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焦磷酸测序法检测KRAS突变的灵敏测序方法

Sensitive sequencing method for KRAS mutation detection by Pyrosequencing.

作者信息

Ogino Shuji, Kawasaki Takako, Brahmandam Mohan, Yan Liying, Cantor Mami, Namgyal Chungdak, Mino-Kenudson Mari, Lauwers Gregory Y, Loda Massimo, Fuchs Charles S

机构信息

Department of Pathology, Brigham and Women's Hospital, Harvard Medical School, 75 Francis St., Boston, MA 02115, USA.

出版信息

J Mol Diagn. 2005 Aug;7(3):413-21. doi: 10.1016/S1525-1578(10)60571-5.

DOI:10.1016/S1525-1578(10)60571-5
PMID:16049314
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1867544/
Abstract

Both benign and malignant tumors represent heterogenous tissue containing tumor cells and non-neoplastic mesenchymal and inflammatory cells. To detect a minority of mutant KRAS alleles among abundant wild-type alleles, we developed a sensitive DNA sequencing assay using Pyrosequencing, ie, nucleotide extension sequencing with an allele quantification capability. We designed our Pyrosequencing assay for use with whole-genome-amplified DNA from paraffin-embedded tissue. Assessing various mixtures of DNA from mutant KRAS cell lines and DNA from a wild-type KRAS cell line, we found that mutation detection rates for Pyrosequencing were superior to dideoxy sequencing. In addition, Pyrosequencing proved superior to dideoxy sequencing in the detection of KRAS mutations from DNA mixtures of paraffin-embedded colon cancer and normal tissue as well as from paraffin-embedded pancreatic cancers. Quantification of mutant alleles by Pyrosequencing was precise and useful for assay validation, monitoring, and quality assurance. Our Pyrosequencing method is simple, robust, and sensitive, with a detection limit of approximately 5% mutant alleles. It is particularly useful for tumors containing abundant non-neoplastic cells. In addition, the applicability of this assay for DNA amplified by whole-genome amplification technique provides an expanded source of DNA for large-scale studies.

摘要

良性肿瘤和恶性肿瘤均为异质性组织,包含肿瘤细胞以及非肿瘤性间充质细胞和炎性细胞。为了在大量野生型等位基因中检测少数突变型KRAS等位基因,我们开发了一种使用焦磷酸测序的灵敏DNA测序分析方法,即具有等位基因定量能力的核苷酸延伸测序。我们设计的焦磷酸测序分析方法用于对石蜡包埋组织的全基因组扩增DNA进行检测。通过评估来自突变型KRAS细胞系的DNA与来自野生型KRAS细胞系的DNA的各种混合物,我们发现焦磷酸测序的突变检测率优于双脱氧测序。此外,在检测石蜡包埋的结肠癌和正常组织的DNA混合物以及石蜡包埋的胰腺癌的KRAS突变方面,焦磷酸测序也证明优于双脱氧测序。通过焦磷酸测序对突变等位基因进行定量精确,对分析验证、监测和质量保证很有用。我们的焦磷酸测序方法简单、稳健且灵敏,检测限约为5%的突变等位基因。它对含有大量非肿瘤细胞的肿瘤特别有用。此外,该分析方法对全基因组扩增技术扩增的DNA的适用性为大规模研究提供了更广泛的DNA来源。

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