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引用次数: 3
摘要
在原核生物中,RecA蛋白催化双链DNA的修复和链交换。RecA结合单链DNA (ssDNA)并形成突触前复合物,其中蛋白质在ssDNA周围聚合形成右手螺旋核蛋白丝结构。在目前的工作中,RecA-ssDNA细丝结构的形成机制采用粗粒度分子动力学模拟建模。来自x射线结构的信息被用来模拟蛋白质本身,而不是它的相互作用;蛋白质与ssDNA之间的相互作用仅通过静电能、芳香能和排斥能来模拟。在本研究中,分别研究了RecA的单体、二聚体和三聚体单元以及4、8和11 nt -长ssDNA。我们的研究结果表明,单体RecA不足以形成核蛋白丝;相反,二聚体RecA是基本的结合单元,较高的多聚体RecA单元促进了细丝的形成。我们的研究结果表明,RecA初级结合位点环区柔韧性对其结合进入的ssDNA至关重要,环区存在的芳香残基在ssDNA结合中起重要作用,ATP可能通过改变RecA蛋白的静电电位来引导ssDNA。
Mechanism of the formation of the RecA–ssDNA nucleoprotein filament structure: a coarse-grained approach
In prokaryotes, the RecA protein catalyzes the repair and strand exchange of double-stranded DNA. RecA binds to single-stranded DNA (ssDNA) and forms a presynaptic complex in which the protein polymerizes around the ssDNA to form a right-handed helical nucleoprotein filament structure. In the present work, the mechanism for the formation of the RecA–ssDNA filament structure is modeled using coarse-grained molecular dynamics simulations. Information from the X-ray structure was used to model the protein itself but not its interactions; the interactions between the protein and the ssDNA were modeled solely by electrostatic, aromatic, and repulsive energies. For the present study, the monomeric, dimeric, and trimeric units of RecA and 4, 8, and 11 NT-long ssDNA, respectively, were studied. Our results indicate that monomeric RecA is not sufficient for nucleoprotein filament formation; rather, dimeric RecA is the elementary binding unit, with higher multimeric units of RecA facilitating filament formation. Our results reveal that loop region flexibility at the primary binding site of RecA is essential for it to bind the incoming ssDNA, that the aromatic residues present in the loop region play an important role in ssDNA binding, and that ATP may play a role in guiding the ssDNA by changing the electrostatic potential of the RecA protein.
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