在存在细胞屏障的情况下微管或肌动蛋白的亚基踏车行为:化学自由能向机械功的可能转化。
Subunit treadmilling of microtubules or actin in the presence of cellular barriers: possible conversion of chemical free energy into mechanical work.
作者信息
Hill T L, Kirschner M W
出版信息
Proc Natl Acad Sci U S A. 1982 Jan;79(2):490-4. doi: 10.1073/pnas.79.2.490.
Abstract
Free microtubule or actin filaments, along with the monomeric forms of the protein, hydrolyze GTP or ATP to produce a flux of subunits through the polymer. This flux, called treadmilling, produces no useful work. In the cell, however, these filaments are likely to be constrained between nucleating sites and other barriers that will limit polymer growth. We study here the effects of a small compression of the filaments resulting from polymerization against such barriers. If subunits can still exchange at the two ends, treadmilling will take place here as well. Under these conditions, the filament system can do useful work. The free energy of NTP hydrolysis can be used to transport materials, attached to the filament, against a resisting force. This process can in principle take place at high efficiency and bears a resemblance in a bioenergetic sense to the utilization of ATP free energy in muscle contraction. The same general principles apply to a polymer in which one end is anchored and one end is free.
摘要
游离的微管或肌动蛋白丝,连同蛋白质的单体形式,水解鸟苷三磷酸(GTP)或三磷酸腺苷(ATP),以产生亚基通过聚合物的通量。这种通量称为踏车行为,不会产生有用的功。然而,在细胞中,这些细丝可能被限制在成核位点和其他限制聚合物生长的屏障之间。我们在此研究由于细丝聚合抵住此类屏障而产生的微小压缩的影响。如果亚基仍能在两端交换,那么这里也会发生踏车行为。在这些条件下,细丝系统可以做有用的功。NTP水解的自由能可用于运输附着在细丝上的物质,以抵抗阻力。这一过程原则上可以高效进行,并且在生物能量学意义上与肌肉收缩中ATP自由能的利用有相似之处。相同的一般原理适用于一端固定而一端游离的聚合物。
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