Understanding the Effect of Magnesium Ion Concentration on the Catalytic Activity of Ribonuclease H through Computation: Does a Third Metal Binding Site Modulate Endonuclease Catalysis?

Matteo Dal Peraro
2010
Article

Résumé

Ribonuclease H (RNase H) belongs to the nucleotidyl-transferase superfamily and hydrolyzes the phosphodiester linkage on the RNA strand of a DNA/RNA hybrid duplex. Due to its activity in HIV reverse transcription, it represents a promising target for anti-HIV drug design. While crystallographic data have located two ions in the catalytic site, there is ongoing debate concerning just how many metal ions bound at the active site are optimal for catalysis. Indeed, experiments have shown a dependency of the catalytic activity on the Mg2+ concentration. Moreover, in RNase H, the glutamate residue E188 has been shown to be essential for full enzymatic activation, regardless of the Mg2+ concentration. The catalytic center is known to contain two Mg2+ ions, and E188 is not one of the primary metal ligands. Herein, classical molecular dynamics (MD) simulations are employed to study the metal-ligand coordination in RNase H at different concentration of Mg2+. Importantly, the presence of a third Mg2+ ion, bound to the second-shell ligand E188, is a persistent feature of the MD simulations. Free energy calculations have identified two distinct conformations, depending on the concentration of Mg2+. At standard concentration, a third Mg2+ is found in the catalytic pocket, but it does not perturb the optimal RNase H active conformation. However, at higher concentration, the third Mg2+ ion heavily perturbs the nucleophilic water and thereby influences the catalytic efficiency of RNase H. In addition, the E188A mutant shows no ability to engage additional Mg2+ ions near the catalytic pocket. This finding likely explains the decrease in catalytic activity of E188A and also supports the key role of E188 in localizing the third Mg2+ ion at the active site. Glutamate residues are commonly found surrounding the metal center in the endonuclease family, which suggests that this structural motif may be an important feature to enhance catalytic activity. The present MD calculations support the hypothesis that RNase H can accommodate three divalent metal ions in its catalytic pocket and provide an in-depth understanding of their dynamic role for catalysis.

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https://infoscience.epfl.ch/record/172296?ln=fr

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Matteo Dal Peraro
2010
Article

Résumé

Official source

https://infoscience.epfl.ch/record/172296?ln=fr

À propos de ce résultat

Concepts associés (15)

Concepts associés

Chargement

Publications associées (38)

Publications associées

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Computational Studies of the Proton-Coupled Metal Ion Transport in the SLC11/NRAMP Family of Transporters

Maria Letizia Merlini

In the last years, it has been demonstrated a link between the overload of metal ions inside nervous system cells and the onset of severe neurodegenerative diseases. This prompted the investigation of the structural and functional properties of transporters responsible for the uptake and regulation of metal ions inside cells. In particular, members of the Nramp/SLC11 ("natural resistance-associated macrophage proteins"/"solute carrier 11") family of transporters tightly regulate the influx of divalent transition-metal ions across cellular membranes contributing to cellular homeostasis. In these secondary active transporters, the translocation of divalent transition metal ions from the extracellular matrix to the cellular cytoplasm is coupled to proton transport (symport). The co-transport is realized using an alternate access mechanism in which the protein is alternately open towards the extracellular matrix, ("outward facing conformation", OFC) or towards the cellular cytoplasm ("inward facing conformation", IFC).Although a wide range of functional and structural studies provided fundamental insights on the proton-coupled transport, most mechanistic details are still unknown. As an example, the coordination sphere of the metal ion in the inward-facing conformation of the protein has only been partially resolved by crystallographic experiments and later attempts to provide comprehensive descriptions led to contradictory models. Furthermore, several experimental evidence proved that proton uniport in the absence of the metal ion, is also possible, suggesting an unusual symporter behaviour for Nramps, in which the two substrates are not tightly coupled. Despite the recent advances in the comprehension of Nramps proton transport, the underlying mechanistic details remain still ambiguous, as demonstrated by inconsistent mechanistic models proposed during the last years.In this thesis, computational methods have been used in order to provide new molecular level insights in the proton-coupled divalent transition metal ions transport performed by Nramps. In particular, a combination of classical molecular dynamics (MD) and QM/MM ab initio MD methods have been applied in order to refine the partially resolved coordination sphere of Mn2+ in the active site of Staphylococcus Capitis Divalent Metal-ion Transporter (ScaDMT), representing the only available crystal structure of a substrate-bound member of the family in an IFC. This QM/MM multiscale approach, using an accurate quantum treatment of the active site and a classical treatment of the surroundings, allowed for state-of-the-art calculations of the entire system that led to the unequivocal identification of the metal's coordination sphere. Furthermore, MD simulations have been performed for both the IFC ScaDMT and Eremococcus Coleocola DMT (EcoDMT), whose crystal structure has been obtained in OFC. Since experimental evidences proved that proton transport can occur even in the absence of the metal ion substrate, we performed simulations of both proteins in their apo forms. These simulations allowed us to characterize four amino acidic residues identified as likely key players in the proton transport process and to determine which role they assume in the process. Finally, we were able to identify the likely primary proton acceptor and proposed a potential route followed by protons in their influx toward the intracellular cytoplasm.

EPFL2022

Chargement

Electrocatalysts play an important part on the route towards environmental friendly energy sources. They support modern technologies like fuel cells to move further away from the utilization of fossil fuels and the resulting CO2 emission into our atmosphere. The main principle of such energy conversion technologies is to store chemical energy within chemical bonds and to release it as electric energy to fulfill the energy demand of today's society. However energy conversion chemistry in such technologies requires catalysts in order to be effective by providing an alternative reaction pathway that lowers activation energies and maximizes the energy output. Providing suitable catalyst surfaces requires a fundamental knowledge of the interaction of reactants and reaction intermediates with the catalyst surfaces. This concern is addressed in this thesis by fabricating specifically tailored molecular components on metal surfaces, which act as organic/inorganic hybrid electrodes for various energy conversion reactions in electrocatalysis. Characterizing the electrode surface is crucial in order to identify active sites of the catalyst. The molecular structure is investigated by surface sensitive techniques, such as STM and XPS in combination with a home-build transfer system, which enables electrode fabrication in UHV and electrocatalytic experiments in a liquid environment. A detailed characterization of organic polymer components on electrode surfaces is obtained by combining experimental data with MD simulations. The morphology of polymer networks can be successfully mimicked and depending on the chemical composition and the structure, spatial correlations on short length scales are reported. Hybrid electrodes with organic polymer co-catalysts reveal an increased catalytic activity for the HER by providing suitable docking sites that act as catalytic active sites. Reactants and reaction intermediates are stabilized via hydrogen bonding, which results in a higher catalytic turnover. The specific designed structure of the organic co-catalyst helps to identify a fraction of the reaction mechanism and highlights the importance of molecular components in electrocatalysis. The utilization of organic units on electrocatalysts provides also an excellent opportunity in order to use single metal atoms as catalysts. Engineering large pi-systems has no significant impact on the ORR activity, while the distance between active sites and the underlying electrode are crucial for enhancing the catalytic activity. A significant factor in using molecular components in electrocatalysis is the stability of the organics. Using electrografting allows to design organic/inorganic hybrid electrodes with covalent bonds between the molecular component and the metal substrate. Attaching empty porphyrin molecules to substrates introduces a powerful technique in molecular engineering, since empty porphyrin cycles can be metallized with various metal centers that can act as electrocatalysts for different electrochemical reactions. In summary, this thesis provides multiple engineering aspects, which are useful in designing molecular components on metal electrodes for energy conversion. Such hybrid catalyst surfaces are capable of improving the catalytic activity and allow to study the mechanism of catalytic reactions. Implementing organic components provides new routes for tailoring novel materials, which deliver new insight into the complex field of electrocatalysis.

EPFL2020

Chargement

An integrative in silico methodology for the identification of modulators of macrophage migration inhibitory factor (MIF) tautomerase activity

Farah El Turk, Bruno Claude Daniel Fauvet, Hilal Lashuel, Hajer Ouertatani-Sakouhi

Macrophage migration inhibitory factor (MIF) is a major proinflammatory cytokine that has been increasingly implicated in the pathogenesis of several inflammatory, autoimmune, infectious and oncogenic diseases. Accumulating evidence suggests that the tautomerase activity of MIF plays a role in modulating some of its intra- and extra-cellular activities. Therefore, the identification and development of small-molecule inhibitors targeting the catalytic activity of MIF has emerged as an attractive and viable therapeutic strategy to attenuate its function in health and disease. Herein we report a novel virtual screening protocol for the discovery of new inhibitors of MIF's tautomerase activity. Our protocol takes into account the flexibility and dynamics of the catalytic site by coupling molecular dynamics (MD) simulations aimed at modeling the protein's flexibility in solution to (i) docking with FlexX, or (ii) docking with FlexX and pharmacophoric filtering with Unity. In addition, we applied in parallel a standalone docking using the new version of Surflex software. The three approaches were used to screen the ChemBridge chemical library and the inhibitory activity of the top-ranked 333 compound obtained from each approach (1000 compound in total) was assessed in vitro using the tautomerase assay. This biochemical validation process resulted in the identification of 12 novel MIF inhibitors corresponding to a 1.2% hit rate. Six of these hits came from Surflex docking; two from FlexX docking with MD simulations and four hits were identified with MDS and pharmacophore filtering with minimal overlap between the hits from each approach. Six hits were identified with IC50 values lower than 10 microM (three hits with IC50 lower than 1 microM); four were shown to be suicide inhibitors and act via covalent modification of the N-terminal catalytic residues Pro1. One additional inhibitor, N-phenyl-N-1,3,4-thiadiazol-2-yl-thiourea, (IC50=300 nM) was obtained from FlexX docking combined to pharmacophoric filtering on one of the eight MD structures. These results demonstrate the power of integrative in silico approaches in the discovery of new modulator of MIF's tautomerase activity. The chemical diversity and mode of action of these compounds suggest that they could be used as molecular probes to elucidate the functions and biology of MIF and as lead candidates in drug developments of anti-MIF drugs.

Elsevier2010

Chargement

Computational Studies of the Proton-Coupled Metal Ion Transport in the SLC11/NRAMP Family of Transporters

Maria Letizia Merlini

EPFL2022

An integrative in silico methodology for the identification of modulators of macrophage migration inhibitory factor (MIF) tautomerase activity

Farah El Turk, Bruno Claude Daniel Fauvet, Hilal Lashuel, Hajer Ouertatani-Sakouhi

Elsevier2010

EPFL2020