内摩擦对生物丝动力学的影响。

Effect of internal friction on biofilament dynamics.

作者信息

Poirier Michael G, Marko John F

机构信息

University of Illinois at Chicago, 845 West Taylor Street, Chicago, Illinois 60607-7059, USA.

出版信息

Phys Rev Lett. 2002 Jun 3;88(22):228103. doi: 10.1103/PhysRevLett.88.228103. Epub 2002 May 16.

DOI:10.1103/PhysRevLett.88.228103

PMID:12059455

Abstract

We consider biofilaments-flexible multimolecule structures common in cell biology-and show how "internal" friction associated with either conformational fluctuations or with fluid flow through narrow pores inside the filaments can dominate the external hydrodynamic friction usually considered to be the main energy dissipation process. The signature of this is wave-number-independent relaxation time of bending fluctuations. Preliminary experimental data for bending fluctuations of single folded (mitotic) chromosomes display these dynamics.

摘要

我们研究了生物细丝（细胞生物学中常见的柔性多分子结构），并展示了与构象波动或细丝内部狭窄孔隙中的流体流动相关的“内部”摩擦如何能够主导通常被认为是主要能量耗散过程的外部流体动力学摩擦。其特征是弯曲波动的波数无关弛豫时间。单条折叠（有丝分裂）染色体弯曲波动的初步实验数据显示了这些动力学特性。

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内摩擦对生物丝动力学的影响。

Effect of internal friction on biofilament dynamics.

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