转录组学将成为罕见病研究的主要工具

IF 1.8 Q3 MEDICINE, RESEARCH & EXPERIMENTAL

Cold Spring Harbor Molecular Case Studies Pub Date : 2022-02-01 DOI:10.1101/mcs.a006198

S. Montgomery, J. Bernstein, M. Wheeler

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引用次数: 11

摘要

在过去的5年中，转录组或rna测序(RNA-seq)逐渐成为罕见疾病诊断和发现的补充检测方法。从这个角度来看，我们总结了RNA-seq在罕见疾病研究中的最新发展和挑战。使用可获得的患者样本，如血液、皮肤或肌肉，RNA-seq能够测定表达的RNA转录物。RNA-seq分析可以识别异常或异常基因表达和选择性剪接，作为支持罕见病研究和诊断的功能证据。此外，除了编码变异之外，许多类型的变异效应也可以被描述，因为影响基因表达和剪接的非编码变异的后果可以直接观察到。这对于那些不成比例地成为异常基因表达基础的结构变异和剪接变异尤其明显，其中RNA-seq既可以测量异常典型剪接，又可以检测深度内含子效应。然而，RNA-seq在罕见疾病研究中的一个主要潜在限制是基因表达的发育和细胞类型特异性，因为致病变异的影响可能仅限于特定的时空背景，并且可能无法从相关组织和疾病表达的时间获取患者的组织样本。我们推测，随着计算方法和新兴实验技术的进步克服了发育和细胞类型特异性，RNA测序和多组学将在罕见疾病诊断和精准健康提供方面得到广泛应用。

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Toward transcriptomics as a primary tool for rare disease investigation

In the past 5 years transcriptome or RNA-sequencing (RNA-seq) has steadily emerged as a complementary assay for rare disease diagnosis and discovery. In this perspective, we summarize several recent developments and challenges in the use of RNA-seq for rare disease investigation. Using an accessible patient sample, such as blood, skin, or muscle, RNA-seq enables the assay of expressed RNA transcripts. Analysis of RNA-seq allows the identification of aberrant or outlier gene expression and alternative splicing as functional evidence to support rare disease study and diagnosis. Further, many types of variant effects can be profiled beyond coding variants, as the consequences of noncoding variants that impact gene expression and splicing can be directly observed. This is particularly apparent for structural variants that disproportionately underlie outlier gene expression and for splicing variants in which RNA-seq can both measure aberrant canonical splicing and detect deep intronic effects. However, a major potential limitation of RNA-seq in rare disease investigation is the developmental and cell type specificity of gene expression as a pathogenic variant's effect may be limited to a specific spatiotemporal context and access to a patient's tissue sample from the relevant tissue and timing of disease expression may not be possible. We speculate that as advances in computational methods and emerging experimental techniques overcome both developmental and cell type specificity, there will be broadening use of RNA sequencing and multiomics in rare disease diagnosis and delivery of precision health.

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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.