Schoutens J E
665 Shaw Street, PO Box 634, Los Alamos, CA 93440-0634 USA.
J Biol Phys. 2004 Jun;30(2):97-122. doi: 10.1023/B:JOBP.0000035852.95326.79.
In Part I of this paper, we present a modelto account for the force generationproducing bending, and the formation of awaveform in sperm flagella. The model isbased on the observation that dimers, andhence microtubules, possess dipole moments.The electric field these dipoles produce isthe source for storing mechanical work indynein arms. The mechanical work is thenreleased and act on the doublets to producea distally directed force with the resultthat bending occurs. The model described isconsistent with experimental observationsreported in the literature. The flexuralrigidity of a dynein arm is alsocalculated. In Part II of this paper, theconsequences of the bending mechanism arediscussed. It is shown that the sum offorces from dynein arms acting distallyalong doublet microtubules in a flagellumis essentially zero when all dyneins areattached thus resulting in the rigor state.The waveform in a flagellum occurs if oneof the sets of bending moments is zero,that is, a row of dyneins are detached oversome distance along the flagellum. Thedirection of the bend in the waveform isdetermined by which set of dynein arms aredetached with respect to the verticalmedian plane of the flagellum. Thepropagation of a bending wave is the resultof a moving region in which alternate sidesfrom the vertical median plane haveinactive dynein arms. The processes bywhich this moving region occurs and therelationship of the above results to thepropulsion of the flagellum are notconsidered.
在本文的第一部分,我们提出了一个模型,用于解释产生弯曲的力的产生以及精子鞭毛中波形的形成。该模型基于这样的观察结果:二聚体以及由此形成的微管具有偶极矩。这些偶极产生的电场是在动力蛋白臂中存储机械功的来源。然后释放机械功并作用于双联微管,产生一个向远端的力,结果导致弯曲发生。所描述的模型与文献中报道的实验观察结果一致。我们还计算了动力蛋白臂的弯曲刚度。在本文的第二部分,讨论了弯曲机制的后果。结果表明,当所有动力蛋白都附着时,沿着鞭毛中的双联微管向远端作用的动力蛋白臂的力的总和基本上为零,从而导致僵硬状态。如果一组弯矩为零,即沿着鞭毛在一定距离内有一排动力蛋白脱离,则鞭毛中会出现波形。波形中弯曲的方向由相对于鞭毛垂直中平面脱离的动力蛋白臂的组决定。弯曲波的传播是一个移动区域的结果,在该区域中,垂直中平面两侧交替出现无活性的动力蛋白臂。本文未考虑该移动区域产生的过程以及上述结果与鞭毛推进的关系。