将流式分选染色体的扩增DNA与大麦高密度SNP图谱相结合。

Coupling amplified DNA from flow-sorted chromosomes to high-density SNP mapping in barley.

作者信息

Simková Hana, Svensson Jan T, Condamine Pascal, Hribová Eva, Suchánková Pavla, Bhat Prasanna R, Bartos Jan, Safár Jan, Close Timothy J, Dolezel Jaroslav

机构信息

Laboratory of Molecular Cytogenetics and Cytometry, Institute of Experimental Botany, Sokolovská 6, CZ-77200 Olomouc, Czech Republic.

出版信息

BMC Genomics. 2008 Jun 19;9:294. doi: 10.1186/1471-2164-9-294.

DOI:10.1186/1471-2164-9-294

PMID:18565235

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2453526/

Abstract

BACKGROUND

Flow cytometry facilitates sorting of single chromosomes and chromosome arms which can be used for targeted genome analysis. However, the recovery of microgram amounts of DNA needed for some assays requires sorting of millions of chromosomes which is laborious and time consuming. Yet, many genomic applications such as development of genetic maps or physical mapping do not require large DNA fragments. In such cases time-consuming de novo sorting can be minimized by utilizing whole-genome amplification.

RESULTS

Here we report a protocol optimized in barley including amplification of DNA from only ten thousand chromosomes, which can be isolated in less than one hour. Flow-sorted chromosomes were treated with proteinase K and amplified using Phi29 multiple displacement amplification (MDA). Overnight amplification in a 20-microlitre reaction produced 3.7 - 5.7 micrograms DNA with a majority of products between 5 and 30 kb. To determine the purity of sorted fractions and potential amplification bias we used quantitative PCR for specific genes on each chromosome. To extend the analysis to a whole genome level we performed an oligonucleotide pool assay (OPA) for interrogation of 1524 loci, of which 1153 loci had known genetic map positions. Analysis of unamplified genomic DNA of barley cv. Akcent using this OPA resulted in 1426 markers with present calls. Comparison with three replicates of amplified genomic DNA revealed >99% concordance. DNA samples from amplified chromosome 1H and a fraction containing chromosomes 2H - 7H were examined. In addition to loci with known map positions, 349 loci with unknown map positions were included. Based on this analysis 40 new loci were mapped to 1H.

CONCLUSION

The results indicate a significant potential of using this approach for physical mapping. Moreover, the study showed that multiple displacement amplification of flow-sorted chromosomes is highly efficient and representative which considerably expands the potential of chromosome flow sorting in plant genomics.

摘要

背景

流式细胞术有助于对单条染色体和染色体臂进行分选，这些可用于靶向基因组分析。然而，某些分析所需的微克级DNA回收需要对数百万条染色体进行分选，这既费力又耗时。然而，许多基因组应用，如遗传图谱的构建或物理图谱绘制，并不需要大片段DNA。在这种情况下，通过全基因组扩增可以将耗时的从头分选降至最低。

结果

在此我们报告了一种在大麦中优化的方案，包括仅从一万条染色体中扩增DNA，这些染色体可在不到一小时内分离出来。对流式分选的染色体用蛋白酶K处理，并使用Phi29多重置换扩增（MDA）进行扩增。在20微升反应中过夜扩增产生了3.7 - 5.7微克DNA，大多数产物在5至30 kb之间。为了确定分选组分的纯度和潜在的扩增偏差，我们对每条染色体上的特定基因进行了定量PCR。为了将分析扩展到全基因组水平，我们进行了寡核苷酸池分析（OPA）以检测1524个位点，其中1153个位点具有已知的遗传图谱位置。使用该OPA对大麦品种Akcent的未扩增基因组DNA进行分析，得到了1426个有信号的标记。与扩增的基因组DNA的三个重复样本进行比较，一致性>99%。对扩增的1H染色体和包含2H - 7H染色体的一个组分的DNA样本进行了检测。除了具有已知图谱位置的位点外，还包括349个具有未知图谱位置的位点。基于此分析，40个新位点被定位到1H染色体上。

结论

结果表明使用这种方法进行物理图谱绘制具有巨大潜力。此外，该研究表明流式分选染色体的多重置换扩增高效且具有代表性，这大大扩展了染色体流式分选在植物基因组学中的潜力。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/466f/2453526/1d44714cfef0/1471-2164-9-294-1.jpg

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将流式分选染色体的扩增DNA与大麦高密度SNP图谱相结合。

Coupling amplified DNA from flow-sorted chromosomes to high-density SNP mapping in barley.

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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