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在拟南芥线粒体中体内新合成的 F1 的积累为植物 F1Fo ATP 合酶的模块化组装提供了证据。

Accumulation of newly synthesized F1 in vivo in arabidopsis mitochondria provides evidence for modular assembly of the plant F1Fo ATP synthase.

机构信息

ARC Centre of Excellence in Plant Energy Biology, The University of Western Australia, Crawley WA 6009, Western Australia, Australia.

出版信息

J Biol Chem. 2012 Jul 27;287(31):25749-57. doi: 10.1074/jbc.M112.373506. Epub 2012 Jun 6.

Abstract

F(1) subcomplex in mitochondrial samples is often considered to be a breakage product of the F(1)F(O) ATP synthase during sample handling and electrophoresis. We have used a progressive (15)N incorporation strategy to investigate the plant F(1)F(O) ATP synthase assembly model and the apparently free F(1) in plant mitochondria which is found in both the inner membrane and matrix. We show that subunits within F(1) in the inner membrane and matrix had a relatively higher (15)N incorporation rate than corresponding subunits in intact membrane F(1)F(O). This demonstrates that free F(1) was a newer pool with a faster turnover rate consistent with it being an assembly intermediate in vivo. Import of [(35)S]Met-labeled F(1) subunit precursors into Arabidopsis mitochondria showed the rapid accumulation of F(1) assembly intermediates. The different (15)N incorporation rate in matrix F(1), inner membrane F(1) and intact F(1)F(O) demonstrates these three represent different protein populations and are likely step by step intermediates during the assembly process of plant mitochondrial ATP synthase. The potential biological implications of in vivo accumulation of enzymatically active F(1) in mitochondria are discussed.

摘要

线粒体样品中的 F(1)亚基复合物通常被认为是在样品处理和电泳过程中 F(1)F(O)ATP 合酶的断裂产物。我们使用渐进的 (15)N 掺入策略来研究植物 F(1)F(O)ATP 合酶组装模型以及在植物线粒体中发现的位于内膜和基质中的明显游离 F(1)。我们表明,内膜和基质中 F(1)内的亚基的 (15)N 掺入率比完整膜 F(1)F(O)中的相应亚基相对较高。这表明游离 F(1)是一个更新的池,具有更快的周转率,与其作为体内组装中间体一致。将 [(35)S]Met 标记的 F(1)亚基前体导入拟南芥线粒体中显示 F(1)组装中间体的快速积累。基质 F(1)、内膜 F(1)和完整 F(1)F(O)中的不同 (15)N 掺入率表明这三种代表不同的蛋白质群体,并且可能是植物线粒体 ATP 合酶组装过程中的逐步中间体。讨论了在线粒体中积累具有酶活性的 F(1)的潜在生物学意义。

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