Unraveling the three-dimensional (3D) genome architecture in Neurodevelopmental Disorders (NDDs).

IF 1.6 4区 医学 Q3 CLINICAL NEUROLOGY Neurogenetics Pub Date : 2024-10-01 Epub Date: 2024-08-27 DOI:10.1007/s10048-024-00774-8
P Carballo-Pacoret, A Carracedo, C Rodriguez-Fontenla
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Abstract

The human genome, comprising millions of pairs of bases, serves as the blueprint of life, encoding instructions for cellular processes. However, genomes are not merely linear sequences; rather, the complex of DNA and histones, known as chromatin, exhibits complex organization across various levels, which profoundly influence gene expression and cellular function. Central to understanding genome organization is the emerging field of three-dimensional (3D) genome studies. Utilizing advanced techniques such as Hi-C, researchers have unveiled non-random dispositions of genomic elements, highlighting their importance in transcriptional regulation and disease mechanisms. Topologically Associating Domains (TADs), that demarcate regions of chromatin with preferential internal interactions, play crucial roles in gene regulation and are increasingly implicated in various diseases such as cancer and schizophrenia. However, their role in Neurodevelopmental Disorders (NDDs) remains poorly understood. Here, we focus on TADs and 3D conservation across the evolution and between cell types in NDDs. The investigation into genome organization and its impact on disease has led to significant breakthroughs in understanding NDDs etiology such ASD (Autism Spectrum Disorder). By elucidating the wide spectrum of ASD manifestations, researchers aim to uncover the underlying genetic and epigenetic factors contributing to its heterogeneity. Moreover, studies linking TAD disruption to NDDs underscore the importance of spatial genome organization in maintaining proper brain development and function. In summary, this review highlights the intricate interplay between genome organization, transcriptional control, and disease pathology, shedding light on fundamental biological processes and offering insights into the mechanisms underlying NDDs like ASD.

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揭示神经发育障碍(NDDs)的三维(3D)基因组结构。
人类基因组由数百万对碱基组成,是生命的蓝图,编码着细胞过程的指令。然而,基因组并不仅仅是线性序列;相反,DNA 和组蛋白的复合体,即染色质,在不同层次上呈现出复杂的组织结构,对基因表达和细胞功能产生深远影响。了解基因组组织的核心是新兴的三维(3D)基因组研究领域。利用 Hi-C 等先进技术,研究人员揭示了基因组元素的非随机分布,突出了它们在转录调控和疾病机制中的重要性。拓扑关联区(TADs)是染色质中具有优先内部相互作用的区域,在基因调控中起着至关重要的作用,而且越来越多地与癌症和精神分裂症等各种疾病有关。然而,人们对它们在神经发育障碍(NDDs)中的作用仍然知之甚少。在这里,我们将重点研究 TADs 和 3D 在 NDDs 的进化过程中和细胞类型之间的保护。对基因组组织及其对疾病影响的研究已在了解自闭症(ASD)等 NDDs 病因学方面取得了重大突破。通过阐明广泛的 ASD 表现,研究人员旨在揭示导致其异质性的潜在遗传和表观遗传因素。此外,将 TAD 干扰与 NDDs 联系起来的研究强调了空间基因组组织在维持大脑正常发育和功能方面的重要性。总之,这篇综述强调了基因组组织、转录控制和疾病病理之间错综复杂的相互作用,揭示了基本的生物学过程,并提供了对 ASD 等 NDDs 潜在机制的见解。
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来源期刊
Neurogenetics
Neurogenetics 医学-临床神经学
CiteScore
3.90
自引率
0.00%
发文量
24
审稿时长
6 months
期刊介绍: Neurogenetics publishes findings that contribute to a better understanding of the genetic basis of normal and abnormal function of the nervous system. Neurogenetic disorders are the main focus of the journal. Neurogenetics therefore includes findings in humans and other organisms that help understand neurological disease mechanisms and publishes papers from many different fields such as biophysics, cell biology, human genetics, neuroanatomy, neurochemistry, neurology, neuropathology, neurosurgery and psychiatry. All papers submitted to Neurogenetics should be of sufficient immediate importance to justify urgent publication. They should present new scientific results. Data merely confirming previously published findings are not acceptable.
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