Atomic-Resolution 1.3 Å Crystal Structure, Inhibition by Sulfate, and Molecular Dynamics of the Bacterial Enzyme DapE

The arrangement of hydroxyl groups in the benzene ring has a significant effect on the propensity of dihydroxybenzoic acids (diOHBAs) to form different solid phases when crystallized from solution. All six diOHBAs were categorized into distinctive groups according to the solid phases obtained when crystallized from selected solvents. A combined study using crystal structure and molecule electrostatic potential surface analysis, as well as an exploration of molecular association in solution using spectroscopic methods and molecular dynamics simulations were used to determine the possible mechanism of how the location of the phenolic hydroxyl groups affect the diversity of solid phases formed by the diOHBAs. The crystal structure analysis showed that classical carboxylic acid homodimers and ring-like hydrogen bond motifs consisting of six diOHBA molecules are prominently present in almost all analyzed crystal structures. Both experimental spectroscopic investigations and molecular dynamics simulations indicated that the extent of intramolecular bonding between carboxyl and hydroxyl groups in solution has the most significant impact on the solid phases formed by the diOHBAs. Additionally, the extent of hydrogen bonding with solvent molecules and the mean lifetime of solute–solvent associates formed by diOHBAs and 2-propanol were also investigated.

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Surface Chemistry, Crystal Structure, Size and Topography Role in the Albumin Adsorption Process on TiO2 Anatase Crystallographic Faces and Its 3D-Nanocrystal: A Molecular Dynamics Study

Coatings ◽

10.3390/coatings11040420 ◽

2021 ◽

Vol 11 (4) ◽

pp. 420

Author(s):

Giuseppina Raffaini

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Surface Chemistry ◽

Protein Adsorption ◽

Adsorption Process ◽

Sol Gel ◽

Interaction Strength ◽

Theoretical Work ◽

Blood Protein ◽

Tio2 Anatase

TiO2 is widely used in biomaterial implants. The topography, chemical and structural properties of titania surfaces are an important aspect to study. The size of TiO2 nanoparticles synthetized by sol–gel method can influence the responses in the biological environment, and by using appropriate heat treatments different contents of different polymorphs can be formed. Protein adsorption is a crucial step for the biological responses, involving, in particular, albumin, the most abundant blood protein. In this theoretical work, using molecular mechanics and molecular dynamics methods, the adsorption process of an albumin subdomain is reported both onto specific different crystallographic faces of TiO2 anatase and also on its ideal three-dimensional nanosized crystal, using the simulation protocol proposed in my previous theoretical studies about the adsorption process on hydrophobic ordered graphene-like or hydrophilic amorphous polymeric surfaces. The different surface chemistry of anatase crystalline faces and the nanocrystal topography influence the adsorption process, in particular the interaction strength and protein fragment conformation, then its biological activity. This theoretical study can be a useful tool to better understand how the surface chemistry, crystal structure, size and topography play a key role in protein adsorption process onto anatase surface so widely used as biomaterial.

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PM-11Lattice Strain Analysis in Gold Nanorods by Means of Atomic Resolution HAADF-STEM Experiments and Molecular Dynamics Simulations

Microscopy ◽

10.1093/jmicro/dfx066 ◽

2017 ◽

Vol 66 (suppl_1) ◽

pp. i23-i23

Author(s):

Kohei Aso ◽

Jens Maebe ◽

Tomokazu Yamamoto ◽

Koji Shigematsu ◽

Syo Matsumura

Keyword(s):

Molecular Dynamics ◽

Molecular Dynamics Simulations ◽

Gold Nanorods ◽

Strain Analysis ◽

Atomic Resolution ◽

Dynamics Simulations

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Synthesis, crystal structure, DFT calculations, Hirshfeld surface analysis, energy frameworks, molecular dynamics and docking studies of novel isoxazolequinoxaline derivative (IZQ) as anti-cancer drug

Journal of Molecular Structure ◽

10.1016/j.molstruc.2021.130004 ◽

2021 ◽

Vol 1232 ◽

pp. 130004

Author(s):

Nadeem Abad ◽

Hamdi Hamid Sallam ◽

Fares Hezam Al-Ostoot ◽

Hussien Ahmed Khamees ◽

Sultan A. Al-horaibi ◽

...

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Dft Calculations ◽

Surface Analysis ◽

Docking Studies ◽

Hirshfeld Surface ◽

Hirshfeld Surface Analysis ◽

Cancer Drug ◽

Anti Cancer

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WHICH IS THE PROTON-SHUTTLE IN ISOXANTHOPTERIN DEAMINASE? QM/MM MD UNDERSTANDING

Journal of Theoretical and Computational Chemistry ◽

10.1142/s0219633613410022 ◽

2013 ◽

Vol 12 (08) ◽

pp. 1341002 ◽

Cited By ~ 1

Author(s):

XIN ZHANG ◽

MING LEI

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Hydrogen Bonds ◽

Proton Transfer ◽

Glutamic Acid ◽

Active Site ◽

Nucleophilic Attack ◽

Zinc Ions ◽

Initial Model ◽

Dynamics Simulations

The deamination process of isoxanthopterin catalyzed by isoxanthopterin deaminase was determined using the combined QM(PM3)/MM molecular dynamics simulations. In this paper, the updated PM3 parameters were employed for zinc ions and the initial model was built up based on the crystal structure. Proton transfer and following steps have been investigated in two paths: Asp336 and His285 serve as the proton shuttle, respectively. Our simulations showed that His285 is more effective than Aap336 in proton transfer for deamination of isoxanthopterin. As hydrogen bonds between the substrate and surrounding residues play a key role in nucleophilic attack, we suggested mutating Thr195 to glutamic acid, which could enhance the hydrogen bonds and help isoxanthopterin get close to the active site. The simulations which change the substrate to pterin 6-carboxylate also performed for comparison. Our results provide reference for understanding of the mechanism of deaminase and for enhancing the deamination rate of isoxanthopterin deaminase.

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X-Ray crystal structure and molecular dynamics of the µ-dimethylcarbene complex [Ru2(CO)2(µ-CO)(µ-CMe2)(η-C5H5)2]

Journal of the Chemical Society Chemical Communications ◽

10.1039/c39810000861 ◽

1981 ◽

pp. 861-862 ◽

Cited By ~ 10

Author(s):

Andrew F. Dyke ◽

Selby A. R. Knox ◽

Kevin A. Mead ◽

Peter Woodward

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

X Ray

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Structural refinement by restrained molecular-dynamics algorithm with small-angle X-ray scattering constraints for a biomolecule

Journal of Applied Crystallography ◽

10.1107/s0021889803026165 ◽

2004 ◽

Vol 37 (1) ◽

pp. 103-109 ◽

Cited By ~ 9

Author(s):

Masaki Kojima ◽

Alexander A. Timchenko ◽

Junichi Higo ◽

Kazuki Ito ◽

Hiroshi Kihara ◽

...

Keyword(s):

Crystal Structure ◽

Molecular Dynamics ◽

Small Angle ◽

Protein Structures ◽

Saxs Data ◽

X Ray ◽

X Ray Scattering ◽

Saxs Curve ◽

Restrained Molecular Dynamics ◽

Ray Scattering

A new algorithm to refine protein structures in solution from small-angle X-ray scattering (SAXS) data was developed based on restrained molecular dynamics (MD). In the method, the sum of squared differences between calculated and observed SAXS intensities was used as a constraint energy function, and the calculation was started from given atomic coordinates, such as those of the crystal. In order to reduce the contribution of the hydration effect to the deviation from the experimental (objective) curve during the dynamics, and purely as an estimate of the efficiency of the algorithm, the calculation was first performed assuming the SAXS curve corresponding to the crystal structure as the objective curve. Next, the calculation was carried out with `real' experimental data, which yielded a structure that satisfied the experimental SAXS curve well. The SAXS data for ribonuclease T1, a single-chain globular protein, were used for the calculation, along with its crystal structure. The results showed that the present algorithm was very effective in the refinement and adjustment of the initial structure so that it could satisfy the objective SAXS data.

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The crystal structure of Proteus vulgaris tryptophan indole-lyase complexed with oxindolyl-L-alanine: implications for the reaction mechanism

Acta Crystallographica Section D Structural Biology ◽

10.1107/s2059798318003352 ◽

2018 ◽

Vol 74 (8) ◽

pp. 748-759

Author(s):

Robert S. Phillips ◽

Adriaan A. Buisman ◽

Sarah Choi ◽

Anusha Hussaini ◽

Zachary A. Wood

Keyword(s):

Crystal Structure ◽

Hydrogen Bond ◽

Aromatic Ring ◽

Active Site ◽

Enzymatic Reaction ◽

Proteus Vulgaris ◽

Bacterial Enzyme ◽

Small Domain ◽

Out Of Plane ◽

Reversible Formation

Tryptophan indole-lyase (TIL) is a bacterial enzyme which catalyzes the reversible formation of indole and ammonium pyruvate from L-tryptophan. Oxindolyl-L-alanine (OIA) is an inhibitor of TIL, with a K i value of about 5 µM. The crystal structure of the complex of Proteus vulgaris TIL with OIA has now been determined at 2.1 Å resolution. The ligand forms a closed quinonoid complex with the pyridoxal 5′-phosphate (PLP) cofactor. The small domain rotates about 10° to close the active site, bringing His458 into position to donate a hydrogen bond to Asp133, which also accepts a hydrogen bond from the heterocyclic NH of the inhibitor. This brings Phe37 and Phe459 into van der Waals contact with the aromatic ring of OIA. Mutation of the homologous Phe464 in Escherichia coli TIL to Ala results in a 500-fold decrease in k cat/K m for L-tryptophan, with less effect on the reaction of other nonphysiological β-elimination substrates. Stopped-flow kinetic experiments of F464A TIL show that the mutation has no effect on the formation of quinonoid intermediates. An aminoacrylate intermediate is observed in the reaction of F464A TIL with S-ethyl-L-cysteine and benzimidazole. A model of the L-tryptophan quinonoid complex with PLP in the active site of P. vulgaris TIL shows that there would be a severe clash of Phe459 (∼1.5 Å apart) and Phe37 (∼2 Å apart) with the benzene ring of the substrate. It is proposed that this creates distortion of the substrate aromatic ring out of plane and moves the substrate upwards on the reaction coordinate towards the transition state, thus reducing the activation energy and accelerating the enzymatic reaction.

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