Department of Biochemistry, University of Missouri, Columbia, Missouri 65211, USA.
Protein Sci. 2010 Jun;19(6):1235-42. doi: 10.1002/pro.402.
Fragment complementation has been used to investigate the role of chain connectivity in the catalytic reaction of phosphomannomutase/phosphoglucomutase (PMM/PGM) from Pseudomonas aeruginosa, a human pathogen. A heterodimer of PMM/PGM, created from fragments corresponding to its first three and fourth domains, was constructed and enzyme activity reconstituted. NMR spectra demonstrate that the fragment corresponding to the fourth (C-terminal) domain exists as a highly structured, independent folding domain, consistent with its varied conformation observed in enzyme-substrate complexes. Steady-state kinetics and thermodynamics studies reported here show that complete conformational freedom of Domain 4, because of the break in the polypeptide chain, is deleterious to catalytic efficiency primarily as a consequence of increased entropy. This extends observations from studies of the intact enzyme, which showed that the degree of flexibility of a hinge region is controlled by the precise sequence of amino acids optimized through evolutionary constraints. This work also sheds light on the functional advantage gained by combining separate folding domains into a single polypeptide chain.
片段互补已被用于研究磷酸甘露糖异构酶/磷酸葡萄糖变位酶(PMM/PGM)的催化反应中链连接性的作用,该酶来自人类病原体铜绿假单胞菌。由对应于其前三个和第四个结构域的片段构建的 PMM/PGM 异源二聚体,并重新构成了酶活性。NMR 谱表明,对应于第四个(C 末端)结构域的片段存在作为一个高度结构化的,独立折叠结构域,这与其在酶-底物复合物中观察到的不同构象一致。这里报道的稳态动力学和热力学研究表明,由于多肽链的断裂,结构域 4 的完全构象自由度对催化效率有害,主要是由于熵的增加。这扩展了对完整酶的研究结果,这些结果表明,铰链区域的柔韧性程度受到通过进化约束优化的精确氨基酸序列的控制。这项工作还揭示了将独立折叠结构域组合成单个多肽链所获得的功能优势。