拥挤环境中酶驱动活性波动的传播

arXiv - PHYS - Biological Physics Pub Date : 2024-08-01 DOI:arxiv-2408.00578

Rik Chakraborty, Arnab Maiti, Diptangshu Paul, Rajnandan Borthakur, K. R. Jayaprakash, Uddipta Ghosh, Krishna Kanti Dey

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摘要

我们通过测量被动微观示踪剂在ficoll和甘油的活性溶液中的扩散，研究了活性酶在拥挤环境中向周围环境的能量转移。尽管与水溶液相比，在人工拥挤介质中观察到的底物周转率较低，被动示踪剂的扩散增强相对较小，但我们发现在有酶活性的拥挤环境中，相对扩散增强明显较高。我们的实验观察结果与支持性分析估计结果相结合，强调了介入介质在促进活性酶周围机械能分布方面的关键作用。

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Propagation of Enzyme-driven Active Fluctuations in Crowded Milieu

We investigated the energy transfer from active enzymes to their surroundings in crowded environments by measuring the diffusion of passive microscopic tracers in active solutions of ficoll and glycerol. Despite observing lower rates of substrate turnover and relatively smaller enhancement of passive tracer diffusion in artificial crowded media compared to those in aqueous solutions, we found a significantly higher relative diffusion enhancement in crowded environments in the presence of enzymatic activity. Our experimental observations, coupled with supporting analytical estimations, underscored the critical role of the intervening media in facilitating mechanical energy distribution around active enzymes.

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arXiv - PHYS - Biological Physics

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