Ivan L Budyak, Olga S Mironova, Naveena Yanamala, Vijayalaxmi Manoharan, Georg Büldt, Ramona Schlesinger, Judith Klein-Seetharaman
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引用次数: 1
Abstract
Chemo- and phototaxis systems in bacteria and archaea serve as models for more complex signal transduction mechanisms in higher eukaryotes. Previous studies of the cytoplasmic fragment of the phototaxis transducer (pHtrII-cyt) from the halophilic archaeon Natronomonas pharaonis showed that it takes the shape of a monomeric or dimeric rod under low or high salt conditions, respectively. CD spectra revealed only approximately 24% helical structure, even in 4 M KCl, leaving it an open question how the rod-like shape is achieved. Here, we conducted CD, FTIR, and NMR spectroscopic studies under different conditions to address this question. We provide evidence that pHtrII-cyt is highly dynamic with strong helical propensity, which allows it to change from monomeric to dimeric helical coiled-coil states without undergoing dramatic shape changes. A statistical analysis of predicted disorder for homologous sequences suggests that structural flexibility is evolutionarily conserved within the methyl-accepting chemotaxis protein family.
细菌和古细菌中的趋化和光趋化系统为高等真核生物中更复杂的信号转导机制提供了模型。先前对嗜盐古菌法老钠单胞菌(Natronomonas pharaonis)的趋光性传感器(pHtrII-cyt)细胞质片段的研究表明,它在低盐或高盐条件下分别呈单体或二聚体棒状。CD光谱显示,即使在4 M KCl中,也只有大约24%的螺旋结构,这就留下了一个悬而未决的问题,即棒状结构是如何形成的。在这里,我们在不同条件下进行了CD, FTIR和NMR光谱研究来解决这个问题。我们提供的证据表明pHtrII-cyt是高度动态的,具有很强的螺旋倾向,这使得它可以从单体变为二聚体的螺旋线圈状态,而不会发生剧烈的形状变化。同源序列预测紊乱的统计分析表明,结构灵活性在甲基接受趋化蛋白家族中是进化保守的。
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