Use of the polymerase chain reaction to isolate an S-locus glycoprotein cDNA introgressed from Brassica campestris into B. napus ssp. oleifera.

Summary A self-incompatible canola-quality Brassica napus ssp. oleifera line (W1) was generated by introgressing the S-locus from a self-incompatible B. campestris plant into the Westar cultivar. Using the polymerase chain reaction (PCR) with primers derived from conserved regions in S-locus glycoprotein (SLG) alleles, the central region of the active SLG gene (910) was obtained. The remaining portions of the cDNA for this 910 gene were subsequently cloned using the PCR-rapid amplification of cDNA ends (RACE) procedure. Sequence analysis revealed that the 910 cDNA show a high degree of sequence similarity to SLG alleles associated with Class I self-incompatible lines. The 910 gene was found to be absent in the original self-compatible cv. Westar (B. napus) and segregated with self-incompatibility in a mixed population generated from a cross between self-incompatible W1 and self-compatible Westar. RNA blot analysis indicated that high levels of 910 mRNAs were present in the stigma as buds approached anthesis. Thus, the SLG allele of W1 transferred from B. campestris via backcrosses to a line of cv. Westar has been identified.     

Development of SCAR markers linked to self-incompatibility in <Emphasis Type="Italic">Brassica napus</Emphasis> L.

‘SI1300’ is a self-incompatible Brassica napus line generated by introgressing an S haplotype from B. rapa ‘Xishuibai’ into a rapeseed cultivar ‘Huayou No. 1’. Five S-locus specific primer pairs were employed to develop cleaved amplified polymorphic sequences (CAPS) markers linked the S haplotype of ‘SI1300’. Two segregating populations (F₂ and BC₁) from the cross between ‘SI1300’ and self-compatible European spring cultivar ‘Defender’, were generated to verify the molecular markers. CAPS analysis revealed no desirable polymorphism between self-incompatible and self-compatible plants. Twenty primer pairs were designed based on the homology-based candidate gene method, and six dominant sequence characterized amplified region (SCAR) markers linked with the S-locus were developed. Of the six markers, three were derived from the SRK and SP11 alleles of class II B. rapa S haplotypes and linked with S haplotype of ‘SI1300’. The other three markers were designed from the SLG-A10 and co-segregated with S haplotype of ‘Defender’. We successfully combined two pairs of them and characterized two multiplex PCR markers which could discriminate the homozygous and heterozygous genotypes. These markers were further validated in 24 F₃ and 22 BC₁F₂ lines of ‘SI1300 × Defender’ and another two segregating populations from the cross ‘SI1300 × Yu No. 9’. Nucleotide sequences of fragments linked with S-locus of ‘SI1300’ showed 99% identity to B. rapa class II S-60 haplotype, and fragments from ‘Defender’ were 97% and 94% identical to SLG and SRK of B. rapa class I S-47 haplotype, respectively. ‘SI1300’ was considered to carry two class II S haplotypes and the S haplotype on the A-genome derived from B. rapa ‘Xishuibai’ determines the SI phenotype, while ‘Defender’ carry a class I S haplotype derived from B. rapa and a class II S haplotype from B. oleracea. SCAR markers developed in this study will be helpful for improving SI lines and accelerating marker-assisted selection process in rapeseed SI hybrid breeding program.     

SLR1 function is dispensable for both self-incompatible rejection and self-compatible pollination processes inBrassica

TheSLR1 gene inBrassica is related both in DNA sequence and in pattern of expression to theS-locus glycoprotein (SLG) gene involved in the self-incompatibility mechanism which recognises and arrests the germination of self pollen. However,SLR1 shows minimal allelic variation and is expressed in both self-incompatible and compatibleBrassica lines and in related, self-compatible cruciferous plants. The function of the SLR1 protein is unknown. TheSLR1 gene was specifically ablated in self-incompatible and self-compatibleBrassica plants byAgrobacterium-mediated transformation with an antisense construct. Primary transformants and homozygous T2 progeny of both self-incompatibleB. oleracea and self-compatibleB. napus recipients were found to exhibit normal pollination responses despite having no detectable SLR1 glycoprotein. This shows that the high, wild-type level of SLR1 protein is not required to sustain the self-incompatibility reaction, nor is it necessary for successful intra-specific cross-pollination between compatible lines.     

Expression of S-locus glycoprotein genes from Brassica oleracea and B. campestris in transgenic plants of self-compatible B. napus cv Westar

Summary Self-compatible Brassica napus var Westar was transformed with SLG, the S-locus-derived gene that encodes S-locus-specific glycoproteins (SLSG). Four allelic variants of SLG isolated from self-incompatible B. oleracea and B. campestris strains homozygous for different S alleles were used. We show that the transgenic plants synthesized SLSG with the same apparent charge, molecular weight, and antigenic properties as that produced by the corresponding self-incompatible strains from which the cloned SLG genes were isolated. In addition, transgene-encoded SLSG was detected specifically in the papillar cells of the stigma, and was correctly targeted to the papillar cell wall. However, SLSG was produced at reduced levels in transgenic plants relative to self-incompatible strains. The introduction of the SLG genes did not confer a self-incompatibility phenotype on the Westar cultivar.     

Cloning and sequencing of cDNAs encoding two SSS

A defective S-allele, S ₀, and a functional S-allele, S _x, have previously been found to be retained in an F₁ hybrid of a self-compatible commercial cultivar of Petunia hybrida. Pistil proteins associated with these two alleles have also been identified. Their amino-terminal sequences have been found to share a high degree of similarity with those of S-proteins characterized from self-incompatible solanaceous species. Here we report the isolation and sequencing of cDNAs encoding S ₀- and S _x-proteins. Their deduced amino acid sequences contain all the consensus primary structural features of S-proteins from self-incompatible solanaceous species. Both proteins also have ribonuclease activity. The implications of these findings are discussed in relation to the presumed function of the S-protein in the self-incompatibility interaction.     

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.     

Expression level of the SLG gene is not correlated with the self-incompatibility phenotype in the class II S haplotypes of Brassica oleracea

In Brassica, the S-locus glycoprotein (SLG) gene has been strongly implicated in the self-incompatibility reaction. Several alleles of this locus have been sequenced, and accordingly grouped as class I (corresponding to dominant S-alleles) and class II (recessive). We recently showed that a self-compatible (Sc) line of Brassica oleracea expressed a class II-like SLG (SLG-Sc) gene. Here, we report that the SLG-Sc glycoprotein is electrophoretically and immunochemically very similar to the recessive SLG-S15 glycoprotein, and is similarly expressed in stigmatic papillae. Moreover, by seed yield analysis, we observe that both alleles are associated with a self-compatibility response, in contrast with the other known recessive S haplotypes (S2 and S5). By genomic DNA blot analysis, we show the existence of molecular homologies between the Sc and S15 haplotypes, but demonstrate that they are not identical. On the other hand, we also report that the S2 haplotype expresses very low amounts of SLG glycoproteins, although it exhibits a self-incompatible phenotype. These results strongly question the precise role of the SLG gene in the molecular mechanisms that control the self-incompatibility reaction of Brassica.     

Sequence complexity of the S receptor kinase gene family in Brassica

A genomic library from an S ₂₉/S ₂₉ self-incompatible genotype of Brassica oleracea was screened with a probe carrying part of the catalytic domain of a Brassica S-receptor kinase (SRK)-like gene. Six positive phage clones with varying hybridisation intensities (K1 to K6) were purified and characterised. A 650–700 by region corresponding to the probe was excised from each clone and sequenced. DNA and predicted protein sequence comparisons based on a multiple alignment identified K5 as a pseudogene, whereas the others could encode functional proteins. K3 was found to have lost an intron from its genomic sequence. The six genes display different degrees of sequence similarity and form two distinct clusters in a dendrogram. The 98% similarity between K4 and K6, which extends across intron sequences, suggests that these might be very recently diverged alleles or daughters of a duplication. In addition, K2 showed a comparably high similarity to the probe. Clones K1, K3 and K5 cross-hybridised with an SLG ₂₉ cDNA probe, indicating the presence of upstream receptor domains homologous to the Brassica SLG gene. This suggests that the previously reported S sequence complexity may be ascribed to a large receptor kinase gene family.     

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.     

PCR-RFLP of S locus for identification of breeding lines in cruciferous vegetables

A simple method of detecting polymorphism of S locus glycoprotein gene, SLG, in Chinese cabbage and cabbage was developed, and used for identification of breeding lines. DNA was amplified by the polymerase chain reaction (PCR) with a pair of primers having S ₆ SLG sequences from inbred lines, and digested with restriction endonucleases which recognize tetranucleotide sequences. The cleaved DNA fragments were size-fractionated by polyacrylamide gel electrophoresis and detected by silver staining. PCR with S ₆ SLG primers amplified a fragment of ca. 1.3kb in more than half of the inbred lines tested. After digestion, polyacrylamide gel electrophoresis revealed polymorphism between the amplified 1.3kb DNA fragments. These polymorphic bands were detected by Southern hybridization using a probe of S ₆ SLG cDNA, suggesting that the amplified DNA was SLG. Primers having the SLG sequences of S ₂ , a representative of recessive S alleles, were used for amplification of SLG in the lines which did not give the 1.3kb DNA fragment by the PCR with S ₆ SLG primers. Polymorphism of amplified DNA was found in these lines. However these primers also appeared to amplify an invariant SLR-2 sequence of 1.3kb in addition to the polymorphic S ₂ SLG related sequences. Although the used primer sequences still need improvement for the analysis of recessive S alleles, PCR-RFLP of SLG was considered to be useful for identification of breeding lines as well as for S allele identification in cruciferous vegetables. F₁ hybrids exhibited the sum of the bands of both parents, and, therefore, this method is expected to be used for a purity test of F₁ seeds.     

The self-compatibility mechanism in <Emphasis Type="Italic">Brassica napus</Emphasis> L. is applicable to F<Subscript>1</Subscript> hybrid breeding

Brassica napus, an allopolyploid species having the A genome of B. rapa and the C genome of B. oleracea, is self-compatible, although both B. rapa and B. oleracea are self-incompatible. We have previously reported that SP11/SCR alleles are not expressed in anthers, while SRK alleles are functional in the stigma in B. napus cv. ‘Westar’, which has BnS-1 similar to B. rapa S-47 and BnS-6 similar to B. oleracea S-15. This genotype is the most frequent S genotype in B. napus, and we hypothesized that the loss of the function of SP11 is the primary cause of the self-compatibility of ‘Westar’. To verify this hypothesis, we transformed ‘Westar’ plants with the SP11 allele of B. rapa S-47. All the transgenic plants and their progeny were completely self-incompatible, demonstrating self-compatibility to be due to the S haplotype having the non-functional SP11 allele in the A genome, which suppresses a functional recessive SP11 allele in the C genome. An artificially synthesized B. napus line having two recessive SP11 alleles was developed by interspecific hybridization between B. rapa and B. oleracea. This line was self-incompatible, but F₁ hybrids between this line and ‘Westar’ were self-compatible. These results suggest that the self-compatibility mechanism of ‘Westar’ is applicable to F₁ seed production in B. napus.     

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.     

Transformation of Brassica oleracea with an S-locus gene from B. campestris changes the self-incompatibility phenotype

Summary An SLG gene derived from the S-locus and encoding and S-locus-specific glycoprotein of Brassica campestris L. was introduced via Agrobacterium-mediated transformation into B. oleracea L. A self-incompatible hybrid and another with partial self-compatibility were used as recipients. The transgenic plants were altered in their pollen-stigma interaction and were fully compatible upon self-pollination. Reciprocal crosses between the transgenic plants and untransformed control plants indicated that the stigma reaction was changed in one recipient strain while the pollen reaction was altered in the other. Due to interspecific incompatibility, we could not demonstrate whether or not the introduced SLG gene confers a new allelic specificity in the transgenic plants. Our results show that the introduced SLG gene perturbs the self-incompatibility phenotype of stigma and pollen.     

Registration of S alleles in Brassica campestris L by the restriction fragment sizes of SLGs

Polymorphism of SLG (the S-locus glycoprotein gene) in Brassica campestris was analyzed by PCR-RFLP using SLG-specific primers. Nucleotide sequences of PCR products from 15 S genotypes were determined in order to characterise the exact DNA fragment sizes detected in the PCR-RFLP analysis. Forty-seven lines homozygous for 27 S-alleles were used as plant material. One combination of primers, PS5 + PS 15, which had a nucleotide sequence specific to a class-I SLG, gave amplification of a single DNA fragment of approximately 1.3kb from the genomic DNA of 15 S genotypes. All the DNA fragments showed different electrophroetic profiles from each other after digestion with MboI or MspI. Different lines having the same S genotype had an identical electrophoretic profile even between the lines collected in Turkey and in Japan. Another class-I SLG-specific primer, PS 18, gave amplification of a 1.3-kb DNA fragment from three other S genotypes in combination with PS 15, and the PCR product also showed polymorphism after cleavage with the restriction endonucleases. Genetic analysis, Southern-hybridization analysis, and determination of the nucleotide sequences of the PCR products suggested that the DNA fragments amplified with these combinations of primers are class-I SLGs. Expected DNA fragment sizes in the present PCR-RFLP condition were calculated from the determined nucleotide sequence of SLG PCR products. A single DNA fragment was also amplified from six S genotypes by PCR with a combination of primers, PS3 + PS21, having a nucleotide sequence specific to a class-II SLG. The amplified DNA showed polymorphisnm after cleavage with restriction endonucleases. The cleaved fragments were detected by Southern-hybridization analysis using a probe of S ⁵ SLG cDNA, a class-IISLG. Partial sequencing revealed a marked similarity of these amplified DNA fragments to a class-II SLG, demonstrating the presence of class-I and class-II S alleles also in B. campestris. The high SLG polymorphism detected by the present investigation suggests the usefulness of the PCR-RFLP method for the identification of S alleles in breeding lines and for listing S alleles in B. campestris.     

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     

Detection of self-incompatible oilseed rape plants (Brassica napus L.) based on molecular markers for identification of the class I S haplotype

The selection of desirable genotypes with recessive characteristics, such as self-incompatible plants, is often difficult or even impossible and represents a crucial barrier in accelerating the breeding process. Molecular approaches and selection based on molecular markers can allow breeders to overcome this limitation. The use of self-incompatibility is an alternative in hybrid breeding of oilseed rape. Unfortunately, stable self-incompatibility is recessive and phenotype-based selection is very difficult and time-consuming. The development of reliable molecular markers for detecting desirable plants with functional self-incompatible genes is of great importance for breeders and allows selection at early stages of plant growth. Because most of these reliable molecular markers are based on discrimination of class I S-locus genes that are present in self-compatible plants, there is a need to use an internal control in order to detect possible PCR inhibition that gives false results during genotyping. In this study, 269 double haploid F₂ oilseed rape plants obtained by microspore embryogenesis were used to verify the applicability of an improved PCR assay based on the detection of the class I SLG gene along with an internal control. Comparative analysis of the PCR genotyping results vs. S phenotype analysis confirmed the applicability of this molecular approach in hybrid breeding programs. This approach allows accurate detection of self-incompatible plants via a different amplification profile.     

Transfer of resistance to the beet cyst nematode (Heterodera Schachtii Schm.) from Sinapis alba L. (white mustard) to the Brassica napus L. gene pool by means of sexual and somatic hybridization

Summary Sexual and somatic hybrid plants have been produced between Sinapis alba L. (white mustard) and Brassica napus L. (oil-seed rape), with the aim to transfer resistance to the beet cyst nematode Heterodera schachtii Schm. (BCN) from white mustard into the oil-seed rape gene pool. Only crosses between diploid accessions of S. alba (2n = 24, S_a1S_a1) as the pistillate parent and several B. napus accessions (2n = 38, AACC) yielded hybrid plants with 31 chromosomes. Crosses between tetraploid accessions of S. alba (2n = 48, S_a1S_a1S_a1S_a1) and B. napus were unsuccessful. Somatic hybrid plants were also obtained between a diploid accession of S. alba and B. napus. These hybrids were mitotically unstable, the number of chromosomes ranging from 56 to more than 90. Analysis of total DNA using a pea rDNA probe confirmed the hybrid nature of the sexual hybrids, whereas for the somatic hybrids a pattern identical to that of B. napus was obtained. Using chloroplast (cp) and mitochondrial (mt) DNA sequences, we found that all of the sexual F₁ hybrids and somatic hybrids contained cpDNA and mtDNA of the S. alba parent. No recombinant mtDNA or cpDNA pattern was observed. Three BC₁ plants were obtained when sexual hybrids were back-crossed with B. napus. Backcrossing of somatic hybrids with B. napus was not successful. Three sexual hybrids and one BC₁ plant, the latter obtained from a cross between a sexual hybrid and B. napus, were found to show a high level of BCN resistance. The level of BCN resistance of the somatic hybrids was in general high, but varied between cuttings from the same plant. Results from cytological studies of chromosome association at meiotic metaphase I in the sexual hybrids suggest partial homology between chromosomes of the AC and S_a1 genomes and thus their potential for gene exchange.     

Isolation of S-alleles from a wild population of Brassica campestris L. at Balcesme,Turkey and their characterization by S-glycoproteins

Summary S-alleles of self-incompatibility were isolated from a wild population of Brassica campestris growing at Balcesme, Turkey. Out of 88 plants observed, 73 were self-incompatible and 4 were self-compatible. In certain families, selfed progenies from a self-incompatible plant segregated into fewer than three incompatibility classes, which is consistent with a one-locus sporophytic genetic control of self-incompatibility. Out of 25 combinations of S-alleles tested, dominance interactions were observed in 6 of them on the pollen side and on 5 of them on the stigma side. The 35 S-homozygotes thus isolated consisted of 18 independent S-alleles. The number of S-alleles in this population was estimated to be more than 30. The S-locus glycoproteins (SLGs) corresponding to the respective S-alleles were identified by iso-electric focusing (IEF)-gel immunoblotting with a polyclonal antiserum against SLG⁸. SLGs in a stigma were generally composed of several bands, one major and a few minor ones, whose molecular weight was similar to each other, and the major and minor bands were heritable in correlation with each other. SDS-PAGE analysis of SLGs differentiated a few juxtaposed bands between 50 and 60 kDa, and the variations in these bands were considered to be due to differences in the number of polysaccharide residues. General features of the variation of S-genes and their SLGs between the populations in Balcesme, Turkey and Oguni, Japan, were comparatively similar to one another, despite the different surroundings and history of these populations.