Mihaela M. Martis scite author profile

Sorghum, an African grass related to sugar cane and maize, is grown for food, feed, fibre and fuel. We present an initial analysis of the approximately 730-megabase Sorghum bicolor (L.) Moench genome, placing approximately 98% of genes in their chromosomal context using whole-genome shotgun sequence validated by genetic, physical and syntenic information. Genetic recombination is largely confined to about one-third of the sorghum genome with gene order and density similar to those of rice. Retrotransposon accumulation in recombinationally recalcitrant heterochromatin explains the approximately 75% larger genome size of sorghum compared with rice. Although gene and repetitive DNA distributions have been preserved since palaeopolyploidization approximately 70 million years ago, most duplicated gene sets lost one member before the sorghum-rice divergence. Concerted evolution makes one duplicated chromosomal segment appear to be only a few million years old. About 24% of genes are grass-specific and 7% are sorghum-specific. Recent gene and microRNA duplications may contribute to sorghum's drought tolerance.

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A chromosome-based draft sequence of the hexaploid bread wheat ( Triticum aestivum ) genome

Mayer¹,

Rogers²,

Doležel³

et al. 2014

Science

1,391

855

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An ordered draft sequence of the 17-gigabase hexaploid bread wheat (Triticum aestivum) genome has been produced by sequencing isolated chromosome arms. We have annotated 124,201 gene loci distributed nearly evenly across the homeologous chromosomes and subgenomes. Comparative gene analysis of wheat subgenomes and extant diploid and tetraploid wheat relatives showed that high sequence similarity and structural conservation are retained, with limited gene loss, after polyploidization. However, across the genomes there was evidence of dynamic gene gain, loss, and duplication since the divergence of the wheat lineages. A high degree of transcriptional autonomy and no global dominance was found for the subgenomes. These insights into the genome biology of a polyploid crop provide a springboard for faster gene isolation, rapid genetic marker development, and precise breeding to meet the needs of increasing food demand worldwide.

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Unlocking the Barley Genome by Chromosomal and Comparative Genomics

Mayer

Martis

Hedley³

et al. 2011

423

416

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We used a novel approach that incorporated chromosome sorting, next-generation sequencing, array hybridization, and systematic exploitation of conserved synteny with model grasses to assign ;86% of the estimated ;32,000 barley (Hordeum vulgare) genes to individual chromosome arms. Using a series of bioinformatically constructed genome zippers that integrate gene indices of rice (Oryza sativa), sorghum (Sorghum bicolor), and Brachypodium distachyon in a conserved synteny model, we were able to assemble 21,766 barley genes in a putative linear order. We show that the barley (H) genome displays a mosaic of structural similarity to hexaploid bread wheat (Triticum aestivum) A, B, and D subgenomes and that orthologous genes in different grasses exhibit signatures of positive selection in different lineages. We present an ordered, information-rich scaffold of the barley genome that provides a valuable and robust framework for the development of novel strategies in cereal breeding.

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Towards a whole‐genome sequence for rye (Secale cereale L.)

et al. 2017

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SUMMARYWe report on a whole-genome draft sequence of rye (Secale cereale L.). Rye is a diploid Triticeae species closely related to wheat and barley, and an important crop for food and feed in Central and Eastern Europe. Through whole-genome shotgun sequencing of the 7.9-Gbp genome of the winter rye inbred line Lo7 we obtained a de novo assembly represented by 1.29 million scaffolds covering a total length of 2.8 Gbp. Our reference sequence represents nearly the entire low-copy portion of the rye genome. This genome assembly was used to predict 27 784 rye gene models based on homology to sequenced grass genomes. Through resequencing of 10 rye inbred lines and one accession of the wild relative S. vavilovii, we discovered more than 90 million single nucleotide variants and short insertions/deletions in the rye genome. From these variants, we developed the high-density Rye600k genotyping array with 600 843 markers, which enabled anchoring the sequence contigs along a high-density genetic map and establishing a synteny-based virtual gene order. Genotyping data were used to characterize the diversity of rye breeding pools and genetic resources, and to obtain a genome-wide map of selection signals differentiating the divergent gene pools. This rye whole-genome sequence closes a gap in Triticeae genome research, and will be highly valuable for comparative genomics, functional studies and genome-based breeding in rye.

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A 4-gigabase physical map unlocks the structure and evolution of the complex genome of Aegilops tauschii, the wheat D-genome progenitor

Luo

You

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

198

259

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The current limitations in genome sequencing technology require the construction of physical maps for high-quality draft sequences of large plant genomes, such as that of Aegilops tauschii, the wheat D-genome progenitor. To construct a physical map of the Ae. tauschii genome, we fingerprinted 461,706 bacterial artificial chromosome clones, assembled contigs, designed a 10K Ae. tauschii Infinium SNP array, constructed a 7,185-marker genetic map, and anchored on the map contigs totaling 4.03 Gb. Using whole genome shotgun reads, we extended the SNP marker sequences and found 17,093 genes and gene fragments. We showed that collinearity of the Ae. tauschii genes with Brachypodium distachyon, rice, and sorghum decreased with phylogenetic distance and that structural genome evolution rates have been high across all investigated lineages in subfamily Pooideae, including that of Brachypodieae. We obtained additional information about the evolution of the seven Triticeae chromosomes from 12 ancestral chromosomes and uncovered a pattern of centromere inactivation accompanying nested chromosome insertions in grasses. We showed that the density of noncollinear genes along the Ae. tauschii chromosomes positively correlates with recombination rates, suggested a cause, and showed that new genes, exemplified by disease resistance genes, are preferentially located in high-recombination chromosome regions. (2), and 90% of its genome was estimated to be repetitive DNA (3). The Ae. tauschii genome and the D genome of hexaploid wheat are closely related due to the recent origin of hexaploid wheat (4). Ae. tauschii is therefore an important resource for wheat breeding, and its genome is an invaluable reference for wheat genomics, as illustrated by the utility of its sequences in the analysis of the wheat gene space (5). The utility of Ae. tauschii for wheat genetics and genomics would be further enhanced by a high-quality draft sequence of its genome. With current technology, the only approach to produce a high-quality de novo draft sequence for a genome of this size and complexity is the orderedclone sequencing approach, which requires a physical map.Physical map construction necessitates fingerprinting multiple genome equivalents of bacterial artificial chromosome (BAC) clones, assembling them into contigs, and anchoring the contigs on a genetic map (6-8). Great strides have been made in BAC fingerprinting techniques (7, 9-12) and software for fingerprint editing and contig assembly (13-16). It is now possible with these technological advances to fingerprint and assemble contigs from hundreds of thousands of BAC clones (7,8,(17)(18)(19). In contrast, contig anchoring remains a weakness in physical mapping of large plant genomes because of their low gene density, extensive gene duplication, and abundance of repetitive DNA. BAC end sequences (BESs) are an effective means of contig anchoring in small genomes (11). In large genomes, however, hundreds of thousands of BESs are needed. DNA hybridization and PCRbased anchoring (6,7,20,21)...

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Mihaela M. Martis

The Sorghum bicolor genome and the diversification of grasses

A chromosome-based draft sequence of the hexaploid bread wheat ( Triticum aestivum ) genome

Unlocking the Barley Genome by Chromosomal and Comparative Genomics

Towards a whole‐genome sequence for rye (Secale cereale L.)

A 4-gigabase physical map unlocks the structure and evolution of the complex genome of Aegilops tauschii, the wheat D-genome progenitor

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