Lucas R. Struble, Jeffrey J. Lovelace, Gloria E.O. Borgstahl
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引用次数: 0
摘要
人类 RAD52 蛋白与 DNA 结合,参与基因组稳定性的维持和几种形式的 DNA 修复,包括同源重组和单链退火。尽管 RAD52 蛋白非常重要,但有关 RAD52 环大小和 RAD52 C 端蛋白-蛋白相互作用结构域变化的结构细节却很少。即使是最近对全长酵母和人类 RAD52 采用低温电子显微镜(cryoEM)方法的尝试,也没有发现包含复制蛋白 A(RPA)和 RAD51 结合域的 C 端半部分的可解释结构。在这项研究中,我们采用单分散纯化两种 RAD52 缺失构建体和小角 X 射线散射(SAXS)的方法,构建了一个包含 RAD52 的 RPA 结合结构域的结构模型。该模型对 DNA 修复专家以及针对 HR 缺陷癌症的药物开发都很有意义。
A glimpse into the hidden world of the flexible C-terminal protein binding domains of human RAD52
Human RAD52 protein binds DNA and is involved in genomic stability maintenance and several forms of DNA repair, including homologous recombination and single-strand annealing. Despite its importance, there are very few structural details about the variability of the RAD52 ring size and the RAD52 C-terminal protein–protein interaction domains. Even recent attempts to employ cryogenic electron microscopy (cryoEM) methods on full-length yeast and human RAD52 do not reveal interpretable structures for the C-terminal half that contains the replication protein A (RPA) and RAD51 binding domains. In this study, we employed the monodisperse purification of two RAD52 deletion constructs and small angle X-ray scattering (SAXS) to construct a structural model that includes RAD52′s RPA binding domain. This model is of interest to DNA repair specialists as well as for drug development against HR-deficient cancers.
期刊介绍:
Journal of Structural Biology (JSB) has an open access mirror journal, the Journal of Structural Biology: X (JSBX), sharing the same aims and scope, editorial team, submission system and rigorous peer review. Since both journals share the same editorial system, you may submit your manuscript via either journal homepage. You will be prompted during submission (and revision) to choose in which to publish your article. The editors and reviewers are not aware of the choice you made until the article has been published online. JSB and JSBX publish papers dealing with the structural analysis of living material at every level of organization by all methods that lead to an understanding of biological function in terms of molecular and supermolecular structure.
Techniques covered include:
• Light microscopy including confocal microscopy
• All types of electron microscopy
• X-ray diffraction
• Nuclear magnetic resonance
• Scanning force microscopy, scanning probe microscopy, and tunneling microscopy
• Digital image processing
• Computational insights into structure
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