Preserving centromere identity: right amounts of CENP-A at the right place and time.

IF 2.8 4区生物学 Q3 BIOCHEMISTRY & MOLECULAR BIOLOGY

Chromosome Research Pub Date : 2025-09-30 DOI:10.1007/s10577-025-09780-4

Zofia Pukało, Bethan Medina-Pritchard, Maria Alba Abad, A Arockia Jeyaprakash

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Abstract

Four decades ago, the discovery of centromere protein-A (CENP-A) marked a pivotal breakthrough in chromosome biology, revealing the epigenetic foundation of centromere identity. CENP-A, a histone H3 variant, directs the formation of the microtubule-binding kinetochore complex, designating the chromosomal site for its assembly and underpins the accurate partitioning of genetic material during cell division. Errors in cell division can give rise to DNA instability and aneuploidy, implicated in human diseases such as cancer. Therefore, discovering the underlying pathways and mechanisms responsible for the formation, regulation and maintenance of the centromere is important to our understanding of genome stability, epigenetic inheritance, and in providing the knowledge to help generate possible treatments and therapeutics. Here, we review various molecular pathways and mechanisms implicated in maintaining centromere identity and highlight some of the key outstanding questions with a focus on the human centromere.

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保持着丝粒的同一性：在正确的时间和地点使用适量的CENP-A。

四十年前，着丝粒蛋白a （CENP-A）的发现标志着染色体生物学的重大突破，揭示了着丝粒同一性的表观遗传学基础。CENP-A是一种组蛋白H3变体，指导微管结合着丝点复合物的形成，指定其组装的染色体位点，并支持细胞分裂过程中遗传物质的准确分配。细胞分裂错误会导致DNA不稳定和非整倍体，这与癌症等人类疾病有关。因此，发现着丝粒形成、调节和维持的潜在途径和机制对于我们理解基因组稳定性、表观遗传以及提供帮助产生可能的治疗和治疗方法的知识非常重要。在这里，我们回顾了与维持着丝粒同一性有关的各种分子途径和机制，并重点介绍了人类着丝粒的一些关键问题。

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

Chromosome Research 生物-生化与分子生物学

CiteScore

4.70

自引率

3.80%

发文量

审稿时长

1 months

期刊介绍： Chromosome Research publishes manuscripts from work based on all organisms and encourages submissions in the following areas including, but not limited, to: · Chromosomes and their linkage to diseases; · Chromosome organization within the nucleus; · Chromatin biology (transcription, non-coding RNA, etc); · Chromosome structure, function and mechanics; · Chromosome and DNA repair; · Epigenetic chromosomal functions (centromeres, telomeres, replication, imprinting, dosage compensation, sex determination, chromosome remodeling); · Architectural/epigenomic organization of the genome; · Functional annotation of the genome; · Functional and comparative genomics in plants and animals; · Karyology studies that help resolve difficult taxonomic problems or that provide clues to fundamental mechanisms of genome and karyotype evolution in plants and animals; · Mitosis and Meiosis; · Cancer cytogenomics.