Pros and cons of HaloPlex enrichment in cancer predisposition genetic diagnosis

AIMS Genetics Pub Date : 2015-12-01 DOI:10.3934/genet.2015.4.263

Agnès Collet, J. Tarabeux, E. Girard, C. D. d’Enghien, L. Golmard, Vivien Deshaies, Alban Lermine, A. Laugé, V. Moncoutier, C. Lefol, F. Copigny, C. Dehainault, Henrique Tenreiro, C. Guy, Khadija Abidallah, C. Barbaroux, E. Rouleau, N. Servant, A. Pauw, D. Stoppa-Lyonnet, C. Houdayer

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引用次数: 6

Abstract

Abstract Panel sequencing is a practical option in genetic diagnosis. Enrichment and library preparation steps are critical in the diagnostic setting. In order to test the value of HaloPlex technology in diagnosis, we designed a custom oncogenetic panel including 62 genes. The procedure was tested on a training set of 71 controls and then blindly validated on 48 consecutive hereditary breast/ovarian cancer (HBOC) patients tested negative for BRCA1/2 mutation. Libraries were sequenced on HiSeq2500 and data were analysed with our academic bioinformatics pipeline. Point mutations were detected using Varscan2, median size indels were detected using Pindel and large genomic rearrangements (LGR) were detected by DESeq. Proper coverage was obtained. However, highly variable read depth was observed within genes. Excluding pseudogene analysis, all point mutations were detected on the training set. All indels were also detected using Pindel. On the other hand, DESeq allowed LGR detection but with poor specificity, preventing its use in diagnostics. Mutations were detected in 8% of BRCA1/2-negative HBOC cases. HaloPlex technology appears to be an efficient and promising solution for gene panel diagnostics. Data analysis remains a major challenge and geneticists should enhance their bioinformatics knowledge in order to ensure good quality diagnostic results.

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HaloPlex富集在癌症易感性遗传诊断中的利弊

面板测序在遗传诊断中是一种实用的选择。富集和文库准备步骤是诊断设置的关键。为了测试HaloPlex技术在诊断中的价值，我们设计了一个包含62个基因的定制癌基因组。该方法在71个对照组的训练集上进行了测试，然后在48例BRCA1/2突变阴性的连续遗传性乳腺癌/卵巢癌(HBOC)患者中进行了盲法验证。利用HiSeq2500对文库进行测序，并通过我们的学术生物信息学管道对数据进行分析。用Varscan2检测点突变，用Pindel检测中位大小索引，用DESeq检测大基因组重排(LGR)。得到了适当的覆盖。然而，在基因内观察到高度可变的读取深度。排除假基因分析，在训练集上检测到所有点突变。所有索引也用Pindel检测。另一方面，DESeq可以检测LGR，但特异性较差，无法用于诊断。在8%的brca1 /2阴性HBOC病例中检测到突变。HaloPlex技术似乎是一种高效且有前途的基因面板诊断解决方案。数据分析仍然是一个主要的挑战，遗传学家应该提高他们的生物信息学知识，以确保高质量的诊断结果。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

AIMS Genetics GENETICS & HEREDITY-

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审稿时长

12 weeks