Véronique Arluison, Marc Folichon, Sergio Marco, Philippe Derreumaux, Olivier Pellegrini, Jérôme Seguin, Eliane Hajnsdorf, Philippe Regnier
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We find that the C-terminal truncated protein is fully capable of binding a polyadenylated RNA (K(d) of 120 pm vs. 50 pm for full-length Hfq). This result shows that the functional core of E. coli Hfq resides in residues 1-70 and confirms previous genetic studies. Using equilibrium unfolding studies, however, we find that full-length Hfq is 1.8 kcal x mol(-1) more stable than its truncated variant. Electron microscopy analysis of both truncated and full-length proteins indicates a structural rearrangement between the subunits upon truncation. This conformational change is coupled to a reduction in beta-strand content, as determined by Fourier transform infra-red. On the basis of these results, we propose that the C-terminal domain could protect the interface between the subunits and stabilize the hexameric Hfq structure. 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引用次数: 58
摘要
宿主因子1 (Hfq)多肽是一种核酸结合蛋白,参与多种多肽的合成。Hfq特别影响几种rna的翻译和稳定性。在早期的一项研究中,使用折叠识别方法使我们能够检测大肠杆菌Hfq和Sm拓扑结构之间的关系。通过一系列生物物理研究进一步验证了这种拓扑结构,并以Sm蛋白为模型构建了Hfq结构。Hfq形成β片环状六聚体。由于我们之前的研究预测了c端区域的大量可选构象,我们已经确定了最后19个c端残基对蛋白质功能是否必要。我们发现c端截断的蛋白完全能够结合聚腺苷化的RNA (K(d)为120 pm,而全长Hfq为50 pm)。这一结果表明大肠杆菌Hfq的功能核心位于残基1-70,证实了之前的遗传研究。然而,通过平衡展开研究,我们发现全长Hfq比截断的变体更稳定1.8 kcal x mol(-1)。截断和全长蛋白的电子显微镜分析表明,截断后亚基之间的结构重排。这种构象变化与β -链含量的减少相结合,由傅里叶变换红外测定。基于这些结果,我们提出c端结构域可以保护亚基之间的界面并稳定六聚体Hfq结构。本文还讨论了c端结构域的起源。
The C-terminal domain of Escherichia coli Hfq increases the stability of the hexamer.
The Hfq (Host factor 1) polypeptide is a nucleic acid binding protein involved in the synthesis of many polypeptides. Hfq particularly affects the translation and the stability of several RNAs. In an earlier study, the use of fold recognition methods allowed us to detect a relationship between Escherichia coli Hfq and the Sm topology. This topology was further validated by a series of biophysical studies and the Hfq structure was modelled on an Sm protein. Hfq forms a beta-sheet ring-shaped hexamer. As our previous study predicted a large number of alternative conformations for the C-terminal region, we have determined whether the last 19 C-terminal residues are necessary for protein function. We find that the C-terminal truncated protein is fully capable of binding a polyadenylated RNA (K(d) of 120 pm vs. 50 pm for full-length Hfq). This result shows that the functional core of E. coli Hfq resides in residues 1-70 and confirms previous genetic studies. Using equilibrium unfolding studies, however, we find that full-length Hfq is 1.8 kcal x mol(-1) more stable than its truncated variant. Electron microscopy analysis of both truncated and full-length proteins indicates a structural rearrangement between the subunits upon truncation. This conformational change is coupled to a reduction in beta-strand content, as determined by Fourier transform infra-red. On the basis of these results, we propose that the C-terminal domain could protect the interface between the subunits and stabilize the hexameric Hfq structure. The origin of this C-terminal domain is also discussed.