Warning: Undefined array key "mm" in /www/wwwroot/www.ai-bt.com/si.php on line 10 Deprecated: trim(): Passing null to parameter #1 ($string) of type string is deprecated in /www/wwwroot/www.ai-bt.com/si.php on line 10 Comparative DNA sequence analysis of mapped wheat ESTs reveals the complexity of genome relationships between rice and wheat.

Literature DB >> 14740255

Comparative DNA sequence analysis of mapped wheat ESTs reveals the complexity of genome relationships between rice and wheat.

Abstract

The use of DNA sequence-based comparative genomics for evolutionary studies and for transferring information from model species to related large-genome species has revolutionized molecular genetics and breeding strategies for improving those crops. Comparative sequence analysis methods can be used to cross-reference genes between species maps, enhance the resolution of comparative maps, study patterns of gene evolution, identify conserved regions of the genomes, and facilitate interspecies gene cloning. In this study, 5,780 Triticeae ESTs that have been physically mapped using wheat ( Triticum aestivum L.) deletion lines and segregating populations were compared using NCBI BLASTN to the first draft of the public rice ( Oryza sativa L.) genome sequence data from 3,280 ordered BAC/PAC clones. A rice genome view of the homoeologous wheat genome locations based on sequence analysis shows general similarity to the previously published comparative maps based on Southern analysis of RFLP. For most rice chromosomes there is a preponderance of wheat genes from one or two wheat chromosomes. The physical locations of non-conserved regions were not consistent across rice chromosomes. Some wheat ESTs with multiple wheat genome locations are associated with the non-conserved regions of similarity between rice and wheat. The inverse view, showing the relationship between the wheat deletion map and rice genomic sequence, revealed the breakdown of gene content and order at the resolution conferred by the physical chromosome deletions in the wheat genome. An average of 35% of the putative single copy genes that were mapped to the most conserved bins matched rice chromosomes other than the one that was most similar. This suggests that there has been an abundance of rearrangements, insertions, deletions, and duplications eroding the wheat-rice genome relationship that may complicate the use of rice as a model for cross-species transfer of information in non-conserved regions.

Entities: Species

Mesh：

Year: 2004 PMID： 14740255 DOI： 10.1007/s10142-003-0098-2

Source DB: PubMed Journal: Funct Integr Genomics ISSN： 1438-793X Impact factor: 3.410

46 in total

1. Physical characterization of the homoeologous group 5 chromosomes of wheat in terms of rice linkage blocks, and physical mapping of some important genes.

Authors: R N Sarma; L Fish; B S Gill; J W Snape
Journal: Genome Date: 2000-02 Impact factor: 2.166

Review 2. Genome relationships: the grass model in current research.

Authors: K M Devos; M D Gale
Journal: Plant Cell Date: 2000-05 Impact factor: 11.277

Review 3. The genetic colinearity of rice and other cereals on the basis of genomic sequence analysis.

Authors: Jeffrey L Bennetzen; Jianxin Ma
Journal: Curr Opin Plant Biol Date: 2003-04 Impact factor: 7.834

4. Different types and rates of genome evolution detected by comparative sequence analysis of orthologous segments from four cereal genomes.

Authors: Wusirika Ramakrishna; Jorge Dubcovsky; Yong-Jin Park; Carlos Busso; John Emberton; Phillip SanMiguel; Jeffrey L Bennetzen
Journal: Genetics Date: 2002-11 Impact factor: 4.562

5. Development of a chromosomal arm map for wheat based on RFLP markers.

Authors: J A Anderson; Y Ogihara; M E Sorrells; S D Tanksley
Journal: Theor Appl Genet Date: 1992-05 Impact factor: 5.699

6. The colinearity of the Sh2/A1 orthologous region in rice, sorghum and maize is interrupted and accompanied by genome expansion in the triticeae.

Authors: Wanlong Li; Bikram S Gill
Journal: Genetics Date: 2002-03 Impact factor: 4.562

7. A physical map of the human genome.

Authors: J D McPherson; M Marra; L Hillier; R H Waterston; A Chinwalla; J Wallis; M Sekhon; K Wylie; E R Mardis; R K Wilson; R Fulton; T A Kucaba; C Wagner-McPherson; W B Barbazuk; S G Gregory; S J Humphray; L French; R S Evans; G Bethel; A Whittaker; J L Holden; O T McCann; A Dunham; C Soderlund; C E Scott; D R Bentley; G Schuler; H C Chen; W Jang; E D Green; J R Idol; V V Maduro; K T Montgomery; E Lee; A Miller; S Emerling; R Gibbs; S Scherer; J H Gorrell; E Sodergren; K Clerc-Blankenburg; P Tabor; S Naylor; D Garcia; P J de Jong; J J Catanese; N Nowak; K Osoegawa; S Qin; L Rowen; A Madan; M Dors; L Hood; B Trask; C Friedman; H Massa; V G Cheung; I R Kirsch; T Reid; R Yonescu; J Weissenbach; T Bruls; R Heilig; E Branscomb; A Olsen; N Doggett; J F Cheng; T Hawkins; R M Myers; J Shang; L Ramirez; J Schmutz; O Velasquez; K Dixon; N E Stone; D R Cox; D Haussler; W J Kent; T Furey; S Rogic; S Kennedy; S Jones; A Rosenthal; G Wen; M Schilhabel; G Gloeckner; G Nyakatura; R Siebert; B Schlegelberger; J Korenberg; X N Chen; A Fujiyama; M Hattori; A Toyoda; T Yada; H S Park; Y Sakaki; N Shimizu; S Asakawa; K Kawasaki; T Sasaki; A Shintani; A Shimizu; K Shibuya; J Kudoh; S Minoshima; J Ramser; P Seranski; C Hoff; A Poustka; R Reinhardt; H Lehrach
Journal: Nature Date: 2001-02-15 Impact factor: 49.962

8. Inferences on the genome structure of progenitor maize through comparative analysis of rice, maize and the domesticated panicoids.

Authors: W A Wilson; S E Harrington; W L Woodman; M Lee; M E Sorrells; S R McCouch
Journal: Genetics Date: 1999-09 Impact factor: 4.562

9. Identification and high-density mapping of gene-rich regions in chromosome group 1 of wheat.

Authors: K S Gill; B S Gill; T R Endo; T Taylor
Journal: Genetics Date: 1996-12 Impact factor: 4.562

10. A draft sequence of the rice genome (Oryza sativa L. ssp. japonica).

Authors: Stephen A Goff; Darrell Ricke; Tien-Hung Lan; Gernot Presting; Ronglin Wang; Molly Dunn; Jane Glazebrook; Allen Sessions; Paul Oeller; Hemant Varma; David Hadley; Don Hutchison; Chris Martin; Fumiaki Katagiri; B Markus Lange; Todd Moughamer; Yu Xia; Paul Budworth; Jingping Zhong; Trini Miguel; Uta Paszkowski; Shiping Zhang; Michelle Colbert; Wei-lin Sun; Lili Chen; Bret Cooper; Sylvia Park; Todd Charles Wood; Long Mao; Peter Quail; Rod Wing; Ralph Dean; Yeisoo Yu; Andrey Zharkikh; Richard Shen; Sudhir Sahasrabudhe; Alun Thomas; Rob Cannings; Alexander Gutin; Dmitry Pruss; Julia Reid; Sean Tavtigian; Jeff Mitchell; Glenn Eldredge; Terri Scholl; Rose Mary Miller; Satish Bhatnagar; Nils Adey; Todd Rubano; Nadeem Tusneem; Rosann Robinson; Jane Feldhaus; Teresita Macalma; Arnold Oliphant; Steven Briggs
Journal: Science Date: 2002-04-05 Impact factor: 47.728

63 in total

Review 1. Molecular markers from the transcribed/expressed region of the genome in higher plants.

Authors: P K Gupta; S Rustgi
Journal: Funct Integr Genomics Date: 2004-04-17 Impact factor: 3.410

2. CNMS: The preferred genic markers for comparative genomic, molecular phylogenetic, functional genetic diversity and differential gene regulatory expression analyses in chickpea.

Authors: Deepak Bajaj; Shouvik Das; Swarup K Parida
Journal: J Biosci Date: 2015-09 Impact factor: 1.826

3. Complex microcolinearity among wheat, rice, and barley revealed by fine mapping of the genomic region harboring a major QTL for resistance to Fusarium head blight in wheat.

Authors: Sixin Liu; Xiuling Zhang; Michael O Pumphrey; Robert W Stack; Bikram S Gill; James A Anderson
Journal: Funct Integr Genomics Date: 2005-11-04 Impact factor: 3.410

4. Macro- and microcolinearity between the genomic region of wheat chromosome 5B containing the Tsn1 gene and the rice genome.

Authors: Huangjun Lu; Justin D Faris
Journal: Funct Integr Genomics Date: 2005-12-22 Impact factor: 3.410

10. Chromosomal rearrangements differentiating the ryegrass genome from the Triticeae, oat, and rice genomes using common heterologous RFLP probes.

Authors: S Sim; T Chang; J Curley; S E Warnke; R E Barker; G Jung
Journal: Theor Appl Genet Date: 2005-03-02 Impact factor: 5.699