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热嗜碱芽孢杆菌 PS3 型 ATP 合酶亚基 ε 的构象转变

Conformational transitions of subunit epsilon in ATP synthase from thermophilic Bacillus PS3.

机构信息

ICORP ATP Synthesis Regulation Project, Japan Science and Technology Corporation, Tokyo, Japan.

出版信息

Biophys J. 2010 Feb 3;98(3):434-42. doi: 10.1016/j.bpj.2009.10.023.

DOI:10.1016/j.bpj.2009.10.023
PMID:20141757
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC2814204/
Abstract

Subunit epsilon of bacterial and chloroplast F(O)F(1)-ATP synthase is responsible for inhibition of ATPase activity. In Bacillus PS3 enzyme, subunit epsilon can adopt two conformations. In the "extended", inhibitory conformation, its two C-terminal alpha-helices are stretched along subunit gamma. In the "contracted", noninhibitory conformation, these helices form a hairpin. The transition of subunit epsilon from an extended to a contracted state was studied in ATP synthase incorporated in Bacillus PS3 membranes at 59 degrees C. Fluorescence energy resonance transfer between fluorophores introduced in the C-terminus of subunit epsilon and in the N-terminus of subunit gamma was used to follow the conformational transition in real time. It was found that ATP induced the conformational transition from the extended to the contracted state (half-maximum transition extent at 140 microM ATP). ADP could neither prevent nor reverse the ATP-induced conformational change, but it did slow it down. Acid residues in the DELSEED region of subunit beta were found to stabilize the extended conformation of epsilon. Binding of ATP directly to epsilon was not essential for the ATP-induced conformational change. The ATP concentration necessary for the half-maximal transition (140 microM) suggests that subunit epsilon probably adopts the extended state and strongly inhibits ATP hydrolysis only when the intracellular ATP level drops significantly below the normal value.

摘要

细菌和叶绿体 F(O)F(1)-ATP 合酶的亚基 epsilon 负责抑制 ATP 酶活性。在芽孢杆菌 PS3 酶中,亚基 epsilon 可以采用两种构象。在“伸展”的抑制构象中,其两个 C 端α-螺旋沿着亚基γ伸展。在“收缩”的非抑制构象中,这些螺旋形成发夹。在 59°C 下,在芽孢杆菌 PS3 膜中掺入的 ATP 合酶中研究了亚基 epsilon 从伸展状态到收缩状态的转变。通过在亚基 epsilon 的 C 端和亚基γ的 N 端引入荧光团之间的荧光能量共振转移,实时跟踪构象转变。结果发现,ATP 诱导从伸展状态到收缩状态的构象转变(在 140μM ATP 下达到最大转变程度的一半)。ADP 既不能预防也不能逆转 ATP 诱导的构象变化,但可以使其减慢。在亚基β的 DELSEED 区域中的酸性残基被发现稳定 epsilon 的伸展构象。ATP 直接结合到 epsilon 上对于 ATP 诱导的构象变化不是必需的。对于半最大转变(140μM)所需的 ATP 浓度表明,亚基 epsilon 可能仅在细胞内 ATP 水平显著低于正常值时采用伸展状态并强烈抑制 ATP 水解。

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