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高等植物H⁺-ATPase功能单元中两个催化位点的证据。

Evidence for Two Catalytic Sites in the Functional Unit of H+-ATPase from Higher Plants.

作者信息

Roberts G., Berberian G., Beauge L.

机构信息

Division de Biofisica, Instituto de Investigacion Medica "Mercedes y Martin Ferreyra," Casilla de Correo 389, 5000 Cordoba, Argentina.

出版信息

Plant Physiol. 1995 Jun;108(2):813-819. doi: 10.1104/pp.108.2.813.

DOI:10.1104/pp.108.2.813

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC157404/

Abstract

We investigated the nature of the complex ATP activation kinetics of plant H+-ATPases. To this aim we analyzed that activation in three isolated isoforms (AHA1, AHA2, and AHA3) of H+-ATPase from Arabidopsis thaliana. The isoforms were obtained by heterologous expression in endoplasmic reticulum of yeast. ATP stimulation was always with low affinity (K0.5 between 500 and 1800 [mu]M). In addition, the curves were not Michaelian and displayed positive cooperativity. Detailed studies with AHA2 showed that (a) enzyme solubilized with lysophosphatidylcholine exhibited Michaelian behavior even in the presence of soybean lecithin liposomes free of enzyme, (b) solubilized enzyme incorporated into the same liposomes displayed two-site kinetics with negative cooperativity, and (c) enzyme partially digested with trypsin lost the C-terminal portion of the molecule. Under this condition the ATP activation kinetics was Michaelian or had a slight negative cooperativity and the K0.5ATP was reduced 3-fold. These data suggest that the functional unit of the H+-ATPase has two catalytic ATP sites with variable cooperativity and kinetics competence of the E(ATP) and E(ATP)2 complexes. Such variability is likely modulated by the association of the enzyme with membrane structures and by a regulatory domain in the C terminus of the enzyme molecule.

摘要

我们研究了植物H⁺-ATP酶复杂的ATP激活动力学的本质。为此，我们分析了拟南芥H⁺-ATP酶的三种分离同工型（AHA1、AHA2和AHA3）中的这种激活作用。这些同工型是通过在酵母内质网中进行异源表达获得的。ATP刺激始终具有低亲和力（K0.5在500至1800 μM之间）。此外，曲线并非米氏曲线，而是表现出正协同性。对AHA2的详细研究表明：（a）用溶血磷脂酰胆碱溶解的酶即使在不存在酶的大豆卵磷脂脂质体存在的情况下也表现出米氏行为；（b）掺入相同脂质体中的溶解酶表现出具有负协同性的双位点动力学；（c）用胰蛋白酶部分消化的酶失去了分子的C末端部分。在此条件下，ATP激活动力学为米氏动力学或具有轻微的负协同性，且K0.5ATP降低了3倍。这些数据表明，H⁺-ATP酶的功能单元具有两个催化ATP位点，E(ATP)和E(ATP)2复合物具有可变的协同性和动力学活性。这种变异性可能受酶与膜结构的结合以及酶分子C末端的调节结构域调控。