生成、验证和纳入高通量功能测定数据的可扩展方法,以改进临床变异分类。

IF 3.8 2区 生物学 Q2 GENETICS & HEREDITY
Samskruthi Reddy Padigepati, David A Stafford, Christopher A Tan, Melanie R Silvis, Kirsty Jamieson, Andrew Keyser, Paola Alejandra Correa Nunez, John M Nicoludis, Toby Manders, Laure Fresard, Yuya Kobayashi, Carlos L Araya, Swaroop Aradhya, Britt Johnson, Keith Nykamp, Jason A Reuter
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引用次数: 0

摘要

随着基因检测的应用和范围不断扩大,如何大规模解释 DNA 序列变异的临床意义仍是一项艰巨的挑战,其中很大一部分被归类为意义不确定的变异(VUS)。基因检测实验室历来部分依赖学术文献中的功能数据来支持变异分类。高通量功能检测或变异效应多重检测(MAVEs)旨在评估DNA变异对蛋白质稳定性和功能的影响,是变异分类的一个重要且日益可用的证据来源,但其潜力在临床实验室环境中才刚刚开始发挥出来。在这里,我们描述了一个用于生成、验证 MAVE 数据并将其纳入应用于临床基因检测的半定量变异分类方法的框架。通过单细胞基因表达测量,我们建立了细胞证据模型,以评估 44 个临床相关基因中 DNA 变异的影响。这一框架还应用于另外 22 个基因的模型,这些基因都有先前发表的 MAVE 数据集。在我们的变异分类方法中,总共纳入了 24 个基因的建模数据。这些数据为对 57,000 多人中的 4043 个观察到的变异进行分类提供了证据。基因检测实验室在生成、分析、验证和整合高通量功能数据证据方面具有得天独厚的优势,并能最终利用这些数据为更多患者提供明确的临床变异分类。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Scalable approaches for generating, validating and incorporating data from high-throughput functional assays to improve clinical variant classification.

Scalable approaches for generating, validating and incorporating data from high-throughput functional assays to improve clinical variant classification.

As the adoption and scope of genetic testing continue to expand, interpreting the clinical significance of DNA sequence variants at scale remains a formidable challenge, with a high proportion classified as variants of uncertain significance (VUSs). Genetic testing laboratories have historically relied, in part, on functional data from academic literature to support variant classification. High-throughput functional assays or multiplex assays of variant effect (MAVEs), designed to assess the effects of DNA variants on protein stability and function, represent an important and increasingly available source of evidence for variant classification, but their potential is just beginning to be realized in clinical lab settings. Here, we describe a framework for generating, validating and incorporating data from MAVEs into a semi-quantitative variant classification method applied to clinical genetic testing. Using single-cell gene expression measurements, cellular evidence models were built to assess the effects of DNA variation in 44 genes of clinical interest. This framework was also applied to models for an additional 22 genes with previously published MAVE datasets. In total, modeling data was incorporated from 24 genes into our variant classification method. These data contributed evidence for classifying 4043 observed variants in over 57,000 individuals. Genetic testing laboratories are uniquely positioned to generate, analyze, validate, and incorporate evidence from high-throughput functional data and ultimately enable the use of these data to provide definitive clinical variant classifications for more patients.

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来源期刊
Human Genetics
Human Genetics 生物-遗传学
CiteScore
10.80
自引率
3.80%
发文量
94
审稿时长
1 months
期刊介绍: Human Genetics is a monthly journal publishing original and timely articles on all aspects of human genetics. The Journal particularly welcomes articles in the areas of Behavioral genetics, Bioinformatics, Cancer genetics and genomics, Cytogenetics, Developmental genetics, Disease association studies, Dysmorphology, ELSI (ethical, legal and social issues), Evolutionary genetics, Gene expression, Gene structure and organization, Genetics of complex diseases and epistatic interactions, Genetic epidemiology, Genome biology, Genome structure and organization, Genotype-phenotype relationships, Human Genomics, Immunogenetics and genomics, Linkage analysis and genetic mapping, Methods in Statistical Genetics, Molecular diagnostics, Mutation detection and analysis, Neurogenetics, Physical mapping and Population Genetics. Articles reporting animal models relevant to human biology or disease are also welcome. Preference will be given to those articles which address clinically relevant questions or which provide new insights into human biology. Unless reporting entirely novel and unusual aspects of a topic, clinical case reports, cytogenetic case reports, papers on descriptive population genetics, articles dealing with the frequency of polymorphisms or additional mutations within genes in which numerous lesions have already been described, and papers that report meta-analyses of previously published datasets will normally not be accepted. The Journal typically will not consider for publication manuscripts that report merely the isolation, map position, structure, and tissue expression profile of a gene of unknown function unless the gene is of particular interest or is a candidate gene involved in a human trait or disorder.
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