人类和其他动物端粒长度相关基因的汇编和功能分类。

IF 0.9 Q3 AGRICULTURE, MULTIDISCIPLINARY
E V Ignatieva, N S Yudin, D M Larkin
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引用次数: 1

摘要

端粒是染色体的末端区域,在细胞分裂时确保其稳定性。端粒缩短引发细胞衰老,这可能导致组织退化和萎缩,因此这一过程与预期寿命缩短和许多疾病的易感性有关。端粒磨损速度的加快可以作为个体预期寿命和健康状况的预测指标。端粒长度是一种复杂的表型性状,由多种因素决定,包括遗传因素。许多研究(包括全基因组关联研究,GWAS)表明端粒长度控制的多基因性质。本研究的目的是利用在各种人类和其他动物种群的研究中获得的GWAS数据来表征端粒长度调节的遗传基础。为此,收集了GWAS实验中与端粒长度相关的基因汇编,其中包括270个人类基因的信息,以及分别在牛、麻雀和线虫中鉴定的23、22和9个基因的信息。其中有两个同源基因编码一种庇护蛋白(人类为POT1,线虫为pot2)。功能分析表明,端粒长度可受编码基因的遗传变异的影响:(1)端粒酶的结构组分;(2)端粒区域的蛋白质组分(庇护蛋白和CST复合物);(3)参与端粒酶生物生成及其活性调控的蛋白;(4)调节庇护素组分功能活性的蛋白质;(5)参与端粒复制和/或封盖的蛋白质;(6)参与选择性端粒延长的蛋白质;(7)对DNA损伤作出反应并负责DNA修复的蛋白质;(8) rna外泌体组分。几个研究小组在不同种族起源的人群中发现的人类基因是编码端粒酶组分如TERC和TERT的基因,以及编码CST复合物组分的STN1基因。显然,影响这些基因功能的多态性位点可能是端粒相关疾病最可靠的易感性标记。有关基因及其功能的系统化数据可作为人类端粒长度相关疾病预后标准的基础。有关控制端粒长度的基因和过程的信息可用于农场动物的标记辅助和基因组选择,旨在增加其生产寿命的持续时间。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Compilation and functional classification of telomere length-associated genes in humans and other animal species.

Compilation and functional classification of telomere length-associated genes in humans and other animal species.

Compilation and functional classification of telomere length-associated genes in humans and other animal species.

Compilation and functional classification of telomere length-associated genes in humans and other animal species.

Telomeres are the terminal regions of chromosomes that ensure their stability while cell division. Telomere shortening initiates cellular senescence, which can lead to degeneration and atrophy of tissues, so the process is associated with a reduction in life expectancy and predisposition to a number of diseases. An accelerated rate of telomere attrition can serve as a predictor of life expectancy and health status of an individual. Telomere length is a complex phenotypic trait that is determined by many factors, including the genetic ones. Numerous studies (including genome-wide association studies, GWAS) indicate the polygenic nature of telomere length control. The objective of the present study was to characterize the genetic basis of the telomere length regulation using the GWAS data obtained during the studies of various human and other animal populations. To do so, a compilation of the genes associated with telomere length in GWAS experiments was collected, which included information on 270 human genes, as well as 23, 22, and 9 genes identified in the cattle, sparrow, and nematode, respectively. Among them were two orthologous genes encoding a shelterin protein (POT1 in humans and pot-2 in C. elegans). Functional analysis has shown that telomere length can be influenced by genetic variants in the genes encoding: (1) structural components of telomerase; (2) the protein components of telomeric regions (shelterin and CST complexes); (3) the proteins involved in telomerase biogenesis and regulating its activity; (4) the proteins that regulate the functional activity of the shelterin components; (5) the proteins involved in telomere replication and/or capping; (6) the proteins involved in the alternative telomere lengthening; (7) the proteins that respond to DNA damage and are responsible for DNA repair; (8) RNA-exosome components. The human genes identified by several research groups in populations of different ethnic origins are the genes encoding telomerase components such as TERC and TERT as well as STN1 encoding the CST complex component. Apparently, the polymorphic loci affecting the functions of these genes may be the most reliable susceptibility markers for telomere-related diseases. The systematized data about the genes and their functions can serve as a basis for the development of prognostic criteria for telomere length-associated diseases in humans. Information about the genes and processes that control telomere length can be used for marker-assisted and genomic selection in the farm animals, aimed at increasing the duration of their productive lifetime.

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来源期刊
Vavilovskii Zhurnal Genetiki i Selektsii
Vavilovskii Zhurnal Genetiki i Selektsii AGRICULTURE, MULTIDISCIPLINARY-
CiteScore
1.90
自引率
0.00%
发文量
119
审稿时长
8 weeks
期刊介绍: The "Vavilov Journal of genetics and breeding" publishes original research and review articles in all key areas of modern plant, animal and human genetics, genomics, bioinformatics and biotechnology. One of the main objectives of the journal is integration of theoretical and applied research in the field of genetics. Special attention is paid to the most topical areas in modern genetics dealing with global concerns such as food security and human health.
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