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通过对简化代表性文库进行深度重测序来发现高通量 SNP,从而在大豆全基因组序列中锚定和定向支架。

High-throughput SNP discovery through deep resequencing of a reduced representation library to anchor and orient scaffolds in the soybean whole genome sequence.

机构信息

Soybean Genomics and Improvement Laboratory, US Department of Agriculture, Agricultural Research Service, Beltsville, MD 20705, USA.

出版信息

BMC Genomics. 2010 Jan 15;11:38. doi: 10.1186/1471-2164-11-38.

DOI:10.1186/1471-2164-11-38
PMID:20078886
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2817691/
Abstract

BACKGROUND

The Soybean Consensus Map 4.0 facilitated the anchoring of 95.6% of the soybean whole genome sequence developed by the Joint Genome Institute, Department of Energy, but its marker density was only sufficient to properly orient 66% of the sequence scaffolds. The discovery and genetic mapping of more single nucleotide polymorphism (SNP) markers were needed to anchor and orient the remaining genome sequence. To that end, next generation sequencing and high-throughput genotyping were combined to obtain a much higher resolution genetic map that could be used to anchor and orient most of the remaining sequence and to help validate the integrity of the existing scaffold builds.

RESULTS

A total of 7,108 to 25,047 predicted SNPs were discovered using a reduced representation library that was subsequently sequenced by the Illumina sequence-by-synthesis method on the clonal single molecule array platform. Using multiple SNP prediction methods, the validation rate of these SNPs ranged from 79% to 92.5%. A high resolution genetic map using 444 recombinant inbred lines was created with 1,790 SNP markers. Of the 1,790 mapped SNP markers, 1,240 markers had been selectively chosen to target existing unanchored or un-oriented sequence scaffolds, thereby increasing the amount of anchored sequence to 97%.

CONCLUSION

We have demonstrated how next generation sequencing was combined with high-throughput SNP detection assays to quickly discover large numbers of SNPs. Those SNPs were then used to create a high resolution genetic map that assisted in the assembly of scaffolds from the 8x whole genome shotgun sequences into pseudomolecules corresponding to chromosomes of the organism.

摘要

背景

大豆共识图谱 4.0 有助于确定由美国能源部联合基因组研究所开发的大豆全基因组序列的 95.6%,但它的标记密度仅足以正确定向序列支架的 66%。需要发现和遗传标记更多的单核苷酸多态性(SNP)标记,以固定和定向剩余的基因组序列。为此,下一代测序和高通量基因分型相结合,以获得更高分辨率的遗传图谱,可以用于固定和定向大部分剩余序列,并有助于验证现有支架构建的完整性。

结果

使用简化代表文库发现了总共 7108 到 25047 个预测 SNP,随后使用 Illumina 序列合成方法在克隆单分子阵列平台上对其进行测序。使用多种 SNP 预测方法,这些 SNP 的验证率在 79%到 92.5%之间。使用 444 个重组自交系创建了一个具有 1790 个 SNP 标记的高分辨率遗传图谱。在 1790 个映射的 SNP 标记中,有 1240 个标记被选择性地选择来靶向现有的未固定或未定向的序列支架,从而将固定序列的数量增加到 97%。

结论

我们已经证明了如何将下一代测序与高通量 SNP 检测相结合,快速发现大量 SNP。然后,这些 SNP 被用于创建一个高分辨率遗传图谱,该图谱有助于将 8x 全基因组鸟枪法序列的支架组装成对应于该生物体染色体的拟分子。

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