Registry alteration in Dynein's microtubule-binding domain: A AAA domain-guided event

IF 3.8 Q2 CHEMISTRY, PHYSICAL Chemical Physics Impact Pub Date : 2024-08-08 DOI:10.1016/j.chphi.2024.100702
Pradipta Kumar Das, Biman Jana
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Abstract

Dynein, a motor protein, harnesses chemical energy from ATP hydrolysis to generate mechanical output as it travels along microtubular tracks. Essential to this process is the microtubule-binding domain (MTBD), which facilitates the interaction with and detachment from microtubules. Previous studies have proposed that the mechanism governing this interaction is primarily driven by the coiled-coil stalk attached to the MTBD. However, conflicting arguments suggest the presence of two-way communications, where the binding and unbinding mechanisms may also influence the nucleotide state of dynein. In this study, we employed all-atom explicit solvent simulations, enhanced sampling techniques, and coarse-grained methodologies to systematically investigate the effects of stalk and MT on the structural stabilities of different conformations of MTBD and their sequence of events during the transition from one to another. We found that the globular MTBD domain without stalk and MT predominantly resides in its weak binding configuration. Upon introduction of a limited length of stalk and interaction with MT, a balance between the strong and weak binding configurations is restored. Further introduction of the full-length stalk and interaction with MT strengthen the kinetic stability of these two configurations. We have also explored the sequence of events of the relevant transition between these two states using coarse-grained simulation protocols both in the presence and absence of interaction with MT. In the absence of MT interactions, we found a mixed conformational state of the system that corresponds to the already published crystal structure of Dynein. In the presence of MT, the conformational change of the stalk precedes the conformational change of the MTBD globular domain. Our findings support the view that the nucleotide state of the AAA+ ring determines the state of the MTBD domain through stalk, shedding light on the intricate mechanisms governing dynein's interaction with microtubules.

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Dynein 微管结合域的注册改变:由 AAA 结构域引导的事件
动力蛋白(Dynein)是一种运动蛋白,当它沿着微管轨道行进时,利用 ATP 水解产生的化学能产生机械输出。微管结合结构域(MTBD)对这一过程至关重要,它能促进与微管的相互作用和脱离。以前的研究认为,这种相互作用的机制主要是由附着在 MTBD 上的盘卷柄驱动的。然而,相互矛盾的论点表明存在双向交流,即结合和解除结合的机制也可能影响动力蛋白的核苷酸状态。在这项研究中,我们采用了全原子显式溶剂模拟、增强采样技术和粗粒度方法,系统地研究了柄和 MT 对 MTBD 不同构象的结构稳定性的影响,以及它们从一种构象转变为另一种构象的过程中的事件序列。我们发现,没有柄和 MT 的球状 MTBD 结构域主要处于弱结合构型。在引入有限长度的柄并与 MT 相互作用后,强结合构型和弱结合构型之间恢复了平衡。进一步引入全长的柄并与 MT 相互作用,会加强这两种构型的动力学稳定性。我们还使用粗粒度模拟协议探讨了在存在和不存在与 MT 的相互作用时,这两种状态之间相关转变的事件序列。在没有 MT 相互作用的情况下,我们发现该系统的混合构象状态与已公布的 Dynein 晶体结构相符。在存在 MT 的情况下,柄的构象变化先于 MTBD 球状结构域的构象变化。我们的研究结果支持AAA+环的核苷酸状态通过柄决定MTBD结构域状态的观点,从而揭示了支配动力蛋白与微管相互作用的复杂机制。
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来源期刊
Chemical Physics Impact
Chemical Physics Impact Materials Science-Materials Science (miscellaneous)
CiteScore
2.60
自引率
0.00%
发文量
65
审稿时长
46 days
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