Identification and characterization of simple sequence repeat (SSR) markers derived in silico from Brassica oleracea genome shotgun sequences

The availability of sequence data derived from shotgun sequencing programs enables mining for simple sequence repeats (SSRs), providing useful genetic markers for crop improvement. This study presents the development and characterization of 40 SSR markers from Brassica oleracea shotgun sequence and their cross‐amplification across Brassica species. The markers show reliable amplification, genome specificity and considerable polymorphism, demonstrating the utility of SSRs for genetic analysis of commercial Brassica germplasm.     

Identification and characterization of simple sequence repeat markers from Brassica napus expressed sequences

The availability of expressed sequence data derived from gene discovery programs enables mining for simple sequence repeats (SSR), providing useful genetic markers for crop improvement. These markers are inexpensive, require minimal labour to produce and can frequently be associated with functionally annotated genes. This study presents the development and characterization of 24 expressed sequence tags (EST)‐SSR markers from Brassica napus and their cross‐amplification across Brassica species. The markers show reliable amplification, genome specificity and considerable polymorphism, demonstrating the utility of EST‐SSRs for genetic analysis of wild Brassica populations and commercial Brassica germplasm.     

Sixteen new simple sequence repeat markers from Brassica juncea expressed sequences and their cross‐species amplification

The availability of expressed sequence data derived from gene discovery programs enables mining for simple sequence repeats (SSR), providing useful genetic markers for crop improvement. These markers are inexpensive, require minimal labour to produce and can frequently be associated with functionally annotated genes. This study presents the development and characterization of 16 expressed sequence tags (EST)‐SSR markers from Brassica juncea and their cross‐amplification across Brassica species. Sixteen primer pairs were assessed for polymorphism in all genomes of the diploid and amphidiploid Brassica species. The markers show reliable amplification, considerable polymorphism and high transferability across species, demonstrating the utility of EST‐SSRs for genetic analysis of brassicas.     

Genomic in situ hybridization in Brassica amphidiploids and interspecific hybrids

Genomic in situ hybridization (GISH) methods were used to detect different genome components within Brassica amphidiploid species and to identify donor chromatin in hybrids between Brassica napus and Raphanus sativus. In Brassica juncea and Brassica carinata the respective diploid donor genomes could be reliably distinguished by GISH, as could all R-genome chromosomes in the intergeneric hybrids. The A- and C-genome components in B. napus could not be clearly distinguished from one another using GISH, confirming the considerable homoeology between these genomes. GISH methods will be extremely beneficial for monitoring chromatin transfer and introgression in interspecific Brassica hybrids. Received: 20 May 1997 / Accepted: 28 July 1997     

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.     

Development and genetic mapping of microsatellite markers from whole genome shotgun sequences in <Emphasis Type="Italic">Brassica oleracea</Emphasis>

The availability of whole genome shotgun sequences (WGSs) in Brassica oleracea provides an unprecedented opportunity for development of microsatellite or simple sequence repeat (SSR) markers for genome analysis and genetic improvement in Brassica species. In this study, a total of 56,465 non-redundant SSRs were identified from the WGSs in B. oleracea, with dinucleotide repeats being the most abundant, followed by tri-, tetra- and pentanucleotide repeats. From these, 1,398 new SSR markers (designated as BoGMS) with repeat length ≥25 bp were developed and used to survey polymorphisms with a panel of six rapeseed varieties, which is the largest number of SSR markers developed for the C genome in a single study. Of these SSR markers, 752 (69.5%) showed polymorphism among the six varieties. Of these, 266 markers that showed clear scorable polymorphisms between B. napus varieties No. 2127 and ZY821 were integrated into an existing B. napus genetic linkage map. These new markers are preferentially distributed on the linkage groups in the C genome, and significantly increased the number of SSR markers in the C genome. These SSR markers will be very useful for gene mapping and marker-assisted selection of important agronomic traits in Brassica species.     

Transferability, amplification quality, and genome specificity of microsatellites inBrassica carinata and related species

No information is available on the transferability and amplification quality of microsatellite (SSR) markers of the public domain inBrassica carinata A. Braun. The objective of the presented research was to study the amplification of a set of 73 SSRs fromB. nigra (L.) Koch andB. napus L. inB. carinata, and to compare the results with those obtained in the amplification of the same markers in otherBrassica species of the U triangle. This set of SSRs fromB. nigra (B genome) andB. napus (AC genome) allows the identification of the 3 basic genomes of theBrassica species tested. 94.3% of the SSR markers fromB. nigra and 97.4% of those fromB. napus amplified SSR-specific products inB. carinata. Very high-quality amplification with a strong signal and easy scoring inB. carinata was recorded for 52.8% of the specific loci fromB. nigra SSRs and 59.3% of the specific loci fromB. napus SSRs, compared to 66.7% inB. nigra and 62.8% inB. napus. Genome specificity and amplification quality ofB. nigra andB. napus SSR markers in the 6 species under study is reported. High-quality transferable SSR markers provide an efficient and cost-effective platform to advance in molecular research inB. carinata.     

Sequence‐level comparative analysis of the Brassica napus genome around two stearoyl‐ACP desaturase loci

We conducted a sequence‐level comparative analyses, at the scale of complete bacterial artificial chromosome (BAC) clones, between the genome of the most economically important Brassica species, Brassica napus (oilseed rape), and those of Brassica rapa, the genome of which is currently being sequenced, and Arabidopsis thaliana. We constructed a new B. napus BAC library and identified and sequenced clones that contain homoeologous regions of the genome including stearoyl‐ACP desaturase‐encoding genes. We sequenced the orthologous region of the genome of B. rapa and conducted comparative analyses between the Brassica sequences and those of the orthologous region of the genome of A. thaliana. The proportion of genes conserved (～56%) is lower than has been reported previously between A. thaliana and Brassica (～66%). The gene models for sets of conserved genes were used to determine the extent of nucleotide conservation of coding regions. This was found to be 84.2 ± 3.9% and 85.8 ± 3.7% between the B. napus A and C genomes, respectively, and that of A. thaliana, which is consistent with previous results for other Brassica species, and 97.5 ± 3.1% between the B. napus A genome and B. rapa, and 93.1 ± 4.9% between the B. napus C genome and B. rapa. The divergence of the B. napus genes from the A genome and the B. rapa genes was greater than anticipated and indicates that the A genome ancestor of the B. napus cultivar studied was relatively distantly related to the cultivar of B. rapa selected for genome sequencing.     

Comparative Analysis between Homoeologous Genome Segments of Brassica napus and Its Progenitor Species Reveals Extensive Sequence-Level Divergence

Homoeologous regions of Brassica genomes were analyzed at the sequence level. These represent segments of the Brassica A genome as found in Brassica rapa and Brassica napus and the corresponding segments of the Brassica C genome as found in Brassica oleracea and B. napus. Analysis of synonymous base substitution rates within modeled genes revealed a relatively broad range of times (0.12 to 1.37 million years ago) since the divergence of orthologous genome segments as represented in B. napus and the diploid species. Similar, and consistent, ranges were also identified for single nucleotide polymorphism and insertion-deletion variation. Genes conserved across the Brassica genomes and the homoeologous segments of the genome of Arabidopsis thaliana showed almost perfect collinearity. Numerous examples of apparent transduplication of gene fragments, as previously reported in B. oleracea, were observed in B. rapa and B. napus, indicating that this phenomenon is widespread in Brassica species. In the majority of the regions studied, the C genome segments were expanded in size relative to their A genome counterparts. The considerable variation that we observed, even between the different versions of the same Brassica genome, for gene fragments and annotated putative genes suggest that the concept of the pan-genome might be particularly appropriate when considering Brassica genomes.     

Genome-wide comparative analysis of NBS-encoding genes between Brassica species and Arabidopsis thaliana

Background

Plant disease resistance (R) genes with the nucleotide binding site (NBS) play an important role in offering resistance to pathogens. The availability of complete genome sequences of Brassica oleracea and Brassica rapa provides an important opportunity for researchers to identify and characterize NBS-encoding R genes in Brassica species and to compare with analogues in Arabidopsis thaliana based on a comparative genomics approach. However, little is known about the evolutionary fate of NBS-encoding genes in the Brassica lineage after split from A. thaliana.

Results

Here we present genome-wide analysis of NBS-encoding genes in B. oleracea, B. rapa and A. thaliana. Through the employment of HMM search and manual curation, we identified 157, 206 and 167 NBS-encoding genes in B. oleracea, B. rapa and A. thaliana genomes, respectively. Phylogenetic analysis among 3 species classified NBS-encoding genes into 6 subgroups. Tandem duplication and whole genome triplication (WGT) analyses revealed that after WGT of the Brassica ancestor, NBS-encoding homologous gene pairs on triplicated regions in Brassica ancestor were deleted or lost quickly, but NBS-encoding genes in Brassica species experienced species-specific gene amplification by tandem duplication after divergence of B. rapa and B. oleracea. Expression profiling of NBS-encoding orthologous gene pairs indicated the differential expression pattern of retained orthologous gene copies in B. oleracea and B. rapa. Furthermore, evolutionary analysis of CNL type NBS-encoding orthologous gene pairs among 3 species suggested that orthologous genes in B. rapa species have undergone stronger negative selection than those in B .oleracea species. But for TNL type, there are no significant differences in the orthologous gene pairs between the two species.

Conclusion

This study is first identification and characterization of NBS-encoding genes in B. rapa and B. oleracea based on whole genome sequences. Through tandem duplication and whole genome triplication analysis in B. oleracea, B. rapa and A. thaliana genomes, our study provides insight into the evolutionary history of NBS-encoding genes after divergence of A. thaliana and the Brassica lineage. These results together with expression pattern analysis of NBS-encoding orthologous genes provide useful resource for functional characterization of these genes and genetic improvement of relevant crops.

Electronic supplementary material

The online version of this article (doi:10.1186/1471-2164-15-3) contains supplementary material, which is available to authorized users.     

Trigenomic Bridges for Brassica Improvement

We introduce and review Brassica crop improvement via trigenomic bridges. Six economically important Brassica species share three major genomes (A, B, and C), which are arranged in diploid (AA, BB, and CC) and allotetraploid (AABB, AACC, and BBCC) species in the classical triangle of U. Trigenomic bridges are Brassica interspecific hybrid plants that contain the three genomes in various combinations, either triploid (ABC), unbalanced tetraploid (e.g., AABC), pentaploid (e.g., AABCC) or hexaploid (AABBCC). Through trigenomic bridges, Brassica breeders can access all the genetic resources in the triangle of U for genetic improvement of existing species and development of new agricultural species. Each of the three Brassica genomes occurs in several species, where they are distinguished as subgenomes with a tag to identify the species of origin. For example, the A subgenome in B. juncea (2n = AABB) is denoted as A^j and the A subgenome in B. napus (2n = AACC) as Aⁿ. Trigenomic bridges have been used to increase genetic diversity in allopolyploid Brassica crop species, such as a new-type B. napus with subgenomes from B. rapa (A^r) and B. carinata (C^c). Recently, trigenomic bridges from several sources have been crossed together as the ‘founders’ of a potentially new allohexaploid Brassica species (AABBCC). During meiosis in a trigenomic bridge, crossovers are expected to form between homologous chromosomes of related subgenomes (for example A^r and Aⁿ), but cross-overs may also occur between non-homologous chromosomes (for example between A and C genome chromosomes). Irregular meiosis is a common feature of new polyploids, and any new allotetraploid or allohexaploid Brassica genotypes derived from a trigenomic bridge must achieve meiotic stability through a process of diploidisation. New sequencing technologies, at the genomic and epigenomic level, may reveal the genetic and molecular basis of diploidization, and accelerate selection of stable allotetraploids or allohexaploids. Armed with new genetic resources from trigenomic bridges, Brassica breeders will be able to improve yield and broaden adaptation of Brassica crops to meet human demands for food and biofuel, particularly in the face of abiotic constraints caused by climate change.     

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.     

Ribosomal DNA is an effective marker of Brassica chromosomes

Simultaneous fluorescence in situ hybridisation with 5S and 25S rDNA probes enables the discrimination of a substantial number of chromosomes of the complement of all diploid and tetraploid Brassica species of the ”U-triangle”, and provides new chromosomal landmarks for the identification of some chromosomes of this genus which were hitherto indistinguishable. Twelve out of 20 chromosomes can be easily identified in diploid Brassica campestris (AA genome), eight out of 16 in Brassica nigra (BB genome), and six out of 18 in Brassica oleracea (CC genome). Furthermore, just two rDNA markers permit 20 out of 36 chromosomes to be distinguished and assigned to either the A or B genomes of the allotetraploid Brassica juncea, and 18 out of 38 chromosomes identified and assigned to the A or C genomes of the allotetraploid Brassica napus. The number of chromosomes bearing rDNA sites in the tetraploids is not in all cases simply the sum of the numbers of sites in their diploid ancestors. This observation is discussed in terms of the phylogeny and variability within the genomes of the species of this group. Received: 13 September 2000 / Accepted: 1 February 2001     

Comparative mitochondrial genome analysis reveals the evolutionary rearrangement mechanism in Brassica

The genus Brassica has many species that are important for oil, vegetable and other food products. Three mitochondrial genome types (mitotype) originated from its common ancestor. In this paper, a B. nigra mitochondrial main circle genome with 232,407 bp was generated through de novo assembly. Synteny analysis showed that the mitochondrial genomes of B. rapa and B. oleracea had a better syntenic relationship than B. nigra. Principal components analysis and development of a phylogenetic tree indicated maternal ancestors of three allotetraploid species in Us triangle of Brassica. Diversified mitotypes were found in allotetraploid B. napus, in which napus‐type B. napus was derived from B. oleracea, while polima‐type B. napus was inherited from B. rapa. In addition, the mitochondrial genome of napus‐type B. napus was closer to botrytis‐type than capitata‐type B. oleracea. The sub‐stoichiometric shifting of several mitochondrial genes suggested that mitochondrial genome rearrangement underwent evolutionary selection during domestication and/or plant breeding. Our findings clarify the role of diploid species in the maternal origin of allotetraploid species in Brassica and suggest the possibility of breeding selection of the mitochondrial genome.     

Genetic changes in a novel breeding population of Brassica napus synthesized from hundreds of crosses between B. rapa and B. carinata

Introgression of genomic variation between and within related crop species is a significant evolutionary approach for population differentiation, genome reorganization and trait improvement. Using the Illumina Infinium Brassica 60K SNP array, we investigated genomic changes in a panel of advanced generation new‐type Brassica napus breeding lines developed from hundreds of interspecific crosses between 122 Brassica rapa and 74 Brassica carinata accessions, and compared them with representative accessions of their three parental species. The new‐type B. napus population presented rich genetic diversity and abundant novel genomic alterations, consisting of introgressions from B. rapa and B. carinata, novel allelic combinations, reconstructed linkage disequilibrium patterns and haplotype blocks, and frequent deletions and duplications (nonrandomly distributed), particularly in the C subgenome. After a much shorter, but very intensive, selection history compared to traditional B. napus, a total of 15 genomic regions with strong selective sweeps and 112 genomic regions with putative signals of selective sweeps were identified. Some of these regions were associated with important agronomic traits that were selected for during the breeding process, while others were potentially associated with restoration of genome stability and fertility after interspecific hybridization. Our results demonstrate how a novel method for population‐based crop genetic improvement can lead to rapid adaptation, restoration of genome stability and positive responses to artificial selection.     

Efficient large-scale development of microsatellites for marker and mapping applications in<Emphasis Type="Italic"> Brassica</Emphasis> crop species

A set of 398 simple sequence repeat markers (SSRs) have been developed and characterised for use with genetic studies of Brassica species. Small-insert (250–900 bp) genomic libraries from Brassica rapa, B. nigra, B. oleracea and B. napus, highly enriched for dinucleotide and trinucleotide SSR motifs, were constructed. Screening the clones with a mixture of oligonucleotide repeat probes revealed positive hybridisation to between 75% and 90% of the clones. Of these, 1,230 were sequenced. Primer pairs were designed for 398 SSR clones, and of these, 270 (67.8%) amplified a PCR product of the expected size in their focal and/or closely related species. A further screen of 138 primers pairs that produced a PCR product in B. napus germplasm found that 86 (62.3%) revealed length polymorphisms within at least one line of a test array representing the four Brassica species. The results of this screen were used to identify 56 SSRs and were combined with 41 SSRs that had previously shown polymorphism between the parents of a B. napus mapping population. These 97 SSR markers were mapped relative to a framework of RFLP markers and detected 136 loci over all 19 linkage groups of the oilseed rape genome.Electronic Supplementary Material Supplementary material is available in the online version of this article at Communicated by O. Savolainen     

Bioactive Sulforaphane from in vitro Propagated Brassica Seedlings

Sulforaphane is a biologically active phytochemical found abundantly in Brassica species. Sulforaphane from eighteen samples of three‐day‐old in vitro seedlings from Brassicas, the Brassica oleracea and Brassica rapa varieties were analyzed by HPLC. San Martino, cavolfiore Alverda, cavolo verza riccio d'Asti and cavolfiore Minaret (4.57; 4.54; 4.53 and 4.53 [mg/g d.w], respectively) seedlings showed the highest level of sulforaphane. The presented data may be applicable to choose sulforaphane‐rich Brassica varieties for functional foods. A higher sulforaphane content in functional foods might offer health benefits or desirable physiological effects.