Bread wheat (Triticum aestivum) is a globally important crop, accounting for 20 per cent of the calories consumed by humans. Major efforts are underway worldwide to increase wheat production by extending genetic diversity and analysing key traits, and genomic resources can accelerate progress. But so far the very large size and polyploid complexity of the bread wheat genome have been substantial barriers to genome analysis. Here we report the sequencing of its large, 17-gigabase-pair, hexaploid genome using 454 pyrosequencing, and comparison of this with the sequences of diploid ancestral and progenitor genomes. We identified between 94,000 and 96,000 genes, and assigned two-thirds to the three component genomes (A, B and D) of hexaploid wheat. High-resolution synteny maps identified many small disruptions to conserved gene order. We show that the hexaploid genome is highly dynamic, with significant loss of gene family members on polyploidization and domestication, and an abundance of gene fragments. Several classes of genes involved in energy harvesting, metabolism and growth are among expanded gene families that could be associated with crop productivity. Our analyses, coupled with the identification of extensive genetic variation, provide a resource for accelerating gene discovery and improving this major crop.
With a global output of 681 million tonnes in 20111, bread wheat accounts for 20% of the calories consumed by humans2 and is an important source of protein, vitamins and minerals. It originated from hybridization between cultivated tetraploid emmer wheat (AABB, Triticum dicoccoides) and diploid goat grass (DD, Aegilops tauschii) approximately 8,000 years ago3. Bread wheat cultivation and domestication has been directly associated with the spread of agriculture and settled societies, and it is now one of the most widely cultivated crops owing to its high yields and nutritional and processing qualities. The three diploid progenitor genomes, AA from Triticum urartu, BB from a species that is unknown but which may be of the section Sitopsis (to which Aegilops speltoides belongs), and DD from Ae. tauschii, radiated from a common Triticeae ancestor between 2.5 and 4.5 million years ago, and AABB tetraploids arose less than 0.5 million years ago4,5. Nucleotide diversity in the AABB and DD genomes is substantially reduced compared with ancestral populations, indicating a major diversity bottleneck on the transition to cultivated lines6.
Grass genomes show extensive long-range conservation of gene order7,8,9. Nevertheless, they are highly dynamic owing to the activities of repeats that contribute to tremendous variation in genome size10, changes in local gene order and pseudogene formation, particularly in larger genomes such as those of maize11 and wheat12. From analysis of BAC contigs on chromosome 3B, the 17-gigabase-pair (Gb) genome was estimated to be composed of approximately 80% repeats, primarily retroelements, with a gene density of between 1 per 87 kilobase pairs and 1 per 184 kilobase pairs13. Despite both the substantial knowledge gained of the wheat genome from these studies and the central importance of the wheat crop, a comprehensive genome-wide analysis of gene content has yet to be conducted owing to its large size, repeat content and polyploid complexity.
We have analysed a low-coverage, long-read (454) shotgun sequence of the hexaploid wheat genome using gene sequences from diverse grasses. From this, we created assemblies of wheat genes in an orthologous gene family framework, used diploid wheat relatives to classify homeologous relationships, and defined a genome-wide catalogue of single nucleotide polymorphisms (SNPs) in the A, B and D genomes. These analyses provide a foundation for genetic and genomic analysis of this key crop.
The wheat variety Chinese Spring (CS42) was selected for sequencing because of its wide use in genome studies14,15. Purified nuclear DNA was sequenced using Roche 454 pyrosequencing technology (GS FLX Titanium and GS FLX+ platforms) to generate 85 Gb of sequence (220 million reads), corresponding to approximately fivefold coverage on the basis of an estimated genome size of 17 Gb. Supplementary Table 1 shows that 79% of the reads had matches to the Triticeae Repeat Sequence Database, and most hit retrotransposons, consistent with previous studies13. To identify A-, B- and D-genome-derived gene assemblies in the hexaploid sequences, we used Illumina sequence assemblies of Triticum monococcum, related to the A-genome donor, Ae. speltoides complementary DNA (cDNA) assemblies and 454 sequences from the D-genome donor Ae. tauschii, respectively. The SOLiD platform was used to generate additional sequence of CS42 and three commercial wheat varieties to increase the accuracy of homeologous SNP identification. Data sets are summarized in Table 1 and Supplementary Table 2, and SNP identification methods are described in Supplementary Information, section 5.2.
An orthologous group assembly (Supplementary Table 3) was created by clustering 454 reads by sequence similarity to orthologous grass gene sequences, and separate assembly of the clusters at high stringency using Newbler (Supplementary Information, section 2). The orthologous genes were derived from rice16, sorghum8, Brachypodium9 and barley full-length cDNAs by OrthoMCL17 clustering. This generated 20,496 orthologous groups (Supplementary Table 4 and Supplementary Fig. 1). The gene model with highest similarity to wheat (termed the orthologous group representative (OGR)) was selected from each orthologous group by stringent BLASTX comparison to a low-copy-number genome assembly (LCG) made by filtering out repetitive sequences and assembling the remaining low-copy-number sequences de novo (Supplementary Table 3). The assemblies are described in Table 2. Nearly 90% of the metabolic genes in Arabidopsis matched OGRs, and the 20,051 OGRs matched 92% of publicly available wheat full-length cDNAs18 and 78.7% of the harvEST set of wheat cDNA assemblies (Supplementary Fig. 2), indicating that they represent nearly all wheat genes.
We optimized parameters for wheat gene assembly using MetaSim19 to generate simulated fivefold 454 reads from the allotetraploid maize genome and from a triplicated rice gene set, with the introduction of sequence variation (Supplementary Information, section 2.7). Similar degrees of coverage over the OGRs were seen for the simulated data sets and wheat 454 reads (Fig. 1a). Rice reads followed the same depth distribution as the wheat reads (Fig. 1b), suggesting that they are a reasonable representation of hexaploid sequences. Maize reads covered their OGRs to a median depth of approximately five, consistent with fivefold coverage.
Simulated maize and triplicated rice 454 reads were used to optimize assembly parameters. Assembly at 99% minimum sequence identity (m.i.) using 40-bp overlap length predicted gene family sizes most accurately (Supplementary Figs 3–6). Wheat 454 reads were preprocessed (Supplementary Table 5) and assembled using 99% m.i. (Supplementary Tables 6 and 7) to create the orthologous group assembly. Figure 1b shows that the depth of coverage of the orthologous group assembly followed a similar pattern to maize, consistent with multiple gene copies. In contrast, the low depth coverage by the LCG assembly suggested that gene family numbers were collapsed. The number of wheat assemblies for each OGR was calculated to determine gene copy numbers (Supplementary Table 7). Figure 1c shows that most OGRs had between one and five distinctive wheat gene assemblies, with a peak of two genes.
The A, B and Ae. tauschii (D) genomes13,20,21 have been estimated to contain approximately 28,000, 38,000 and 36,000 genes, respectively. We estimated the number of genes in the hexaploid wheat genome to range between 94,000 and 96,000 (Supplementary Information, section 2.10). This is reasonably consistent with estimates based on wheat chromosome sequences13. Comparing our transcriptome assembly (Supplementary Information, sections 2.8 and 2.9) and wheat harvEST with the wheat OGRs showed that 76% and, respectively, 65% were expressed under the conditions used for RNA isolation. Similar results were found in barley22, rice16 and maize23, indicating that the assemblies are bona fide wheat genes.
We defined the overall extent of gene conservation between wheat and the most closely related sequenced pooid grass, Brachypodium distachyon9,24. Track 1 of Fig. 2 shows that there is a high degree of overlap between the gene sets of Brachypodium and wheat, but with regions of lower conservation, for example on Brachypodium chromosomes 1 and 4. Syntenic maps of the Brachypodium genome and the A-, B- and D-chromosome groups were created by integrating high-density wheat EST-based markers25 with Brachypodium genes (Fig. 2, tracks 5, 6 and 7, respectively). Supplementary Fig. 7 shows the A-, B- and D-genome markers separately. Syntenic alignments were readily identifiable and conformed to the predicted major patterns9,26. We identified many insertions and/or translocations of blocks of genes within the overall conserved patterns of gene order, including the major rearrangement on chromosome 4A as shown on Brachypodium chromosome 1 (ref. 20). Lower marker density on the D genome is evident in track 7. The higher-resolution genetic map identified a new syntenic alignment of Triticeae group 5 to Brachypodium chromosome 3 genes.
Genome change in polyploid wheat
We determined the influence of polyploidy on gene content in hexaploid wheat by defining the sizes of gene families in hexaploid wheat and the diploid progenitor Ae. tauschii from the copy number of genes for each OGR, which were then paired with the gene family size of the OGR in sequenced diploid grasses (Supplementary Information, section 2.6). The mean family size was 1.4 members. Supplementary Fig. 8 shows relationships between wheat and diploid orthologous gene family across the full scale of orthologous gene family sizes. This approach accurately reconstructed gene family sizes in simulated maize and ‘hexaploid’ rice genomes (Figs 3a, b), although larger gene family sizes tended to be underestimated. Figure 3c, d shows the relationships between Ae. tauschii and wheat genes. Single-member gene families in hexaploid wheat and Ae. tauschii were maintained to a similar extent as those seen in sequenced diploid grasses, consistent with Southern blot analyses of single-copy genes27. Using the D genome as a diploid reference, we calculated the Triticeae hexaploid/diploid gene family size ratio to be between 2.5:1 and 2.7:1, derived from the geometric mean (2.5:1) and the slopes of the blue line and the red line (2.7:1) in Fig. 3e. Comparing this with the expected hexaploid/diploid ratio of 3:1 indicates the loss of between 10,000 and 16,000 genes in hexaploid wheat compared with the three diploid progenitors (Supplementary Information, section 2.10). This is consistent with earlier studies of gene loss in newly synthesized wheat polyploids28 and the erosion of genetic diversity during wheat domestication6.
Despite this overall trend of gene family size reduction, gene families with fewer or more members than expected were identified in Ae. tauschii and hexaploid wheat, as shown by green dots (more members) and brown dots (fewer members) in Fig. 3c (Ae. tauschii) and Fig. 3d (hexaploid wheat). Supplementary Tables 10–12 show the over- and under-represented functional categories of protein. Most of the over-represented categories in expanded gene families are common to wheat and Ae. tauschii: these include ribosome proteins, components of photosystem II, storage proteins, transposon-related proteins, cytochrome P450s, NB-ARC domain proteins involved in defence responses, proteins related to pollen allergens and F-box proteins. Five of the eleven families encoding hydrogen ion transmembrane transporters were significantly more numerous in Ae. tauschii than in wheat. Analysis of gene families (Supplementary Fig. 9) showed that they encode different subunits of ATPases. We speculate that they may provide proton gradients to support Na+ exclusion in Ae. tauschii29 and the accumulation of minerals in other Aegilops species30.
Several classes of plant DNA transposons31,32 and retroelements33 create and amplify gene fragments, disrupt genes and create pseudogenes, which can influence gene expression through epigenetic mechanisms34. We identified a set of almost 233,000 gene fragments that mapped to the same regions of their OGRs, forming ‘stacks’ that were sufficiently divergent not to assemble into their cognate gene assemblies (Fig. 4a). Two classes were identified: those containing Pfam domains and those aligning with non-Pfam domains of OGRs. Nearly 30% of the OGRs had associated gene fragments (Supplementary Table 13) that most frequently covered between 5 and 15% of the OGR length (Fig. 4b). Figure 4c shows that the alignment identities of gene fragments against their OGRs were substantially lower than the identities of cognate regions within wheat gene assemblies. Supplementary Fig. 10 shows the distribution of stacks along genes and the ratio of non-synonymous to synonymous substitutions (Ka/Ks) along the genes. Pfam domains found in stacks were enriched for zinc-finger motifs in mutator transposons (Supplementary Table 14), consistent with their role in pseudogene formation31. F-box, protein kinase and NB-ARC domains, which are found in the most rapidly evolving gene families in plants9,35, are also over-represented.
Determining homeologous relationships of gene assemblies
We classified gene assemblies as A-, B- or D-genome-derived according to sequence similarity to Illumina sequence assemblies from T. monococcum, cDNA assemblies from Ae. speltoides and, respectively, 454 reads from Ae. tauschii by applying a support vector machine learning approach (Supplementary Section 5, Supplementary Figs 11 and 12, and Supplementary Tables 15–18). Supplementary Fig. 13 shows that 66% of the gene assemblies were classified with high overall precision (>70%) and recall into the A genome (28.3%), the B genome (29.2%) and the D genome (33.8%). The other 9% of classified assemblies have stop codons. The othes 34% with low classification probabilities are likely to be very similar homeologues. Comparison with a subset of A-, B- and D-genome SNPs confirmed 72% of A-genome classifications and 85% of D-genome classifications (Fig. 2 and Supplementary Table 19). Discrimination of putative B-genome genes was only ∼60%, possibly owing both to the use of cDNA sequences for classification when most of the informative sequence polymorphisms are intronic, and to uncertainty about the ancestry of the B genome5. The set of 132,552 SNPs allocated to the A, B and D genomes is displayed using Brachypodium as a template in tracks 2–4 of Fig. 2.
There were no significant differences between the respective distributions of GO Slim molecular function categories in the A, B and D genes (Supplementary Fig. 14), indicating that at this level of functional categorization there is no biased gene loss36 in any of the genomes. Nevertheless, analysis of GO Slim terms associated with stop codons in A, B and D gene assemblies showed that there was a strong tendency to retain functional copies of genes encoding transcription factors in all three genomes (Supplementary Fig. 15), similar to the preferential retention of these genes in Arabidopsis genome duplications37. This indicates that genome-specific transcriptional regulatory networks tend to be maintained in wheat.
Using whole-genome 454 sequencing, we assembled gene sequences representing an essentially complete gene set, and a significant number were assigned to the A, B or D genome. Although the assemblies are fragmentary, they form a powerful framework for identifying genes, accelerating further genome sequencing and facilitating genome-scale analyses. The identification of over 132,000 SNPs in A, B and D genes facilitates analysis of quantitative trait loci and association studies of traits. Comparison with the sequences of diploid progenitors and relatives showed pronounced reductions in the size of large gene families in wheat despite the relatively recent formation of the hexaploid (Fig. 3e), consistent with smaller-scale analyses28,38. The scale of gene loss in hexaploid wheat compared with maize36 and Brassica rapa39 is significantly smaller, possibly as a result of its relatively recent origin and the absence of intergenome recombination40. Nevertheless, gene loss in wheat could be rapid, as shown in the newly created allopolyploid Tragopogon miscellus41. Most functional classes show equal gene loss in the three genomes, but families of transcription factors showed a clear tendency to be retained as functional genes in all three genomes. These may maintain transcriptional networks in each genome and contribute to non-additive gene expression42 and genome plasticity. In contrast to the overall loss of gene family members, several classes of gene families with predicted roles in defence, nutritional content, energy metabolism and growth have increased sizes in the Triticeae lineage, possibly as a result of selection during domestication.
Major efforts are underway to improve wheat productivity by increasing genetic diversity in breeding materials and through genetic analysis of traits43. The genomic resources that we have developed promise to accelerate progress by facilitating the identification of useful variation in genes of wheat landraces and progenitor species, and by providing genomic landmarks to guide progeny selection. Analysis of complex polygenic traits such as yield and nutrient use efficiency will also be accelerated, contributing to sustainable increases in wheat crop production.
A single-seed descent line of T. aestivum landrace Chinese Spring was sequenced, because it is widely used for cytogenetic analysis44 and physical mapping15. Triticum monococcum accession 4342-96 is a community standard line for targeting induced local lesions in genomes, physical mapping and genetic analysis; and Ae. tauschii ssp strangulata accession AL8/78, which is used for physical and genetic mapping, was sequenced using 454 technology.
Sequence for the T. aestivum wheat gene assembly was generated using Roche 454 pyrosequencing on the GS FLX Titanium and GS FLX+ platforms. Additional sequence read data sets for T. aestivum, T. monococcum and Ae. tauschii were generated using three platforms, Illumina, 454 and SOLiD, to analyse homeologous sequences and SNPs (a list of all data sets is in Supplementary Table 2). Orthologous groups were created from rice, sorghum and B. distachyon genome sequences and barley full-length cDNA sequences. Wheat gene assemblies were named according to their OGR and were identified by a seven-digit identifier and their predicted genome (for example Traes_Bradi1g12345_0000001_D and Traes_Sb3g33333_6543210_A). Gene and cDNA assemblies can be searched at the MIPS Wheat Genome Database (http://mips.helmholtz-muenchen.de/plant/wheat/uk454survey/index.jsp). All sequence data has been deposited in publicly accessible databases, described in Supplementary Information. Sequence assemblies, annotated gene sequences and their relationships are available for download from the European Bioinformatics Institute (http://www.ebi.ac.uk) and viewing in a synteny-based Ensembl genome browser. Annotated gene sequences and their relationships can be viewed in a Brachypodium synteny-based Ensembl genome browser (http://plants.ensembl.org/brachypodium_distachyon).
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DNA sequence was generated by The University of Liverpool Centre for Genomic Research (United Kingdom), 454 Life Sciences (United States), The Cold Spring Harbor Woodbury Genome Centre (United States) and The Genome Analysis Centre (United Kingdom). This work was supported by UK Biological and Biotechnological Sciences Research Council (BBSRC) grants BB/G012865, BB/G013985/1 and BB/G013004/1, to K.J.E., M.W.B. and N. Hall; a Wolfson Merit Award from the Royal Society, to N. Hall; BBSRC Strategic Programme grant B/J004588/1 (GRO), to M.W.B.; EC TriticeaeGenome grant number 212019, to K.F.X.M. and M.W.B.; The TRITEX Project of the Plant20130 Initiative of the German Ministry of Education and Research grant number 0315954C, to K.F.X.M.; EC Transplant Grant 283496, to K.F.X.M. and P.K., a BBSRC Career Development Fellowship BB/H022333/1, to A.H., US NSF grants IOS-1032105 and DBI-0923128, to W.R.M.; USDA-NIFA grant 2008-35300-04588, to B.G.; and US NSF grants DBI-0701916, to J.D., and DBI-0822100, to S. Kianian.
W.R.M. has participated in Illumina-sponsored meetings and received travel reimbursement and honoraria for presenting at these events.
This file contains Supplementary Text and Data 1-5, Supplementary Tables 1-9, 13, 15-19 (see separate files for Supplementary Tables 10, 11, 12, 14), Supplementary Figures 1-6, 8-15 (see separate file for Supplementary Figure 7) and additional references. (PDF 1770 kb)
Supplementary Figure 7
This figure shows the separate maps of genetic markers on the A, B and D genomes. (PDF 1476 kb)
Supplementary Table 10
This table contains the over- and under-represented GO terms of expanded and contracted wheat gene families. (XLS 36 kb)
Supplementary Table 11
This table contains the over- and under-represented Pfam terms of expanded and contracted wheat gene families. (XLS 76 kb)
Supplementary Table 12
This table contains the over- and under-represented GO and Pfam terms of expanded Ae. tauschii gene families. (XLS 70 kb)
Supplementary Table 14
This table shows the Pfam domains in gene fragments. (XLS 205 kb)
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Brenchley, R., Spannagl, M., Pfeifer, M. et al. Analysis of the bread wheat genome using whole-genome shotgun sequencing. Nature 491, 705–710 (2012). https://doi.org/10.1038/nature11650
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