一种线粒体 DNA 变异分类的综合方法：一个临床诊断实验室的经验。

An integrated approach for classifying mitochondrial DNA variants: one clinical diagnostic laboratory's experience.

机构信息

Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA.

出版信息

Genet Med. 2012 Jun;14(6):620-6. doi: 10.1038/gim.2012.4. Epub 2012 Mar 8.

DOI:10.1038/gim.2012.4

PMID:22402757

Abstract

PURPOSE

The mitochondrial genome is highly polymorphic. A unique feature of deleterious mitochondrial DNA (mtDNA) mutations is heteroplasmy. Genetic background and variable penetrance also play roles in the pathogenicity for a mtDNA variant. Clinicians are increasingly interested in requesting mtDNA testing. However, interpretation of uncharacterized mtDNA variants is a great challenge. We suggest a stepwise interpretation procedure for clinical service.

METHODS

We describe the algorithms used to interpret novel and rare mtDNA variants. mtDNA databases and in silico predictive algorithms are used to evaluate the pathogenic potential of novel and/or rare mtDNA variants.

RESULTS

mtDNA variants can be classified into three categories: benign variants, unclassified variants, and deleterious mutations based on database search and in silico prediction. Targeted DNA sequence analysis of matrilineal relatives, heteroplasmy quantification, and functional studies are useful to classify mtDNA variants.

CONCLUSION

Clinical significance of a novel or rare variant is critical in the diagnosis of the disease and counseling of the family. Based on the results from clinical, biochemical, and molecular genetic studies of multiple family members, proper interpretation of mtDNA variants is important for clinical laboratories and for patient care.

摘要

目的

线粒体基因组高度多态。有害线粒体 DNA(mtDNA)突变的一个独特特征是异质性。遗传背景和可变外显率也在 mtDNA 变体的致病性中起作用。临床医生越来越有兴趣要求进行 mtDNA 检测。然而，对未表征的 mtDNA 变体的解释是一个巨大的挑战。我们建议为临床服务制定逐步解释程序。

方法

我们描述了用于解释新的和罕见的 mtDNA 变体的算法。mtDNA 数据库和计算机预测算法用于评估新的和/或罕见的 mtDNA 变体的致病潜力。

结果

基于数据库搜索和计算机预测，mtDNA 变体可分为三类：良性变体、未分类变体和有害突变。对母系亲属的靶向 DNA 序列分析、异质性定量和功能研究有助于对 mtDNA 变体进行分类。

结论

新型或罕见变体的临床意义对疾病的诊断和家庭咨询至关重要。基于多个家族成员的临床、生化和分子遗传学研究结果，对 mtDNA 变体进行适当的解释对于临床实验室和患者护理非常重要。

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一种线粒体 DNA 变异分类的综合方法：一个临床诊断实验室的经验。

An integrated approach for classifying mitochondrial DNA variants: one clinical diagnostic laboratory's experience.

机构信息

出版信息

PURPOSE

METHODS

RESULTS

CONCLUSION

目的

方法

结果

结论

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