未知临床意义变异分类的计算和实验方法

IF 1.8 Q3 MEDICINE, RESEARCH & EXPERIMENTAL

Cold Spring Harbor Molecular Case Studies Pub Date : 2022-04-01 DOI:10.1101/mcs.a006196

M. Spielmann, Martin Kircher

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引用次数: 7

摘要

测序能力的提高、成本的降低以及国家和国际的协调努力已导致下一代测序(NGS)技术在患者护理中的广泛应用。更普遍地说，人类遗传学和基因组医学对越来越多的患者越来越重要。一些团体已经在讨论对每个人出生时的基因组进行测序的前景。与数字健康记录一起，这将使个性化治疗和预防措施成为可能，即所谓的精准医疗。这一过程的核心步骤是确定使我们更容易患病的疾病致病突变或变异组合。尽管各种技术进步已经改进了对遗传改变的识别，但对已识别的变异的解释和排序仍然是一个重大挑战。基于我们对分子过程或先前确定的疾病变异的知识，我们可以确定潜在的功能遗传变异，并且使用不同的证据线，我们有时能够直接证明其致病性。然而，绝大多数变异被归类为临床意义不确定的变异(VUSs)，没有足够的实验证据来确定其致病性。在这些情况下，可以使用计算方法来提高优先级，并且越来越多的实验方法工具箱正在出现，可用于分析VUSs的分子效应。在这里，我们讨论如何计算和实验方法可以用来创建各种分子和细胞表型的变异效应目录。我们讨论了将大规模功能数据与机器学习和临床知识相结合的前景，以便为临床应用开发准确的致病性预测。

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Computational and experimental methods for classifying variants of unknown clinical significance

The increase in sequencing capacity, reduction in costs, and national and international coordinated efforts have led to the widespread introduction of next-generation sequencing (NGS) technologies in patient care. More generally, human genetics and genomic medicine are gaining importance for more and more patients. Some communities are already discussing the prospect of sequencing each individual's genome at time of birth. Together with digital health records, this shall enable individualized treatments and preventive measures, so-called precision medicine. A central step in this process is the identification of disease causal mutations or variant combinations that make us more susceptible for diseases. Although various technological advances have improved the identification of genetic alterations, the interpretation and ranking of the identified variants remains a major challenge. Based on our knowledge of molecular processes or previously identified disease variants, we can identify potentially functional genetic variants and, using different lines of evidence, we are sometimes able to demonstrate their pathogenicity directly. However, the vast majority of variants are classified as variants of uncertain clinical significance (VUSs) with not enough experimental evidence to determine their pathogenicity. In these cases, computational methods may be used to improve the prioritization and an increasing toolbox of experimental methods is emerging that can be used to assay the molecular effects of VUSs. Here, we discuss how computational and experimental methods can be used to create catalogs of variant effects for a variety of molecular and cellular phenotypes. We discuss the prospects of integrating large-scale functional data with machine learning and clinical knowledge for the development of accurate pathogenicity predictions for clinical applications.

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来源期刊

Cold Spring Harbor Molecular Case Studies MEDICINE, RESEARCH & EXPERIMENTAL-

CiteScore

3.20

自引率

0.00%

发文量

期刊介绍： Cold Spring Harbor Molecular Case Studies is an open-access, peer-reviewed, international journal in the field of precision medicine. Articles in the journal present genomic and molecular analyses of individuals or cohorts alongside their clinical presentations and phenotypic information. The journal''s purpose is to rapidly share insights into disease development and treatment gained by application of genomics, proteomics, metabolomics, biomarker analysis, and other approaches. The journal covers the fields of cancer, complex diseases, monogenic disorders, neurological conditions, orphan diseases, infectious disease, gene therapy, and pharmacogenomics. It has a rapid peer-review process that is based on technical evaluation of the analyses performed, not the novelty of findings, and offers a swift, clear path to publication. The journal publishes: Research Reports presenting detailed case studies of individuals and small cohorts, Research Articles describing more extensive work using larger cohorts and/or functional analyses, Rapid Communications presenting the discovery of a novel variant and/or novel phenotype associated with a known disease gene, Rapid Cancer Communications presenting the discovery of a novel variant or combination of variants in a cancer type, Variant Discrepancy Resolution describing efforts to resolve differences or update variant interpretations in ClinVar through case-level data sharing, Follow-up Reports linked to previous observations, Plus Review Articles, Editorials, and Position Statements on best practices for research in precision medicine.