Yazar "A. Wassenaar, Tsjerk" seçeneğine göre listele

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    Molecular dynamics investigation of Helicobacter pylori chemotactic protein CheY1 and two mutants
    (2014) Yildirim, Ahmet; Tekpinar, Mustafa; A. Wassenaar, Tsjerk
    CheY is a chemotactic response regulator protein modulating the rotation direction of bacterial flagellar motors. It plays an important role in the colonization and infection of Helicobacter pylori (H. pylori), which is a common pathogen. Recently, the structure of CheY1 of H. pylori (HpCheY1) was solved, showing similarities and differences with CheY from E. coli. Here, we report 200 ns atomistic molecular dynamics (MD) simulations of HpCheY1 and two mutants. The results suggest that the surface of HpCheY1 has regions with increased affinity for Mg²⁺. In addition, wildtype HpCheY1 (WT HpCheY1) shows characteristic dynamics in helix 4, which is involved in FliM binding. This dynamics is altered in the D53A mutant and completely suppressed in the T84A mutant. The results are discussed in relation to the binding and function of HpCheY1.
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    Molecular dynamics study of the effect of active site protonation on Helicobacter pylori 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase
    (2015) Tekpinar, Mustafa; Yildirim, Ahmet; A. Wassenaar, Tsjerk
    The protein 5'-methylthioadenosine/S-adenosylhomocysteine nucleosidase (MTAN) is involved in the quorum sensing of several bacterial species, including Helicobacter pylori. In particular, these bacteria depend on MTAN for synthesis of vitamin K2 homologs. The residue D198 in the active site of MTAN seems to be of crucial importance, by acting as a hydrogen-bond acceptor for the ligand. In this study, we investigated the conformation and dynamics of apo and holo H. pylori MTAN (HpMTAN), and assessed the effect of protonation of D198 by use of molecular dynamics simulations. Our results show that protonation of the active site of HpMTAN can cause a conformational transition from a closed state to an open state even in the absence of substrate, via inter-chain mechanical coupling.
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    Statistical efficiency of methods for computing free energy of hydration
    (2018) Yildirim, Ahmet; A. Wassenaar, Tsjerk; van der Spoel, David
    The hydration free energy (HFE) is a critical property for predicting and understanding chemical and biological processes in aqueous solution. There are a number of computational methods to derive HFE, generally classified into the equilibrium or non-equilibrium methods, based on the type of calculations used. In the present study, we compute the hydration free energies of 34 small, neutral, organic molecules with experimental HFE between +2 and -16 kcal/mol. The one-sided non-equilibrium methods Jarzynski Forward (JF) and Backward (JB), the two-sided non-equilibrium methods Jarzynski mean based on the average of JF and JB, Crooks Gaussian Intersection (CGI), and the Bennett Acceptance Ratio (BAR) are compared to the estimates from the two-sided equilibrium method Multistate Bennett Acceptance Ratio (MBAR), which is considered as the reference method for HFE calculations, and experimental data from the literature. Our results show that the estimated hydration free energies from all the methods are consistent with MBAR results, and all methods provide a mean absolute error of ∼0.8 kcal/mol and root mean square error of ∼1 kcal for the 34 organic molecules studied. In addition, the results show that one-sided methods JF and JB result in systematic deviations that cannot be corrected entirely. The statistical efficiency ε of the different methods can be expressed as the one over the simulation time times the average variance in the HFE. From such an analysis, we conclude that ε(MBAR) > ε(BAR) ≈ ε(CGI) > ε(JX), where JX is any of the Jarzynski methods. In other words, the non-equilibrium methods tested here for the prediction of HFE have lower computational efficiency than the MBAR method.