从细菌人工染色体末端序列中发现微卫星并进行遗传定位，以锚定大豆物理图谱和遗传图谱。

Microsatellite discovery from BAC end sequences and genetic mapping to anchor the soybean physical and genetic maps.

作者信息

Shoemaker Randy C, Grant David, Olson Terry, Warren Wesley C, Wing Rod, Yu Yeisoo, Kim HyeRan, Cregan Perry, Joseph Bindu, Futrell-Griggs Montona, Nelson Will, Davito Jon, Walker Jason, Wallis John, Kremitski Colin, Scheer Debbie, Clifton Sandra W, Graves Tina, Nguyen Henry, Wu Xiaolei, Luo Mingcheng, Dvorak Jan, Nelson Rex, Cannon Steven, Tomkins Jeff, Schmutz Jeremy, Stacey Gary, Jackson Scott

机构信息

USDA-ARS-CICGR Unit, Department of Agronomy, Ames, IA 50011-1010, USA.

出版信息

Genome. 2008 Apr;51(4):294-302. doi: 10.1139/G08-010.

DOI:10.1139/G08-010

PMID:18356965

Abstract

Whole-genome sequencing of the soybean (Glycine max (L.) Merr. 'Williams 82') has made it important to integrate its physical and genetic maps. To facilitate this integration of maps, we screened 3290 microsatellites (SSRs) identified from BAC end sequences of clones comprising the 'Williams 82' physical map. SSRs were screened against 3 mapping populations. We found the AAT and ACT motifs produced the greatest frequency of length polymorphisms, ranging from 17.2% to 32.3% and from 11.8% to 33.3%, respectively. Other useful motifs include the dinucleotide repeats AG, AT, and AG, with frequency of length polymorphisms ranging from 11.2% to 18.4% (AT), 12.4% to 20.6% (AG), and 11.3% to 16.4% (GT). Repeat lengths less than 16 bp were generally less useful than repeat lengths of 40-60 bp. Two hundred and sixty-five SSRs were genetically mapped in at least one population. Of the 265 mapped SSRs, 60 came from BAC singletons not yet placed into contigs of the physical map. One hundred and ten originated in BACs located in contigs for which no genetic map location was previously known. Ninety-five SSRs came from BACs within contigs for which one or more other BACs had already been mapped. For these fingerprinted contigs (FPC) a high percentage of the mapped markers showed inconsistent map locations. A strategy is introduced by which physical and genetic map inconsistencies can be resolved using the preliminary 4x assembly of the whole genome sequence of soybean.

摘要

大豆（Glycine max (L.) Merr. 'Williams 82'）的全基因组测序使得整合其物理图谱和遗传图谱变得至关重要。为了促进图谱的整合，我们筛选了从构成“Williams 82”物理图谱的克隆的BAC末端序列中鉴定出的3290个微卫星（SSR）。针对3个作图群体对SSR进行了筛选。我们发现AAT和ACT基序产生的长度多态性频率最高，分别为17.2%至32.3%和11.8%至33.3%。其他有用的基序包括二核苷酸重复序列AG、AT和GT，其长度多态性频率范围分别为11.2%至18.4%（AT）、12.4%至20.6%（AG）和11.3%至16.4%（GT）。长度小于16 bp的重复序列通常不如40 - 60 bp的重复序列有用。265个SSR在至少一个群体中进行了遗传定位。在这265个定位的SSR中，60个来自尚未放入物理图谱重叠群的BAC单拷贝。110个起源于位于重叠群中的BAC，这些重叠群之前没有已知的遗传图谱位置。95个SSR来自重叠群中的BAC，其中一个或多个其他BAC已经被定位。对于这些指纹重叠群（FPC），很大比例的定位标记显示出不一致的图谱位置。本文介绍了一种策略，通过该策略可以利用大豆全基因组序列的初步4倍组装来解决物理图谱和遗传图谱的不一致问题。

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从细菌人工染色体末端序列中发现微卫星并进行遗传定位，以锚定大豆物理图谱和遗传图谱。

Microsatellite discovery from BAC end sequences and genetic mapping to anchor the soybean physical and genetic maps.

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