Distribution of similar self-incompatibility (<Emphasis Type="Italic">S</Emphasis>) haplotypes in different genera,<Emphasis Type="Italic"> Raphanus</Emphasis> and<Emphasis Type="Italic"> Brassica</Emphasis>

The nucleotide sequences of ten SP11 and nine SRK alleles in Raphanus sativus were determined, and deduced amino acid sequences were compared with those of Brassica SP11 and SRK. The amino acid sequence identity of class-I SP11s in R. sativus was about 30% on average, the highest being 52.2%, while that of the S domain of class-I SRK was 77.0% on average and ranged from 70.8% to 83.9%. These values were comparable to those of SP11 and SRK in Brassica oleracea and B. rapa. SP11 of R. sativus S-21 was found to be highly similar to SP11 of B. rapa S-9 (89.5% amino acid identity), and SRK of R. sativus S-21 was similar to SRK of B. rapa S-9 (91.0%). SP11 and SRK of R. sativus S-19 were also similar to SP11 and SRK of B. oleracea S-20, respectively. These similarities of both SP11 and SRK alleles between R. sativus and Brassica suggest that these S haplotype pairs originated from the same ancestral S haplotypes.     

Simple and efficient methods for <Emphasis Type="Italic">S</Emphasis> genotyping and <Emphasis Type="Italic">S</Emphasis> screening in genus <Emphasis Type="Italic">Brassica</Emphasis> by dot-blot analysis

In F₁ hybrid breeding of Brassica vegetables utilizing the self-incompatibility system, identification of S genotypes in breeding lines is required. In the present study, we developed S-tester lines of 87 S haplotypes, i.e., 42 S haplotypes in B. rapa and 45 S haplotypes in B. oleracea. With these materials, we established a simple, efficient, and reliable dot-blot technique for S genotyping for 40 S haplotypes of B. rapa and and 33 of B. oleracea using allele-specific oligonucleotide probes and allele-specific primer pairs designed from sequences of each SP11 allele. In this method, DNA fragments amplified using multiplex primer pairs with digoxigenin-dUTP were hybridized with dot-blotted allele-specific oligonucleotide probes with distinct signals. In addition, we developed a screening method for identification of plants harboring a particular S haplotype using a labeled allele-specific oligonucleotide probe. This method is considered to be useful for purity testing of F₁ hybrid seeds.     

Recognition specificity of self-incompatibility maintained after the divergence of Brassica oleracea and Brassica rapa

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.     

Nucleotide sequence analysis of <Emphasis Type="Italic">S</Emphasis>-locus genes to unify <Emphasis Type="Italic">S</Emphasis> haplotype nomenclature in radish

Radish, belonging to the family Brassicaceae, has a self-incompatibility which is controlled by multiple alleles on the S locus. To employ the self-incompatibility in an F₁ breeding system, identification of S haplotypes is necessary. Since collection of S haplotypes and determination of nucleotide sequences of SLG, SRK, and SCR alleles in cultivated radish have been conducted by different groups independently, the same or similar sequences with different S haplotype names and different sequences with the same S haplotype names have been registered in public databases, resulting in confusion of S haplotype names for researchers and breeders. In the present study, we developed S homozygous lines from radish F₁ hybrid cultivars in Japan and determined the nucleotide sequences of SCR, the S domain and the kinase domain of SRK, and the SLG of a large number of S haplotypes. Comparing these sequences with our previously published sequences, the haplotypes were ordered into 23 different S haplotypes. The sequences of the 23 S haplotypes were compared with S haplotype sequences registered by different groups, and we suggested a unification of these S haplotypes. Furthermore, dot-blot hybridization using SRK allele-specific probes was examined for developing a standard method for S haplotype identification.     

<Emphasis Type="Italic">S</Emphasis> genotyping and <Emphasis Type="Italic">S</Emphasis> screening utilizing <Emphasis Type="Italic">SFB</Emphasis> gene polymorphism in Japanese plum and sweet cherry by dot-blot analysis

Most Rosaceae fruit trees such as Japanese plum and sweet cherry have a gametophytic self-incompatibility (GSI) system controlled by a single S locus containing at least two linked genes with multiple alleles, i.e., S-RNase as a pistil determinant and SFB (S-haplotype-specific F-box gene) as a candidate for the pollen S determinant. For identification of S genotypes, many methods based on polymerase chain reaction (PCR) utilizing polymorphism in length of the S-RNase and SFB gene have been developed. In this study, we developed two dot-blot analysis methods for S-haplotype identification utilizing allele-specific oligonucleotides based on the SFB-HVa region, which has high sequence polymorphism. Dot-blotting of allele-specific oligonucleotides hybridized with digoxigenin-labeled PCR products allowed S genotyping of plants with nine S haplotypes (S-a, S-b, S-c, S-e, S-f, S-h, S-k, S-7 and S-10) in Japanese plum and ten S haplotypes (S-1, S-2, S-3, S-4, S-4′, S-5, S-6, S-7, S-9 and S-16) in sweet cherry (dot-blot-S-genotyping). In addition, dot-blotting of PCR products of SFB probed with the allele-specific oligonucleotides, occasionally utilizing competitive hybridization, was successful in screening for a desirable S haplotype in sweet cherry (dot-blot-S-screening).     

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.     

Physical size of the <Emphasis Type="Italic">S</Emphasis> locus region defined by genetic recombination and genome sequencing in <Emphasis Type="Italic">Ipomoea trifida</Emphasis>, Convolvulaceae

Sporophytic self-incompatibility (SSI) in the genus Ipomoea (Convolvulaceae) is controlled by a single polymorphic S locus. We have previously analyzed genomic sequences of an approximately 300 kb region spanning the S locus of the S ₁ haplotype and characterized the genomic structure around this locus. Here, we further define the physical size of the S locus region by mapping recombination breakpoints, based on sequence analysis of PCR fragments amplified from the genomic DNA of recombinants. From the recombination analysis, the S locus of the S ₁ haplotype was delimited to a 0.23 cM region of the linkage map, which corresponds to a maximum physical size of 212 kb. To analyze differences in genomic organization between S haplotypes, fosmid contigs spanning approximately 67 kb of the S ₁₀ haplotype were sequenced. Comparison with the S ₁ genomic sequence revealed that the S haplotype-specific divergent regions (SDRs) spanned 50.7 and 34.5 kb in the S ₁ and S ₁₀ haplotypes, respectively and that their flanking regions showed a high sequence similarity. In the sequenced region of the S ₁₀ haplotype, five of the 12 predicted open reading frames (ORFs) were found to be located in the divergent region and showed co-linear organization of genes between the two S haplotypes. Based on the size of the SDRs, the physical size of the S locus was estimated to fall within the range 34–50 kb in Ipomoea.     

Phylogenetic analysis of <Emphasis Type="Italic">Brassiceae</Emphasis> based on the nucleotide sequences of the <Emphasis Type="Italic">S</Emphasis>-locus related gene, <Emphasis Type="Italic">SLR1</Emphasis>

Nucleotide sequences of orthologs of the S-locus related gene, SLR1, in 20 species of Brassicaceae were determined and compared with the previously reported SLR1 sequences of six species. Identities of deduced amino-acid sequences with Brassica oleracea SLR1 ranged from 66.0% to 97.6%, and those with B. oleracea SRK and SLR2 were less than 62% and 55%, respectively. In multiple alignment of deduced amino-acid sequences, the 180-190th amino-acid residues from the initial methionine were highly variable, this variable region corresponding to hypervariable region I of SLG and SRK. A phylogenetic tree based on the deduced amino-acid sequences showed a close relationship of SLR1 orthologs of species in the Brassicinae and Raphaninae. Brassica nigra SLR1 was found to belong to the same clade as Sinapis arvensis and Diplotaxis siifolia, while the sequences of the other Brassica species belonged to another clade together with B. oleracea and Brassica rapa. The phylogenetic tree was similar to previously reported trees constructed using the data of electrophoretic band patterns of chloroplast DNA, though minor differences were found. Based on synonymous substitution rates in SLR1, the diversification time of SLR1 orthologs between species in the Brassicinae was estimated. The evolution and function of SLR1 and the phylogenetic relationship of Brassiceae plants are 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.     

Unique haplotypes of co-segregating major histocompatibility class II <Emphasis Type="Italic">A</Emphasis> and class II <Emphasis Type="Italic">B</Emphasis> alleles in Atlantic salmon (<Emphasis Type="Italic">Salmo salar</Emphasis>) give rise to diverse class II genotypes

Sequence-based typing of a breeding population (G1) consisting of 84 Atlantic salmon individuals revealed the presence of 7 Sasa-DAA and 7 Sasa-DAB expressed alleles. Subsequent typing of 1,182 individuals belonging to 33 families showed that Sasa-DAA and Sasa-DAB segregate as haplotypes. In total seven unique haplotypes were established, with frequencies in the population studied ranging from 0.01 to 0.49. Each haplotype is characterized by a unique minisatellite marker size embedded in the 3' untranslated region of the Sasa-DAA gene. These data corroborate the fact that Atlantic salmon express a single class II locus, consisting of tightly linked class II A and class B genes. The seven haplotypes give rise to 15 genotypes with frequencies varying between 0.01 and 0.23; 21 class II homozygous individuals were present in the G1 population. We also studied the frequency distribution in another breeding population (G4, n=374) using the minisatellite marker. Only one new marker size was present, suggesting the presence of one new class II haplotype. The marker frequency distribution in the G4 population differed markedly from the G1 population. The genomic organizations of two Sasa-DAA and Sasa-DAB alleles were determined, and supported the notion that these alleles belong to the same locus. In contrast to other studies of salmonid class II sequences, phylogenetic analyses of brown trout and Atlantic class II A and class II B sequences provided support for trans-species polymorphism.     

Genetic structure of <Emphasis Type="Italic">Varroa destructor</Emphasis> populations infesting <Emphasis Type="Italic">Apis mellifera</Emphasis> colonies in Argentina

Although mitochondrial DNA mapping of Varroa destructor revealed the presence of several haplotypes, only two of them (Korean and Japanese haplotypes) were capable to infest Apis mellifera populations. Even though the Korean haplotype is the only one that has been reported in Argentina, these conclusions were based on mites sampled in apiaries from a specific geographical place (Buenos Aires province). To study mites from several sites of Argentina could reveal the presence of the Japanese genotype, especially considering sites near to Brazil, where Japanese haplotype was already detected. The aim of this work was to study the genetic structure of V. destructor populations from apiaries located in various provinces of Argentina, in order to determine the presence of different haplotypes. The study was carried out between January 2006 and December 2009. Phoretic adult Varroa mites were collected from honey bee workers sampled from colonies of A. mellifera located in Entre Ríos, Buenos Aires, Corrientes, Río Negro, Santa Cruz and Neuquén provinces. Twenty female mites from each sampling site were used to carry out the genetic analysis. For DNA extraction a nondestructive method was used. DNA sequences were compared to Korean haplotype (AF106899) and Japanese haplotype (AF106897). All DNA sequences obtained from mite populations sampled in Argentina, share 98% of similitude with Korean Haplotype (AF106899). Taking into account these results, we are able to conclude that Korean haplotype is cosmopolite in Argentina.     

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.     

Intrahaplotype polymorphism at the Brassica S locus

The S locus receptor kinase and the S locus glycoproteins are encoded by genes located at the S locus, which controls the self-incompatibility response in Brassica. In class II self-incompatibility haplotypes, S locus glycoproteins can be encoded by two different genes, SLGA and SLGB. In this study, we analyzed the sequences of these genes in several independently isolated plants, all of which carry the same S haplotype (S(2)). Two groups of S(2) haplotypes could be distinguished depending on whether SRK was associated with SLGA or SLGB. Surprisingly, SRK alleles from the two groups could be distinguished at the sequence level, suggesting that recombination rarely occurs between haplotypes of the two groups. An analysis of the distribution of polymorphisms along the S domain of SRK showed that hypervariable domains I and II tend to be conserved within haplotypes but to be highly variable between haplotypes. This is consistent with these domains playing a role in the determination of haplotype specificity.     

Existence of<Emphasis Type="Italic">Sinorhizobium meliloti</Emphasis> genomic fragment hybridizing with the<Emphasis Type="Italic">nifM</Emphasis> gene of<Emphasis Type="Italic">Klebsiella pneumoniae</Emphasis>

A novel finding that genomic restriction fragments of symbiotic nitrogen fixer S. meliloti hybridized with nifM gene probe of the free-living diazotroph Klebsiella pneumoniae is reported. When SmaI endonuclease was used to digest S. meliloti DNA, a unique hybridizing band was obtained.     

Polymorphism of the <Emphasis Type="Italic">CONSTANS</Emphasis> gene in <Emphasis Type="Italic">Brassica</Emphasis> plants

Using a direct amplification of genomic DNA from two Brassica rapa forms, we obtained two homologs of the CONSTANS gene, which controls the photoperiodic induction of flowering in Arabidopsis plants. The cloned fragments of B. rapa genome were identified as members of the CONSTANS-LIKE1 class. By aligning the nucleotide sequences of the CONSTANS gene and its homologs, three classes, CONSTANS, CONSTANS-LIKE1, and CONSTANS-LIKE2, were distinctly discerned by their primary structure. The pattern of restriction fragment length polymorphisms (RFLP) of the CONSTANS homologs in B. carinata, B. juncea, B. napus, B. nigra, B. oleracea, and B. rapa were genome-specific; in addition, the CONSTANS homologs were classified by plant geographic origin, and we assume that such classification is related to plant photoperiodic response.Translated from Fiziologiya Rastenii, Vol. 52, No. 2, 2005, pp. 274–281.Original Russian Text Copyright © 2005 by Martynov, Khavkin.This revised version was published online in April 2005 with a corrected cover date.     

Mitochondrial <Emphasis Type="Italic">cox</Emphasis>1 and plastid <Emphasis Type="Italic">rbc</Emphasis>L genes of <Emphasis Type="Italic">Gracilaria vermiculophylla</Emphasis> (Gracilariaceae,Rhodophyta)

The mitochondrial cytochrome c oxidase subunit I gene sequence was recently developed for DNA barcoding of red algal species. We determined the 1245 base pairs of the gene from 27 taxa of an agar-producing species, Gracilaria vermiculophylla, and putative relatives and compared the results with rbcL data from the same species. A total of 392 positions (31.5%) were variable, 282 positions (22.6%) were parsimoniously informative, and average sequence divergence was 13% in an ingroup. Within G. vermiculophylla, pairwise divergence of the gene was variable up to 11 bp (0.9%). Seven recognized haplotypes of cox1 tended to be geographically related. In the aligned 1386 bp of rbcL, three haplotypes were recognized. These results suggest that cox1 is a valuable molecular marker within species and will be very useful in haplotype analyses.     

<Emphasis Type="Italic">Ty</Emphasis>1<Emphasis Type="Italic">/copia</Emphasis>- and <Emphasis Type="Italic">Ty</Emphasis>3<Emphasis Type="Italic">/gypsy</Emphasis>-like DNA sequences in <Emphasis Type="Italic">Helianthus </Emphasis>species

Two repeated DNA sequences isolated from a partial genomic DNA library of Helianthus annuus, p HaS13 and p HaS211, were shown to represent portions of the int gene of a Ty3 /gypsy retroelement and of the RNase-Hgene of a Ty1 /copia retroelement, respectively. Southern blotting patterns obtained by hybridizing the two probes to BglII- or DraI-digested genomic DNA from different Helianthus species showed p HaS13 and p HaS211 were parts of dispersed repeats at least 8 and 7 kb in length, respectively, that were conserved in all species studied. Comparable hybridization patterns were obtained in all species with p HaS13. By contrast, the patterns obtained by hybridizing p HaS211 clearly differentiated annual species from perennials. The frequencies of p HaS13- and p HaS211-related sequences in different species were 4.3x10(4)-1.3x10(5) copies and 9.9x10(2)-8.1x10(3) copies per picogram of DNA, respectively. The frequency of p HaS13-related sequences varied widely within annual species, while no significant difference was observed among perennial species. Conversely, the frequency variation of p HaS211-related sequences was as large within annual species as within perennials. Sequences of both families were found to be dispersed along the length of all chromosomes in all species studied. However, Ty3 /gypsy-like sequences were localized preferentially at the centromeric regions, whereas Ty1/ copia-like sequences were less represented or absent around the centromeres and plentiful at the chromosome ends. These findings suggest that the two sequence families played a role in Helianthusgenome evolution and species divergence, evolved independently in the same genomic backgrounds and in annual or perennial species, and acquired different possible functions in the host genomes.