Detailed Recombination Studies Along Chromosome 3B Provide New Insights on Crossover Distribution in Wheat (Triticum aestivum L.)

In wheat (Triticum aestivum L.), the crossover (CO) frequency increases gradually from the centromeres to the telomeres. However, little is known about the factors affecting both the distribution and the intensity of recombination along this gradient. To investigate this, we studied in detail the pattern of CO along chromosome 3B of bread wheat. A dense reference genetic map comprising 102 markers homogeneously distributed along the chromosome was compared to a physical deletion map. Most of the COs (90%) occurred in the distal subtelomeric regions that represent 40% of the chromosome. About 27% of the proximal regions surrounding the centromere showed a very weak CO frequency with only three COs found in the 752 gametes studied. Moreover, we observed a clear decrease of CO frequency on the distal region of the short arm. Finally, the intensity of interference was assessed for the first time in wheat using a Gamma model. The results showed m values of 1.2 for male recombination and 3.5 for female recombination, suggesting positive interference along wheat chromosome 3B.     

A high density physical map of chromosome 1BL supports evolutionary studies,map-based cloning and sequencing in wheat

Background

As for other major crops, achieving a complete wheat genome sequence is essential for the application of genomics to breeding new and improved varieties. To overcome the complexities of the large, highly repetitive and hexaploid wheat genome, the International Wheat Genome Sequencing Consortium established a chromosome-based strategy that was validated by the construction of the physical map of chromosome 3B. Here, we present improved strategies for the construction of highly integrated and ordered wheat physical maps, using chromosome 1BL as a template, and illustrate their potential for evolutionary studies and map-based cloning.

Results

Using a combination of novel high throughput marker assays and an assembly program, we developed a high quality physical map representing 93% of wheat chromosome 1BL, anchored and ordered with 5,489 markers including 1,161 genes. Analysis of the gene space organization and evolution revealed that gene distribution and conservation along the chromosome results from the superimposition of the ancestral grass and recent wheat evolutionary patterns, leading to a peak of synteny in the central part of the chromosome arm and an increased density of non-collinear genes towards the telomere. With a density of about 11 markers per Mb, the 1BL physical map provides 916 markers, including 193 genes, for fine mapping the 40 QTLs mapped on this chromosome.

Conclusions

Here, we demonstrate that high marker density physical maps can be developed in complex genomes such as wheat to accelerate map-based cloning, gain new insights into genome evolution, and provide a foundation for reference sequencing.     

Multi-environment analysis and improved mapping of a yield-related QTL on chromosome 3B of wheat

Improved mapping, multi-environment quantitative trait loci (QTL) analysis and dissection of allelic effects were used to define a QTL associated with grain yield, thousand grain weight and early vigour on chromosome 3BL of bread wheat (Triticum aestivum L.) under abiotic stresses. The QTL had pleiotropic effects and showed QTL x environment interactions across 21 diverse environments in Australia and Mexico. The occurrence and the severity of water deficit combined with high temperatures during the growing season affected the responsiveness of this QTL, resulting in a reversal in the direction of allelic effects. The influence of this QTL can be substantial, with the allele from one parent (RAC875) increasing grain yield by up to 12.5 % (particularly in environments where both heat and drought stress occurred) and the allele from the other parent (Kukri) increasing grain yield by up to 9 % in favourable environments. With the application of additional markers and the genotyping of additional recombinant inbred lines, the genetic map in the QTL region was refined to provide a basis for future positional cloning.     

Colinearity and gene density in grass genomes

Grasses are the single most important plant family in agriculture. In the past years, comparative genetic mapping has revealed conserved gene order (colinearity) among many grass species. Recently, the first studies at gene level have demonstrated that microcolinearity of genes is less conserved: small scale rearrangements and deletions complicate the microcolinearity between closely related species, such as sorghum and maize, but also between rice and other crop plants. In spite of these problems, rice remains the model plant for grasses as there is limited useful colinearity between Arabidopsis and grasses. However, studies in rice have to be complemented by more intensive genetic work on grass species with large genomes (maize, Triticeae). Gene-rich chromosomal regions in species with large genomes, such as wheat, have a high gene density and are ideal targets for partial genome sequencing.     

Biolistic transformation of wheat: increased production of plants with simple insertions and heritable transgene expression

The feasibility of map-based cloning in wheat has been demonstrated recently, opening new perspectives for a better understanding of wheat plant biology and for accelerating wheat improvement in the coming decades. To validate the function of candidate genes, an efficient transformation system is needed. Here, we have performed two methods for wheat transformation using particle bombardment that ensures the production of transgenic plants with simple integration patterns for research purposes and stable transgene expression for accurate and rapid validation of gene function. To establish this method, we used the bar and pmi selectable genes either as part of whole plasmids, gene cassettes (obtained by PCR or purified on agarose gels), or as dephosphorylated cassettes. The analysis of about 300 transgenic plants showed that the use of gene cassettes or dephosphorylated gene cassettes leads to a majority (50–60 %) of simple integration events. This is significantly higher than the number of simple events obtained with whole plasmids (9–25 %). Moreover, the decrease of the quantity of DNA from 500 to 5 ng/µl for PCR-amplified cassettes used for transformation increased the number of single integration events. The transformation efficiency remained stable at 2.5 %, and a higher number of plants expressing the transgenes were obtained with the dephosphorylated cassette. No correlation was observed between the complexity of the events and stability of expression of the transgene, suggesting that plasmid sequences could be involved on transgene silencing. The inheritability of the transgene was demonstrated in T1 and T2 generations. These results show that biolistic transformation of dephosphorylated gene cassettes provides an easy and efficient route to produce backbone vector-free transgenic wheat carrying and expressing intact and single transgenes.     

Organization and evolution of transposable elements along the bread wheat chromosome 3B

Background

The 17 Gb bread wheat genome has massively expanded through the proliferation of transposable elements (TEs) and two recent rounds of polyploidization. The assembly of a 774 Mb reference sequence of wheat chromosome 3B provided us with the opportunity to explore the impact of TEs on the complex wheat genome structure and evolution at a resolution and scale not reached so far.

Results

We develop an automated workflow, CLARI-TE, for TE modeling in complex genomes. We delineate precisely 56,488 intact and 196,391 fragmented TEs along the 3B pseudomolecule, accounting for 85% of the sequence, and reconstruct 30,199 nested insertions. TEs have been mostly silent for the last one million years, and the 3B chromosome has been shaped by a succession of bursts that occurred between 1 to 3 million years ago. Accelerated TE elimination in the high-recombination distal regions is a driving force towards chromosome partitioning. CACTAs overrepresented in the high-recombination distal regions are significantly associated with recently duplicated genes. In addition, we identify 140 CACTA-mediated gene capture events with 17 genes potentially created by exon shuffling and show that 19 captured genes are transcribed and under selection pressure, suggesting the important role of CACTAs in the recent wheat adaptation.

Conclusion

Accurate TE modeling uncovers the dynamics of TEs in a highly complex and polyploid genome. It provides novel insights into chromosome partitioning and highlights the role of CACTA transposons in the high level of gene duplication in wheat.

Electronic supplementary material

The online version of this article (doi:10.1186/s13059-014-0546-4) contains supplementary material, which is available to authorized users.     

Analysis of a contiguous 211 kb sequence in diploid wheat (Triticum monococcum L.) reveals multiple mechanisms of genome evolution

In plant species with large genomes such as wheat or barley, genome organization at the level of DNA sequence is largely unknown. The largest sequences that are publicly accessible so far from Triticeae genomes are two 60 kb and 66 kb intervals from barley. Here, we report on the analysis of a 211 kb contiguous DNA sequence from diploid wheat (Triticum monococcum L.). Five putative genes were identified, two of which show similarity to disease resistance genes. Three of the five genes are clustered in a 31 kb gene-enriched island while the two others are separated from the cluster and from each other by large stretches of repetitive DNA. About 70% of the contig is comprised of several classes of transposable elements. Ten different types of retrotransposons were identified, most of them forming a pattern of nested insertions similar to those found in maize and barley. Evidence was found for major deletion, insertion and duplication events within the analysed region, suggesting multiple mechanisms of genome evolution in addition to retrotransposon amplification. Seven types of foldback transposons, an element class previously not described for wheat genomes, were characterized. One such element was found to be closely associated with genes in several Triticeae species and may therefore be of use for the identification of gene-rich regions in these species.