Insights into the role of electrostatics in temperature adaptation: a comparative study of psychrophilic, mesophilic, and thermophilic subtilisin-like serine proteases

Yuan-Ling Xia; Jian-Hong Sun; Shi-Meng Ai; Yi Li; Xing Du; Peng Sang; Li-Quan Yang; Yun-Xin Fu; Shu-Qun Liu

doi:10.1039/c8ra05845h

Insights into the role of electrostatics in temperature adaptation: a comparative study of psychrophilic, mesophilic, and thermophilic subtilisin-like serine proteases

RSC Adv. 2018 Aug 22;8(52):29698-29713. doi: 10.1039/c8ra05845h. eCollection 2018 Aug 20.

Authors

Yuan-Ling Xia¹, Jian-Hong Sun¹, Shi-Meng Ai², Yi Li¹, Xing Du¹, Peng Sang³, Li-Quan Yang³, Yun-Xin Fu^{1

4}, Shu-Qun Liu^{1

5}

Affiliations

¹ State Key Laboratory for Conservation and Utilization of Bio-Resources in Yunnan, Yunnan University Kunming Yunnan P. R. China Yunxin.Fu@uth.tmc.edu shuqunliu@ynu.edu.com.
² Department of Applied Mathematics, Yunnan Agricultural University Kunming Yunnan P. R. China.
³ College of Agriculture and Biological Science, Dali University Dali Yunnan P. R. China.
⁴ Human Genetics Center and Division of Biostatistics, School of Public Health, The University of Texas Health Science Center Houston Texas USA.
⁵ Key Laboratory for Tumor Molecular Biology of High Education in Yunnan Province, School of Life Sciences, Yunnan University Kunming Yunnan P. R. China.

Abstract

To investigate the role of electrostatics in different temperature adaptations, we performed a comparative study on subtilisin-like serine proteases from psychrophilic Vibrio sp. PA-44 (VPR), mesophilic Engyodontium album (Tritirachium album) (PRK), and thermophilic Thermus aquaticus (AQN) using multiple-replica molecular dynamics (MD) simulations combined with continuum electrostatics calculations. The results reveal that although salt bridges are not a crucial factor in determining the overall thermostability of these three proteases, they on average provide the greatest, moderate, and least electrostatic stabilization to AQN, PRK, and VPR, respectively, at the respective organism growth temperatures. Most salt bridges in AQN are effectively stabilizing and thus contribute to maintaining the overall structural stability at 343 K, while nearly half of the salt bridges in VPR interconvert between being stabilizing and being destabilizing, likely aiding in enhancing the local conformational flexibility at 283 K. The individual salt bridges, salt-bridge networks, and calcium ions contribute differentially to local stability and flexibility of these three enzyme structures, depending on their spatial distributions and electrostatic strengths. The shared negatively charged surface potential at the active center of the three enzymes may provide the active-center flexibility necessary for nucleophilic attack and proton transfer. The differences in distributions of the electro-negative, electro-positive, and electro-neutral potentials, particularly over the back surfaces of the three proteases, may modulate/affect not only protein solubility and thermostability but also structural stability and flexibility/rigidity. These results demonstrate that electrostatics contributes to both heat and cold adaptation of subtilisin-like serine proteases through fine-tuning, either globally or locally, the structural stability and conformational flexibility/rigidity, thus providing a foundation for further engineering and mutagenesis studies.