UNC-104 transport properties are robust and independent of changes in its cargo binding

Amir Shee, Vidur Sabharwal, Sandhya P. Koushika, Amitabha Nandi, Debasish Chaudhuri
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Abstract

Cargo distribution within eukaryotic cells relies on the active transport mechanisms driven by molecular motors. Despite their critical role, the intricate relationship between motor transport properties and cargo binding - and its impact on motor distribution - remains inadequately understood. Additionally, improper regulation of ubiquitination, a pivotal post-translational modification that affects protein degradation, activation, and localization, is associated with several neurodegenerative diseases. Recent data showed that ubiquitination can alter motor-cargo binding of the Kinesin-3 motor UNC-104 / KIF1A that transports synaptic vesicles. To investigate how ubiquitin-like modifications affect motor protein function, particularly cargo binding, transport properties, and distribution, we utilize the PLM neuron of C. elegans as a model system. Using fluorescent microscopy, we assess the distribution of cargo-bound UNC-104 motors along the axon and probe their dynamics using FRAP experiments. We model cargo binding kinetics with a Master equation and motor density dynamics using a Fokker-Planck approach. Our combined experimental and theoretical analysis reveals that ubiquitin-like knockdowns enhance UNC-104's cooperative binding to its cargo. However, these modifications do not affect UNC-104's transport properties, such as processivity and diffusivity. Thus, while ubiquitin-like modifications significantly impact the cargo-binding of UNC-104, they do not alter its transport dynamics, keeping the homeostatic distribution of UNC-104 unchanged.
UNC-104 的运输特性非常稳定,不受货物结合变化的影响
真核细胞内的货物运输依赖于分子马达驱动的主动运输机制。此外,泛素化(一种影响蛋白质降解、激活和定位的关键性翻译后修饰)的不当调控与多种神经退行性疾病相关。最近的数据显示,泛素化可以改变运输突触小泡的驱动蛋白-3 运动器 UNC-104 / KIF1A 的运动-货物结合。为了研究泛素样修饰如何影响运动蛋白的功能,特别是载体结合、运输特性和分布,我们利用秀丽隐杆线虫的 PLM 神经元作为模型系统。利用荧光显微镜,我们评估了货物结合的 UNC-104 马达沿轴突的分布,并利用 FRAP 实验探究了它们的动力学。我们用马斯特方程建立了货物结合动力学模型,并用福克-普朗克方法建立了马达密度动力学模型。我们结合实验和理论分析发现,类似泛素的锁定会增强 UNC-104 与其货物的合作性结合。然而,这些修饰并不影响 UNC-104 的运输特性,如过程性和扩散性。因此,虽然泛素样修饰会显著影响 UNC-104 的货物结合,但不会改变其运输动力学,从而使 UNC-104 的平衡分布保持不变。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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