A single mutation Gln142Lys doubles the catalytic activity of VPR, a cold adapted subtilisin-like serine proteinase

Kristinn R. Óskarsson; Mads Nygaard; Brynjar Ellertsson; Sigríður H. Thorbjarnardottir; Elena Papaleo; Magnús M. Kristjánsson

doi:10.1016/j.bbapap.2016.07.003

A single mutation Gln142Lys doubles the catalytic activity of VPR, a cold adapted subtilisin-like serine proteinase

Kristinn R. Óskarsson
, Mads Nygaard
, Brynjar Ellertsson
, Sigríður H. Thorbjarnardottir
, Elena Papaleo
, Magnús M. Kristjánsson

University of Iceland

Research output: Contribution to journal › Article › peer-review

Abstract

Structural comparisons of the cold adapted subtilase VPR and its thermophilic homologue, aqualysin I (AQUI) indicated the presence of additional salt bridges in the latter. Few of those appear to contribute significantly to thermal stability of AQUI. This includes a putative salt bridge between residues Lys142 and Glu172 as its deletion did not have any significant effect on its stability or activity (Jónsdóttir et al. (2014)). Insertion of this putative salt bridge into the structure of VPR, in a double mutant (VPRΔC_Q142K/S172E), however was detrimental to the stability of the enzyme. Incorporation of either the Q142K or S172E mutations into VPR, were found to significantly affect the catalytic properties of the enzyme. The single mutation Q142K was highly effective, as it increased the k_cat and k_cat/K_m more than twofold. When the Q142K mutation was inserted into a thermostabilized, but a low activity mutant of VPR (VPRΔC_N3P/I5P), the activity increased about tenfold in terms of k_cat and k_cat/K_m, while retaining the stability of the mutant. Molecular dynamics simulations of the single mutants were carried out to provide structural rationale for these experimental observations. Based on root mean square fluctuation (RMSF) profiles, the two mutants were more flexible in certain regions of the structure and the Q142K mutant had the highest overall flexibility of the three enzymes. The results suggest that weakening of specific H-bonds resulting from the mutations may be propagated over some distance giving rise to higher flexibility in the active site regions of the enzyme, causing higher catalytic activity in the mutants.

Original language	English
Pages (from-to)	1436-1443
Number of pages	8
Journal	Biochimica et Biophysica Acta - Proteins and Proteomics
Volume	1864
Issue number	10
DOIs	https://doi.org/10.1016/j.bbapap.2016.07.003
Publication status	Published - 1 Oct 2016

Bibliographical note

Funding Information: EP has been supported by ISCRA-CINECA HPC grants sb-AQUI-HP10CN2H3L and NetDyn-HP10C2TOOC on Galileo and the PRACE-3IP project ( FP7 RI-312763 ) resource Chimera based in Poland with the DECI-11th DyNet project. The authors also would like to thank Prof. Hannes Jonsson for providing access to the Sol cluster at the Science Institute of the University of Iceland, where part of the simulations were carried out. We also thank Jóhanna Arnórsdóttir for helpful discussions and Sophie Tschirner for technical assistance in parts of this project. This work was supported by the University of Iceland Research Fund. Publisher Copyright: © 2016 Elsevier B.V.

Other keywords

Flexibility
Molecular dynamics
Protease
Subtilase
Temperature adaptation
Thermophilic

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10.1016/j.bbapap.2016.07.003

Cite this

@article{6d0c641502f3419b8eac176522c202c6,

title = "A single mutation Gln142Lys doubles the catalytic activity of VPR, a cold adapted subtilisin-like serine proteinase",

abstract = "Structural comparisons of the cold adapted subtilase VPR and its thermophilic homologue, aqualysin I (AQUI) indicated the presence of additional salt bridges in the latter. Few of those appear to contribute significantly to thermal stability of AQUI. This includes a putative salt bridge between residues Lys142 and Glu172 as its deletion did not have any significant effect on its stability or activity (J{\'o}nsd{\'o}ttir et al. (2014)). Insertion of this putative salt bridge into the structure of VPR, in a double mutant (VPRΔC\_Q142K/S172E), however was detrimental to the stability of the enzyme. Incorporation of either the Q142K or S172E mutations into VPR, were found to significantly affect the catalytic properties of the enzyme. The single mutation Q142K was highly effective, as it increased the kcat and kcat/Km more than twofold. When the Q142K mutation was inserted into a thermostabilized, but a low activity mutant of VPR (VPRΔC\_N3P/I5P), the activity increased about tenfold in terms of kcat and kcat/Km, while retaining the stability of the mutant. Molecular dynamics simulations of the single mutants were carried out to provide structural rationale for these experimental observations. Based on root mean square fluctuation (RMSF) profiles, the two mutants were more flexible in certain regions of the structure and the Q142K mutant had the highest overall flexibility of the three enzymes. The results suggest that weakening of specific H-bonds resulting from the mutations may be propagated over some distance giving rise to higher flexibility in the active site regions of the enzyme, causing higher catalytic activity in the mutants.",

keywords = "Flexibility, Molecular dynamics, Protease, Subtilase, Temperature adaptation, Thermophilic",

author = "{\'O}skarsson, \{Kristinn R.\} and Mads Nygaard and Brynjar Ellertsson and Thorbjarnardottir, \{Sigr{\'i}{\dh}ur H.\} and Elena Papaleo and Kristj{\'a}nsson, \{Magn{\'u}s M.\}",

note = "Funding Information: EP has been supported by ISCRA-CINECA HPC grants sb-AQUI-HP10CN2H3L and NetDyn-HP10C2TOOC on Galileo and the PRACE-3IP project ( FP7 RI-312763 ) resource Chimera based in Poland with the DECI-11th DyNet project. The authors also would like to thank Prof. Hannes Jonsson for providing access to the Sol cluster at the Science Institute of the University of Iceland, where part of the simulations were carried out. We also thank J{\'o}hanna Arn{\'o}rsd{\'o}ttir for helpful discussions and Sophie Tschirner for technical assistance in parts of this project. This work was supported by the University of Iceland Research Fund. Publisher Copyright: {\textcopyright} 2016 Elsevier B.V.",

year = "2016",

month = oct,

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doi = "10.1016/j.bbapap.2016.07.003",

language = "English",

volume = "1864",

pages = "1436--1443",

journal = "Biochimica et Biophysica Acta - Proteins and Proteomics",

issn = "1570-9639",

publisher = "Elsevier B.V.",

number = "10",

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TY - JOUR

T1 - A single mutation Gln142Lys doubles the catalytic activity of VPR, a cold adapted subtilisin-like serine proteinase

AU - Óskarsson, Kristinn R.

AU - Nygaard, Mads

AU - Ellertsson, Brynjar

AU - Thorbjarnardottir, Sigríður H.

AU - Papaleo, Elena

AU - Kristjánsson, Magnús M.

N1 - Funding Information: EP has been supported by ISCRA-CINECA HPC grants sb-AQUI-HP10CN2H3L and NetDyn-HP10C2TOOC on Galileo and the PRACE-3IP project ( FP7 RI-312763 ) resource Chimera based in Poland with the DECI-11th DyNet project. The authors also would like to thank Prof. Hannes Jonsson for providing access to the Sol cluster at the Science Institute of the University of Iceland, where part of the simulations were carried out. We also thank Jóhanna Arnórsdóttir for helpful discussions and Sophie Tschirner for technical assistance in parts of this project. This work was supported by the University of Iceland Research Fund. Publisher Copyright: © 2016 Elsevier B.V.

PY - 2016/10/1

Y1 - 2016/10/1

N2 - Structural comparisons of the cold adapted subtilase VPR and its thermophilic homologue, aqualysin I (AQUI) indicated the presence of additional salt bridges in the latter. Few of those appear to contribute significantly to thermal stability of AQUI. This includes a putative salt bridge between residues Lys142 and Glu172 as its deletion did not have any significant effect on its stability or activity (Jónsdóttir et al. (2014)). Insertion of this putative salt bridge into the structure of VPR, in a double mutant (VPRΔC_Q142K/S172E), however was detrimental to the stability of the enzyme. Incorporation of either the Q142K or S172E mutations into VPR, were found to significantly affect the catalytic properties of the enzyme. The single mutation Q142K was highly effective, as it increased the kcat and kcat/Km more than twofold. When the Q142K mutation was inserted into a thermostabilized, but a low activity mutant of VPR (VPRΔC_N3P/I5P), the activity increased about tenfold in terms of kcat and kcat/Km, while retaining the stability of the mutant. Molecular dynamics simulations of the single mutants were carried out to provide structural rationale for these experimental observations. Based on root mean square fluctuation (RMSF) profiles, the two mutants were more flexible in certain regions of the structure and the Q142K mutant had the highest overall flexibility of the three enzymes. The results suggest that weakening of specific H-bonds resulting from the mutations may be propagated over some distance giving rise to higher flexibility in the active site regions of the enzyme, causing higher catalytic activity in the mutants.

AB - Structural comparisons of the cold adapted subtilase VPR and its thermophilic homologue, aqualysin I (AQUI) indicated the presence of additional salt bridges in the latter. Few of those appear to contribute significantly to thermal stability of AQUI. This includes a putative salt bridge between residues Lys142 and Glu172 as its deletion did not have any significant effect on its stability or activity (Jónsdóttir et al. (2014)). Insertion of this putative salt bridge into the structure of VPR, in a double mutant (VPRΔC_Q142K/S172E), however was detrimental to the stability of the enzyme. Incorporation of either the Q142K or S172E mutations into VPR, were found to significantly affect the catalytic properties of the enzyme. The single mutation Q142K was highly effective, as it increased the kcat and kcat/Km more than twofold. When the Q142K mutation was inserted into a thermostabilized, but a low activity mutant of VPR (VPRΔC_N3P/I5P), the activity increased about tenfold in terms of kcat and kcat/Km, while retaining the stability of the mutant. Molecular dynamics simulations of the single mutants were carried out to provide structural rationale for these experimental observations. Based on root mean square fluctuation (RMSF) profiles, the two mutants were more flexible in certain regions of the structure and the Q142K mutant had the highest overall flexibility of the three enzymes. The results suggest that weakening of specific H-bonds resulting from the mutations may be propagated over some distance giving rise to higher flexibility in the active site regions of the enzyme, causing higher catalytic activity in the mutants.

KW - Flexibility

KW - Molecular dynamics

KW - Protease

KW - Subtilase

KW - Temperature adaptation

KW - Thermophilic

UR - https://www.scopus.com/pages/publications/84980370572

U2 - 10.1016/j.bbapap.2016.07.003

DO - 10.1016/j.bbapap.2016.07.003

M3 - Article

C2 - 27456266

SN - 1570-9639

VL - 1864

SP - 1436

EP - 1443

JO - Biochimica et Biophysica Acta - Proteins and Proteomics

JF - Biochimica et Biophysica Acta - Proteins and Proteomics

IS - 10

ER -

A single mutation Gln142Lys doubles the catalytic activity of VPR, a cold adapted subtilisin-like serine proteinase

Abstract

Bibliographical note

Other keywords

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