陆地棉（G. hirsutum L.）中同源染色体12和26的综合遗传与物理图谱

An integrated genetic and physical map of homoeologous chromosomes 12 and 26 in Upland cotton (G. hirsutum L.).

作者信息

Xu Zhanyou, Kohel Russell J, Song Guoli, Cho Jaemin, Yu Jing, Yu Shuxun, Tomkins Jeffrey, Yu John Z

机构信息

USDA-ARS, Southern Plains Agricultural Research Center, Crop Germplasm Research Unit, 2881 F&B Road, College Station, TX 77845, USA.

出版信息

BMC Genomics. 2008 Feb 28;9:108. doi: 10.1186/1471-2164-9-108.

DOI:10.1186/1471-2164-9-108

PMID:18307816

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2270834/

Abstract

BACKGROUND

Upland cotton (G. hirsutum L.) is the leading fiber crop worldwide. Genetic improvement of fiber quality and yield is facilitated by a variety of genomics tools. An integrated genetic and physical map is needed to better characterize quantitative trait loci and to allow for the positional cloning of valuable genes. However, developing integrated genomic tools for complex allotetraploid genomes, like that of cotton, is highly experimental. In this report, we describe an effective approach for developing an integrated physical framework that allows for the distinguishing between subgenomes in cotton.

RESULTS

A physical map has been developed with 220 and 115 BAC contigs for homeologous chromosomes 12 and 26, respectively, covering 73.49 Mb and 34.23 Mb in physical length. Approximately one half of the 220 contigs were anchored to the At subgenome only, while 48 of the 115 contigs were allocated to the Dt subgenome only. Between the two chromosomes, 67 contigs were shared with an estimated overall physical similarity between the two chromosomal homeologs at 40.0 %. A total of 401 fiber unigenes plus 214 non-fiber unigenes were located to chromosome 12 while 207 fiber unigenes plus 183 non-fiber unigenes were allocated to chromosome 26. Anchoring was done through an overgo hybridization approach and all anchored ESTs were functionally annotated via blast analysis.

CONCLUSION

This integrated genomic map describes the first pair of homoeologous chromosomes of an allotetraploid genome in which BAC contigs were identified and partially separated through the use of chromosome-specific probes and locus-specific genetic markers. The approach used in this study should prove useful in the construction of genome-wide physical maps for polyploid plant genomes including Upland cotton. The identification of Gene-rich islands in the integrated map provides a platform for positional cloning of important genes and the targeted sequencing of specific genomic regions.

摘要

背景

陆地棉（G. hirsutum L.）是全球主要的纤维作物。各种基因组学工具有助于纤维品质和产量的遗传改良。需要一个整合的遗传和物理图谱来更好地表征数量性状位点，并实现有价值基因的图位克隆。然而，为像棉花这样的复杂异源四倍体基因组开发整合的基因组工具极具挑战性。在本报告中，我们描述了一种开发整合物理框架的有效方法，该方法可区分棉花的亚基因组。

结果

已构建了一个物理图谱，分别针对同源染色体12和26有220个和115个细菌人工染色体（BAC）重叠群，物理长度分别覆盖73.49 Mb和34.23 Mb。220个重叠群中约一半仅锚定到At亚基因组，而115个重叠群中的48个仅分配到Dt亚基因组。在这两条染色体之间，有67个重叠群是共享的，两条染色体同源物之间的估计总体物理相似性为40.0%。共有401个纤维单基因加上214个非纤维单基因定位到染色体12，而207个纤维单基因加上183个非纤维单基因分配到染色体26。通过重叠杂交方法进行锚定，所有锚定的表达序列标签（EST）通过blast分析进行功能注释。

结论

这个整合的基因组图谱描述了异源四倍体基因组的第一对同源染色体，其中BAC重叠群通过使用染色体特异性探针和位点特异性遗传标记得以鉴定并部分分离。本研究中使用的方法在构建包括陆地棉在内的值物多倍体基因组的全基因组物理图谱时应会很有用。整合图谱中富含基因区域的鉴定为重要基因的图位克隆和特定基因组区域的靶向测序提供了一个平台。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/12c7/2270834/e2128faf8d25/1471-2164-9-108-1.jpg

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陆地棉（G. hirsutum L.）中同源染色体12和26的综合遗传与物理图谱

An integrated genetic and physical map of homoeologous chromosomes 12 and 26 in Upland cotton (G. hirsutum L.).

作者信息

机构信息

出版信息

BACKGROUND

RESULTS

CONCLUSION

背景

结果

结论

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