Department of Biochemistry and Cell Biology, Rice University, Houston, Texas 77005-1892, USA.
Proteins. 2010 Feb 1;78(2):357-64. doi: 10.1002/prot.22549.
The structure of the trimeric adenylate kinase from the Archaebacteria Methanococcus mariplaludis (AK(MAR)) has been solved to 2.5-A resolution and the temperature dependent stability and kinetics of the enzyme measured. The K(M) and V(max) of AK(MAR) exhibit only modest temperature dependence from 30 degrees -60 degrees C. Although M. mariplaludis is a mesophile with a maximum growth temperature of 43 degrees C, AK(MAR) has a very broad functional range and stability (T(m) = 74.0 degrees C) that are more consistent with a thermophilic enzyme with high thermostability and exceptional activity over a wide range of temperatures, suggesting that this microbe may have only recently invaded a mesophilic niche and has yet to fully adapt. A comparison of the Local Structural Entropy (LSE) for AK(MAR) to the related adenylate kinases from the mesophile Methanococcus voltae and thermophile Methanococcus thermolithotrophicus show that changes in LSE are able to fully account for the intermediate stability of AK(MAR) and highlights a general mechanism for protein adaptation in this class of enzymes.
古生菌甲烷八叠球菌(AK(MAR))三聚体腺苷酸激酶的结构已解析至 2.5-A 分辨率,并测量了酶的温度依赖性稳定性和动力学。AK(MAR)的 K(M)和 V(max)在 30 度至 60 度之间仅表现出适度的温度依赖性。尽管甲烷八叠球菌是一种最适生长温度为 43 度的中温生物,但 AK(MAR)具有非常广泛的功能范围和稳定性(T(m)= 74.0 度),这更符合具有高热稳定性和在很宽温度范围内具有异常活性的嗜热酶,表明该微生物可能最近才侵入中温小生境,尚未完全适应。将 AK(MAR)与中温生物甲烷球菌和嗜热生物嗜热甲烷球菌的相关腺苷酸激酶的局部结构熵(LSE)进行比较表明,LSE 的变化能够完全解释 AK(MAR)的中间稳定性,并突出了该酶类中蛋白质适应的一般机制。
