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胸腺素β4改变肌动蛋白单体的构象和动力学。

Thymosin-beta(4) changes the conformation and dynamics of actin monomers.

作者信息

De La Cruz E M, Ostap E M, Brundage R A, Reddy K S, Sweeney H L, Safer D

机构信息

Pennsylvania Muscle Institute and Department of Physiology, University of Pennsylvania School of Medicine, Philadelphia, Pennsylvania 19104 USA.

出版信息

Biophys J. 2000 May;78(5):2516-27. doi: 10.1016/S0006-3495(00)76797-X.

DOI:10.1016/S0006-3495(00)76797-X
PMID:10777749
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC1300842/
Abstract

Thymosin-beta(4) (Tbeta(4)) binds actin monomers stoichiometrically and maintains the bulk of the actin monomer pool in metazoan cells. Tbeta(4) binding quenches the fluorescence of N-iodoacetyl-N'-(5-sulfo-1-naphthyl)ethylenediamine (AEDANS) conjugated to Cys(374) of actin monomers. The K(d) of the actin-Tbeta(4) complex depends on the cation and nucleotide bound to actin but is not affected by the AEDANS probe. The different stabilities are determined primarily by the rates of dissociation. At 25 degrees C, the free energy of Tbeta(4) binding MgATP-actin is primarily enthalpic in origin but entropic for CaATP-actin. Binding is coupled to the dissociation of bound water molecules, which is greater for CaATP-actin than MgATP-actin monomers. Proteolysis of MgATP-actin, but not CaATP-actin, at Gly(46) on subdomain 2 is >12 times faster when Tbeta(4) is bound. The C terminus of Tbeta(4) contacts actin near this cleavage site, at His(40). By tritium exchange, Tbeta(4) slows the exchange rate of approximately eight rapidly exchanging amide protons on actin. We conclude that Tbeta(4) changes the conformation and structural dynamics ("breathing") of actin monomers. The conformational change may reflect the unique ability of Tbeta(4) to sequester actin monomers and inhibit nucleotide exchange.

摘要

胸腺素β4(Tβ4)以化学计量方式结合肌动蛋白单体,并维持后生动物细胞中大部分肌动蛋白单体库。Tβ4结合可淬灭与肌动蛋白单体的半胱氨酸(Cys)374共轭的N - 碘乙酰基 - N'-(5 - 磺基 - 1 - 萘基)乙二胺(AEDANS)的荧光。肌动蛋白 - Tβ4复合物的解离常数(Kd)取决于与肌动蛋白结合的阳离子和核苷酸,但不受AEDANS探针影响。不同的稳定性主要由解离速率决定。在25℃时,Tβ4结合MgATP - 肌动蛋白的自由能主要源于焓,但结合CaATP - 肌动蛋白时则源于熵。结合与结合水分子的解离相关,CaATP - 肌动蛋白的结合水分子解离比MgATP - 肌动蛋白单体更多。当Tβ4结合时,亚结构域2上甘氨酸(Gly)46处的MgATP - 肌动蛋白(而非CaATP - 肌动蛋白)的蛋白水解速度快12倍以上。Tβ4的C末端在该切割位点附近的组氨酸(His)40处与肌动蛋白接触。通过氚交换,Tβ4减缓了肌动蛋白上大约八个快速交换酰胺质子的交换速率。我们得出结论,Tβ4改变了肌动蛋白单体的构象和结构动力学(“呼吸”)。构象变化可能反映了Tβ4隔离肌动蛋白单体并抑制核苷酸交换的独特能力。

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