Size matters in telomere biology disorders ‒ expanding phenotypic spectrum in patients with long or short telomeres.

IF 2 4区医学 Q3 ONCOLOGY

Hereditary Cancer in Clinical Practice Pub Date : 2023-05-15 DOI:10.1186/s13053-023-00251-7

Anna Byrjalsen, Anna Engell Brainin, Thomas Kromann Lund, Mette Klarskov Andersen, Anne Marie Jelsig

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Abstract

The end of each chromosome consists of a DNA region termed the telomeres. The telomeres serve as a protective shield against degradation of the coding DNA sequence, as the DNA strand inevitably ‒ with each cell division ‒ is shortened. Inherited genetic variants cause telomere biology disorders when located in genes (e.g. DKC1, RTEL1, TERC, TERT) playing a role in the function and maintenance of the telomeres. Subsequently patients with telomere biology disorders associated with both too short or too long telomeres have been recognized. Patients with telomere biology disorders associated with short telomeres are at increased risk of dyskeratosis congenita (nail dystrophy, oral leukoplakia, and hyper- or hypo-pigmentation of the skin), pulmonary fibrosis, hematologic disease (ranging from cytopenia to leukemia) and in rare cases very severe multiorgan manifestations and early death. Patients with telomere biology disorders associated with too long telomeres have in recent years been found to confer an increased risk of melanoma and chronic lymphocytic leukemia. Despite this, many patients have an apparently isolated manifestation rendering telomere biology disorders most likely underdiagnosed. The complexity of telomere biology disorders and many causative genes makes it difficult to design a surveillance program which will ensure identification of early onset disease manifestation without overtreatment.

Abstract Image

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端粒生物学疾病中的大小问题--扩大长端粒或短端粒患者的表型谱。

每条染色体的末端都有一个被称为端粒的 DNA 区域。端粒是防止编码 DNA 序列降解的保护罩，因为每次细胞分裂，DNA 链都会不可避免地缩短。当基因（如 DKC1、RTEL1、TERC、TERT）位于对端粒的功能和维护起作用的位置时，遗传基因变异就会导致端粒生物学疾病。随后，端粒生物失调患者被认为与端粒过短或过长有关。端粒生物学紊乱导致端粒过短的患者患先天性角化不良症（指甲营养不良、口腔白斑病、皮肤色素沉着过多或过少）、肺纤维化、血液病（从全血细胞减少症到白血病）的风险增加，在极少数情况下还会出现非常严重的多器官表现和早期死亡。近年来发现，患有端粒生物学疾病的端粒过长患者罹患黑色素瘤和慢性淋巴细胞白血病的风险增加。尽管如此，许多患者的表现显然是孤立的，因此端粒生物失调症很可能被诊断不足。由于端粒生物紊乱的复杂性和致病基因的多样性，很难设计出一种监测方案来确保在不过度治疗的情况下识别早期发病的疾病表现。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Hereditary Cancer in Clinical Practice 医学-肿瘤学

CiteScore

3.10

自引率

5.90%

发文量

审稿时长

>12 weeks

期刊介绍： Hereditary Cancer in Clinical Practice is an open access journal that publishes articles of interest for the cancer genetics community and serves as a discussion forum for the development appropriate healthcare strategies. Cancer genetics encompasses a wide variety of disciplines and knowledge in the field is rapidly growing, especially as the amount of information linking genetic differences to inherited cancer predispositions continues expanding. With the increased knowledge of genetic variability and how this relates to cancer risk there is a growing demand not only to disseminate this information into clinical practice but also to enable competent debate concerning how such information is managed and what it implies for patient care. Topics covered by the journal include but are not limited to: Original research articles on any aspect of inherited predispositions to cancer. Reviews of inherited cancer predispositions. Application of molecular and cytogenetic analysis to clinical decision making. Clinical aspects of the management of hereditary cancers. Genetic counselling issues associated with cancer genetics. The role of registries in improving health care of patients with an inherited predisposition to cancer.