Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases

Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases

Abstract Background Esterases and lipases hydrolyze short-chain esters and long-chain triglycerides, respectively, and therefore play essential roles in the synthesis and decomposition of ester bonds in the pharmaceutical and food industries. Many SGNH family esterases share high similarity in seque...

Full description

Bibliographic Details
Main Authors: Zhengyang Li, Long Li, Yingyi Huo, Zijun Chen, Yu Zhao, Jing Huang, Shuling Jian, Zhen Rong, Di Wu, Jianhua Gan, Xiaojian Hu, Jixi Li, Xue-Wei Xu
Format: Article
Language:English
Published: BMC 2020-06-01
Series:Biotechnology for Biofuels
Subjects:
Esterase
SGNH superfamily
Swapped structure
Alkaline adaptability
Online Access:http://link.springer.com/article/10.1186/s13068-020-01742-8
id doaj-472f3f9343b641e38d21cb6d3da94de3
record_format Article
collection DOAJ
language English
format Article
sources DOAJ
author Zhengyang Li
Long Li
Yingyi Huo
Zijun Chen
Yu Zhao
Jing Huang
Shuling Jian
Zhen Rong
Di Wu
Jianhua Gan
Xiaojian Hu
Jixi Li
Xue-Wei Xu
spellingShingle Zhengyang Li
Long Li
Yingyi Huo
Zijun Chen
Yu Zhao
Jing Huang
Shuling Jian
Zhen Rong
Di Wu
Jianhua Gan
Xiaojian Hu
Jixi Li
Xue-Wei Xu
Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
Biotechnology for Biofuels
Esterase
SGNH superfamily
Swapped structure
Alkaline adaptability
author_facet Zhengyang Li
Long Li
Yingyi Huo
Zijun Chen
Yu Zhao
Jing Huang
Shuling Jian
Zhen Rong
Di Wu
Jianhua Gan
Xiaojian Hu
Jixi Li
Xue-Wei Xu
author_sort Zhengyang Li
title Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
title_short Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
title_full Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
title_fullStr Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
title_full_unstemmed Structure-guided protein engineering increases enzymatic activities of the SGNH family esterases
title_sort structure-guided protein engineering increases enzymatic activities of the sgnh family esterases
publisher BMC
series Biotechnology for Biofuels
issn 1754-6834
publishDate 2020-06-01
description Abstract Background Esterases and lipases hydrolyze short-chain esters and long-chain triglycerides, respectively, and therefore play essential roles in the synthesis and decomposition of ester bonds in the pharmaceutical and food industries. Many SGNH family esterases share high similarity in sequences. However, they have distinct enzymatic activities toward the same substrates. Due to a lack of structural information, the detailed catalytic mechanisms of these esterases remain barely investigated. Results In this study, we identified two SGNH family esterases, CrmE10 and AlinE4, from marine bacteria with significantly different preferences for pH, temperature, metal ion, and organic solvent tolerance despite high sequence similarity. The crystal structures of these two esterases, including wild type and mutants, were determined to high resolutions ranging from 1.18 Å to 2.24 Å. Both CrmE10 and AlinE4 were composed of five β-strands and nine α-helices, which formed one compact N-terminal α/β globular domain and one extended C-terminal domain. The aspartic residues (D178 in CrmE10/D162 in AlinE4) destabilized the conformations of the catalytic triad (Ser-Asp-His) in both esterases, and the metal ion Cd2+ might reduce enzymatic activity by blocking proton transfer or substrate binding. CrmE10 and AlinE4 showed distinctly different electrostatic surface potentials, despite the similar atomic architectures and a similar swap catalytic mechanism. When five negatively charged residues (Asp or Glu) were mutated to residue Lys, CrmE10 obtained elevated alkaline adaptability and significantly increased the enzymatic activity from 0 to 20% at pH 10.5. Also, CrmE10 mutants exhibited dramatic change for enzymatic properties when compared with the wide-type enzyme. Conclusions These findings offer a perspective for understanding the catalytic mechanism of different esterases and might facilitate the industrial biocatalytic applications.
topic Esterase
SGNH superfamily
Swapped structure
Alkaline adaptability
url http://link.springer.com/article/10.1186/s13068-020-01742-8
work_keys_str_mv AT zhengyangli structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT longli structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT yingyihuo structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT zijunchen structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT yuzhao structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT jinghuang structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT shulingjian structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT zhenrong structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT diwu structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT jianhuagan structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT xiaojianhu structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT jixili structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
AT xueweixu structureguidedproteinengineeringincreasesenzymaticactivitiesofthesgnhfamilyesterases
_version_ 1724667430428475392
spelling doaj-472f3f9343b641e38d21cb6d3da94de32020-11-25T03:08:06ZengBMCBiotechnology for Biofuels1754-68342020-06-0113111410.1186/s13068-020-01742-8Structure-guided protein engineering increases enzymatic activities of the SGNH family esterasesZhengyang Li0Long Li1Yingyi Huo2Zijun Chen3Yu Zhao4Jing Huang5Shuling Jian6Zhen Rong7Di Wu8Jianhua Gan9Xiaojian Hu10Jixi Li11Xue-Wei Xu12State Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityKey Laboratory of Marine Ecosystem Dynamics, Ministry of Natural Resources, Ministry of Natural Resources & Second Institute of OceanographyState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityKey Laboratory of Marine Ecosystem Dynamics, Ministry of Natural Resources, Ministry of Natural Resources & Second Institute of OceanographyKey Laboratory of Marine Ecosystem Dynamics, Ministry of Natural Resources, Ministry of Natural Resources & Second Institute of OceanographyState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityState Key Laboratory of Genetic Engineering, School of Life Sciences, MOE Engineering Research Center of Gene Technology, Shanghai Engineering Research Center of Industrial Microorganisms, Fudan UniversityKey Laboratory of Marine Ecosystem Dynamics, Ministry of Natural Resources, Ministry of Natural Resources & Second Institute of OceanographyAbstract Background Esterases and lipases hydrolyze short-chain esters and long-chain triglycerides, respectively, and therefore play essential roles in the synthesis and decomposition of ester bonds in the pharmaceutical and food industries. Many SGNH family esterases share high similarity in sequences. However, they have distinct enzymatic activities toward the same substrates. Due to a lack of structural information, the detailed catalytic mechanisms of these esterases remain barely investigated. Results In this study, we identified two SGNH family esterases, CrmE10 and AlinE4, from marine bacteria with significantly different preferences for pH, temperature, metal ion, and organic solvent tolerance despite high sequence similarity. The crystal structures of these two esterases, including wild type and mutants, were determined to high resolutions ranging from 1.18 Å to 2.24 Å. Both CrmE10 and AlinE4 were composed of five β-strands and nine α-helices, which formed one compact N-terminal α/β globular domain and one extended C-terminal domain. The aspartic residues (D178 in CrmE10/D162 in AlinE4) destabilized the conformations of the catalytic triad (Ser-Asp-His) in both esterases, and the metal ion Cd2+ might reduce enzymatic activity by blocking proton transfer or substrate binding. CrmE10 and AlinE4 showed distinctly different electrostatic surface potentials, despite the similar atomic architectures and a similar swap catalytic mechanism. When five negatively charged residues (Asp or Glu) were mutated to residue Lys, CrmE10 obtained elevated alkaline adaptability and significantly increased the enzymatic activity from 0 to 20% at pH 10.5. Also, CrmE10 mutants exhibited dramatic change for enzymatic properties when compared with the wide-type enzyme. Conclusions These findings offer a perspective for understanding the catalytic mechanism of different esterases and might facilitate the industrial biocatalytic applications.http://link.springer.com/article/10.1186/s13068-020-01742-8EsteraseSGNH superfamilySwapped structureAlkaline adaptability

Similar Items