Abstract: One of the causes of genome size expansion is considered to be amplification of retrotransposons. We determined nucleotide sequences of 24 PCR products for each of six retrotransposons in Brassica rapa and Brassica oleracea. Phylogenetic trees of these sequences showed species-specific clades. We also sequenced STF7a homologs and Tto1 homologs, 24 PCR products each, in nine diploids and three allopolyploids, and constructed phylogenetic trees. In these phylogenetic trees, species-specific clades of diploid species were also formed, but retrotransposons of allopolyploids were clustered into the clades of their original genomes, indicating that these two retrotransposons amplified after speciation of the nine diploids. Genetic variation in these retrotransposons may have arisen before emergence of allopolyploid species. There was a positive correlation between the genome size and the average number of substitutions of STF7a and Tto1 homologs in at least seven diploids. The implications of these results in the genome evolution of Brassicaceae are herein discussed.

Abstract: A central question in genomic imprinting is how a specific sequence is recognized as the target for epigenetic marking. In both mammals and plants, imprinted genes are often associated with tandem repeats and transposon-related sequences, but the role of these elements in epigenetic gene silencing remains elusive. FWA is an imprinted gene in Arabidopsis thaliana expressed specifically in the female gametophyte and endosperm. Tissue-specific and imprinted expression of FWA depends on DNA methylation in the FWA promoter, which is comprised of two direct repeats containing a sequence related to a SINE retroelement. Methylation of this element causes epigenetic silencing, but it is not known whether the methylation is targeted to the SINE-related sequence itself or the direct repeat structure is also necessary. Here we show that the repeat structure in the FWA promoter is highly diverse in species within the genus Arabidopsis. Four independent tandem repeat formation events were found in three closely related species. Another related species, A. halleri, did not have a tandem repeat in the FWA promoter. Unexpectedly, even in this species, FWA expression was imprinted and the FWA promoter was methylated. In addition, our expression analysis of FWA gene in vegetative tissues revealed high frequency of intra-specific variation in the expression level. In conclusion, we show that the tandem repeat structure is dispensable for the epigenetic silencing of the FWA gene. Rather, SINE-related sequence is sufficient for imprinting, vegetative silencing, and targeting of DNA methylation. Frequent independent tandem repeat formation events in the FWA promoter led us to propose that they may be a consequence, rather than cause, of the epigenetic control. The possible significance of epigenetic variation in reproductive strategies during evolution is also discussed.

Abstract: DNA methylation and histone modification play important roles in regulating gene expression. The DDM1 gene in Arabidopsis thaliana (AtDDM1) is required for the maintenance of DNA methylation level and histone H3 methylation pattern. We isolated DDM1 homologs of Brassica rapa, BrDDM1a and BrDDM1b, which have 84.4% and 84.1% deduced amino acid sequence identities with AtDDM1, respectively. Both the BrDDM1a and BrDDM1b genes were found to be expressed in vegetative and reproductive tissues. B. rapa ddm1-RNAi transgenic plants with reduced levels of BrDDM1a/BrDDM1b expression showed genome-wide and non-tissue-specific demethylation. These results suggest that the BrDDM1a and BrDDM1b genes are orthologs of AtDDM1 and are required for the maintenance of DNA methylation as is AtDDM1. Despite genome-wide demethylation, developmental abnormalities were not found in the ddm1-RNAi transgenic plants. Dominance relationships of SP11/SCR alleles, the determinant of pollen recognition specificity in Brassica self-incompatibility, in S heterozygotes in B. rapa were not influenced by the low level of the BrDDM1 expression. Transcriptional reactivation of retrotransposon-like sequences observed in the ddm1-RNAi transgenic plants indicates that BrDDM1a and BrDDM1b participate in silencing of retrotransposons. Hypomethylation states of the ddm1-RNAi transgenic plants were inherited by plants of the next generation even by plants which had lost the RNAi construct by segregation. Remethylation was observed in a few progenies. Efficiencies of remethylation in the progenies without the RNAi construct were different between 18S rDNA, BoSTF12a/15a, and BrTto1 sequences.

Abstract: Brassica napus is an amphidiploid species with the A genome from Brassica rapa and the C genome from Brassica oleracea. Although B. rapa, B. oleracea and artificially synthesized amphidiploids with the AC genome are self-incompatible, B. napus is self-compatible. Six S genotypes were identified in B. napus, five of which had class I S haplotypes from one species and a class II S haplotype from the other species, and mutations causing self-compatibility were identified in three of these S genotypes. The most predominant S genotype (BnS-1;BnS-6), which is that of cv. 'Westar', had a class I S haplotype similar to B. rapa S-47 (BrS-47) and a class II S haplotype similar to B. oleracea S-15 (BoS-15). The stigmas of 'Westar' rejected the pollen grains of both BrS-47 and BoS-15, while reciprocal crossings were compatible. Insertion of a DNA fragment of about 3.6 kb was found in the promoter region of the SP11/SCR allele of BnS-1, and transcripts of SP11/SCR were not detected in 'Westar'. The nucleotide sequence of the SP11 genomic DNA of BnS-6 was 100% identical to that of SP11 of BoS-15. Class I SP11 alleles from one species showed dominance over class II SP11 alleles from the other species in artificially synthesized B. napus lines, suggesting that the non-functional dominant SP11 allele suppressed the expression of the recessive SP11 allele in 'Westar'. Two other S genotypes in B. napus also had non-functional class I S haplotypes together with recessive BnS-6. These observations suggest independent origins of self-compatibility in B. napus.

Abstract: DNA polymorphism of the Wx gene in glutinous rice cultivars was investigated by PCR-RF-SSCP and heteroduplex cleavage analysis using Brassica petiole extract, and the nucleotide sequence variations were identified. Most japonica-type glutinous rice was found to have a 23-bp duplication in the second exon, which causes loss of the function of granule-bound starch synthase (GBSS) encoded by the Wx gene. Without the 23-bp duplication, there was an insertion of 7,764 bp in the ninth exon of the wx allele of 'Oragamochi'. Expression analysis of the wx allele using RT-PCR and Northern blot analysis revealed that transcripts of the 'Oragamochi' wx allele are about 1-kb shorter and that the deduced amino acid sequence of the transcript lacks a motif important for GBSS. Therefore, this insertion was considered to be the cause of the glutinous trait of 'Oragamochi'. This 7,764-bp insertion had long terminal repeats, a primer binding site, and a polypurine tract, but no sequence homologous with gag and pol, suggesting that it is a non-autonomous element. Furthermore, it had a structure similar to Dasheng and may be a member of Dasheng.

Abstract: Molecular imprinting is the differential expression and/or silencing of alleles according to their parent of origin [1, 2]. Conflicts between parents, or parents and offspring, should cause "arms races," with accelerated evolution of the genes involved in imprinting. This should be detectable in the evolution of imprinting genes' protein sequences and in the promoter regions of imprinted genes. Previous studies, however, found no evidence of more amino acid substitutions in imprinting genes [1, 3]. We have analyzed sequence diversity of the Arabidopsis lyrata Medea (MEA) gene and divergence from the A. thaliana sequence, including the first study of the promoter region. In A. thaliana, MEA is imprinted, with paternal alleles silenced in endosperm cells [4, 5], and also functions in the imprinting machinery [4, 6]; MEA protein binding at the MEA promoter region indicates self-regulated imprinting [7-9]. We find the same paternal MEA allele silencing in A. lyrata endosperm but no evidence for adaptive evolution in the coding region, whereas the 5' flanking region displays high diversity, with distinct haplotypes, suggesting balancing selection in the promoter region.

Abstract: In self-incompatibility, a number of S haplotypes are maintained by frequency-dependent selection, which results in trans-specific S haplotypes. The region of several kilobases (approximately 40-60 kb) from SP6 to SP2, including self-incompatibility-related genes and some adjacent genes in Brassica rapa, has high nucleotide diversity due to the hitchhiking effect, and therefore we call this region the "S-locus complex." Recombination in the S-locus complex is considered to be suppressed. We sequenced regions of >50 kb of the S-locus complex of three S haplotypes in B. rapa and found higher nucleotide diversity in intergenic regions than in coding regions. Two highly similar regions of >10 kb were found between BrS-8 and BrS-46. Phylogenetic analysis using trans-specific S haplotypes (called interspecific pairs) of B. rapa and B. oleracea suggested that recombination reduced the nucleotide diversity in these two regions and that the genes not involved in self-incompatibility in the S-locus complex and the kinase domain, but not the S domain, of SRK have also experienced recombination. Recombination may reduce hitchhiking diversity in the S-locus complex, whereas the region from the S domain to SP11 would disfavor recombination.

Abstract: Self-compatible S-54 homozygotic plants were found in progenies of an F(1) hybrid cultivar in Chinese cabbage. Pollination tests revealed that this self-compatibility is controlled by the S locus and caused by the loss of the recognition function of the stigma. SRK, the gene for the recognition molecule in the stigma, was normally transcribed and translated in the self-compatible plants. The 1034-bp region in the receptor domain of SRK in the self-compatible plants was 100% identical to SLG in S-54, while that in self-incompatible S-54 homozygotic plants was 95.1% identical. These results suggest that the self-compatibility of the S-54 homozygotes is due to amino-acid changes caused by gene conversion from SLG to SRK.

Abstract: 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.

Abstract: Mutations in the S locus of a self-compatible cultivar Yellow Sarson in Brassica rapa, which has a self-compatible class-I S haplotype, S-f2, were investigated. S-28 in Brassica oleracea was found to be a member of an interspecific pair with S-f2 in B. rapa. The original S haplotype of S-f2 was identified to be S-54 in B. rapa. Sequence comparison of alleles in S-f2 with those in S-54 and B. oleracea S-28 revealed insertion of a retrotransposon-like sequence in the first intron of SRK and 89-bp deletion in the promoter region of SP11. No transcripts of SRK and SP11 were detected in S-f2 homozygotes, suggesting that the insertion and the deletion in SRK and SP11, respectively, caused the loss of the function of these genes. Promoter assay using transgenic plants indicated that the SP11 promoter of S-f2 has no activity. Heterozygotes of S-f2 and a normal class-II S haplotype, S-60, in B. rapa were found to be self-compatible. Interestingly, transcription of SP11-60 was revealed to be suppressed in the S-f2/S-60 heterozygotes, suggesting that an untranscribed class-I SP11 allele suppresses the expression of a recessive class-II SP11 allele in the anthers of S heterozygotes. Similar phenomenon was observed in heterozygotes of a self-compatible class-I S haplotype and a self-incompatible class-II S haplotype in B. oleracea.

Abstract: DNA methylation is essential for normal development and plays important roles in regulating gene expression in plants. Analysis of the key enzymes catalyzing DNA methylation is important to understand epigenetic phenomena. In this study, three putative methyltransferase genes, BrMET1a, BrMET1b, and BrCMT, were isolated from a genome library of Brassica rapa. Structural conservation of the amino acid sequence between BrMET1a/BrMET1b and AtMET1 and that between BrCMT and AtCMT3 suggests that they may function as DNA methyltransferase. BrMET1a was expressed in vegetative and reproductive organs, while BrMET1b was expressed only in pistils, indicating that these two genes have different functions. BrCMT was expressed especially in stamens at the stage of 2-4 days before anthesis. We isolated three DNA methyltransferase genes in Brassica rapa and indicated differences of expression patterns of these DNA methyltransferase genes and expression levels in different tissues and developmental stages, suggesting that these genes might play important roles in epigenetic gene regulation in B. rapa.

Abstract: Nuclear so-called fertility-restorer genes reverse the pollen sterility of cytoplasmic male-sterile (CMS) plants caused by disturbed mitochondrial-nuclear interactions. We identified a CMS-associated chimeric mitochondrial gene in an alloplasmic CMS line of Brassica oleracea in the 'mur' system. This novel chimeric gene, orf72, was found in the mitochondrial genome of donor cytoplasm. It was located downstream of normal rps7 and contained part of atp9 (atp9-b). It was expressed specifically on the nuclear background of CMS B. oleracea, partially suppressed in the fertility-restored line and entirely suppressed in the cytoplasmic donor.

Abstract: 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.

Abstract: We have identified several interspecific pairs of S haplotypes having highly similar SRK and SP11/SCR sequences between Brassica oleracea and Brassica rapa. The recognition specificities of S haplotypes in these pairs were examined with three different methods. Stigmas of interspecific hybrids between an S-32 homozygote in B. oleracea and an S-60 homozygote in B. rapa, which were produced to avoid the interspecific incompatibility between the two species, showed incompatibility to the pollen of an S-8 homozygote in B. rapa and to the pollen of an S-15 homozygote in B. oleracea, while it showed compatibility to the pollen of other S haplotypes, suggesting B. oleracea S-32 and B. rapa S-60 have the same recognition specificity as B. rapa S-8 and B. oleracea S-15. Pollen grains of transgenic S-60 homozygous plants in B. rapa carrying a transgene of SP11-24 from B. oleracea were incompatible to B. rapa S-36 stigma, indicating that B. oleracea S-24 and B. rapa S-36 have the same recognition specificity. Application of the SP11 protein of B. rapa S-41 and S-47 onto the surface of B. oleracea S-64 stigmas and S-12 stigmas, respectively, resulted in the incompatibility reaction to pollen grains of another S haplotype, but application onto the stigmas of other S haplotypes did not, suggesting that B. oleracea S-64 stigmas and S-12 stigmas recognized the B. rapa SP11-41 and SP11-47 proteins as self SP11 proteins, respectively. Besides having evolutionary implications, finding of many interspecific pairs of S haplotypes can provide insight into the molecular mechanism of self-recognition. Comparing deduced amino-acid sequences of SP11 proteins and SRK proteins in the pairs, regions of SP11 and SRK important for self-recognition are discussed.

Abstract: A self-incompatibility system is used for F(1) hybrid breeding in Brassicaceae vegetables. The determinants of recognition specificity of self-incompatibility in Brassica are SRK in the stigma and SP11/SCR in the pollen. Nucleotide sequences of SP11 alleles are more highly variable than those of SRK. We analyzed the S haplotype specificity of SP11 DNA by Southern-blot analysis and dot-blot analysis using 16 S haplotypes in Brassica oleracea, and found that DNA fragments of a mature protein region of SP11 cDNA, SP11(m), of eight S haplotypes can detect only the SP11 alleles of the same S haplotypes. This specificity makes these methods useful for S haplotype identification. Therefore, we developed two methods of dot-blot analysis for SP11. One is dot blotting of DNA samples, i.e. plant genomic DNA probed with labeled SP11(m), and the other is dot blotting of SP11(m) DNA fragments probed with labeled DNA samples, i.e. the SP11 coding region labeled by PCR using a template of plant genomic DNA. The former is useful for testing many plant materials. The latter is suitable, if there is no previous information on the S haplotypes of plant materials.

Abstract: The determinants of recognition specificity of self-incompatibility in Brassica are SRK in the stigma and SP11/SCR in the pollen, respectively. In the pair of S haplotypes BrS46 (S46 in B. rapa) and BoS7 (S7 in B. oleracea), which have highly similar SRK alleles, the SP11 alleles were found to be similar, with 96.1% identity in the deduced amino acid sequence. Two other pairs of S haplotypes, BrS47 and BoS12, and BrS8 and BoS32, having highly similar SRK and SP11 alleles between the two species were also found. The haplotypes in each pair are considered to have been derived from a single S haplotype in the ancestral species. The allotetraploid produced by interspecific hybridization between homozygotes of BrS46 and BoS15 showed incompatibility with a BoS7 homozygote and compatibility with other B. oleracea S haplotypes in reciprocal crossings. This result indicates that BrS46 and BoS7 have maintained the same recognition specificity after the divergence of the two species and that amino acid substitutions found in such cases in both SRK alleles and SP11 alleles do not alter the recognition specificity. DNA blot analysis of SRK, SP11, SLG and other S-locus genes showed different DNA fragment sizes between the interspecific pairs of S haplotypes. A much lower level of sequence similarity was observed outside the genes of SRK and SP11 between BrS46 and BoS7. These results suggest that the DNA sequences of the regions intervening between the S-locus genes were diversified after or at the time of speciation. This is the first report demonstrating the presence of common S haplotypes in different plant species and presenting definite evidence of the trans-specific evolution of self-incompatibility genes.