ATP合酶的动力学模型：ATP合成速率的pH依赖性

Kinetic model of ATP synthase: pH dependence of the rate of ATP synthesis.

作者信息

Jain S, Nath S

机构信息

Department of Biochemical Engineering and Biotechnology, Indian Institute of Technology, Hauz Khas, 110 016, New Delhi, India.

出版信息

FEBS Lett. 2000 Jul 7;476(3):113-7. doi: 10.1016/s0014-5793(00)01716-6.

DOI:10.1016/s0014-5793(00)01716-6

PMID:10913596

Abstract

Recently, a novel molecular mechanism of torque generation in the F(0) portion of ATP synthase was proposed [Rohatgi, Saha and Nath (1998) Curr. Sci. 75, 716-718]. In this mechanism, rotation of the c-subunit was conceived to take place in 12 discrete steps of 30 degrees each due to the binding and unbinding of protons to/from the leading and trailing Asp-61 residues of the c-subunit, respectively. Based on this molecular mechanism, a kinetic scheme has been developed in this work. The scheme considers proton transport driven by a concentration gradient of protons across the proton half-channels, and the rotation of the c-subunit by changes in the electrical potential only. This kinetic scheme has been analyzed mathematically and an expression has been obtained to explain the pH dependence of the rate of ATP synthesis by ATP synthase under steady state operating conditions. For a single set of three enzymological kinetic parameters, this expression predicts the rates of ATP synthesis which agree well with the experimental data over a wide range of pH(in) and pH(out). A logical consequence of our analysis is that DeltapH and Deltapsi are kinetically inequivalent driving forces for ATP synthesis.

摘要

最近，有人提出了一种关于ATP合酶F(0)部分产生扭矩的新分子机制[罗哈吉、萨哈和纳特（1998年），《当代科学》75卷，第716 - 718页]。在这种机制中，由于质子分别与c亚基的前端和后端天冬氨酸61残基结合和脱离，c亚基的旋转被设想为以每步30度的12个离散步骤进行。基于这种分子机制，本研究开发了一种动力学方案。该方案考虑了由质子跨质子半通道的浓度梯度驱动的质子运输，以及仅由电势变化引起的c亚基的旋转。对该动力学方案进行了数学分析，并得到了一个表达式，用于解释在稳态操作条件下ATP合酶合成ATP速率的pH依赖性。对于一组单一的三个酶学动力学参数，该表达式预测的ATP合成速率在很宽的pH（内）和pH（外）范围内与实验数据吻合良好。我们分析的一个合理结果是，ΔpH和Δψ是ATP合成动力学上不等效的驱动力。

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ATP合酶的动力学模型：ATP合成速率的pH依赖性

Kinetic model of ATP synthase: pH dependence of the rate of ATP synthesis.

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