TY - JOUR
T1 - Improving the activity and thermostability of GH2 β-glucuronidases via domain reassembly
AU - Liu, Mingzhu
AU - Yu, Jing
AU - Lv, Bo
AU - Hou, Yuhui
AU - Liu, Xinhe
AU - Feng, Xudong
AU - Li, Chun
N1 - Publisher Copyright:
© 2021 Wiley Periodicals LLC
PY - 2021/5
Y1 - 2021/5
N2 - Glycoside hydrolase family 2 (GH2) enzymes are generally composed of three domains: TIM-barrel domain (TIM), immunoglobulin-like β-sandwich domain (ISD), and sugar-binding domain (SBD). The combination of these three domains yields multiple structural combinations with different properties. Theoretically, the drawbacks of a given GH2 fold may be circumvented by efficiently reassembling the three domains. However, very few successful cases have been reported. In this study, we used six GH2 β-glucuronidases (GUSs) from bacteria, fungi, or humans as model enzymes and constructed a series of mutants by reassembling the domains from different GUSs. The mutants PGUS-At, GUS-PAA, and GUS-PAP, with reassembled domains from fungal GUSs, showed improved expression levels, activity, and thermostability, respectively. Specifically, compared to the parental enzyme, the mutant PGUS-At displayed 3.8 times higher expression, the mutant GUS-PAA displayed 1.0 time higher catalytic efficiency (kcat/Km), and the mutant GUS-PAP displayed 7.5 times higher thermostability at 65°C. Furthermore, two-hybrid mutants, GUS-AEA and GUS-PEP, were constructed with the ISD from a bacterial GUS and SBD and TIM domain from fungal GUSs. GUS-AEA and GUS-PEP showed 30.4% and 23.0% higher thermostability than GUS-PAP, respectively. Finally, molecular dynamics simulations were conducted to uncover the molecular reasons for the increased thermostability of the mutant.
AB - Glycoside hydrolase family 2 (GH2) enzymes are generally composed of three domains: TIM-barrel domain (TIM), immunoglobulin-like β-sandwich domain (ISD), and sugar-binding domain (SBD). The combination of these three domains yields multiple structural combinations with different properties. Theoretically, the drawbacks of a given GH2 fold may be circumvented by efficiently reassembling the three domains. However, very few successful cases have been reported. In this study, we used six GH2 β-glucuronidases (GUSs) from bacteria, fungi, or humans as model enzymes and constructed a series of mutants by reassembling the domains from different GUSs. The mutants PGUS-At, GUS-PAA, and GUS-PAP, with reassembled domains from fungal GUSs, showed improved expression levels, activity, and thermostability, respectively. Specifically, compared to the parental enzyme, the mutant PGUS-At displayed 3.8 times higher expression, the mutant GUS-PAA displayed 1.0 time higher catalytic efficiency (kcat/Km), and the mutant GUS-PAP displayed 7.5 times higher thermostability at 65°C. Furthermore, two-hybrid mutants, GUS-AEA and GUS-PEP, were constructed with the ISD from a bacterial GUS and SBD and TIM domain from fungal GUSs. GUS-AEA and GUS-PEP showed 30.4% and 23.0% higher thermostability than GUS-PAP, respectively. Finally, molecular dynamics simulations were conducted to uncover the molecular reasons for the increased thermostability of the mutant.
KW - MD simulation
KW - glycoside hydrolase family 2
KW - protein engineering
KW - reassembly of domains
KW - β-glucuronidase
UR - http://www.scopus.com/inward/record.url?scp=85100983882&partnerID=8YFLogxK
U2 - 10.1002/bit.27710
DO - 10.1002/bit.27710
M3 - Article
C2 - 33559890
AN - SCOPUS:85100983882
SN - 0006-3592
VL - 118
SP - 1962
EP - 1972
JO - Biotechnology and Bioengineering
JF - Biotechnology and Bioengineering
IS - 5
ER -