临床遗传学关联中的挑战：一种表型 - 多个基因。

Challenges in Clinicogenetic Correlations: One Phenotype - Many Genes.

作者信息

Gannamani Rahul, van der Veen Sterre, van Egmond Martje, de Koning Tom J, Tijssen Marina A J

机构信息

Department of Neurology University of Groningen, University Medical Centre Groningen Groningen The Netherlands.

Department of Genetics University of Groningen, University Medical Centre Groningen Groningen The Netherlands.

出版信息

Mov Disord Clin Pract. 2021 Mar 2;8(3):311-321. doi: 10.1002/mdc3.13163. eCollection 2021 Apr.

DOI:10.1002/mdc3.13163

PMID:33816658

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC8015914/

Abstract

BACKGROUND

In the field of movement disorders, what you see (phenotype) is seldom what you get (genotype). Whereas 1 phenotype was previously associated to 1 gene, the advent of next-generation sequencing (NGS) has facilitated an exponential increase in disease-causing genes and genotype-phenotype correlations, and the "one-phenotype-many-genes" paradigm has become prominent.

OBJECTIVES

To highlight the "one-phenotype-many-genes" paradigm by discussing the main challenges, perspectives on how to address them, and future directions.

METHODS

We performed a scoping review of the various aspects involved in identifying the underlying molecular cause of a movement disorder phenotype.

RESULTS

The notable challenges are (1) the lack of gold standards, overlap in clinical spectrum of different movement disorders, and variability in the interpretation of classification systems; (2) selecting which patients benefit from genetic tests and the choice of genetic testing; (3) problems in the variant interpretation guidelines; (4) the filtering of variants associated with disease; and (5) the lack of standardized, complete, and up-to-date gene lists. Perspectives to address these include (1) deep phenotyping and genotype-phenotype integration, (2) adherence to phenotype-specific diagnostic algorithms, (3) implementation of current and complementary bioinformatic tools, (4) a clinical-molecular diagnosis through close collaboration between clinicians and genetic laboratories, and (5) ongoing curation of gene lists and periodic reanalysis of genetic sequencing data.

CONCLUSIONS

Despite the rapidly emerging possibilities of NGS, there are still many steps to take to improve the genetic diagnostic yield. Future directions, including post-NGS phenotyping and cohort analyses enriched by genotype-phenotype integration and gene networks, ought to be pursued to accelerate identification of disease-causing genes and further improve our understanding of disease biology.

摘要

背景

在运动障碍领域，所见（表型）很少等同于所得（基因型）。以往一种表型与一个基因相关联，而下一代测序（NGS）技术的出现推动了致病基因数量以及基因型 - 表型相关性呈指数级增长，“一种表型 - 多个基因”的模式变得突出。

目的

通过讨论主要挑战、应对挑战的观点以及未来方向，突出“一种表型 - 多个基因”的模式。

方法

我们对确定运动障碍表型潜在分子病因所涉及的各个方面进行了范围综述。

结果

显著的挑战包括：（1）缺乏金标准、不同运动障碍临床谱的重叠以及分类系统解释的变异性；（2）选择哪些患者能从基因检测中获益以及基因检测的选择；（3）变异解读指南存在的问题；（4）与疾病相关变异的筛选；（5）缺乏标准化、完整且最新的基因列表。应对这些挑战的观点包括：（1）深入表型分析和基因型 - 表型整合；（2）遵循特定表型的诊断算法；（3）应用当前及补充性生物信息学工具；（4）临床医生与基因实验室密切合作进行临床 - 分子诊断；（5）持续整理基因列表并定期重新分析基因测序数据。

结论

尽管NGS迅速涌现出各种可能性，但提高基因诊断率仍有许多工作要做。应探索未来方向，包括NGS后的表型分析以及通过基因型 - 表型整合和基因网络丰富的队列分析，以加速致病基因的鉴定并进一步增进我们对疾病生物学的理解。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/71e4/8015914/1f255d41f7d1/MDC3-8-311-g001.jpg

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临床遗传学关联中的挑战：一种表型 - 多个基因。

Challenges in Clinicogenetic Correlations: One Phenotype - Many Genes.

作者信息

机构信息

出版信息

BACKGROUND

OBJECTIVES

METHODS

RESULTS

CONCLUSIONS

背景

目的

方法

结果

结论

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