Cross-transferability and Polymorphic Potential of Genomic STMS Markers of Brassica Species

The present study was carried out with the objective of evaluating genomic STMS markers developed earlier in Brassica napus, B. oleracea, B. rapa and B. nigra for their use in Brassica juncea and B. carinata. Ninety-six of the 100 STMS markers used under standardized annealing temperatures and gel concentrations produced clear reproducible amplification pattern. For majority of the markers 60 °C annealing temperature and 3.5% metaphor agarose gel were found suitable. High cross-transferability of STMS markers to related Brassica species including B. carinata (91.6%) and B. juncea (87.5%) suggested the possibility of utilizing these markers for genome analysis in the species where no such markers are available. The ‘B’ genome derived markers showed lower level of transferability to the ‘A’ and ‘C’ genome Brassica species. The potential of STMS markers to detect polymorphism among Brassica species and genera was 98.9%. The level of inter-specific polymorphism was much higher than the intea-specific polymorphism. The markers capable of revealing polymorphism among Brassica species and genera would be useful in Brassica introgression breeding programme. The polymorphic markers were found efficient in establishing the expected evolutionary relationships among the six different Brassica species and two related genera. Low level of intra-specific polymorphism revealed by these markers suggested use of a large set of such markers for various applications in Brassica genetics, genomics and breeding.     

Brassica taxonomy based on nuclear restriction fragment length polymorphisms (RFLPs)

Summary Restriction fragment length polymorphisms (RFLPs) of nuclear DNAs have been used to explore the origin and evolution of the six cultivated Brassica species. Extensive RFLP variation was found at the species, subspecies and variety levels. Based on RFLP data from Brassica and related genera, a detailed phylogenetic tree was generated using the PAUP microcomputer program, which permits a quantitative analysis of the interrelationships among Brassica species. The results suggested that 1) B. nigra originated from one evolutionary pathway with Sinapis arvensis or a close relative as the likely progenitor, whereas B. campestris and B. oleracea came from another pathway with a possible common ancestor in wild B. oleracea or a closely related nine chromosome species; 2) the amphidiploid species B. napus and B. juncea have evolved through different combinations of the diploid morphotypes and thus polyphyletic origins may be a common mechanism for the natural occurrence of amphidiploids in Brassica; 3) the cytoplasm has played an important role in the nuclear genome evolution of amphidiploid species when the parental diploid species contain highly differentiated cytoplasms. A scheme for the origins of diploid and amphidiploid species is depicted based on evidence gathered from nuclear RFLP analysis, cpDNA RFLP analysis, cytogenetic studies and classical taxonomy.     

Different genome-specific chromosome stabilities in synthetic Brassica allohexaploids revealed by wide crosses with Orychophragmus

Background and Aims

In sexual hybrids between cultivated Brassica species and another crucifer, Orychophragmus violaceus (2n = 24), parental genome separation during mitosis and meiosis is under genetic control but this phenomenon varies depending upon the Brassica species. To further investigate the mechanisms involved in parental genome separation, complex hybrids between synthetic Brassica allohexaploids (2n = 54, AABBCC) from three sources and O. violaceus were obtained and characterized.

Methods

Genomic in situ hybridization, amplified fragment length polymorphism (AFLP) and single-strand conformation polymorphism (SSCP) were used to explore chromosomal/genomic components and rRNA gene expression of the complex hybrids and their progenies.

Key Results

Complex hybrids with variable fertility exhibited phenotypes that were different from the female allohexaploids and expressed some traits from O. violaceus. These hybrids were mixoploids (2n = 34–46) and retained partial complements of allohexaploids, including whole chromosomes of the A and B genomes and some of the C genome but no intact O. violaceus chromosomes; AFLP bands specific for O. violaceus, novel for two parents and absent in hexaploids were detected. The complex hybrids produced progenies with chromosomes/genomic complements biased to B. juncea (2n = 36, AABB) and novel B. juncea lines with two genomes of different origins. The expression of rRNA genes from B. nigra was revealed in all allohexaploids and complex hybrids, showing that the hierarchy of nucleolar dominance (B. nigra, BB > B. rapa, AA > B. oleracea, CC) in Brassica allotetraploids was still valid in these plants.

Conclusions

The chromosomes of three genomes in these synthetic Brassica allohexaploids showed different genome-specific stabilities (B > A > C) under induction of alien chromosome elimination in crosses with O. violaceus, which was possibly affected by nucleolar dominance.Key words: Synthetic Brassica allohexaploids, Orychophragmus violaceus, intergeneric hybrids, genomic in situ hybridization, amplified fragment length polymorphism, single-strand conformation polymorphism, chromosome elimination, chromosome stability, nucleolar dominance     

Sexuality and Genetic Identity in the Agaricus Section Arvenses

Twelve wild collections and one commercial strain were used to characterize breeding systems and to develop molecular identities in the Arvenses section of the genus Agaricus, which includes the “horse mushroom” A. arvensis. Two morphotypes were identified based on macro- and micromorphological features. However, not all collections could be delimited by conventional taxonomic characters. Sequencing of the small subunit intergenic spacer (ITS) region (368 to 370 bp) of the rRNA genes clearly resolved the 13 collections into two clusters consistent with the identified morphotypes. Single-spore progenies and mating type testers were established and used to test intra- and interstock compatibility. The two compatibility groups identified were consistent with ITS clusters. Compatibility group I stocks readily interbred within the constraints of a unifactorial heterothallic system with a multiallelic mating type factor. Compatibility group II had a more restricted breeding pattern, and interactions were difficult to predict on the basis of mating type. Morphological data, ITS sequences, and the ability to interbreed suggest that these collections are part of a complex of interrelated species. Single-spore, homokaryotic isolates from both compatibility groups were able to fruit in compost culture, and two of the collections may represent natural homokaryotic fruiting. We conclude that species from the section Arvenses have versatile unifactorial heterothallic life cycles that permit both interbreeding and homokaryotic fruiting.     

Cloning of TTG1 gene and PCR identification of genomes A,B and C in Brassica species

Arabidopsis Transparent Testa Glabra 1 (TTG1) genes were cloned from three diploid Brassica species (B. rapa, B. nigra and B. oleracea) and two amphidiploids species (B. juncea and B. carinata) by homology cloning. TTG1 homologues identified in all the accessions of the investigated species had a coding sequence of 1,014 bp. One copy was obtained from each diploid species and two copies from each amphidiploid species. Combined analysis of the TTG1 sequences cloned in this study with those obtained from public databases demonstrated that three, forty-five and seven nucleotides were specific variations in TTG1 genes from genomes A, B and C, respectively. Primers designed with genome-specific nucleotide variations were able to distinguish among TTG1 genes originating from genomes A, B and C in Brassica. Therefore, the TTG1 gene could serve as a candidate marker gene to detect the pollen flow of Brassica and provide an alternative method for the detection of pollen drift and risk assessment of gene flow in Brassica species.     

Flavonol glycosides in Brassica and Sinapis

The 7-glucosides and 3,7-diglucosides of kaempferol and isorhamnetin were identified in leaves and flowers of Sinapis arvensis. Additionally, the 3-sophoroside-7-glucosides of kaempferol, quercetin and isorhamnetin were found in leaves of S. arvensis and Brassica oleracea. Two dimensional surveys of leaf extracts of 27 species and cultivars of Brassica and Sinapis showed that the same pattern occurred in most species. B. tournefortii and S. flexuosa were exceptional in having flavonol 3-monosides and 3-diglycosides instead. The results suggest that it is the glycosidic patterns, rather than the distribution of the flavonol aglycones, which are likely to be of taxonomic value for distinguishing groups of species or genera within the Cruciferae.     

Brassica taxonomy based on nuclear restriction fragment length polymorphisms (RFLPs)

Summary RFLPs were used to study genome evolution and phylogeny in Brassica and related genera. Thirtyeight accessions, including 10 accessions of B. rapa (syn. campestris), 9 cultivated types of B. oleracea, 13 nine-chromosome wild brassicas related to B. oleracea, and 6 other species in Brassica and allied genera, were examined with more then 30 random genomic DNA probes, which identified RFLPs mapping to nine different linkage groups of the B. rapa genome. Based on the RFLP data, phylogenetic trees were constructed using the PAUP microcomputer program. Within B. rapa, accessions of pak choi, narinosa, and Chinese cabbage from East Asia constituted a group distinct from turnip and wild European populations, consistent with the hypothesis that B. rapa had two centers of domestication. A wild B. rapa accession from India was positioned in the tree between European types and East Asian types, suggesting an evolutionary pathway from Europe to India, then to South China. Cultivated B. oleracea morphotypes showed monophyletic origin with wild B. oleracea or B. alboglabra as possible ancestors. Various kales constitute a highly diverse group, and represent the primitive morphotypes of cultivated B. oleracea from which cabbage, broccoli, cauliflower, etc. probably have evolved. Cauliflower was found to be closely related to broccoli, whereas cabbage was closely related to leafy kales. A great diversity existed among the 13 collections of nine-chromosome wild brassicas related to B. oleracea, representing various taxonomic states from subspecies to species. Results from these studies suggested that two basic evolutionary pathways exist for the diploid species examined. One pathway gave rise to B. fruticulosa, B. nigra, and Sinapis arvensis, with B. adpressa or a close relative as the initial ancestor. Another pathway gave rise to B. oleracea and B. rapa, with Diplotaxis erucoides or a close relative as the initial ancestor. Raphanus sativus and Eruca sativus represented intermediate types between the two lineages, and might have been derived from introgression or hybridization between species belonging to different lineages. Molecular evidence for an ascending order of chromosome numbers in the evolution of Brassica and allied genera was obtained on the basis of RFLP data and phylogenetic analysis.     

Unique chromosome behavior and genetic control in Brassica×Orychophragmus wide hybrids: a review

Researchers recognized early that chromosome behavior, as other morphological characters, is under genetic control and gave some cytogenetical examples such as the homoeologous chromosome pairing in wheat. In the intergeneric sexual hybrids between cultivated Brassica species and another crucifer Orychophragmus violaceus, the phenomenon of parental genome separation was found under genetic control during mitosis and meiosis. The cytogenetics of these hybrids was species-specific for Brassica parents. The different chromosome behavior of hybrids with three Brassica diploids (B. rapa, B. nigra and B. oleracea) might contribute to the different cytology of hybrids with three tetraploids (B. napus, B. juncea and B. carinata). The finding that genome-specific retention or loss of chromosomes in hybrids of O. violaceus with B. carinata and synthetic Brassica hexaploids (2n=54, AABBCC) is likely related to nucleolar dominance gives new insight into the molecular mechanisms regarding the cytology in these hybrids. It is proposed that the preferential expressions of genes for centromeric proteins from one parent (such as the well presented centromeric histone H3) are related with chromosome stability in wide hybrids and nucleolar dominance is beneficial to the production of centromere-specific proteins of the rRNAs-donor parent and to the stability of its chromosomes.     

Production of fertile intergeneric somatic hybrids between Brassica napus and Sinapis arvensis for the enrichment of the rapeseed gene pool

Somatic hybrids between Brassica napus (oilseed rape) and its wild relative Sinapis arvensis (Xinjiang wild mustard) from northwestern China were produced by fusing mesophyll protoplasts. Fifty-four plants were identified as symmetric hybrids and four as asymmetric hybrids by random amplified polymorphic DNA analysis and nuclear DNA content. The morphology of investigated 58 hybrid plants resembled characters from both parental species. Highly fertile hybrids were recovered where the fertility was associated with the choice of B. napus genotype. Enhanced disease resistance to Leptosphaeria maculans was found in S. arvensis and in the hybrid offspring. This plant material has great potentials not only for use as a bridge for the introduction of a number of valuable traits from the wild species to Brassica crops but also for breeding new varieties with improved blackleg resistance.     

Molecular characterization of the flowering time gene FRIGIDA in Brassica genomes A and C

An important determinant of flowering time variation in Arabidopsis, the FRIGIDA (FRI) gene has not been until recently investigated in economically important Brassica species. In diploid Brassica species, this gene exists as two paralogous loci on chromosomes A3 and A4 (B. rapa; A genome), and C3 and C9 (B. oleracea; C genome). Each locus is represented by several genome-specific alleles, which are discerned primarily by polymorphisms in C- and especially N-terminal regions. Locus- and genome-specific sequences of two FRI paralogues are conserved almost completely in the subgenomes A and C of tetraploid B. napus. The phylogenetic analysis of available FRI sequences presumes that the duplication of FRI loci preceded speciation in the genus Brassica.     

Development and validation of donor-specific STS markers for tracking alien introgressions into <Emphasis Type="Italic">Brassica juncea</Emphasis> (L.) Czern

Alien introgressions into crop plants rely on phenotypic evaluation. Employing molecular markers could greatly accelerate this and help discover new alleles/QTLs. We report here a new strategy to develop markers for tracking introgression using genome survey sequence. We demonstrate this using an advanced backcross population of Brassica juncea involving the wild species Diplotaxis erucoides. To develop D. erucoides-specific markers, 72 million single end reads were obtained using Ion-Torrent platform. Quality reads (67.6 million) were checked against Brassica database and the redundant reads were eliminated. De novo assembly of the remaining 14.6 million reads gave 3895 contigs (> 1 kb), which were used to design 101 donor-specific (DS) STS markers. Of these, 89 markers showed polymorphism between D. erucoides and B. juncea. Genotyping of 90 randomly picked plants with 31 donor-specific STS markers detected 22 plants containing 17 markers. Alien introgression was also detected in eight of the 22 lines displaying phenotypes deviating from B. juncea parent. The marker DSSTS 70 was found in six of the nine lines showing glossy leaf suggesting its association with the trait. This is the first study demonstrating the use of molecular markers for implementing reverse genetics approach for alien introgression into crop plants.     

The vernalization gene FRIGIDA in cultivated Brassica species

The repressor FLOWERING LOCUS C (FLC) holds a key position among the genes, which drive Arabidopsis floral transition along the vernalization pathway. The FRIGIDA (FRI) gene activates FLC expression, and the interplay of strong and weak alleles of FLC and FRI in many cases explains the variations in Arabidopsis requirement for cold induction. In annual and biennial life forms of Brassica, the variations in time to flower have been also related to FLC; whereas the place of FRI in the vernalization process has not been sufficiently elucidated. In contrast to Arabidopsis, FRI in Brassica genomes A and C and presumably B is represented by two expressible loci, FRI.a and FRI.b, each of them manifesting genome-specific polymorphisms. FRI.a and FRI.b sequences from diploid species B. rapa (genome A) and B. oleracea (genome C) are conserved (96–99% similarity) in subgenomes A and C of tetraploid species B. carinata (genome BC), B. juncea (genome AB), and B. napus (genome AC). Phylogenetic analysis of FRI sequences in the genus Brassica clearly discerns the lineages A/C and B, while in the family Brassicaceae, two FRI clusters discriminated by such analysis correspond to the lineages I (including the genus Arabidopsis) and II (including the genus Brassica). The origin of two FRI loci is discussed in the context of the Brassicaceae evolution via paleopolyploidy and subsequent genome reorganization.     

Plant regeneration capacity of mesophyll protoplasts from Brassica napus and related species

Protoplasts from a total of thirty-six genotypes of Brassica species – B. napus, B. campestris (syn. B. rapa), B. juncea, and three distant relatives, Orychophragmus violaceus, Isatis indigotica and Xinjiang wild rape – were analysed for shoot regeneration using a feeder culture system. With the exception of B. campestris and Xinjiang wild rape, some genotypes of all the species could regenerate plants with high efficiency (above 20% of isolated calli initiating shoots). Several genotypes with high regeneration ability were elite breeding lines. Culture conditions as well as genotype had a significant impact on shoot regeneration frequency. In particular, silver nitrate added to the regeneration medium at doses of 6 and 30 μM improved shoot regeneration frequency to 25.4% and 52.2% of isolated calli, respectively, compared to 7.3% percent shoot regeneration without silver nitrate in seven responsive genotypes. Addition of silver nitrate to the regeneration medium also induced shoot regeneration in non-responsive genotypes. Intact plants could be obtained within three months from protoplast isolation in the regenerative genotypes using the current culture system. Advantages of mesophyll protoplasts as compared to protoplasts isolated from hypocotyls for genetic manipulation in Brassica species are discussed. This revised version was published online in June 2006 with corrections to the Cover Date.     

Polymorphism of the <Emphasis Type="Italic">LEAFY</Emphasis> Gene in <Emphasis Type="Italic">Brassica</Emphasis> Plants

The arabidopsis gene LEAFY controls the induction of flowering and maintenance of the floral meristem identity. By comparing the primary structure of LEAFY and its homologs in other Brassicaceae species and beyond this family, we singled out four clusters corresponding to three systematically remote families of angiosperms, Brassicaceae, Solanaceae, and Poaceae, and to gymnosperms. Both structural and functional distinctions of LEAFY homologs from their arabidopsis prototype expanded in the range Brassicaceae—Solanaceae—Poaceae. A LEAFY homolog from B. juncea cloned in our laboratory was used as a hybridization probe to analyze the restriction fragment length polymorphism in six Brassica species comprising diploid (AA, BB, and CC) and allotetraploid (AABB, AACC, and BBCC) genomes. In this way we recognized LEAFY fragments specific of genomes A, B, and C; in contrast, the variations of the length and structure of the LEAFY intron 2 were not genome-specific. LEAFY polymorphism in the Brassica accessions comprising genome B was related to their geographic origin and apparently to the adaptation to day length.     

Comparison of ISSR,IRAP and REMAP markers for assessing genetic diversity in different species of <Emphasis Type="Italic">Brassica</Emphasis> sp.

Molecular markers provide facilities in order to study genetic diversity and relationship among genotypes. In this study, genetic diversity among 35 genotype of Brassica sp. (belonging B. napus, B. juncea, B. rapa, B. nigra) were determined using 13 ISSR, 3 IRAP markers and 18 REMAP (primer combinations of ISSR and retrotransposon primer). The percentage of polymorphism for ISSR, IRAP and REMAP was 96.38, 94 and 96%, respectively. By comparison between markers, ISSRs indicated the highest expected heterozygosity (He) and Shannon’s information index (I) with value of 0.34 and 0.51, respectively, while REMAP marker had by far the highest number of polymorphic bands (340) and marker index (7.1) among all fragments scored over all markers. In pattern of clustering based on Bayesian methods, K = 8 was resulted for combined data clustering that was more organized clustering for genotypes compared to others. This research suggests the combined data of ISSR, IRAP and REMAP markers are most reliable than each solely marker whilst have been clustered genotypes in their taxonomic classification of Brassica without any mixture. Principle coordinate analysis (PCoA) separated 35 genotypes in four groups which all of genotypes were clustered correctly based on their taxonomic classification. The findings of this study provide the valuable insight into the Brassica species relationships in terms of similarity among genotypes which can be helpful in breeding programs, and also demonstrate that retrotransposon markers are legible for genetic diversity and next genetic analysis in Brassica genus.     

Comparative Evaluation of RAPD, ISSR and Anchored-SSR Markers in the Assessment of Genetic Diversity and Fingerprinting of Oilseed Brassica Genotypes

Forty-two genotypes representing oilseed Brassica species were analyzed for the level of genetic diversity and molecular identity using Random Amplified Polymorphic DNA (RAPD), Inter-Simple Sequence Repeat (ISSR) and 5'-Anchored Simple Sequence Repeat (ASSR) markers. DNA profiles revealed high degree of interspecific polymorphism, while the level was considerably low within a species, particularly in B. juncea. The UPGMA clusters clearly delineated genotypes of the respective Brassica species. Comparison of cophenetic matrices indicated a high degree of correspondence between dendrograms generated by different marker systems. A minimum of 10 random primers (approximately 105 bands) were required for the RAPD profiles to generate the expected cluster. Comparatively less number of primers was required to do the same in case of ISSR (4 primers) and ASSR (3 primers). The principal component analysis revealed similar genetic relationship among the genotypes as in cluster analysis. Although none of the DNA profiles could individually identify all the B. juncea genotypes, a combined DNA profile consisting 125 markers from the informative primers of all the three DNA marker systems could do the same. A positive correlation was found among the marker utility parameters (calculated for individual primers of different marker systems) such as marker index (MI), resolving power (Rp) and discrimination coefficient (D) with the number of genotypes identified by each primer with a few exceptions. Single plant analysis for a set of five B. juncea varieties revealed absence of intra-varietal heterogeneity in case of ASSR profiles, thereby suggesting its utility in varietal identification and differentiation.     

Genome-Wide Microsatellite Characterization and Marker Development in the Sequenced Brassica Crop Species

Although much research has been conducted, the pattern of microsatellite distribution has remained ambiguous, and the development/utilization of microsatellite markers has still been limited/inefficient in Brassica, due to the lack of genome sequences. In view of this, we conducted genome-wide microsatellite characterization and marker development in three recently sequenced Brassica crops: Brassica rapa, Brassica oleracea and Brassica napus. The analysed microsatellite characteristics of these Brassica species were highly similar or almost identical, which suggests that the pattern of microsatellite distribution is likely conservative in Brassica. The genomic distribution of microsatellites was highly non-uniform and positively or negatively correlated with genes or transposable elements, respectively. Of the total of 115 869, 185 662 and 356 522 simple sequence repeat (SSR) markers developed with high frequencies (408.2, 343.8 and 356.2 per Mb or one every 2.45, 2.91 and 2.81 kb, respectively), most represented new SSR markers, the majority had determined physical positions, and a large number were genic or putative single-locus SSR markers. We also constructed a comprehensive database for the newly developed SSR markers, which was integrated with public Brassica SSR markers and annotated genome components. The genome-wide SSR markers developed in this study provide a useful tool to extend the annotated genome resources of sequenced Brassica species to genetic study/breeding in different Brassica species.     

Genic Microsatellite Markers in Brassica rapa: Development, Characterization, Mapping, and Their Utility in Other Cultivated and Wild Brassica Relatives

Genic microsatellite markers, also known as functional markers, are preferred over anonymous markers as they reveal the variation in transcribed genes among individuals. In this study, we developed a total of 707 expressed sequence tag-derived simple sequence repeat markers (EST-SSRs) and used for development of a high-density integrated map using four individual mapping populations of B. rapa. This map contains a total of 1426 markers, consisting of 306 EST-SSRs, 153 intron polymorphic markers, 395 bacterial artificial chromosome-derived SSRs (BAC-SSRs), and 572 public SSRs and other markers covering a total distance of 1245.9 cM of the B. rapa genome. Analysis of allelic diversity in 24 B. rapa germplasm using 234 mapped EST-SSR markers showed amplification of 2 alleles by majority of EST-SSRs, although amplification of alleles ranging from 2 to 8 was found. Transferability analysis of 167 EST-SSRs in 35 species belonging to cultivated and wild brassica relatives showed 42.51% (Sysimprium leteum) to 100% (B. carinata, B. juncea, and B. napus) amplification. Our newly developed EST-SSRs and high-density linkage map based on highly transferable genic markers would facilitate the molecular mapping of quantitative trait loci and the positional cloning of specific genes, in addition to marker-assisted selection and comparative genomic studies of B. rapa with other related species.     

Cloning, Sequencing and Characterization of FAE1 Genes of Brassica juncea cv Pusa Bold and the Mutant fae1 of B. rapa cv Tobin

Level of erucic acid (22:1), the major storage fatty acid of oil seed Brassica, is controlled by the activity of the Fatty Acid Elongation1 (FAE1) gene. Southern hybridization revealed the presence of two FAE1 genes in B. juncea. The two FAE1 genes of B. juncea and the mutant fae1 of B. rapa cv Tobin were isolated from genomic libraries of the respective species and sequenced. The two BjFAE1 gene sequences shared more than 98% homology and contained ORF capable of coding for 509/510 amino acid polypeptides. One of the FAE1 genes of B. juncea was found to be nearly identical (99.6%) to the mutant formof B. rapa suggesting its origin from the later species. Comparison of the sequences generated with one another and with other FAE1 sequences in the database revealed that substitution of C₂₃₃ (cysteine) with G (glycine) might be responsible for the loss of enzyme activity in B. rapa cv Tobin.