The Role of Conserved Residues in the DEDDh Motif: the Proton-Transfer Mechanism of HIV-1 RNase H

Dürr, Simon; Bohuszewicz, Olga; Berta, Dénes; Suardíaz, Reynier; Jambrina, Pablo G.; Peter, Christine; Shao, Yihan; Rosta, Edina

doi:10.1021/acscatal.1c01493

Cited by 18 publications

(18 citation statements)

References 77 publications

(276 reference statements)

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“…They obtained an activation barrier energy of 15.5 kcal mol –1 for the rate-determining step, in agreement with experimental data. Using DFT (B3LYP) and CHARMM 27 force field, Dürr et al 76 conducted a series of extensive QM/MM calculations combined with Hamiltonian replica exchange to elucidate the RNA cleavage mechanism of HIV-1 “RNase H”. They found an overall reaction barrier of ∼19 kcal mol –1 , associated with the phosphate-cleavage step, which matches the experimental rate.…”

Section: Resultsmentioning

confidence: 99%

QM/MM Well-Tempered Metadynamics Study of the Mechanism of XBP1 mRNA Cleavage by Inositol Requiring Enzyme 1α RNase

Mahdizadeh

Pålsson

Carlesso

et al. 2022

J. Chem. Inf. Model.

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A range of in silico methodologies were herein employed to study the unconventional XBP1 mRNA cleavage mechanism performed by the unfolded protein response (UPR) mediator Inositol Requiring Enzyme 1α (IRE1). Using Protein–RNA molecular docking along with a series of extensive restrained/unrestrained atomistic molecular dynamics (MD) simulations, the dynamical behavior of the system was evaluated and a reliable model of the IRE1/XBP1 mRNA complex was constructed. From a series of well-converged quantum mechanics molecular mechanics well-tempered metadynamics (QM/MM WT-MetaD) simulations using the Grimme dispersion interaction corrected semiempirical parametrization method 6 level of theory (PM6-D3) and the AMBER14SB-OL3 force field, the free energy profile of the cleavage mechanism was determined, along with intermediates and transition state structures. The results show two distinct reaction paths based on general acid–general base type mechanisms, with different activation energies that perfectly match observations from experimental mutagenesis data. The study brings unique atomistic insights into the cleavage mechanism of XBP1 mRNA by IRE1 and clarifies the roles of the catalytic residues H910 and Y892. Increased understanding of the details in UPR signaling can assist in the development of new therapeutic agents for its modulation.

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Section: Resultsmentioning

confidence: 99%

QM/MM Well-Tempered Metadynamics Study of the Mechanism of XBP1 mRNA Cleavage by Inositol Requiring Enzyme 1α RNase

Mahdizadeh

Pålsson

Carlesso

et al. 2022

J. Chem. Inf. Model.

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“…Information about conserved residues has sometimes been helpful in the search for enzyme reaction mechanisms; , however, to our knowledge, there has not yet been an attempt in the literature to verify alternative enzyme reaction mechanism variants by the systematic matching of all conserved amino acids with CFs.…”

Section: Resultsmentioning

confidence: 99%

“…This indicates the significant flexibility of charged side chains already reported in other related studies, 30−32 which will also be extensively explored in this work. Information about conserved residues has sometimes been helpful in the search for enzyme reaction mechanisms; 38,39 however, to our knowledge, there has not yet been an attempt in the literature to verify alternative enzyme reaction mechanism variants by the systematic matching of all conserved amino acids with CFs.…”

Section: ■ Methodsmentioning

confidence: 99%

Catalytic Fields as a Tool to Analyze Enzyme Reaction Mechanism Variants and Reaction Steps

2021

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Catalytic fields representing the topology of the optimal molecular environment charge distribution that reduces the activation barrier have been used to examine alternative reaction variants and to determine the role of conserved catalytic residues for two consecutive reactions catalyzed by the same enzyme. Until now, most experimental and conventional top-down theoretical studies employing QM/MM or ONIOM methods have focused on the role of enzyme electric fields acting on broken bonds of reactants. In contrast, our bottom-up approach dealing with a small reactant and transition-state model allows the analysis of the opposite effects: how the catalytic field resulting from the charge redistribution during the enzyme reaction acts on conserved amino acid residues and contributes to the reduction of the activation barrier. This approach has been applied to the family of histidyl tRNA synthetases involved in the translation of the genetic code into the protein amino acid sequence. Activation energy changes related to conserved charged amino acid residues for 12 histidyl tRNA synthetases from different biological species allowed to compare on equal footing the catalytic residues involved in ATP aminoacylation and tRNA charging reactions and to analyze different reaction mechanisms proposed in the literature. A scan of the library of atomic multipoles for amino acid side-chain rotamers within the catalytic field pointed out the change in the Glu83 conformation as the critical catalytic effect, providing, at low computational cost, insight into the electrostatic preorganization of the enzyme catalytic site at a level of detail that has not yet been accessible in conventional experimental or theoretical methods. This opens the way for rational reverse biocatalyst design at a very limited computational cost without resorting to empirical methods.

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“…However, due to their high computational cost, the routine application of the ai-QM/MM potentials is often limited to minimum energy pathway (MEP) calculations, where only O(10 2 ) QM/MM energy/force calculations are required to optimize each point along a discretized reaction pathway. Less common is the direct employment of ai-QM/MM models in the minimum free energy a) Electronic mail: jpu@iupui.edu b) Electronic mail: kwangho.nam@uta.edu c) Electronic mail: yihan.shao@ou.edu pathway (MFEP) simulations, [21][22][23][24][25][26][27][28][29][30] which typically involve O (10 4 ) QM/MM energy/force calculations to sample each point/window along the free energy pathway and thus require hundreds of thousands (if not millions) of computer core-hours. Consequently, direct QM/MM MFEP simulation often resort to less-accurate semiempirical QM/MM (se-QM/MM) Hamiltonians based on AM1, 31 PM3, 32 PM6, 33 or tight-binding DFT [34][35][36][37] methods.…”

Section: Introductionmentioning

confidence: 99%

Accelerating ab initio QM/MM Molecular Dynamics Simulations with Multiple Time Step Integration and a Recalibrated Semi-empirical QM/MM Hamiltonian

Pan

Van

Epifanovsky

et al. 2022

Preprint

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Molecular dynamics (MD) simulations employing ab initio quantum mechanical and molecular mechanical (ai-QM/MM) potentials are considered to be the state of the art, but the high computational cost associated with the ai-QM calculations remains a theoretical challenge for their routine application. Here, we present a modified protocol of Multiple Time Step (MTS) method to accelerate ai-QM/MM MD simulations of condensed-phase reactions. Within a previous MTS protocol [Nam, J. Chem. Theory Comput., 2014, 10, 2175], reference forces are evaluated using a low-level (semi-empirical QM/MM) Hamiltonian and employed at inner time steps to propagate the nuclear motions. Correction forces, which arise from the force differences between high-level (ai-QM/MM) and low-level Hamiltonians, are applied at outer time steps, where the MTS algorithm allows the time-reversible integration of the correction forces. To increase the outer step size, which is bound by the highest-frequency component in the correction forces, the semi-empirical QM Hamiltonian is re-calibrated in this work to minimize the magnitude of the correction forces. The remaining high frequency modes, which are mainly bond stretches involving hydrogen atoms, are then removed from the correction forces. When combined with Langevin or SIN(R) thermostat, the modified MTS-QM/MM scheme remains robust with an up to 8 fs (with Langevin) or 10 fs (with SIN(R)) outer time step (with 1 fs inner time steps) for the chorismate mutase system. This leads to an over 5-fold speedup over standard ai-QM/MM simulations, without sacrificing the accuracy in the predicted free energy profile of the reaction.

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The Role of Conserved Residues in the DEDDh Motif: the Proton-Transfer Mechanism of HIV-1 RNase H

Cited by 18 publications

References 77 publications

QM/MM Well-Tempered Metadynamics Study of the Mechanism of XBP1 mRNA Cleavage by Inositol Requiring Enzyme 1α RNase

QM/MM Well-Tempered Metadynamics Study of the Mechanism of XBP1 mRNA Cleavage by Inositol Requiring Enzyme 1α RNase

Catalytic Fields as a Tool to Analyze Enzyme Reaction Mechanism Variants and Reaction Steps

Accelerating ab initio QM/MM Molecular Dynamics Simulations with Multiple Time Step Integration and a Recalibrated Semi-empirical QM/MM Hamiltonian

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