotide sequence of an 86.4-kb region that includes the SP11, SRK, and SLG genes of Brassica rapa S-60 (a class-II S haplotype) was determined. In the sequenced region, 13 putative genes were found besides SP11-60, SRK-60, and SLG-60. Five of these sequences were isolated as cDNAs, five were homologues of known genes, cDNAs, or ORFs, and three are hypothetical ORFs. Based on their nucleotide sequences, however, some of them are thought to be non-functional. Two regions of colinearity between the class-II S-60 and Brassica class-I S haplotypes were identified, i.e., S flanking region 1 which shows partial colinearity of non-genic sequences and S flanking region 2 which shows a high level of colinearity. The observed colinearity made it possible to compare the order of SP-11, SRK, and SLG genes in the S locus between the five sequenced S haplotypes. It emerged that the order of SRK and SLG in class-II S-60 is the reverse of that in the four class-I S haplotypes reported so far, and the order of SP11, SRK and SLG is the opposite of that in the class-I haplotype S-910. The possible gene designated as SAN1 (S locus Anther-expressed Non-coding RNA like-1), which is located in the region between SP11-60 and SRK-60, has features reminiscent of genes for non-coding RNAs (ncRNAs), but no homologous sequences were found in the databases. This sequence is transcribed in anthers but not in stigmas or leaves. These features of the genomic structure of S-60 are discussed with special reference to the characteristics of class-II S haplotypes.     

芸薹属自交不亲和基因的分子生物学及进化模式

芸薹属的自交不亲和性是受单基因座、复等位基因控制的孢子体控制型。自交不亲和基因座位（S-locus）是由多个基因组成的复杂区域,称之为S多基因家族,其大多数成员分布于芸薹属的整个染色体组。目前已鉴定出100多个S等位基因,它们的起源分化始于一千万年前。S-座位上存在的多基因有3种：SRK,SLG和SCR/SP11;SRK和SLG在柱头中表达,SCR/SP11在雄蕊中表达。SRK蛋白在识别同类花粉的过程中起主要作用,而SLG蛋白增强了这种自交不亲和反应。SLG与SRK基因中编码S-结构域的核苷酸序列相似性程度高达85％～98%。基因转换可能是SLG和SRK的高度同源性能够得以保持的原因。SRK,SLG和SCR基因紧密相连,并表现出高水平的序列多样性。SRK与SLG基因间的距离很近,在20～25 kb之间。在柱头和花粉中,自交不亲和等位基因之间的共显性关系要比显性和隐性关系更加普遍,这是芸薹属自交不亲和性的一大特点。自交不亲和基因的进化模式存在两种假说：双基因进化模式和中性变异体进化模式;可能存在几种不同的进化方式,它们共同在自然群体中新的S等位基因进化过程中起作用。     

Sporophytic self-incompatibility in Senecio squalidus L (Asteraceae)--the search for S

Senecio squalidus (Oxford Ragwort) is being used as a model species to study the genetics and molecular genetics of self-incompatibility (SI) in the Asteraceae. S. squalidus has a strong system of sporophytic SI (SSI) and populations within the UK contain very few S alleles probably due to a population bottleneck experienced on its introduction to the UK. The genetic control of SSI in S. squalidus is complex and may involve a second locus epistatic to S. Progress towards identifying the female determinant of SSI in S. squalidus is reviewed here. Research is focused on plants carrying two defined S alleles, S(1) and S(2). S(2) is dominant to S(1) in pollen and stigma. RT-PCR was used to amplify three SRK-like cDNAs from stigmas of S(1)S(2) heterozygotes, but the expression patterns of these cDNAs suggest that they are unlikely to be directly involved in SI or pollen-stigma interactions in contrast to SSI in the Brassicaceae. Stigma-specific proteins associated with the S(1) allele and the S(2) allele have been identified using isoelectric focusing and these proteins have been designated SSP1 (Stigma S-associated Protein 1) and SSP2. SSP1 and SSP2 cDNAs have been cloned by 3' and 5' RACE and shown to be allelic forms of the same gene, SSP. The expression of SSP and its linkage to the S locus are currently being investigated. Initial results show SSP to be expressed exclusively in stigmas and developmentally regulated, with maximal expression occurring at and just before anthesis when SI is fully functional, SSP expression being undetectable in immature buds. Together these data suggest that SSP is a strong candidate for a Senecio S-gene.     

Genetic mapping and molecular characterization of the self-incompatibility (S) locus in Petunia inflata

Gametophytic self-incompatibility (SI) possessed by the Solanaceae is controlled by a highly polymorphic locus called the S locus. The S locus contains two linked genes, S-RNase, which determines female specificity, and the as yet unidentified pollen S gene, which determines male specificity in SI interactions. To identify the pollen S gene of Petunia inflata, we had previously used mRNA differential display and subtractive hybridization to identify 13 pollen-expressed genes that showed S -haplotype-specific RFLP. Here, we carried out recombination analysis of 1205 F2 plants to determine the genetic distance between each of these S -linked genes and S-RNase. Recombination was observed between four of the genes (3.16, G211, G212, and G221) and S-RNase, whereas no recombination was observed for the other nine genes (3.2, 3.15, A113, A134, A181, A301, G261, X9, and X11). A genetic map of the S locus was constructed, with 3.16 and G221 delimiting the outer limits. None of the observed crossovers disrupted SI, suggesting that all the genes required for SI are contained in the chromosomal region defined by 3.16 and G221. These results and our preliminary chromosome walking results suggest that the S locus is a huge multi-gene complex. Allelic sequence diversity of G221 and 3.16, as well as of 3.2, 3.15, A113, A134 and G261, was determined by comparing two or three alleles of their cDNA and/or genomic sequences. In contrast to S-RNase, all these genes showed very low degrees of allelic sequence diversity in the coding regions, introns, and flanking regions.     

Self-incompatibility in flowering plants: the Brassica model.

Self-incompatibility (SI) is a widespread mechanism in flowering plants that prevents self-fertilization. Self-pollen recognition relies on the products of genes located at the S (self-incompatibility) locus. Significant progress towards understanding molecular interactions allowing stigmatic cells to recognize and reject self-pollen in Brassica has been made during the past two years. Thus, the male and female determinants responsible of the self-incompatibility (SI) response have been identified. The structural features of these molecules strongly suggest that SI response is triggered by a ligand-receptor interaction.