Zhi Zheng, Lyuqin Zheng, Meret Arter, Kaixian Liu, Shintaro Yamada, David Ontoso, Soonjoung Kim, Scott Keeney
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引用次数: 0
摘要
减数分裂重组始于 SPO11 产生 DNA 双链断裂(DSB)1。在大多数物种中,SPO11 对减数分裂至关重要,但它会产生具有诱变潜力2 和配子杀伤潜力3 的危险 DSB。因此,细胞必须利用 SPO11 的有益功能,同时将其风险降到最低4 - 它们是如何做到这一点的,目前仍鲜为人知。在此,我们报告了纯化的重组小鼠 SPO11 与 TOP6BL 结合后的 DNA 体外裂解重组。SPO11-TOP6BL 复合物在溶液中是单体(1:1),与 DNA 紧密结合,但二聚体(2:2)组装可裂解 DNA 以形成共价 5′连接,这需要 SPO11 活性位点残基、二价金属离子和 SPO11 二聚体。SPO11 还能重新密封被其切割的 DNA。利用 AlphaFold 3 进行的结构建模表明,DNA 在裂解前是弯曲的5。体外裂解显示出一种序列偏差,这种偏差部分解释了体内 DSB 位点的偏好。在复杂的 DNA 底物上,裂解效率很低,部分原因是 SPO11 很容易被困在与 DSB 不相容的(可能是单体)结合状态中,这种状态的交换速度很慢。不过,在有利于二聚体组装的底物上或通过人为地使 SPO11 二聚化,裂解效果会得到改善。我们的研究结果提供了一个模型,在这个模型中,内在的弱二聚化限制了 SPO11 在体内的活性,使其非常依赖于集中和控制 DSB 形成的附属蛋白。
Reconstitution of SPO11-dependent double-strand break formation
Meiotic recombination starts with SPO11 generation of DNA double-strand breaks (DSBs)1. SPO11 is critical for meiosis in most species, but it generates dangerous DSBs with mutagenic2 and gametocidal3 potential. Cells must therefore utilize the beneficial functions of SPO11 while minimizing its risks4—how they do so remains poorly understood. Here we report reconstitution of DNA cleavage in vitro with purified recombinant mouse SPO11 bound to TOP6BL. SPO11–TOP6BL complexes are monomeric (1:1) in solution and bind tightly to DNA, but dimeric (2:2) assemblies cleave DNA to form covalent 5′ attachments that require SPO11 active-site residues, divalent metal ions and SPO11 dimerization. SPO11 can also reseal DNA that it has nicked. Structure modelling with AlphaFold 3 suggests that DNA is bent prior to cleavage5. In vitro cleavage displays a sequence bias that partially explains DSB site preferences in vivo. Cleavage is inefficient on complex DNA substrates, partly because SPO11 is readily trapped in DSB-incompetent (presumably monomeric) binding states that exchange slowly. However, cleavage is improved with substrates that favour dimer assembly or by artificially dimerizing SPO11. Our results inform a model in which intrinsically weak dimerization restrains SPO11 activity in vivo, making it exquisitely dependent on accessory proteins that focus and control DSB formation.
期刊介绍:
Nature is a prestigious international journal that publishes peer-reviewed research in various scientific and technological fields. The selection of articles is based on criteria such as originality, importance, interdisciplinary relevance, timeliness, accessibility, elegance, and surprising conclusions. In addition to showcasing significant scientific advances, Nature delivers rapid, authoritative, insightful news, and interpretation of current and upcoming trends impacting science, scientists, and the broader public. The journal serves a dual purpose: firstly, to promptly share noteworthy scientific advances and foster discussions among scientists, and secondly, to ensure the swift dissemination of scientific results globally, emphasizing their significance for knowledge, culture, and daily life.
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