The Role of Telomeres in Human Disease.

IF 7.7 2区 生物学 Q1 GENETICS & HEREDITY Annual review of genomics and human genetics Pub Date : 2022-08-31 DOI:10.1146/annurev-genom-010422-091101
Mary Armanios
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引用次数: 29

Abstract

Telomere biology was first studied in maize, ciliates, yeast, and mice, and in recent decades, it has informed understanding of common disease mechanisms with broad implications for patient care. Short telomere syndromes are the most prevalent premature aging disorders, with prominent phenotypes affecting the lung and hematopoietic system. Less understood are a newly recognized group of cancer-prone syndromes that are associated with mutations that lengthen telomeres. A large body of new data from Mendelian genetics and epidemiology now provides an opportunity to reconsider paradigms related to the role of telomeres in human aging and cancer, and in some cases, the findings diverge from what was interpreted from model systems. For example, short telomeres have been considered potent drivers of genome instability, but age-associated solid tumors are rare in individuals with short telomere syndromes, and T cell immunodeficiency explains their spectrum. More commonly, short telomeres promote clonal hematopoiesis, including somatic reversion, providing a new leukemogenesis paradigm that is independent of genome instability. Long telomeres, on the other hand, which extend the cellular life span in vitro, are now appreciated to be the most common shared germline risk factor for cancer in population studies. Through this contemporary lens, I revisit here the role of telomeres in human aging, focusing on how short and long telomeres drive cancer evolution but through distinct mechanisms.

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端粒在人类疾病中的作用。
端粒生物学最初是在玉米、纤毛虫、酵母和小鼠中进行研究的,近几十年来,它为了解常见疾病的机制提供了信息,对患者护理具有广泛的意义。短端粒综合征是最常见的早衰疾病,其突出的表型影响肺和造血系统。人们不太了解的是一组新发现的易患癌症的综合征,它们与端粒延长的突变有关。来自孟德尔遗传学和流行病学的大量新数据现在为重新考虑端粒在人类衰老和癌症中的作用提供了机会,在某些情况下,这些发现与模型系统的解释有所不同。例如,短端粒被认为是基因组不稳定的有力驱动因素,但年龄相关的实体瘤在短端粒综合征患者中很少见,T细胞免疫缺陷解释了它们的谱。更常见的是,短端粒促进克隆造血,包括体细胞逆转,提供了一种独立于基因组不稳定性的新的白血病发生模式。另一方面,在体外延长细胞寿命的长端粒,现在被认为是人口研究中最常见的共同生殖系癌症风险因素。通过当代的视角,我在这里重新审视端粒在人类衰老中的作用,重点关注短端粒和长端粒是如何通过不同的机制驱动癌症进化的。
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来源期刊
CiteScore
14.90
自引率
1.10%
发文量
29
期刊介绍: Since its inception in 2000, the Annual Review of Genomics and Human Genetics has been dedicated to showcasing significant developments in genomics as they pertain to human genetics and the human genome. The journal emphasizes genomic technology, genome structure and function, genetic modification, human variation and population genetics, human evolution, and various aspects of human genetic diseases, including individualized medicine.
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