Susan M Bailey, Stephen R Kunkel, Joel S Bedford, Michael N Cornforth
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引用次数: 0
摘要
辐射细胞遗传学有着丰富的历史,但该领域以外的人却很少了解。早期的放射生物学以物理学和生物物理学概念为主,这些概念大量借鉴了辐射诱导染色体畸变的研究。从这些研究中,生物效应与吸收剂量、剂量率和电离密度变化之间的定量关系被编纂成放射生物学理论的关键概念,这些概念已延续了近一个世纪。本综述旨在从历史的角度阐述其中的一些概念,包括支持以下论点的证据,即染色体畸变是许多(如果不是大多数)电离辐射对人类产生的生物效应的基础,包括诱发癌症和根除肿瘤。这些研究发现的意义已远远超出其最初的范围。有丝分裂细胞中的染色体结构重排最初被认为是由于间期辐射产生的断裂,随后是附近其他断裂末端的重新连接或错误连接。这些相对温和的开端最终导致了通过非同源末端连接对双链断裂进行 DNA 修复的发现和特征描述,其对各种生物过程的重要性现已得到广泛重视。V(D)J 重组和物种形成就是其中的两个例子。细胞遗传学、新兴的分子放射生物学和第三代测序技术的快速发展成为新旧技术的交汇点。因此,新兴的 "细胞基因组学 "领域在更全面地了解电离辐照的生物效应机制方面具有独特的优势。
The Central Role of Cytogenetics in Radiation Biology.
Radiation cytogenetics has a rich history seldom appreciated by those outside the field. Early radiobiology was dominated by physics and biophysical concepts that borrowed heavily from the study of radiation-induced chromosome aberrations. From such studies, quantitative relationships between biological effect and changes in absorbed dose, dose rate and ionization density were codified into key concepts of radiobiological theory that have persisted for nearly a century. This review aims to provide a historical perspective of some of these concepts, including evidence supporting the contention that chromosome aberrations underlie development of many, if not most, of the biological effects of concern for humans exposed to ionizing radiations including cancer induction, on the one hand, and tumor eradication on the other. The significance of discoveries originating from these studies has widened and extended far beyond their original scope. Chromosome structural rearrangements viewed in mitotic cells were first attributed to the production of breaks by the radiations during interphase, followed by the rejoining or mis-rejoining among ends of other nearby breaks. These relatively modest beginnings eventually led to the discovery and characterization of DNA repair of double-strand breaks by non-homologous end joining, whose importance to various biological processes is now widely appreciated. Two examples, among many, are V(D)J recombination and speciation. Rapid technological advancements in cytogenetics, the burgeoning fields of molecular radiobiology and third-generation sequencing served as a point of confluence between the old and new. As a result, the emergent field of "cytogenomics" now becomes uniquely positioned for the purpose of more fully understanding mechanisms underlying the biological effects of ionizing radiation exposure.
期刊介绍:
Radiation Research publishes original articles dealing with radiation effects and related subjects in the areas of physics, chemistry, biology
and medicine, including epidemiology and translational research. The term radiation is used in its broadest sense and includes specifically
ionizing radiation and ultraviolet, visible and infrared light as well as microwaves, ultrasound and heat. Effects may be physical, chemical or
biological. Related subjects include (but are not limited to) dosimetry methods and instrumentation, isotope techniques and studies with
chemical agents contributing to the understanding of radiation effects.