Efficient calculation of enzyme reaction free energy profiles using a hybrid differential relaxation algorithm: Application to mycobacterial zinc hydrolases

Determination of the free energy profile for an enzyme reaction mechanism is of primordial relevance, paving the way for our understanding of the enzyme's catalytic power at the molecular level. Although hybrid, mostly DFT-based, QM/MM methods have been extensively applied to this type of studi...

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Detalles Bibliográficos
Autores principales: Romero, J.M., Martin, M., Ramirez, C.L., Dumas, V.G., Marti, M.A., Karabencheva-Christova T.
Formato: SER
Materias:
Free energy
HyDRA
Jarzynski's relationship
M. tuberculosis
MshB
QM/MM
Rv1170
Rv3717
Zn hydrolases
amidase
amide
carbonyl derivative
hydrolase
hydroxide
MA amidase
MshB enzyme
unclassified drug
zinc ion
bacterial protein
divalent cation
n acetylmuramoylalanine amidase
N-acetyl-1-D-inosityl-2-amino-2-deoxy-alpha-D-glucopyranoside deacetylase
proton
water
zinc
algorithm
catalysis
Conference Paper
crystal structure
enzyme analysis
human
Mycobacterium tuberculosis
nonhuman
priority journal
proton transport
reaction analysis
tuberculosis
biocatalysis
chemistry
enzymology
molecular dynamics
protein secondary structure
protein tertiary structure
quantum theory
species difference
thermodynamics
Algorithms
Amidohydrolases
Bacterial Proteins
Biocatalysis
Cations, Divalent
Humans
Molecular Dynamics Simulation
N-Acetylmuramoyl-L-alanine Amidase
Protein Structure, Secondary
Protein Structure, Tertiary
Protons
Quantum Theory
Species Specificity
Thermodynamics
Water
Zinc
Acceso en línea:http://hdl.handle.net/20.500.12110/paper_18761623_v100_n_p33_Romero
Aporte de:
Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires
Descripción
Sumario:Determination of the free energy profile for an enzyme reaction mechanism is of primordial relevance, paving the way for our understanding of the enzyme's catalytic power at the molecular level. Although hybrid, mostly DFT-based, QM/MM methods have been extensively applied to this type of studies, achieving accurate and statistically converged results at a moderate computational cost is still an open challenge. Recently, we have shown that accurate results can be achieved in less computational time, combining Jarzynski's relationship with a hybrid differential relaxation algorithm (HyDRA), which allows partial relaxation of the solvent during the nonequilibrium steering of the reaction. In this work, we have applied this strategy to study two mycobacterial zinc hydrolases. Mycobacterium tuberculosis infections are still a worldwide problem and thus characterization and validation of new drug targets is an intense field of research. Among possible drug targets, recently two essential zinc hydrolases, MshB (Rv1170) and MA-amidase (Rv3717), have been proposed and structurally characterized. Although possible mechanisms have been proposed by analogy to the widely studied human Zn hydrolases, several key issues, particularly those related to Zn coordination sphere and its role in catalysis, remained unanswered. Our results show that mycobacterial Zn hydrolases share a basic two-step mechanism. First, the attacking water becomes deprotonated by the conserved base and establishes the new C-O bond leading to a tetrahedral intermediate. The intermediate requires moderate reorganization to allow for proton transfer to the amide N and C-N bond breaking to occur in the second step. Zn ion plays a key role in stabilizing the tetrahedral intermediate and balancing the negative charge of the substrate during hydroxide ion attack. Finally, comparative analysis of other Zn hydrolases points to a convergent mechanistic evolution. © 2015 Elsevier Inc. All rights reserved.

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