暗基因组与复等位基因:精准医学的挑战。
The dark genome and pleiotropy: challenges for precision medicine.
机构信息
MRC Harwell Institute, Harwell, OX11 0RD, UK.
出版信息
Mamm Genome. 2019 Aug;30(7-8):212-216. doi: 10.1007/s00335-019-09813-4.
Abstract
Surprisingly we remain ignorant of the function of the majority of genes in the human and mouse genomes. The dark genome is a major obstacle to the interpretation of the function of human genetic variation and its impact on disease. At the same time, pleiotropy, how individual variants influence multiple phenotypes, is key to understanding gene function and the role of genes and genetic networks in disease systems. Both understanding the genetics of disease and developing new therapeutic approaches and advances in precision medicine are all compromised by our limited knowledge of gene function and pleiotropic effects. Illuminating the dark genome and revealing pleiotropy across the genome requires a highly coordinated and international effort to acquire and analyse high-dimensional phenotype data from model organisms. We describe briefly how the International Mouse Phenotyping Consortium is addressing these challenges and the novel features of the pleiotropic landscape that are revealed by functional genomics programmes at genome-wide scale.
摘要
令人惊讶的是,我们仍然不知道人类和老鼠基因组中大多数基因的功能。暗基因组是解释人类遗传变异及其对疾病影响的主要障碍。同时,个体变体如何影响多种表型的多效性是理解基因功能以及基因和遗传网络在疾病系统中的作用的关键。理解疾病的遗传学以及开发新的治疗方法和精准医疗的进展都受到我们对基因功能和多效性影响的有限知识的限制。阐明暗基因组并揭示全基因组的多效性需要高度协调和国际化的努力,从模式生物中获取和分析高维表型数据。我们简要描述了国际小鼠表型联盟如何应对这些挑战,以及功能基因组学计划在全基因组范围内揭示的多效性景观的新颖特征。
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