Functional tuning of the catalytic residue pKa in a de novo designed esterase

ABSTRACT AlleyCatE is a de novo designed esterase that can be allosterically regulated by calcium ions. This artificial enzyme has been shown to hydrolyze p‐nitrophenyl acetate (pNPA) and 4‐nitrophenyl‐(2‐phenyl)‐propanoate (pNPP) with high catalytic efficiency. AlleyCatE was created by introducing...

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Published in:Proteins, structure, function, and bioinformatics structure, function, and bioinformatics, 2017-09, Vol.85 (9), p.1656-1665
Main Authors: Hiebler, Katharina, Lengyel, Zsófia, Castañeda, Carlos A., Makhlynets, Olga V.
Format: Article
Language:English
Subjects:
Acetic acid
Calcium
Calcium ions
Calcium-binding protein
Calmodulin
Catalysis
Computer applications
Efficiency
electrostatic potential
Electrostatic properties
Electrostatics
Empirical analysis
Enzymes
ester hydrolysis
Esterase
Histidine
Hydrophobicity
NMR
Nuclear magnetic resonance
p-Nitrophenylacetic acid
pH effects
pH rate profile
pKa of histidine
Proteins
Spectrometers
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container_issue 9
container_start_page 1656
container_title Proteins, structure, function, and bioinformatics
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creator Hiebler, Katharina
Lengyel, Zsófia
Castañeda, Carlos A.
Makhlynets, Olga V.
description ABSTRACT AlleyCatE is a de novo designed esterase that can be allosterically regulated by calcium ions. This artificial enzyme has been shown to hydrolyze p‐nitrophenyl acetate (pNPA) and 4‐nitrophenyl‐(2‐phenyl)‐propanoate (pNPP) with high catalytic efficiency. AlleyCatE was created by introducing a single‐histidine residue (His144) into a hydrophobic pocket of calmodulin. In this work, we explore the determinants of catalytic properties of AlleyCatE. We obtained the pKa value of the catalytic histidine using experimental measurements by NMR and pH rate profile and compared these values to those predicted from electrostatics pKa calculations (from both empirical and continuum electrostatics calculations). Surprisingly, the pKa value of the catalytic histidine inside the hydrophobic pocket of calmodulin is elevated as compared to the model compound pKa value of this residue in water. We determined that a short‐range favorable interaction with Glu127 contributes to the elevated pKa of His144. We have rationally modulated local electrostatic potential in AlleyCatE to decrease the pKa of its active nucleophile, His144, by 0.7 units. As a direct result of the decrease in the His144 pKa value, catalytic efficiency of the enzyme increased by 45% at pH 6. This work shows that a series of simple NMR experiments that can be performed using low field spectrometers, combined with straightforward computational analysis, provide rapid and accurate guidance to rationally improve catalytic efficiency of histidine‐promoted catalysis. Proteins 2017; 85:1656–1665. © 2017 Wiley Periodicals, Inc.
doi_str_mv 10.1002/prot.25321
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This artificial enzyme has been shown to hydrolyze p‐nitrophenyl acetate (pNPA) and 4‐nitrophenyl‐(2‐phenyl)‐propanoate (pNPP) with high catalytic efficiency. AlleyCatE was created by introducing a single‐histidine residue (His144) into a hydrophobic pocket of calmodulin. In this work, we explore the determinants of catalytic properties of AlleyCatE. We obtained the pKa value of the catalytic histidine using experimental measurements by NMR and pH rate profile and compared these values to those predicted from electrostatics pKa calculations (from both empirical and continuum electrostatics calculations). Surprisingly, the pKa value of the catalytic histidine inside the hydrophobic pocket of calmodulin is elevated as compared to the model compound pKa value of this residue in water. We determined that a short‐range favorable interaction with Glu127 contributes to the elevated pKa of His144. We have rationally modulated local electrostatic potential in AlleyCatE to decrease the pKa of its active nucleophile, His144, by 0.7 units. As a direct result of the decrease in the His144 pKa value, catalytic efficiency of the enzyme increased by 45% at pH 6. This work shows that a series of simple NMR experiments that can be performed using low field spectrometers, combined with straightforward computational analysis, provide rapid and accurate guidance to rationally improve catalytic efficiency of histidine‐promoted catalysis. 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source Wiley-Blackwell Read & Publish Collection
subjects Acetic acid
Calcium
Calcium ions
Calcium-binding protein
Calmodulin
Catalysis
Computer applications
Efficiency
electrostatic potential
Electrostatic properties
Electrostatics
Empirical analysis
Enzymes
ester hydrolysis
Esterase
Histidine
Hydrophobicity
NMR
Nuclear magnetic resonance
p-Nitrophenylacetic acid
pH effects
pH rate profile
pKa of histidine
Proteins
Spectrometers
title Functional tuning of the catalytic residue pKa in a de novo designed esterase
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