Mallam Anna L, Morris Elizabeth R, Jackson Sophie E
University Chemical Laboratory, University of Cambridge, Lensfield Road, Cambridge CB2 1EW, England.
Proc Natl Acad Sci U S A. 2008 Dec 2;105(48):18740-5. doi: 10.1073/pnas.0806697105. Epub 2008 Nov 17.
One of the most striking topological features to be found in a protein is that of a distinct knot formed by the path of the polypeptide backbone. Such knotted structures represent some of the smallest "self-tying" knots observed in Nature. Proteins containing a knot deep within their structure add an extra complication to the already challenging protein-folding problem; it is not obvious how, during the process of folding, a substantial length of polypeptide chain manages to spontaneously thread itself through a loop. Here, we probe the folding mechanism of YibK, a homodimeric alpha/beta-knot protein containing a deep trefoil knot at its carboxy terminus. By analyzing the effect of mutations made in the knotted region of the protein we show that the native structure in this area remains undeveloped until very late in the folding reaction. Single-site destabilizing mutations made in the knot structure significantly affect only the folding kinetics of a late-forming intermediate and the slow dimerization step. Furthermore, we find evidence to suggest that the heterogeneity observed in the denatured state is not caused by isomerization of the single cis proline bond as previously thought, but instead could be a result of the knotting mechanism. These results allow us to propose a folding model for YibK where the threading of the polypeptide chain and the formation of native structure in the knotted region of the protein occur independently as successive events.
在蛋白质中发现的最显著的拓扑特征之一,是由多肽主链路径形成的独特结。这种打结结构代表了自然界中观察到的一些最小的“自打结”结。在其结构深处含有结的蛋白质,给本就具有挑战性的蛋白质折叠问题又增添了额外的复杂性;在折叠过程中,相当长的一段多肽链是如何设法自发地穿过一个环,这并不明显。在这里,我们探究了YibK的折叠机制,YibK是一种同二聚体α/β-结蛋白,在其羧基末端含有一个深三叶草结。通过分析在蛋白质打结区域引入的突变的影响,我们表明该区域的天然结构直到折叠反应的很晚阶段才形成。在结结构中引入的单一位点去稳定化突变仅显著影响后期形成的中间体的折叠动力学和缓慢的二聚化步骤。此外,我们发现有证据表明,在变性状态下观察到的异质性并非如先前认为的那样是由单个顺式脯氨酸键的异构化引起的,而是可能是打结机制的结果。这些结果使我们能够提出一个YibK的折叠模型,其中多肽链的穿线和蛋白质打结区域天然结构的形成作为连续事件独立发生。