Phylogenetic Analysis of S-Locus Genes Reveals the Complicated Evolution Relationship of S Haplotypes in Brassica

Self-incompatibility (SI) is reported to play a key role in the evolution of species as it promotes their outcrossing through the recognition and rejection of self-pollen grains. In Brassica, two S-locus genes expressed in the stigma, S-locus glycoprotein (SLG) gene and S-locus receptor kinase (SRK) gene, and one expressed in the pollen, S-locus protein 11 (SP11) gene, were linked as an S haplotype. In order to analyze the evolutionary relationships of S haplotypes in Brassica, a total of 39 SRK, 37 SLG, and 58 SP11 sequences of Brassica oleracea, Brassica rapa and Brassica napus were aligned. Two phylogenetic trees with similar pattern were constructed based on the nucleotide sequences of SRK/SLG and SP11, respectively. Class I and class II alleles were clustered into two distinct groups, and alleles from different species, including all the interspecific pairs of S haplotypes, were closely related to each other. The S-locus genes identified in B. napus were intermingled in phylogenetic trees. All these observations showed that class I and class II S haplotypes diverged ahead of the species differentiation in Brassica. The evolution and the genetic diversity of S haplotypes in Brassica were discussed. Moreover, the relationships between S haplotypes and SI phenotypes in Brassica, especially in B. napus, were also discussed.     

The AtPP gene of the Brassica napus S locus region is specifically expressed in the stigma and encodes a protein similar to a methyltransferase involved in plant defense

Self-incompatibility (SI) in Brassica is controlled by the S locus. The specificity of the SI response is controlled on the stigma side by the S receptor kinase (SRK) and on the pollen side by the SCR (S locus cysteine-rich) protein, but other proteins might be involved in the process of self-pollen rejection. In this study, we show that the AtPP gene linked to the S locus of Brassica napus is expressed in the stigmas of SI lines. AtPP has a developmental pattern of expression similar to the SRK gene. The AtPP protein has similarity with members of an Arabidopsis protein family and with an S-adenosyl-L-methionine:salicylic acid carboxyl methyltransferase, which is a plant defense-related protein of Clarkia breweri representing a new class of methyltransferases. A member of the AtPP gene family is present in the homeolog region of the S locus in Arabidopsis. Therefore, this gene might have co-evolved with S genes from an ancestral S locus of Brassicaceae. Possible functions of the AtPP protein in the self-recognition process are discussed. Received: 9 October 2000 / Revision accepted: 23 April 2001     

Antisense suppression of thioredoxin<Emphasis Type="Italic">h</Emphasis>mRNA in <Emphasis Type="Italic">Brassica napus cv.</Emphasis>

In Brassica, the thioredoxinhproteins, THL1 and THL2, were previously found to be potential inhibitors of the S receptor kinase (SRK) in the Brassica self-incompatibilty response. To investigate the biological roles of THL1 and THL2 in pollen–pistil interactions, the stigma-specific SLR1 promoter was used to drive antisense THL1/2 expression in Brassica napus cv. Westar. This cultivar is normally compatible, but antisense suppression of THL1/2 led to a low level constitutive rejection of all Brassica napus pollen tested. Fluorescence microscopy revealed that the pollen rejection was a typical Brassica self-incompatibility rejection response with reduced pollen adhesion, germination and pollen tube growth. In addition, Westar was found to express the SLG₁₅ and SRK₁₅ proteins which may be the target of regulation by THL1 and THL2. Thus, these results indicate that the THL1 and THL2 are required for full pollen acceptance in B. napus cv. Westar.     

Three members of the S multigene family are linked to the S locus of Brassica

Two self-incompatibility genes in Brassica, SLG and SRK (SLG encodes a glycoprotein; SRK encodes a receptor-like kinase), are included in the S multigene family. Products of members of the S multigene family have an SLG-like domain (S domain) in common, which may function as a receptor. In this study, three clustered members of the S multigene family, BcRK1, BcRL1 and BcSL1, were characterized. BcRK1 is a putative functional receptor kinase gene expressed in leaves, flower buds and stigmas, while BcRL1 and BcSL1 are considered to be pseudogenes because deletions causing frameshifts were identified in these sequences. Sequence and expression pattern of BcRK1 were most similar to those of the Arabidopsis receptor-like kinase gene ARK1, indicating that BcRK1 might have a function similar to that of ARK1, in processes such as cell expansion or plant growth. Interestingly, the region containing BcRK1, BcRL1 and BcSL1 is genetically linked to the S locus and the physical distance between SLG, SRK and the three S-related genes was estimated to be less than 610 kb. Thus the genes associated with self-incompatibility exist within a cluster of S-like genes in the genome of Brassica. Received: 15 April 1997 / Accepted: 13 June 1997     

Sequence and expression of endogenous S-locus glycoprotein genes in self-compatible Brassica napus

Brassica napus is an amphidiploid plant which is self-compatible even though it is derived from hybridisation of the self-incompatible species B. oleracea and B. campestris. Experiments were undertaken to establish if S-locus glycoprotein (SLG) genes exist in B. napus and whether these are expressed as in self-incompatible Brassica species. Two different stigma-specific cDNA sequences homologous to SLG genes were obtained from the B. napus cultivar Westar. One of these sequences, SLG _WS1, displayed highest homology to class I SLG alleles, whereas the other, SLG _WS2, showed greatest homology to class II SLG genes. Both were expressed at high levels in Westar stigmas following a developmental pattern typical of SLG genes in the self-incompatible diploids. We infer that they represent the endogenous SLG genes at the two homoeologous S-loci. The occurrence of normally expressed SLG genes and its relevance to the self-compatible phenotype of B. napus is discussed.     

RFLP mapping of loci controlling self-incompatibility in <Emphasis Type="Italic">Brassica campestris</Emphasis> and their comparative mapping with <Emphasis Type="Italic">B. napus</Emphasis> and <Emphasis Type="Italic">B. oleracea</Emphasis>

RFLP analysis of a cDNA probe SLG6, governing self incompatibility (SI) in Brassica oleracea, using a recombinant inbred population of Brassica campestris followed by genetic linkage analysis led to the detection of two marker loci, SLG6a and SLG6b controlling SI. SLG6a was mapped in linkage group (LG) 9 and was flanked by the RFLP markers ec4f10 (6.4 cM) and wg5b9 (4.2 cM). SLG6b positioned in LG 2 and was flanked by the RFLP markers wg2d11 (9.9 cM) and ec4e7 (26.9 cM). These results indicated the scope of marker-aided introgression of these genes into self-compatible genotypes for production of SI lines suitable for hybridization in B. campestris. Comparative mapping of LG 9 containing SLG6b with corresponding linkage groups of B. oleracea (BO 2) and B. napus (BN 16) led to the detection of small homologous regions with SLG6 locus linked with another RFLP locus. This evidenced for homology of the SLG genes across Brassica species and possibility of using any single cloned SLG gene for development of SI lines in any Brassica species.     

Introduction of SLG (S locus glycoprotein) alters the phenotype of endogenous S haplotype,but confers no new S haplotype specificity in Brassica rapa L.

Self-incompatibility (SI) in Brassicaceae is genetically controlled by the S locus complex in which S locus glycoprotein (SLG) and S receptor kinase (SRK) genes have been identified, and these two genes encoding stigma proteins are believed to play important roles in SI recognition reaction. Here we introduced the SLG⁴³ gene of Brassica rapa into a self-incompatible cultivar, Osome, of B. rapa, and examined the effect of this transgene on the SI behavior of the transgenic plants. Preliminary pollination experiments demonstrated that Osome carried S⁵² and S⁶⁰, and both were codominant in stigma, but S⁵² was dominant to S⁶⁰ in pollen. S⁴³ was found to be recessive to S⁵² and codominant with S⁶⁰ in stigma. The nucleotide sequence of SLG⁴³ was more similar to that of SLG⁵² (87.8% identity) than to that of SLG⁶⁰ (74.8% identity). Three of the ten primary transformants (designated No. 1 to No. 10) were either completely (No. 9) or partially (No. 6 and No. 7) self-compatible; the SI phenotype of the stigma was changed from S⁵²S⁶⁰ to S⁶⁰, but the SI phenotype of the pollen was not altered. In these three plants, the mRNA and protein levels of both SLG⁴³ and SLG⁵² were reduced, whereas those of SLG⁶⁰ were not. All the plants in the selfed progeny of No. 9 and No. 6 regained SI and they produced a normal level of SLG⁵². These results suggest that the alteration of the SI phenotype of the stigma in the transformants Nos. 6, 7, and 9 was the result of specific co-suppression between the SLG⁴³ transgene and the endogenous SLG⁵² gene. Three of the transformants (Nos. 5, 8 and 10) produced SLG⁴³ protein, but their SI phenotype was not altered. The S⁶⁰ homozygotes in the selfed progeny of No. 10 which produced the highest level of SLG⁴³ were studied because S⁴³ was codominant with S⁶⁰ in the stigma. They produced SLG⁴³ at approximately the same level as did S⁴³S⁶⁰ heterozygotes, but did not show S⁴³ haplotype specificity at the stigma side. We conclude that SLG is necessary for the expression of the S haplotype specificity in the stigma but the introduction of SLG alone is not sufficient for conferring a novel S haplotype specificity to the stigma.     

Physical distances between S-locus genes in various S haplotypes of Brassica rapa and B. oleracea

In Brassica, self-incompatibility genes SLG (for S-locus glycoprotein) and SRK (for S-receptor kinase) are located in the S-locus complex region with several other S-linked genes. The S locus is a highly polymorphic region: polymorphism has been observed not only in sequences of SLG and SRK but also in the location of the S-locus genes. In order to compare the physical location of the S-locus genes in various S haplotypes, we used six class-I S haplotypes of B. rapa and seven class-I S haplotypes of B. oleracea in this study. DNA gel blot analysis using pulsed-field gel electrophoresis (PFGE) showed that the physical distances between SLG and SRK in B. rapa are significantly shorter than those in B. oleracea and that the sizes of MluI and BssHII fragments harboring SLG and SRK are less variable within B. rapa than within B. oleracea. We concluded that several large genomic fragments might have been inserted into the S-locus region of B. oleracea after allelic differentiation of S-locus genes. Received: 20 September 1999 / Accepted: 8 October 1999     

Analysis of S-locus and expression of S-alleles of self-compatible rapid-cycling Brassica oleracea ‘TO1000DH3’

Brassica oleracea is a strictly self-incompatible (SI) plant, but rapid-cycling B. oleracea ‘TO1000DH3’ is self-compatible (SC). Self-incompatibility in Brassicaceae is controlled by multiple alleles of the S-locus. Three S-locus genes, S-locus glycoprotein (SLG), S-locus receptor kinase (SRK) and S-locus protein 11 or S-locus cysteine-rich (SP11/SCR), have been reported to date, all of which are classified into class I and II. In this study, we investigated the molecular mechanism behind alterations of SI to SC in rapid-cycling B. olerace ‘TO1000DH3’. Class I SRK were identified by genomic DNA PCR and PCR-RFLP analysis using SRK specific markers and found to be homozygous. Cloning and sequencing of class I SRK revealed a normal kinase domain without any S-domain/transmembrane domain. Moreover, S-locus sequencing analysis revealed only an SLG sequence, but no SP11/SCR. Expression analysis showed no SRK expression in the stigma, although other genes involved in the SI recognition reaction (SLG, MLPK, ARC1, THL) were found to have normal expression in the stigma. Taken together, the above results suggest that structural aberrations such as deletion of the SI recognition genes may be responsible for the breakdown of SI in rapid-cycling B. oleracea ‘TO1000DH3’.     

Isolation and Characterization of a Class I SLG Gene from Chinese Cabbage (Brassica campestris)

In Brassica species, self-incompatibility in the recognition reaction between self and non-self pollens is determined by two genes, SLG and SRK, at the S locus. We have cloned and characterized a genomic DNA fragment containing a complete open reading frame of the SLG gene from Chinese cabbage. The genomic clone, named BcSLG2, was found to possess the region that shares a homology of 77% in amino acid identity with the SLG46 gene of Brassica campestris. Northern blot analysis revealed that the BcSLG2 gene expression is restricted to the pistil of Chinese cabbage flower. In situ hybridization showed that in the pistil, the gene is expressed predominantly in the stigmatic tissue. Much lower expression in the tapetum was also detectable at an immature stage of the flower development. Southern blot hybridization with the BcSLG2 DNA probe showed polymorphism in the SLG gene organization of the Chinese cabbage plants. These results will provide valuable information in understanding the S gene complex of the Chinese cabbage plants.     

Polymorphism of the S -locus glycoprotein gene ( SLG ) and the S -locus related gene ( SLR1 ) in Raphanus sativus L. and self-incompatible ornamental plants in the Brassicaceae

The S-locus glycoprotein gene, SLG, which participates in the pollen-stigma interaction of self-incompatibility, and its unlinked homologue, SLR1, were analyzed in Raphanus sativus and three self-incompatible ornamental plants in the Brassicaceae. Among twenty-nine inbred lines of R. sativus, eighteen S haplotypes were identified on the basis of DNA polymorphisms detected by genomic Southern analysis using Brassica SLG probes. DNA fragments of SLG alleles specifically amplified from eight S haplotypes by PCR with class I SLG-specific primers showed different profiles following polyacrylamide gel electrophoresis, after digestion with a restriction endonuclease. The nucleotide sequences of the DNA fragments of these eight R. sativus SLG alleles were determined. Degrees of similarity of the nucleotide sequences to a Brassica SLG (S  ⁶ SLG) ranged from 85.6% to 91.9%. Amino acid sequences deduced from these had the twelve conserved cysteine residues and the three hypervariable regions characteristic of Brassica SLGs. Phylogenetic analysis of the SLG sequences from Raphanus and Brassica revealed that the Raphanus SLGs did not form an independent cluster, but were dispersed in the tree, clustering together with Brassica SLGs. These results suggest that diversification of the SLG alleles of Raphanus and Brassica occurred before differentiation of these genera. Although SLR1 sequences from Orychophragmus violaceus were shown to be relatively closely related to Brassica and Raphanus SLR1 sequences, DNA fragments that are highly homologous to the Brassica SLG were not detected in this species. Two other ornamental plants in the Brassicaceae, which are related more distantly to Brassica than Orychophragmus, also lacked sequences highly homologous to Brassica SLG genes. The evolution of self-incompatibility in the Brassicaceae is discussed. Received: 9 October 1997 / Accepted: 27 January 1998     

Characterization of the S locus genes, SLG and SRK, of the Brassica S3 haplotype: identification of a membrane-localized protein encoded by the S locus receptor kinase gene

The S locus, which controls the self-incompatibility response in Brassica, has been shown to contain at least two genes. SLG encodes a secreted S locus glycoprotein whilst SRK encodes a putative S locus receptor kinase. SRK has been shown potentially to encode a functional kinase and genetic evidence indicates that this gene is essential for the self-incompatibility response. Here the characterization of the SRK and SLG genes of a Brassica line homozygous for the S₃ haplotype is described. A 120 kDa glycoprotein was identified in stigmas and several lines of evidence indicated that this protein is encoded by the SRK₃ gene. First, the 120 kDa glycoprotein was recognized by antibodies raised against peptides based on the SRK₃ gene sequence. Secondly, this protein is polymorphic and, in an F₂ population segregating for the S₃ haplotype, was expressed only in plants possessing the S₃ haplotype. Thirdly, the 120 kDa protein was expressed specifically in stigmas. Finally, the 120 kDa protein was only extracted from stigmas in the presence of detergent indicating that it is anchored in the membrane. SRK has been predicted to encode a transmembrane glycoprotein based on the deduced amino acid sequence. Located on the membrane, SRK is in a position to interface between an extracellular recognition event between pollen and pistil and an intracellular signal transduction pathway which initiates the self-incompatibility response.     

Physical linkage of the SLG and SRK genes at the self-incompatibility locus of Brassica oleracea

Summary In Brassica oleracea, the pollen-stigma interaction of self-incompatibility is controlled by a single genetically defined locus designated S. Molecular studies have identified two genes that are tightly linked to the classically defined S locus: The S-Locus Glycoprotein (SLG) gene and the S-Receptor Kinase (SRK) gene. In previous RFLP linkage analyses with probes specific for SLG and SRK, we were unable to identify any recombination events between SLG, SRK, and self-incompatibility phenotype. In this paper, we use pulsed-field gel electrophoresis (PFGE) in conjunction with DNA blot analysis to characterize the S-locus region from two highly divergent self-incompatibility genotypes, S ₂ and S ₆. We establish the physical linkage of SLG and SRK in each genotype, and demonstrate that the two genes are separated by a maximum distance of 220 kb in the S ₆ genotype and 350 kb in the S ₂ genotype. Furthermore, a comparison of the data from the two genotypes reveals that a high level of polymorphism exists across the entire S-locus region.     

Three members of the S multigene family are linked to the S locus of Brassica

Two self-incompatibility genes in Brassica, SLG and SRK (SLG encodes a glycoprotein; SRK encodes a receptor-like kinase), are included in the S multigene family. Products of members of the S multigene family have an SLG-like domain (S domain) in common, which may function as a receptor. In this study, three clustered members of the S multigene family, BcRK1, BcRL1 and BcSL1, were characterized. BcRK1 is a putative functional receptor kinase gene expressed in leaves, flower buds and stigmas, while BcRL1 and BcSL1 are considered to be pseudogenes because deletions causing frameshifts were identified in these sequences. Sequence and expression pattern of BcRK1 were most similar to those of the Arabidopsis receptor-like kinase gene ARK1, indicating that BcRK1 might have a function similar to that of ARK1, in processes such as cell expansion or plant growth. Interestingly, the region containing BcRK1, BcRL1 and BcSL1 is genetically linked to the S locus and the physical distance between SLG, SRK and the three S-related genes was estimated to be less than 610 kb. Thus the genes associated with self-incompatibility exist within a cluster of S-like genes in the genome of Brassica.     

Does the genome of Corylus avellana L. contain sequences homologous to the self-incompatibility gene of Brassica?

Self-incompatibility is a genetic mechanism enforcing cross-pollination in plants. Hazelnut (Corylus avellana L.) expresses the sporophytic type of self-incompatibility, for which the molecular genetic basis is characterized only in Brassica. The hypothesis that the hazelnut genome contains homologs of Brassica self-incompatibility genes was tested. The S-locus glycoprotein gene (SLG) and the kinase-encoding domain of the S-receptor kinase (SRK) gene of B. oleracea L. were used to probe blots of genomic DNA from six genotypes of hazelnut. Weak hybridization with the SLG probe was detected for all hazelnut genotypes tested; however, no hybridization was detected with PCR-generated probes corresponding to two conserved regions of the SLG gene. One of these PCR probes included the region of SLG encoding the 11 invariant cysteine residues that are an important structural feature of all S-family genes. The present evidence suggests that hazelnut DNA hybridizing to SLG differs significantly from the Brassica gene, and that the S-genes cloned from Brassica will not be useful for exploring self-incompatibility in hazelnut.     

Polymorphism of the S -locus glycoprotein gene (SLG ) and the S -locus related gene (SLR1 ) in Raphanus sativus L. and self-incompatible ornamental plants in the Brassicaceae

The S-locus glycoprotein gene, SLG, which participates in the pollen-stigma interaction of self-incompatibility, and its unlinked homologue, SLR1, were analyzed in Raphanus sativus and three self-incompatible ornamental plants in the Brassicaceae. Among twenty-nine inbred lines of R. sativus, eighteen S haplotypes were identified on the basis of DNA polymorphisms detected by genomic Southern analysis using Brassica SLG probes. DNA fragments of SLG alleles specifically amplified from eight S haplotypes by PCR with class I SLG-specific primers showed different profiles following polyacrylamide gel electrophoresis, after digestion with a restriction endonuclease. The nucleotide sequences of the DNA fragments of these eight R. sativus SLG alleles were determined. Degrees of similarity of the nucleotide sequences to a Brassica SLG (S? ⁶ SLG) ranged from 85.6% to 91.9%. Amino acid sequences deduced from these had the twelve conserved cysteine residues and the three hypervariable regions characteristic of Brassica SLGs. Phylogenetic analysis of the SLG sequences from Raphanus and Brassica revealed that the Raphanus SLGs did not form an independent cluster, but were dispersed in the tree, clustering together with Brassica SLGs. These results suggest that diversification of the SLG alleles of Raphanus and Brassica occurred before differentiation of these genera. Although SLR1 sequences from Orychophragmus violaceus were shown to be relatively closely related to Brassica and Raphanus SLR1 sequences, DNA fragments that are highly homologous to the Brassica SLG were not detected in this species. Two other ornamental plants in the Brassicaceae, which are related more distantly to Brassica than Orychophragmus, also lacked sequences highly homologous to Brassica SLG genes. The evolution of self-incompatibility in the Brassicaceae is discussed.