Your search keyword '"Troy Wymore"' showing total 59 results

1. Mechanistics of pH-Dependent Sulfmyoglobin Formation: Spin Control and His64 Proton Relay

Author

Angel D. Rodriguez-Mackenzie, Lysmarie Santos-Velazquez, Héctor D. Arbelo-Lopez, Troy Wymore, and Juan Lopez-Garriga

Subjects

Chemistry, QD1-999

Abstract

The chemistry of hydrogen sulfide (H2S) has been directed towards physiologically relevant hemeproteins, including myoglobin, hemoglobin, and other similar proteins. Despite substantial efforts, there remains a need to elucidate the mechanism and identify the species involved in the reaction between oxy-hemeproteins and H2S. Here, we summarize both our experimental data and computational modeling results revealing the mechanisms by which sulfmyoglobin (sulfMb) and sulfhemoglobin (sulfHb) are formed. Our experimental data at pH 7.4 reveal differences in intensity between sulfMb and sulfHb chromophores in the 620 nm charge transfer region. This behavior could be attributed to the incomplete reaction of tetrameric oxy-Hb with H2S, where not all heme groups form sulfheme. The data also show that, for the reaction of oxy-myoglobin (oxy-Mb) and H2S, the 622 nm charge transfer band increases in intensity from a pH of 6.6 to 5.0. This increase is attributed to the presence of the heme pocket distal His64εδ, which is positively charged, resulting in an elevated yield of sulfMb formation compared to the mono-protonated tautomer, His64ε. Computational hybrid QM/MM methods support the conclusion, indicating that oxy-Mb His64εδ (pH 5.0) reacts with H2S in the triplet state, favored by −31.0 kcal/mol over the singlet His64ε (pH 6.6) species. The phenomenon is facilitated by a hydrogen bonding network within the heme pocket, between His64εδ, heme Fe(II)O2, and H2S. The results establish an energetically favored quantitative mechanism to produce sulfMb (−69.1 kcal/mol) from the reactions of oxy-Mb and H2S. Curiously, the mechanism between met-aquo Mb, H2O2, and H2S shows similar reaction pathways and leads to sulfheme formation (−135.3 kcal/mol). The energetic barrier towards intermediate Cpd-0 is the limiting step in sulfheme formation for both systems. ‬Both mechanisms show that the thiyl radical, HS•, is the species attacking the β-β double bond of heme pyrrole B, leading to the sulfheme structure.

Published

2024

2. Visualizing Tetrahedral Oxyanion Bound in HIV‑1 Protease Using Neutrons: Implications for the Catalytic Mechanism and Drug Design

Author

Mukesh Kumar, Kalyaneswar Mandal, Matthew P. Blakeley, Troy Wymore, Stephen B. H. Kent, John M. Louis, Amit Das, and Andrey Kovalevsky

Subjects

Chemistry, QD1-999

Published

2020

3. Positioning-Group-Enabled Biocatalytic Oxidative Dearomatization

Author

Summer A. Baker Dockrey, Carolyn E. Suh, Attabey Rodríguez Benítez, Troy Wymore, and Alison R. H. Narayan

Subjects

Chemistry, QD1-999

Published

2019

4. FROM MOLECULAR PHYLOGENETICS TO QUANTUM CHEMISTRY: DISCOVERING ENZYME DESIGN PRINCIPLES THROUGH COMPUTATION

Author

Troy Wymore and Charles L. Brooks, III

Subjects

Bioinformatics, Phylogenetics, Hybrid Quantum Chemical/Molecular Mechanical Methods, Enzyme Evolution, Structure-Function Relationships, Biotechnology, TP248.13-248.65

Published

2012

5. Deciphering the evolution of flavin-dependent monooxygenase stereoselectivity using ancestral sequence reconstruction

Author

Chang-Hwa Chiang, Troy Wymore, Attabey Rodríguez Benítez, Azam Hussain, Janet L. Smith, Charles L. Brooks, and Alison R. H. Narayan

Subjects

Multidisciplinary

Abstract

Controlling the selectivity of a reaction is critical for target-oriented synthesis. Accessing complementary selectivity profiles enables divergent synthetic strategies, but is challenging to achieve in biocatalytic reactions given enzymes’ innate preferences of a single selectivity. Thus, it is critical to understand the structural features that control selectivity in biocatalytic reactions to achieve tunable selectivity. Here, we investigate the structural features that control the stereoselectivity in an oxidative dearomatization reaction that is key to making azaphilone natural products. Crystal structures of enantiocomplementary biocatalysts guided the development of multiple hypotheses centered on the structural features that control the stereochemical outcome of the reaction; however, in many cases, direct substitutions of active site residues in natural proteins led to inactive enzymes. Ancestral sequence reconstruction (ASR) and resurrection were employed as an alternative strategy to probe the impact of each residue on the stereochemical outcome of the dearomatization reaction. These studies suggest that two mechanisms are active in controlling the stereochemical outcome of the oxidative dearomatization reaction: one involving multiple active site residues in AzaH and the other dominated by a single Phe to Tyr switch in TropB and AfoD. Moreover, this study suggests that the flavin-dependent monooxygenases (FDMOs) adopt simple and flexible strategies to control stereoselectivity, which has led to stereocomplementary azaphilone natural products produced by fungi. This paradigm of combining ASR and resurrection with mutational and computational studies showcases sets of tools for understanding enzyme mechanisms and provides a solid foundation for future protein engineering efforts.

Published

2023

6. The Plasmodium Glutathione S-transferase - Bioinformatics Characterization and Classification into the Sigma Class.

Author

Emilee E. Colón-Lorenzo, Adelfa E. Serrano, Hugh B. Nicholas Jr., Troy Wymore, Alexander Ropelewski, and Ricardo González-Méndez

Published

2010

7. Capturing the Catalytic Proton of Dihydrofolate Reductase: Implications for General Acid–Base Catalysis

Author

Brad C. Bennett, Andrey Kovalevsky, Paul Langan, Troy Wymore, Zhihong Li, Charles L. Brooks, Chris Dealwis, Qun Wan, and Mark A. Wilson

Subjects

deuteron, Steric effects, Proton, Hydronium, Protonation, 010402 general chemistry, solvent, 01 natural sciences, Catalysis, chemistry.chemical_compound, neutron diffraction, Computational chemistry, Dihydrofolate reductase, enzyme mechanism, biology, 010405 organic chemistry, Chemistry, Hydride, Substrate (chemistry), dynamics, General Chemistry, 0104 chemical sciences, biology.protein, pH-dependent, Research Article

Abstract

Acid–base catalysis, which involves one or more proton transfer reactions, is a chemical mechanism commonly employed by many enzymes. The molecular basis for catalysis is often derived from structures determined at the optimal pH for enzyme activity. However, direct observation of protons from experimental structures is quite difficult; thus, a complete mechanistic description for most enzymes remains lacking. Dihydrofolate reductase (DHFR) exemplifies general acid–base catalysis, requiring hydride transfer and protonation of its substrate, DHF, to form the product, tetrahydrofolate (THF). Previous X-ray and neutron crystal structures coupled with theoretical calculations have proposed that solvent mediates the protonation step. However, visualization of a proton transfer has been elusive. Based on a 2.1 Å resolution neutron structure of a pseudo-Michaelis complex of E. coli DHFR determined at acidic pH, we report the direct observation of the catalytic proton and its parent solvent molecule. Comparison of X-ray and neutron structures elucidated at acidic and neutral pH reveals dampened dynamics at acidic pH, even for the regulatory Met20 loop. Guided by the structures and calculations, we propose a mechanism where dynamics are crucial for solvent entry and protonation of substrate. This mechanism invokes the release of a sole proton from a hydronium (H3O+) ion, its pathway through a narrow channel that sterically hinders the passage of water, and the ultimate protonation of DHF at the N5 atom.

Published

2021

8. GTKDynamo: A PyMOL plug-in for QC/MM hybrid potential simulations.

Author

José Fernando R. Bachega, Luís Fernando S. M. Timmers, Lucas Assirati, Leonardo R. Bachega, Martin J. Field, and Troy Wymore

Published

2013

9. Visualizing Tetrahedral Oxyanion Bound in HIV-1 Protease Using Neutrons: Implications for the Catalytic Mechanism and Drug Design

Author

Kalyaneswar Mandal, Mukesh Kumar, Amit Das, Stephen B. H. Kent, Troy Wymore, Matthew P. Blakeley, John M. Louis, and Andrey Kovalevsky

Subjects

Protease, biology, Peptidomimetic, Chemistry, Stereochemistry, Isostere, Hydrogen bond, General Chemical Engineering, medicine.medical_treatment, Oxyanion, General Chemistry, Article, Protease inhibitor (biology), chemistry.chemical_compound, HIV-1 protease, Tetrahedral carbonyl addition compound, biology.protein, medicine, QD1-999, medicine.drug

Abstract

HIV-1 protease is indispensable for virus propagation and an important therapeutic target for antiviral inhibitors to treat AIDS. As such inhibitors are transition-state mimics, a detailed understanding of the enzyme mechanism is crucial for the development of better anti-HIV drugs. Here, we used room-temperature joint X-ray/neutron crystallography to directly visualize hydrogen atoms and map hydrogen bonding interactions in a protease complex with peptidomimetic inhibitor KVS-1 containing a reactive nonhydrolyzable ketomethylene isostere, which, upon reacting with the catalytic water molecule, is converted into a tetrahedral intermediate state, KVS-1TI. We unambiguously determined that the resulting tetrahedral intermediate is an oxyanion, rather than the gem-diol, and both catalytic aspartic acid residues are protonated. The oxyanion tetrahedral intermediate appears to be unstable, even though the negative charge on the oxyanion is delocalized through a strong n → π* hyperconjugative interaction into the nearby peptidic carbonyl group of the inhibitor. To better understand the influence of the ketomethylene isostere as a protease inhibitor, we have also examined the protease structure and binding affinity with keto-darunavir (keto-DRV), which similar to KVS-1 includes the ketomethylene isostere. We show that keto-DRV is a significantly less potent protease inhibitor than DRV. These findings shed light on the reaction mechanism of peptide hydrolysis catalyzed by HIV-1 protease and provide valuable insights into further improvements in the design of protease inhibitors.

Published

2020

10. Stochastic Pairwise Alignments and Scoring Methods for Comparative Protein Structure Modeling.

Author

Adam C. Marko, Kate A. Stafford, and Troy Wymore

Published

2007

11. Radical Tropolone Biosynthesis

Author

Markos Koutmos, TylerJ. Doyon, Leena Mallik, Paul M. Zimmerman, Alison R. H. Narayan, Di Yang, Troy Wymore, and Kevin C Skinner

Subjects

chemistry.chemical_compound, Natural product, chemistry, biology, Biosynthesis, Dioxygenase, Stereochemistry, Biocatalysis, biology.protein, Active site, Ring (chemistry), Tropolone, Small molecule

Abstract

Non-heme iron (NHI) enzymes perform a variety of oxidative rearrangements to advance simple building blocks toward complex molecular scaffolds within secondary metabolite pathways. Many of these transformations occur with selectivity that is unprecedented in small molecule catalysis, spurring an interest in the enzymatic processes which lead to a particular rearrangement. In-depth investigations of NHI mechanisms examine the source of this selectivity and can offer inspiration for the development of novel synthetic transformations. However, the mechanistic details of many NHI-catalyzed rearrangements remain underexplored, hindering full characterization of the chemistry accessible to this functionally diverse class of enzymes. For NHI-catalyzed rearrangements which have been investigated, mechanistic proposals often describe one-electron processes, followed by single electron oxidation from the substrate to the iron(III)-hydroxyl active site species. Here, we examine the ring expansion mechanism employed in fungal tropolone biosynthesis. TropC, an α-ketoglutarate- dependent NHI dioxygenase, catalyzes a ring expansion in the biosynthesis of tropolone natural product stipitatic acid through an under-studied mechanism. Investigation of both polar and radical mechanistic proposals suggests tropolones are constructed through a radical ring expansion. This biosynthetic route to tropolones is supported by X-ray crystal structure data combined with molecular dynamics simulations, alanine-scanning of active site residues, assessed reactivity of putative biosynthetic intermediates, and quantum mechanical (QM) calculations. These studies support a radical ring expansion in fungal tropolone biosynthesis.

Published

2020

12. Hydroxyl Radical-Coupled Electron-Transfer Mechanism of Flavin-Dependent Hydroxylases

Author

Attabey Rodríguez Benítez, Charles L. Brooks, Troy Wymore, Sara E. Tweedy, Paul M. Zimmerman, and Alison R. H. Narayan

Subjects

Green chemistry, Molecular Dynamics Simulation, 010402 general chemistry, Hydroxylation, 01 natural sciences, Article, Electron Transport, chemistry.chemical_compound, Electron transfer, Electrophilic substitution, Spin chemistry, Bacterial Proteins, Computational chemistry, 0103 physical sciences, Materials Chemistry, Physical and Theoretical Chemistry, Density Functional Theory, 010304 chemical physics, Bacteria, Chemistry, Hydroxyl Radical, Substrate (chemistry), 4-Hydroxybenzoate-3-Monooxygenase, 0104 chemical sciences, Surfaces, Coatings and Films, Yield (chemistry), Biocatalysis, Hydroxyl radical

Abstract

Class A flavin-dependent hydroxylases (FdHs) catalyze the hydroxylation of organic compounds in a site and stereoselective manner. In stark contrast, conventional synthetic routes require environmentally hazardous reagents and give modest yields. Thus, understanding the detailed mechanism of this class of enzymes is essential to their rational manipulation for applications in green chemistry and pharmaceutical production. Both electrophilic substitution and radical intermediate mechanisms have been proposed as interpretations of FdH hydroxylation rates and optical spectra. While radical mechanistic steps are often difficult to examine directly, modern quantum chemistry calculations combined with statistical mechanical approaches can yield detailed mechanistic models providing insight that can be used to differentiate reaction pathways. In the current work, we report quantum mechanical/molecular mechanical (QM/MM) calculations on the fungal TropB enzyme that show an alternative reaction pathway in which hydroxylation through a hydroxyl radical coupled electron transfer (HRC-ET) mechanism is significantly favored over electrophilic substitution. Furthermore, QM/MM calculations on several modified flavins provide a more consistent interpretation of the experimental trends in the reaction rates seen experimentally for a related enzyme, para-hydroxybenzoate hydroxylase (PHBH). These calculations should guide future enzyme and substrate design strategies and broaden the scope of biological spin chemistry.

Published

2019

13. A reaction pathway to compound 0 intermediates in oxy-myoglobin through interactions with hydrogen sulfide and His64

Author

Hector D. Arbelo-Lopez, Angel D. Rodriguez-Mackenzie, Juan López-Garriga, and Troy Wymore

Subjects

Oxygen storage, Protonation, 010402 general chemistry, Photochemistry, 01 natural sciences, Article, Reaction coordinate, 03 medical and health sciences, chemistry.chemical_compound, Catalytic Domain, Materials Chemistry, Singlet state, Hydrogen Sulfide, Physical and Theoretical Chemistry, Triplet state, Spectroscopy, Bond cleavage, 030304 developmental biology, 0303 health sciences, Diradical, Chemistry, Myoglobin, Hydrogen Peroxide, Computer Graphics and Computer-Aided Design, 0104 chemical sciences, Oxygen

Abstract

Myoglobin (Mb) binds oxygen with high affinity as a low spin singlet complex and thus functions as an oxygen storage protein. Yet, hybrid Density Functional Theory/Molecular Mechanical (DFT/MM) calculations of oxy-Mb models predict that the O(2) bond is much less resistant to breaking in the presence of hydrogen sulfide (H(2)S) compared with water. Specifically, a hydrogen atom from H(2)S can be transferred to the distal oxygen atom through homolytic cleavage of the S–H bond to form the intermediate Compound (Cpd) 0 structure and a thiyl radical. In the presence of a neutral His64 (Nε protonation, His64-ε) and H(2)S, only a metastable Cpd 0 would be formed as the active site is devoid of any additional proton donor to fully break the O(2) bond. In contrast, the calculations predict that the triplet state is significantly favored over the open shell singlet diradical state throughout the entire reaction coordinate in the presence of H(2)S and a positively charged His64. Furthermore, a positively charged His64 can readily donate a proton to Cpd 0 to fully break the O(2) bond resulting in a configuration analogous to reported reaction models of a hemoglobin mutant bound to H(2)O(2) with H(2)S present. Typically, exotic techniques are required to generate Cpd 0 but under the conditions just described the intermediate is readily detected in UV–Vis spectra at room temperature. The effect is observed as a 2 nm red shift of the Soret band from 414 nm to 416 nm (pH 5.0, His64-εδ) and from 416 nm to 418 nm (pH 6.6, His64-ε).

Published

2019

14. Structural basis for selectivity in flavin-dependent monooxygenase-catalyzed oxidative dearomatization

Author

B.A. Palfey, S.E. Tweedy, Troy Wymore, D. Khare, C.L. Brooks rd, Janet L. Smith, A. Rodriguez Benitez, Alison R. H. Narayan, April L. Lukowski, and S.A. Baker Dockrey

Subjects

biology, 010405 organic chemistry, Chemistry, Flavoprotein, General Chemistry, Flavin group, Oxidative phosphorylation, Monooxygenase, 010402 general chemistry, 01 natural sciences, Combinatorial chemistry, Catalysis, Article, 0104 chemical sciences, Molecular dynamics, Biocatalysis, biology.protein, Selectivity

Abstract

Biocatalytic reactions embody many features of ideal chemical transformations, including the potential for impeccable selectivity, high catalytic efficiency, mild reaction conditions and the use of environmentally benign reagents. These advantages have created a demand for biocatalysts that expand the portfolio of complexity-generating reactions available to synthetic chemists. However, the tradeoff that often exists between the substrate scope of a biocatalyst and its selectivity limits the application of enzymes in synthesis. We recently demonstrated that a flavin-dependent monooxygenase, TropB, maintains high levels of site- and stereoselectivity across a range of structurally diverse substrates. Herein, we disclose the structural basis for substrate binding in TropB, which performs a synthetically challenging asymmetric oxidative dearomatization reaction with exquisite site- and stereoselectivity across a range of phenol substrates, providing a foundation for future protein engineering and reaction development efforts. Our hypothesis for substrate binding is informed by a crystal structure of TropB and molecular dynamics simulations with the corresponding computational TropB model and is supported by experimental data. In contrast to canonical class A FAD-dependent monooxygenases in which substrates bind in a protonated form, our data indicate that the phenolate form of the substrate binds in the active site. Furthermore, the substrate position is controlled through twopoint binding of the phenolate oxygen to Arg206 and Tyr239, which are shown to have distinct and essential roles in catalysis. Arg206 is involved in the reduction of the flavin cofactor, suggesting a role in flavin dynamics. Further, QM/MM simulations reveal the interactions that govern the facial selectivity that leads to a highly enantioselective transformation. Thus, the structural origins of the high levels of site-and stereoselectivity observed in reactions of TropB across a range of substrates are elucidated, providing a foundation for future protein engineering and reaction development efforts.

Published

2019

15. Productive reorientation of a bound oxime reactivator revealed in room temperature X-ray structures of native and VX-inhibited human acetylcholinesterase

Author

Oksana Gerlits, Zoran Radić, Palmer Taylor, Xiaotian Kong, Troy Wymore, Andrey Kovalevsky, Donald K. Blumenthal, and Xiaolin Cheng

Subjects

Biochemistry & Molecular Biology, Molecular model, Stereochemistry, Molecular Dynamics Simulation, Crystallography, X-Ray, Biochemistry, Medical and Health Sciences, structure-function, Serine, Vaccine Related, chemistry.chemical_compound, Catalytic Domain, Biodefense, Oximes, medicine, Humans, reactivation mechanism, Molecular Biology, Density Functional Theory, Nerve agent, RS-170B, X-ray crystallography, Crystallography, Binding Sites, Chemistry, molecular modeling, Prevention, Temperature, Organothiophosphorus Compounds, Cell Biology, acetylcholinesterase, Biological Sciences, Oxime, VX-inhibition, Acetylcholinesterase, Small molecule, Recombinant Proteins, Protein Structure and Folding, Chemical Sciences, X-Ray, Cholinergic, Cholinesterase Inhibitors, protein chemical modification, oxime reactivator, Acetylcholine, medicine.drug

Abstract

Exposure to organophosphorus compounds (OPs) may be fatal if untreated, and a clear and present danger posed by nerve agent OPs has become palpable in recent years. OPs inactivate acetylcholinesterase (AChE) by covalently modifying its catalytic serine. Inhibited AChE cannot hydrolyze the neurotransmitter acetylcholine leading to its build-up at the cholinergic synapses and creating an acute cholinergic crisis. Current antidotes, including oxime reactivators that attack the OP-AChE conjugate to free the active enzyme, are inefficient. Better reactivators are sought, but their design is hampered by a conformationally rigid portrait of AChE extracted exclusively from 100K X-ray crystallography and scarcity of structural knowledge on human AChE (hAChE). Here, we present room temperature X-ray structures of native and VX-phosphonylated hAChE with an imidazole-based oxime reactivator, RS-170B. We discovered that inhibition with VX triggers substantial conformational changes in bound RS-170B from a “nonproductive” pose (the reactive aldoxime group points away from the VX-bound serine) in the reactivator-only complex to a “semi-productive” orientation in the VX-modified complex. This observation, supported by concurrent molecular simulations, suggested that the narrow active-site gorge of hAChE may be significantly more dynamic than previously thought, allowing RS-170B to reorient inside the gorge. Furthermore, we found that small molecules can bind in the choline-binding site hindering approach to the phosphorous of VX-bound serine. Our results provide structural and mechanistic perspectives on the reactivation of OP-inhibited hAChE and demonstrate that structural studies at physiologically relevant temperatures can deliver previously overlooked insights applicable for designing next-generation antidotes.

Published

2019

16. Neutron scattering in the biological sciences: progress and prospects

Author

Hugh O'Neill, Kushol Gupta, David Fushman, Raquel L. Lieberman, John P. Marino, Edward Lyman, Loukas Petridis, Xiaolin Cheng, Christopher B. Stanley, Frederick Herberle, Yimin Mao, Alexei P. Sokolov, David J.E. Callaway, Yang Zhang, Frank Heinrich, Judith Peters, Robert M. Briber, Xiang-Qiang Chu, Paul W. Fenimore, Liang Hong, Joseph E. Curtis, Flora Meilleur, Jeremy C. Smith, Peter C. E. Moody, Andrey Kovalevsky, William B. O'Dell, Rana Ashkar, Frank Gabel, Mark Dadmun, Norman Wagner, Troy Wymore, Susan Krueger, Michael Weinrich, Kevin L. Weiss, Eugenia Kharlampieva, Hassina Z. Bilheux, Gerald R. Kneller, Mathias Lösche, Ursula Perez-Salas, Heliosa Bordallo, Zvi Kelman, Paul Langan, John Katsaras, Yun Liu, Carla Mattos, Jonathan D. Nickels, Réseaux Innovation Territoires et Mondialisation (RITM), Université Paris-Sud - Paris 11 (UP11), Dept Chem, UnivTennessee, The University of Tennessee [Knoxville], Ctr Biomol Struct & Org, University of Maryland [College Park], University of Maryland System-University of Maryland System, Institut de biologie structurale (IBS - UMR 5075 ), Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National de la Recherche Scientifique (CNRS), Ctr Neutron Res, National Institute of Standards and Technology [Gaithersburg] (NIST), Theorical Division (LANL), Los Alamos National Laboratory (LANL), Computer Engineering Department (Polytechnic School), Universidad de Alcalá - University of Alcalá (UAH), Department of Chemistry [Leicester], University of Leicester, Australian National University (ANU), University of Tennessee System, Centre de biophysique moléculaire (CBM), Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Centre National de la Recherche Scientifique (CNRS)-Institut de Chimie du CNRS (INC), Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), and Université d'Orléans (UO)-Institut National de la Santé et de la Recherche Médicale (INSERM)-Institut de Chimie du CNRS (INC)-Centre National de la Recherche Scientifique (CNRS)

Subjects

0301 basic medicine, Models, Molecular, Neutrons, Crystallography, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], Computer science, Scattering, neutron scattering, biological systems, Deuterium Exchange Measurement, Proteins, Neutron scattering, Deuterium, Field (geography), 03 medical and health sciences, Neutron Diffraction, 030104 developmental biology, Structural Biology, structure and dynamics, Animals, Humans, Neutron, Instrumentation (computer programming), Biochemical engineering, Biological sciences

Abstract

International audience; The scattering of neutrons can be used to provide information on the structure and dynamics of biological systems on multiple length and time scales. Pursuant to a National Science Foundation-funded workshop in February 2018, recent developments in this field are reviewed here, as well as future prospects that can be expected given recent advances in sources, instrumentation and computational power and methods. Crystallography, solution scattering, dynamics, membranes, labeling and imaging are examined. For the extraction of maximum information, the incorporation of judicious specific deuterium labeling, the integration of several types of experiment, and interpretation using high-performance computer simulation models are often found to be particularly powerful.

Published

2018

17. Charge Transfer and π to π* Transitions in the Visible Spectra of Sulfheme Met Isomeric Structures

Author

Angel D. Rodriguez-Mackenzie, Elddie M. Roman-Morales, Troy Wymore, Hector D. Arbelo-Lopez, and Juan López-Garriga

Subjects

0301 basic medicine, Heme, Molecular Dynamics Simulation, 010402 general chemistry, Ring (chemistry), 01 natural sciences, Spectral line, 03 medical and health sciences, Hemoglobins, Methionine, Atomic orbital, Isomerism, Materials Chemistry, Molecular orbital, Physical and Theoretical Chemistry, Nuclear Magnetic Resonance, Biomolecular, Chemistry, Time-dependent density functional theory, 0104 chemical sciences, Surfaces, Coatings and Films, Crystallography, 030104 developmental biology, Absorption band, Spectrophotometry, Excited state, Mutagenesis, Site-Directed, Quantum Theory, Density functional theory

Abstract

Since the 1863 discovery of a new green hemoglobin derivative called “sulfhemoglobin”, the nature of the characteristic 618 nm absorption band has been the subject of several hypotheses. The experimental spectra are a function of the observation time and interplay between two major sulfheme isomer concentrations (a three- and five-membered ring adduct), with the latter being the dominant isomer at longer times. Thus, time-dependent density functional theory (TDDFT) was used to calculate the sulfheme excited states and visualize the highest occupied molecular orbitals (HOMOs) and lowest unoccupied MOs (LUMOs) of both isomers in order to interpret the transitions between them. These two isomers have distinguishable a1u and a2u HOMO energies. Formation of the three-membered ring SA isomeric structure decreases the energy of the HOMO a1u and a2u orbitals compared to the unmodified heme due to the electron-withdrawing, sulfur-containing, three-membered ring. Conversely, formation of the SC isomeric structure d...

Published

2018

18. Volatile squalene from a nonseed plant Selaginella moellendorffii : Emission and biosynthesis

Author

Xinlu Chen, Feng Chen, Troy Wymore, Tobias G. Köllner, Fei Wang, Hao Chen, Qidong Jia, and Yifan Jiang

Subjects

Models, Molecular, Selaginellaceae, Squalene, Physiology, Molecular Sequence Data, Plant Science, Genes, Plant, chemistry.chemical_compound, Selaginella moellendorffii, Triterpene, Biosynthesis, Gene Expression Regulation, Plant, Escherichia coli, Genetics, Amino Acid Sequence, chemistry.chemical_classification, Volatile Organic Compounds, Sequence Homology, Amino Acid, biology, ATP synthase, Metabolic intermediate, biology.organism_classification, Terpenoid, Amino acid, Farnesyl-Diphosphate Farnesyltransferase, chemistry, Biochemistry, Biocatalysis, biology.protein

Abstract

The triterpene squalene is a key metabolic intermediate for sterols, hopanoids and various other triterpenoids. The biosynthesis of squalene is catalyzed by squalene synthase (SQS), which converts two molecules of farnesyl diphosphate to squalene. In this study, a lycophyte Selaginella moellendorffii was found to emit squalene as a volatile compound under a number of conditions that mimic biotic stresses. Searching the genome sequence of S. moellendorffii led to the identification of a putative squalene synthase gene. It was designated as SmSQS. SmSQS is homologous to known squalene synthases from other plants and animals at both the amino acid level and structural level. Recombinant SmSQS expressed in Escherichia coli catalyzed the formation of squalene using farnesyl diphosphate as substrate. The expression of SmSQS was significantly induced by the same set of stress factors that induced the emission of volatile squalene from S. moellendorffii plants. Taken together, these results support that SmSQS is responsible for the biosynthesis of volatile squalene and volatile squalene may have a role in the defense of S. moellendorffii plants against biotic stresses.

Published

2015

19. Structural Basis of Activity against Aztreonam and Extended Spectrum Cephalosporins for Two Carbapenem-Hydrolyzing Class D β-Lactamases from Acinetobacter baumannii

Author

David A. Leonard, Agnieszka Szarecka, Rachel A. Powers, Kip Chumba J. Kaitany, Neil V. Klinger, Jozlyn R. Clasman, James R. LaFleur, Robert A. Bonomo, Joshua M. Mitchell, Troy Wymore, Cynthia M. June, and Magdalena A. Taracila

Subjects

Acinetobacter baumannii, Carbapenem, medicine.drug_class, Cephalosporin, Aztreonam, Biochemistry, Article, Protein Structure, Secondary, beta-Lactamases, Microbiology, Bacterial protein, chemistry.chemical_compound, Antibiotic resistance, Bacterial Proteins, polycyclic compounds, medicine, Acinetobacter species, integumentary system, biology, Hydrolysis, β lactamases, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Cephalosporins, Kinetics, chemistry, bacteria, medicine.drug

Abstract

The carbapenem-hydrolyzing class D β-lactamases OXA-23 and OXA-24/40 have emerged worldwide as causative agents for β-lactam antibiotic resistance in Acinetobacter species. Many variants of these enzymes have appeared clinically, including OXA-160 and OXA-225, which both contain a P → S substitution at homologous positions in the OXA-24/40 and OXA-23 backgrounds, respectively. We purified OXA-160 and OXA-225 and used steady-state kinetic analysis to compare the substrate profiles of these variants to their parental enzymes, OXA-24/40 and OXA-23. OXA-160 and OXA-225 possess greatly enhanced hydrolytic activities against aztreonam, ceftazidime, cefotaxime, and ceftriaxone when compared to OXA-24/40 and OXA-23. These enhanced activities are the result of much lower Km values, suggesting that the P → S substitution enhances the binding affinity of these drugs. We have determined the structures of the acylated forms of OXA-160 (with ceftazidime and aztreonam) and OXA-225 (ceftazidime). These structures show that the R1 oxyimino side-chain of these drugs occupies a space near the β5-β6 loop and the omega loop of the enzymes. The P → S substitution found in OXA-160 and OXA-225 results in a deviation of the β5-β6 loop, relieving the steric clash with the R1 side-chain carboxypropyl group of aztreonam and ceftazidime. These results reveal worrying trends in the enhancement of substrate spectrum of class D β-lactamases but may also provide a map for β-lactam improvement.

Published

2015

20. Exploring the Physicochemical Properties of Oxime-Reactivation Therapeutics for Cyclosarin, Sarin, Tabun, and VX Inactivated Acetylcholinesterase

Author

Emilio Xavier Esposito, Terry R. Stouch, Troy Wymore, and Jeffry D. Madura

Subjects

Models, Molecular, Quantitative structure–activity relationship, Sarin, Stereochemistry, Cyclosarin, Toxicology, Mice, Structure-Activity Relationship, chemistry.chemical_compound, Organophosphorus Compounds, Oximes, Animals, Humans, Structure–activity relationship, Tabun, Dose-Response Relationship, Drug, Molecular Structure, Chemistry, Physical, Reproducibility of Results, Organothiophosphorus Compounds, General Medicine, Oxime, Acetylcholinesterase, Organophosphates, Rats, chemistry, Cholinesterase Inhibitors, Conjugate

Abstract

The inactivation of acetylcholinesterase (AChE) by organophosphorus agent (OP) compounds is a serious problem regardless of how the individual was exposed. The reactivation of OP-inactivated AChE is dependent on the OP conjugate, and commonly a specific oxime is better at reactivating a specific OP conjugate than several diverse OP conjugates. The presented research explores the physicochemical properties needed for the reactivation of OP-inactivated AChE. Four different OPs, cyclosarin, sarin, tabun, and VX, were analyzed using the same set of oxime reactivators. A trial descriptor pool of semiempirical, traditional, and molecular interaction field descriptors was used to construct an ensemble of QSAR models for each OP-conjugate pair. Based on the molecular information and the cross-validation ability, individual QSAR models were selected to be part of an OP-conjugate consensus model. The OP-conjugate specific models provide important insight into the physicochemical properties required to reactivate the OP conjugates of interest. The reactivation of AChE inactivated with either cyclosarin or tabun requires the oxime therapeutic to possess an overall polar-positive surface area. Oxime therapeutics for the reactivation of sarin-inactivated AChE are conformationally dependent while oxime reverse therapeutics for VX require a compact region with a highly hydrophilic region and two positively charged pyridine rings.

Published

2014

21. GTKDynamo: A PyMOL plug-in for QC/MM hybrid potential simulations

Author

Luis Fernando Saraiva Macedo Timmers, Lucas Assirati, Martin J. Field, José Fernando Ruggiero Bachega, Troy Wymore, and Leonardo R. Bachega

Subjects

Quantum chemical, 010304 chemical physics, Computer science, Phase (waves), Process (computing), Molecular simulation, General Chemistry, Electronic structure, 010402 general chemistry, computer.software_genre, 01 natural sciences, 0104 chemical sciences, Visualization, Computational science, Computational Mathematics, 0103 physical sciences, Plug-in, computer

Abstract

Hybrid quantum chemical (QC)/molecular mechanical (MM) potentials are very powerful tools for molecular simulation. They are especially useful for studying processes in condensed phase systems, such as chemical reactions, that involve a relatively localized change in electronic structure and where the surrounding environment contributes to these changes but can be represented with more computationally efficient functional forms. Despite their utility, however, these potentials are not always straightforward to apply since the extent of significant electronic structure changes occurring in the condensed phase process may not be intuitively obvious. To facilitate their use we have developed an open-source graphical plug-in, GTKDynamo, that links the PyMOL visualization program and the pDynamo QC/MM simulation library. This article describes the implementation of GTKDynamo and its capabilities and illustrates its application to QC/MM simulations.

Published

2013

22. Asymmetric Ligand Binding Facilitates Conformational Transitions in Pentameric Ligand-Gated Ion Channels

Author

Pei Tang, Yan Xu, Lu Tian Liu, David D. Mowrey, Dan Willenbring, Troy Wymore, Mary Hongying Cheng, and Xinghua Lu

Subjects

Models, Molecular, Binding Sites, Protein Conformation, Chemistry, GLIC, General Chemistry, Crystal structure, Ligand-Gated Ion Channels, Molecular Dynamics Simulation, Ligands, Biochemistry, Article, Catalysis, Crystallography, Molecular dynamics, Colloid and Surface Chemistry, Protein structure, Molecule, Ligand-gated ion channel, Binding site, Ion channel

Abstract

The anesthetic propofol inhibits the currents of the homo-pentameric ligand-gated ion channel GLIC, yet the crystal structure of GLIC with five propofol molecules bound symmetrically shows an open-channel conformation. To address this dilemma and determine if symmetry of propofol binding sites affects the channel conformational transition, we performed a total of 1.5 As of molecular dynamics simulations for different GLIC systems with propofol occupancies of 0, 1, 2, 3, and 5. GLIC without propofol binding or with five propofol molecules bound symmetrically showed similar channel conformation and hydration status over multiple replicates of 100-ns simulations. In contrast, asymmetric binding to one, two or three equivalent sites in different subunits accelerated the channel dehydration, which was accompanied by increased conformational heterogeneity of the pore and shifted the lateral and radial tilting angles of the pore-lining TM2 towards a closed-channel conformation. The results differentiate two groups of systems based on the propofol binding symmetry. The difference between symmetric and asymmetric groups is correlated with the variance in the propofol-binding cavity adjacent to the hydrophobic gate and the force imposed by the bound propofol. Asymmetrically bound propofol produced greater variance in the cavity size that could further elevate the conformation heterogeneity. The force trajectory generated by propofol in each subunit over the course of a simulation exhibits an ellipsoidal shape, which has the larger component tangential to the pore. Asymmetric propofol binding creates an unbalanced force that expedites the channel conformation transitions. The findings from this study not only suggest that asymmetric binding underlies the propofol functional inhibition of GLIC, but also advocate for the role of symmetry breaking in facilitating channel conformational transitions.

Published

2013

23. A Distal Disulfide Bridge in OXA-1 β-Lactamase Stabilizes the Catalytic Center and Alters the Dynamics of the Specificity Determining Ω Loop

Author

Nikolay A. Simakov, Jeremy C. Smith, David A. Leonard, Troy Wymore, and Agnieszka Szarecka

Subjects

0301 basic medicine, chemistry.chemical_classification, Principal Component Analysis, biology, Stereochemistry, Dynamics (mechanics), Active site, Periplasmic space, Molecular Dynamics Simulation, beta-Lactamases, Surfaces, Coatings and Films, Catalysis, Substrate Specificity, Loop (topology), 03 medical and health sciences, Molecular dynamics, 030104 developmental biology, Enzyme, chemistry, Biocatalysis, Materials Chemistry, biology.protein, Disulfides, Physical and Theoretical Chemistry

Abstract

Widespread antibiotic resistance, particularly when mediated by broad-spectrum β-lactamases, has major implications for public health. Substitutions in the active site often allow broad-spectrum enzymes to accommodate diverse types of β-lactams. Substitutions observed outside the active site are thought to compensate for the loss of thermal stability. The OXA-1 clade of class D β-lactamases contains a pair of conserved cysteines located outside the active site that forms a disulfide bond in the periplasm. Here, the effect of the distal disulfide bond on the structure and dynamics of OXA-1 was investigated via 4 μs molecular dynamics simulations. The results reveal that the disulfide promotes the preorganized orientation of the catalytic residues and affects the conformation of the functionally important Ω loop. Furthermore, principal component analysis reveals differences in the global dynamics between the oxidized and reduced forms, especially in the motions involving the Ω loop. A dynamical network analysis indicates that, in the oxidized form, in addition to its role in ligand binding, the KTG family motif is a central hub of the global dynamics. As activity of OXA-1 has been measured only in the reduced form, we suggest that accurate assessment of its functional profile would require oxidative conditions mimicking periplasm.

Published

2016

24. Homolytic Cleavage of Both Heme-Bound Hydrogen Peroxide and Hydrogen Sulfide Leads to the Formation of Sulfheme

Author

Nikolay A. Simakov, Hector D. Arbelo-Lopez, Troy Wymore, Jeremy C. Smith, and Juan López-Garriga

Subjects

0301 basic medicine, Hemeprotein, Inorganic chemistry, Protoporphyrins, Heme, Molecular Dynamics Simulation, 010402 general chemistry, Ring (chemistry), Photochemistry, 01 natural sciences, 03 medical and health sciences, chemistry.chemical_compound, Hemoglobins, Catalytic Domain, Materials Chemistry, Molecule, Animals, Hydrogen Sulfide, Physical and Theoretical Chemistry, Hydrogen peroxide, Pyrrole, Hydrogen bond, Hydrogen Bonding, Hydrogen Peroxide, 0104 chemical sciences, Surfaces, Coatings and Films, Bivalvia, 030104 developmental biology, chemistry, Mutagenesis, Site-Directed, Quantum Theory, Oxygen binding

Abstract

Many heme-containing proteins with a histidine in the distal E7 (HisE7) position can form sulfheme in the presence of hydrogen sulfide (H2S) and a reactive oxygen species such as hydrogen peroxide. For reasons unknown, sulfheme derivatives are formed specifically on solvent-excluded heme pyrrole B. Sulfhemes severely decrease the oxygen-binding affinity in hemoglobin (Hb) and myoglobin (Mb). Here, use of hybrid quantum mechanical/molecular mechanical methods has permitted characterization of the entire process of sulfheme formation in the HisE7 mutant of hemoglobin I (HbI) from Lucina pectinata. This process includes a mechanism for H2S to enter the solvent-excluded active site through a hydrophobic channel to ultimately form a hydrogen bond with H2O2 bound to Fe(III). Proton transfer from H2O2 to His64 to form compound (Cpd) 0, followed by hydrogen transfer from H2S to the Fe(III)-H2O2 complex, results in homolytic cleavage of the O-O and S-H bonds to form a reactive thiyl radical (HS(•)), ferryl heme Cpd II, and a water molecule. Subsequently, the addition of HS(•) to Cpd II, followed by three proton transfer reactions, results in the formation of a three-membered ring ferric sulfheme that avoids migration of the radical to the protein matrix, in contrast to that in other peroxidative reactions. The transformation of this three-membered episulfide ring structure to the five-membered thiochlorin ring structure occurs through a significant potential energy barrier, although both structures are nearly isoenergetic. Both three- and five-membered ring structures reveal longer NB-Fe(III) bonds compared with other pyrrole nitrogen-Fe(III) bonds, which would lead to decreased oxygen binding. Overall, these results are in agreement with a wide range of experimental data and provide fertile ground for further investigations of sulfheme formation in other heme proteins and additional effects of H2S on cell signaling and reactivity.

Published

2016

25. Clinical variants of the native class d beta-lactamase of acinetobacter baumannii pose an emerging threat through ıncreased hydrolytic activity against carbapenems

Author

Cynthia M. June, Ayşegül Saral, David A. Leonard, Zachary L. Klamer, Troy Wymore, Emma C. Schroder, Kyle A. Sugg, Agnieszka Szarecka, and Saral, Ayşegül

Subjects

Acinetobacter baumannii, 0301 basic medicine, Carbapenem, [No Keywords Available], Protein Conformation, medicine.drug_class, 030106 microbiology, Cephalosporin, Aztreonam, Molecular Dynamics Simulation, beta-Lactam Resistance, beta-Lactamases, Substrate Specificity, 03 medical and health sciences, chemistry.chemical_compound, Protein structure, Mechanisms of Resistance, Catalytic Domain, medicine, polycyclic compounds, Humans, Monobactam, Pharmacology (medical), Pathogen, Pharmacology, Genetics, biology, Chemistry, Hydrolysis, biochemical phenomena, metabolism, and nutrition, biology.organism_classification, Infectious Diseases, Amino Acid Substitution, Carbapenems, Doripenem, bacteria, medicine.drug

Abstract

The threat posed by the chromosomally encoded class D β-lactamase of Acinetobacter baumannii (OXA-51/66) has been unclear, in part because of its relatively low affinity and turnover rate for carbapenems. Several hundred clinical variants of OXA-51/66 have been reported, many with substitutions of active-site residues. We determined the kinetic properties of OXA-66 and five clinical variants with respect to a wide variety of β-lactam substrates. The five variants displayed enhanced activity against carbapenems and in some cases against penicillins, late-generation cephalosporins, and the monobactam aztreonam. Molecular dynamics simulations show that in OXA-66, P130 inhibits the side-chain rotation of I129 and thereby prevents doripenem binding because of steric clash. A single amino acid substitution at this position (P130Q) in the variant OXA-109 greatly enhances the mobility of both I129 and a key active-site tryptophan (W222), thereby facilitating carbapenem binding. This expansion of substrate specificity represents a very worrisome development for the efficacy of β-lactams against this troublesome pathogen.

Published

2016

26. The Class D β-lactamase family: residues governing the maintenance and diversity of function

Author

Troy Wymore, Kimberly R. Lesnock, Carlos A. Ramirez-Mondragon, Hugh B. Nicholas, and Agnieszka Szarecka

Subjects

Models, Molecular, Entropy, Bioengineering, Computational biology, Biochemistry, Catalysis, beta-Lactamases, Structure-Activity Relationship, Bacterial Proteins, Phylogenetics, Proteobacteria, Structure–activity relationship, Disulfides, Binding site, Molecular Biology, Phylogeny, Binding Sites, Multiple sequence alignment, biology, Phylogenetic tree, Active site, Hydrogen Bonding, Serine hydrolase, Original Articles, biology.organism_classification, biology.protein, Biotechnology

Abstract

Class D β-lactamases, a major source of bacterial resistance to β-lactam antibiotic therapies, represent a distinct subset of the β-lactamase superfamily. They share a serine hydrolase mechanism with Classes A/C vs. Class B. Further understanding of their sequence–structure–function relationships would benefit efforts to design a new generation of antibiotics as well as to predict evolutionary mechanisms in response to such therapies. Here we describe analyses based on our high-resolution multiple sequence alignment and phylogenetic tree of ∼80 Class D β-lactamases that leverage several 3D structures of these enzymes. We observe several sequence clusters on the phylogenetic tree, some that are species specific while others include several species from α-, β- and γ-proteobacteria. Residues characteristic of a specific cluster were identified and shown to be located just outside the active site, possibly modulating the function of the catalytic residues to facilitate reactions with specific types of β-lactams. Most significant was the discovery of a likely disulfide bond in a large group composed of α-, β- and γ-proteobacteria that would contribute to enzyme stability and hence bacterial viability under antibiotic assault. A network of co-evolving residues was identified which suggested the importance of maintaining a surface for binding a highly conserved Phe69.

Published

2011

27. Gamma glutamyl semialdehyde dehydrogenase: Simulations on native and mutant forms support the importance of outer shell lysines

Author

Adam Kraut, Troy Wymore, and John Hempel

Subjects

Models, Molecular, biology, Chemistry, Stereochemistry, Lysine, Thermus thermophilus, Mutant, Active site, General Medicine, Toxicology, biology.organism_classification, Serine, 1-Pyrroline-5-Carboxylate Dehydrogenase, Residue (chemistry), Tetrahedral carbonyl addition compound, Catalytic Domain, Mutation, Mutation (genetic algorithm), biology.protein, Peptide bond

Abstract

Our computer simulations of gamma glutamyl semialdehyde dehydrogenase (GGSALDH, pyrroline 5-carboxylate dehydrogenase, ALDH4) were initiated from the Thermus thermophilus crystal structures in an effort to understand the effects of a seemingly subtle mutation. In humans, a natural S352L mutation gives rise to type II hyperprolinemia (mental retardation). The mutation occurs in what might be a priori considered the outer shell of the active site, affecting a residue of no obvious significance. In another member of the superfamily (ALDH3) this serine residue is an aspartate, which tethers the “distal” Lys. It has been our hypothesis that in ALDH3 this is a beneficial interaction, enabling the “proximal” Lys to interact with the carbonyl oxygen of the peptide bond with the catalytic Cys, allowing the Cys amide N to transiently protonate the tetrahedral intermediate. That the role of this Asp is significant is proved by a natural Asp-to-Asn mutation that abolishes activity. The Ser-to-Leu exchange in GGSALDH might be expected to alter the water structure at the site of mutation, and the MM simulations clearly support this. It was our hypothesis, based on initial static models of the mutation, that the leucyl side chain would block the direct or indirect interaction of the distal Lys with the active site. Our simulations indicate that this lysine residue is indeed important in explaining the molecular pathology of the mutation. Through small rotations of its C–C bonds, the Lys ɛ-amino group comes into H-bonding distance with Ser-326, the equivalent of human Ser-352. In the S326L mutant, this interaction is not possible, while the water network from this residue to the target main-chain carbonyl oxygen is disturbed as well.

Published

2009

28. A quantum chemical study of the mechanism of action of Vitamin K carboxylase (VKC)

Author

Darrel W. Stafford, David W. Deerfield, Troy Wymore, Charles H. Davis, and Lee G. Pedersen

Subjects

Hydroquinone, Hydrogen, Stereochemistry, chemistry.chemical_element, Epoxide, Computer Graphics and Computer-Aided Design, Oxygen, Transition state, chemistry.chemical_compound, chemistry, Mechanism of action, Alkoxide, Materials Chemistry, medicine, Molecule, Physical and Theoretical Chemistry, medicine.symptom, Spectroscopy

Abstract

A reaction path including transition states is generated for the Dowd mechanism [P. Dowd, R. Hershlne, S.W. Ham, S. Naganathan. Vitamin K and energy transduction: a base strength amplification mechanism. Science 269 (2005) 1684-1691] of action for Vitamin K carboxylase (VKC) using quantum chemical methods (B3LYP/6-311G**). VKC, an essential enzyme in mammalian systems, catalyzes the conversion of hydroquinone form of Vitamin K to the epoxide form in the presence of oxygen. An intermediate species of the oxidation of Vitamin K, an alkoxide, acts apparently to abstract the gamma hydrogen from specifically located glutamate residues. We are able to follow the Dowd proposed path to generate this alkoxide species. The geometries of the proposed model intermediates and transition states in the mechanism are energy optimized. We find that the most energetic step in the mechanism is the uni-deprotonation of the hydroquinone - once this occurs, there is only a small barrier of 3.5kcal/mol for the interaction of oxygen with the carbon to be attacked - and then the reaction proceeds downhill in free energy to form the critical alkoxide species. The results are consistent with the idea that the enzyme probably acts to facilitate the formation of the epoxide by reducing the energy required to deprotonate the hydroquinone form.

Published

2007

29. A quantum chemical study of the mechanism of action of Vitamin K epoxide reductase (VKOR)

Author

David W. Deerfield, Lee G. Pedersen, Troy Wymore, Charles H. Davis, and Darrel W. Stafford

Subjects

biology, Chemistry, Stereochemistry, Active site, Epoxide, Protonation, Reductase, Computer Graphics and Computer-Aided Design, Transition state, Quinone, chemistry.chemical_compound, Materials Chemistry, biology.protein, Molecule, Vitamin K epoxide reductase, Physical and Theoretical Chemistry, Spectroscopy

Abstract

A reaction path including transition states is generated for the Silverman mechanism [R.B. Silverman, Chemical model studies for the mechanism of Vitamin K epoxide reductase, J. Am. Chem. Soc. 103 (1981) 5939–5941] of action for Vitamin K epoxide reductase (VKOR) using quantum mechanical methods (B3LYP/6-311G**). VKOR, an essential enzyme in mammalian systems, acts to convert Vitamin K epoxide, formed by Vitamin K carboxylase, to its (initial) quinone form for cellular reuse. This study elaborates on a prior work that focused on the thermodynamics of VKOR [D.W. Deerfield II, C.H. Davis, T. Wymore, D.W. Stafford, L.G. Pedersen, Int. J. Quant. Chem. 106 (2006) 2944–2952]. The geometries of proposed model intermediates and transition states in the mechanism are energy optimized. We find that once a key disulfide bond is broken, the reaction proceeds largely downhill. An important step in the conversion of the epoxide back to the quinone form involves initial protonation of the epoxide oxygen. We find that the source of this proton is likely a free mercapto group rather than a water molecule. The results are consistent with the current view that the widely used drug Warfarin likely acts by blocking binding of Vitamin K at the VKOR active site and thereby effectively blocking the initiating step. These results will be useful for designing more complete QM/MM studies of the enzymatic pathway once three-dimensional structural data is determined and available for VKOR.

Published

2007

30. Mechanistic Implications of the Cysteine−Nicotinamide Adduct in Aldehyde Dehydrogenase Based on Quantum Mechanical/Molecular Mechanical Simulations

Author

David W. Deerfield, Troy Wymore, and John Hempel

Subjects

Niacinamide, Protein Conformation, Stereochemistry, Oxyanion, Photochemistry, Biochemistry, Formyltetrahydrofolate dehydrogenase, Article, Adduct, chemistry.chemical_compound, Nucleophile, Humans, Computer Simulation, Cysteine, Aldehydes, biology, Nicotinamide, Hydride, Aldehyde Dehydrogenase, Mitochondrial, Active site, Aldehyde Dehydrogenase, NAD, chemistry, biology.protein, Quantum Theory, NAD+ kinase, Protons

Abstract

Recent computer simulations of the cysteine nucleophilic attack on propanal in human mitochondrial Aldehyde Dehydrogenase (ALDH2) yielded an unexpected result; the chemically reasonable formation of a dead-end cysteine-cofactor adduct when NAD+ was in the “hydride transfer” position. More recently, this adduct found independent crystallographic support in work on formyltetrahydrofolate dehydrogenase, work which further found evidence of the same adduct on re-examination of deposited electron densities of ALDH2. Although the experimental data showed this adduct was reversible, several mechanistic questions arise from the fact that it forms at all. Here, we present results from further Quantum Mechanical/Molecular Mechanical (QM/MM) simulations toward understanding the mechanistic implications of adduct formation. These simulations revealed that formation of the oxyanion thiohemiacetal intermediate only when the nicotinamide ring of NAD+ is oriented away from the active site, contrary to prior arguments. In contrast, and in seeming paradox, when NAD is oriented to receive the hydride, disassociation of the oxyanion intermediate to form the dead-end adduct is more thermodynamically-favored than maintaining the oxyanion intermediate necessary for catalysis to proceed. However, this disassociation to the adduct could be avoided through proton transfer from the enzyme to the intermediate. Our results continue to indicate that the unlikely source of this proton is the Cys302 main chain amide.

Published

2007

31. Long-Range Electrostatics-Induced Two-Proton Transfer Captured by Neutron Crystallography in an Enzyme Catalytic Site

Author

Amit Das, Oksana Gerlits, David A. Keen, Andrey Kovalevsky, Matthew P. Blakeley, Jerry M. Parks, Paul Langan, John M. Louis, Chen-Hsiang Shen, Troy Wymore, Kevin L. Weiss, Irene T. Weber, and Jeremy C. Smith

Subjects

0301 basic medicine, Proton, Static Electricity, Protonation, 010402 general chemistry, 01 natural sciences, Molecular mechanics, Catalysis, Article, Substrate Specificity, 03 medical and health sciences, HIV Protease, Catalytic Domain, Static electricity, Neutron, Crystallography, biology, 010405 organic chemistry, Chemistry, Active site, General Medicine, General Chemistry, Electrostatics, 0104 chemical sciences, 030104 developmental biology, biology.protein, Quantum Theory, Protons

Abstract

Proton transfer is integral to many biochemical processes. However, the direct observation and structural characterization of biological proton transfer has hitherto not been possible. Here, neutron crystallography directly locates two protons before and after a pH-induced two-proton transfer between the catalytic aspartic acid residues and the hydroxyl group of the bound clinical drug, darunavir, in the catalytic site of enzyme HIV-1 protease. The two-proton transfer is triggered by electrostatic effects arising from protonation state changes of surface residues far from the active site. The mechanism and pH effect are supported by QM/MM calculations. We propose that the low-pH proton configuration in the catalytic site is critical for the catalytic action of this enzyme and may apply more generally to other aspartic proteases. Neutrons therefore represent a superb probe to obtain structural details for proton transfer reactions in biological systems at a truly atomic level.

Published

2015

32. Quantum chemical study of the mechanism of action of vitamin K epoxide reductase (VKOR)

Author

Charles H. Davis, Darrel W. Stafford, Lee G. Pedersen, David W. Deerfield, and Troy Wymore

Subjects

Quantum chemical, Chemistry, Stereochemistry, Reductase, Vitamin k, Condensed Matter Physics, Atomic and Molecular Physics, and Optics, Mechanism of action, Computational chemistry, medicine, Vitamin K epoxide reductase, Physical and Theoretical Chemistry, medicine.symptom, Quantum

Abstract

Possible model, but simplistic, mechanisms for the action of vitamin K epoxide reductase (VKOR) are investigated with quantum mechanical methods (B3LYP/6-311G**). The geometries of proposed model intermediates in the mechanisms are energy optimized. Finally, the energetics of the proposed (pseudo-enzymatic) pathways are compared. We find that the several pathways are all energetically feasible. These results will be useful for designing quantum mechanical/molecular mechanical method (QM/MM) studies of the enzymatic pathway once three-dimensional structural data are determined and available for VKOR. © 2006 Wiley Periodicals, Inc. Int J Quantum Chem, 2006

Published

2006

33. Molecular recognition of aldehydes by aldehyde dehydrogenase and mechanism of nucleophile activation

Author

Hugh B. Nicholas, Alexander D. MacKerell, David W. Deerfield, Troy Wymore, Samuel S. Cho, and John Hempel

Subjects

Concerted reaction, Chemistry, Stereochemistry, Hydrogen bond, Biochemistry, Benzaldehyde, Molecular dynamics, chemistry.chemical_compound, Molecular recognition, Nucleophile, Structural Biology, Computational chemistry, Molecule, Molecular Biology, Conformational isomerism

Abstract

Experimental structural data on the state of substrates bound to class 3 Aldehyde Dehydrogenases (ALDH3A1) is currently unknown. We have utilized molecular mechanics (MM) simulations, in conjunction with new force field parameters for aldehydes, to study the atomic details of benzaldehyde binding to ALDH3A1. Our results indicate that while the nucleophilic Cys243 must be in the neutral state to form what are commonly called near-attack conformers (NACs), these structures do not correlate with increased complexation energy calculated with the MM-Generalized Born Molecular Volume (GBMV) method. The negatively charged Cys243 (thiolate form) of ALDH3A1 also binds benzaldehyde in a stable conformation but in this complex the sulfur of Cys243 is oriented away from benzaldehyde yet yields the most favorable MM-GBMV complexation energy. The identity of the general base, Glu209 or Glu333, in ALDHs remains uncertain. The MM simulations reveal structural and possible functional roles for both Glu209 and Glu333. Structures from the MM simulations that would support either glutamate residue as the general base were further examined with Hybrid Quantum Mechanical (QM)/MM simulations. These simulations show that, with the PM3/OPLS potential, Glu209 must go through a step-wise mechanism to activate Cys243 through an intervening water molecule while Glu333 can go through a more favorable concerted mechanism for the same activation process.

Published

2004

34. Parametrization of 2-Bromo-2-Chloro-1,1,1-Trifluoroethane (Halothane) and Hexafluoroethane for Nonbonded Interactions

Author

Zhanwu Liu, Yan Xu, Troy Wymore, Alexander C. Saladino, and Pei Tang

Subjects

chemistry.chemical_compound, Neon, Chemistry, Computational chemistry, Ab initio quantum chemistry methods, Hexafluoroethane, Ab initio, Molecule, chemistry.chemical_element, Charge (physics), Physical and Theoretical Chemistry, Parametrization, 1,1,1-Trifluoroethane

Abstract

Ab initio and empirical methods were combined to optimize the partial atomic charges and Lennard-Jones parameters for two halogenated compounds, halothane (CF3CHClBr, a potent volatile anesthetic) and hexafluoroethane (CF3CF3, a nonanesthetic). Charge optimization was achieved using empirical calculations by systematically adjusting the charge assignments to fit minimum interaction energies and geometries between a TIP3 water molecule and the halogenated compounds to the corresponding values from the ab initio calculations, which were carried out at the HF/6-311+G(2d,p) and HF/6-31G(d) levels for halothane and hexafluoroethane, respectively. To optimize the Lennard-Jones parameters, the initial estimates were obtained from scaling the values from the ab initio minimum interaction energies and geometries between neon and the halogenated compounds calculated at the MP3/6-311++G(3d,3p) level. The Lennard-Jones parameters were further refined by fitting the empirical interaction energies to the corresponding ...

Published

2004

35. Neutron crystallographic and scattering studies of function and inhibition of HIV-1 protease

Author

Andrey Kovalevsky, Matthew P. Blakeley, John M. Louis, Troy Wymore, Amit Das, Oksana Gerlits, Irene T. Weber, and David A. Keen

Subjects

Materials science, biology, Scattering, Condensed Matter Physics, Biochemistry, Inorganic Chemistry, Crystallography, HIV-1 protease, Structural Biology, biology.protein, General Materials Science, Neutron, Physical and Theoretical Chemistry, Function (biology)

Published

2017

36. L-Arabinose binding, isomerization, and epimerization by D-xylose isomerase: X-ray/neutron crystallographic and molecular simulation study

Author

Amandeep K. Sangha, David A. Keen, Andrey Kovalevsky, B. Leif Hanson, Sax A. Mason, Jerry M. Parks, H. L. Carrell, Zoë Fisher, Matthew P. Blakeley, V. Trevor Forsyth, Paul Langan, Zamin Koo Yang, Jeremy C. Smith, Troy Wymore, David E. Graham, and Jenny P. Glusker

Subjects

Arabinose, Xylose isomerase, Stereochemistry, Stereoisomerism, Isomerase, Molecular Dynamics Simulation, Crystallography, X-Ray, chemistry.chemical_compound, Bacterial Proteins, Structural Biology, Monosaccharide, Magnesium, Molecular Biology, Aldose-Ketose Isomerases, chemistry.chemical_classification, Chemistry, Furanose, Streptomyces, Crystallography, Biocatalysis, Thermodynamics, Isomerization, Cadmium, Protein Binding

Abstract

SummaryD-xylose isomerase (XI) is capable of sugar isomerization and slow conversion of some monosaccharides into their C2-epimers. We present X-ray and neutron crystallographic studies to locate H and D atoms during the respective isomerization and epimerization of L-arabinose to L-ribulose and L-ribose, respectively. Neutron structures in complex with cyclic and linear L-arabinose have demonstrated that the mechanism of ring-opening is the same as for the reaction with D-xylose. Structural evidence and QM/MM calculations show that in the reactive Michaelis complex L-arabinose is distorted to the high-energy 5S1 conformation; this may explain the apparent high KM for this sugar. MD-FEP simulations indicate that amino acid substitutions in a hydrophobic pocket near C5 of L-arabinose can enhance sugar binding. L-ribulose and L-ribose were found in furanose forms when bound to XI. We propose that these complexes containing Ni2+ cofactors are Michaelis-like and the isomerization between these two sugars proceeds via a cis-ene-diol mechanism.

Published

2014

37. Hydrolysis of DFP and the nerve agent (S)-sarin by DFPase proceeds along two different reaction pathways: implications for engineering bioscavengers

Author

Troy Wymore, Martin J. Field, Paul Langan, Jerry M. Parks, Jeremy C. Smith, Institut de biologie structurale (IBS - UMR 5075 ), Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Direction de Recherche Fondamentale (CEA) (DRF (CEA)), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Centre National de la Recherche Scientifique (CNRS), inconnu, Inconnu, Department of Physiology, Monash University [Clayton], Center for Molecular Biophysics [Oak Ridge], Oak Ridge National Laboratory [Oak Ridge] (ORNL), UT-Battelle, LLC-UT-Battelle, LLC, Centre National de la Recherche Scientifique (CNRS)-Université Grenoble Alpes [2016-2019] (UGA [2016-2019])-Institut de Recherche Interdisciplinaire de Grenoble (IRIG), Commissariat à l'énergie atomique et aux énergies alternatives (CEA)-Commissariat à l'énergie atomique et aux énergies alternatives (CEA), and Thomas, Frank

Subjects

Models, Molecular, Sarin, Isoflurophate, Stereochemistry, [SDV.BBM.BS] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], Protein Conformation, Loligo, 010402 general chemistry, Protein Engineering, 01 natural sciences, Article, Catalysis, chemistry.chemical_compound, Hydrolysis, Nucleophile, Materials Chemistry, medicine, Animals, Chemical Warfare Agents, Physical and Theoretical Chemistry, Diisopropyl-fluorophosphatase, Nerve agent, chemistry.chemical_classification, [SDV.BBM.BS]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Structural Biology [q-bio.BM], 010405 organic chemistry, Chemistry, 0104 chemical sciences, Surfaces, Coatings and Films, Enzyme, Phosphoric Triester Hydrolases, Thermodynamics, medicine.drug

Abstract

International audience; Organophosphorus (OP) nerve agents such as (S)-sarin are among the most highly toxic compounds that have been synthesized. Engineering enzymes that catalyze the hydrolysis of nerve agents ("bioscavengers") is an emerging prophylactic approach to diminish their toxic effects. Although its native function is not known, diisopropyl fluorophosphatase (DFPase) from Loligo vulgaris catalyzes the hydrolysis of OP compounds. Here, we investigate the mechanisms of diisopropylfluorophosphate (DFP) and (S)-sarin hydrolysis by DFPase with quantum mechanical/molecular mechanical umbrella sampling simulations. We find that the mechanism for hydrolysis of DFP involves nucleophilic attack by Asp229 on phosphorus to form a pentavalent intermediate. P-F bond dissociation then yields a phosphoacyl enzyme intermediate in the rate-limiting step. The simulations suggest that a water molecule, coordinated to the catalytic Ca(2+), donates a proton to Asp121 and then attacks the tetrahedral phosphoacyl intermediate to liberate the diisopropylphosphate product. In contrast, the calculated free energy barrier for hydrolysis of (S)-sarin by the same mechanism is highly unfavorable, primarily because of the instability of the pentavalent phosphoenzyme species. Instead, simulations suggest that hydrolysis of (S)-sarin proceeds by a mechanism in which Asp229 could activate an intervening water molecule for nucleophilic attack on the substrate. These findings may lead to improved strategies for engineering DFPase and related six-bladed β-propeller folds for more efficient degradation of OP compounds.

Published

2014

38. Molecular dynamics simulation of class 3 aldehyde dehydrogenase

Author

John Hempel, Hugh B. Nicholas, and Troy Wymore

Subjects

Stereochemistry, Coenzymes, Aldehyde dehydrogenase, In Vitro Techniques, Toxicology, Cofactor, Molecular dynamics, chemistry.chemical_compound, Catalytic Domain, Animals, chemistry.chemical_classification, biology, Nicotinamide, Active site, Substrate (chemistry), General Medicine, Aldehyde Dehydrogenase, NAD, Rats, Kinetics, Enzyme, Models, Chemical, chemistry, Benzaldehydes, biology.protein, Quantum Theory, Thermodynamics, NAD+ kinase, Holoenzymes

Abstract

Molecular dynamics (MD) simulation of the rat class 3 aldehyde dehydrogenase (ALDH) with nicotinamide dinucleotide (NAD) cofactors and explicit water molecules are reported. Our results demonstrate that MD simulation using the latest methodologies can maintain the crystal structure of the enzyme, as well as closely reproduce the short timescale dynamics of the enzyme. Furthermore, the examination of the distance between the nucleophilic Cys-243 and the NAD cofactor reveal important fluctuations that could be linked to ALDH catalysis. Finally, our quantum mechanical model of benzaldehyde in the active site of ALDH demonstrates that the enzyme requires only minor conformational changes to be poised for nucleophilic attack on the substrate.

Published

2001

39. Molecular dynamics simulation of the structure and dynamics of a dodecylphosphocholine micelle in aqueous solution

Author

Xinfeng Gao, T.C. Wong, and Troy Wymore

Subjects

chemistry.chemical_classification, Aqueous solution, Hydrogen, Chemistry, Organic Chemistry, chemistry.chemical_element, Moment of inertia, Micelle, Analytical Chemistry, Inorganic Chemistry, Molecular dynamics, Hydrocarbon, Computational chemistry, Chemical physics, Molecule, Conformational isomerism, Spectroscopy

Abstract

A molecular dynamics (MD) simulation study of a dodecylphosphocholine (DPC) micelle in water is presented. This system contains 60 DPC molecules in 5294 water molecules. The structure, shape, hydrocarbon chain fluidity, the hydration of the head group and the hydrocarbon chain, and the dynamics of the micelle were analyzed from the 1.2 ns constant pressure MD simulation. The micelle was found to be slightly prolate, with the ratio of the moments of inertia 1:24:1.11:1. The penetration of water into the interior of the micelle is limited. The interaction of water with the micelle mainly comes from the head group, and the modes of interaction with the positively charged choline group and the negatively charged phosphate group can be deciphered from the radial distribution functions between these groups and both the hydrogen and the oxygen atoms of water. From the ratio of the trans/gauche conformers on the hydrocarbon chain, and the density distribution of the various carbons with respect to the center of the mass of the micelle, the conformational properties of the hydrocarbon chains have been analyzed. The dynamics of the micelle was probed by the trans–gauche conformational transition rates and from the time correlation function of the C–H bonds. From the latter, the order parameters and the correlation times for the internal motions have been obtained. These parameters were found to be, for the most part, in excellent agreement with those obtained from NMR relaxation.

Published

1999

40. Molecular Dynamics Study of Substance P Peptides Partitioned in a Sodium Dodecylsulfate Micelle

Author

Tuck C. Wong and Troy Wymore

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Protein Conformation, Lipid Bilayers, Biophysics, Substance P, Micelle, Biophysical Phenomena, Hydrophobic effect, Molecular dynamics, Protein structure, Side chain, Organic chemistry, Amino Acid Sequence, Carbon Tetrachloride, Micelles, Chemistry, Hydrogen bond, Solvation, Sodium Dodecyl Sulfate, Water, Nuclear magnetic resonance spectroscopy, Crystallography, Solvents, Thermodynamics, Research Article

Abstract

Two neuropeptides, substance P (SP) and SP-tyrosine-8 (SP-Y8), have been studied by molecular dynamics (MD) simulation in an explicit sodium dodecylsulfate (SDS) micelle. Initially, distance restraints derived from NMR nuclear Overhauser enhancements (NOE) were incorporated in the restrained MD (RMD) during the equilibration stage of the simulation. It was shown that when SP-Y8 was initially placed in an insertion (perpendicular) configuration, the peptide equilibrated to a surface-bound (parallel) configuration in approximately 450 ps. After equilibration, the conformation and orientation of the peptides, the solvation of both the backbone and the side chain of the residues, hydrogen bonding, and the dynamics of the peptides were analyzed from trajectories obtained from the RMD or the subsequent free MD (where the NOE restraints were removed). These analyses showed that the peptide backbones of all residues are either solvated by water or are hydrogen-bonded. This is seen to be an important factor against the insertion mode of interaction. Most of the interactions come from the hydrophobic interaction between the side chains of Lys-3, Pro-4, Phe-7, Phe-8, Leu-10, and Met-11 for SP, from Lys-3, Phe-7, Leu-10, and Met-11 in SP-Y8, and the micellar interior. Significant interactions, electrostatic and hydrogen bonding, between the N-terminal residues, Arg-Pro-Lys, and the micellar headgroups were observed. These latter interactions served to affect both the structure and, especially, the flexibility, of the N-terminus. The results from simulation of the same peptides in a water/CCl4 biphasic cell were compared with the results of the present study, and the validity of using the biphasic system as an approximation for peptide-micelle or peptide-bilayer systems is discussed.

Published

1999

41. Molecular Dynamics Study of Substance P Peptides in a Biphasic Membrane Mimic

Author

Troy Wymore and Tuck C. Wong

Subjects

Models, Molecular, Magnetic Resonance Spectroscopy, Protein Conformation, Lipid Bilayers, Biophysics, Substance P, Biophysical Phenomena, Hydrophobic effect, Molecular dynamics, Protein structure, Side chain, Organic chemistry, Amino Acid Sequence, Carbon Tetrachloride, Protein secondary structure, Micelles, Hydrogen bond, Chemistry, Solvation, Membrane Proteins, Water, Hydrogen Bonding, Nuclear magnetic resonance spectroscopy, Crystallography, Solvents, Thermodynamics, Research Article

Abstract

Two neuropeptides, substance P (SP) and SP-tyrosine-8 (SP-Y8), have been studied by molecular dynamics (MD) simulation in a TIP3P water/CCl4 biphasic solvent system as a mimic for the water-membrane system. Initially, distance restraints derived from NMR nuclear Overhauser enhancements (NOE) were incorporated in the restrained MD (RMD) in the equilibration stage of the simulation. The starting orientation/position of the peptides for the MD simulation was either parallel to the water/CCl4 interface or in a perpendicular/insertion mode. In both cases the peptides equilibrated and adopted a near-parallel orientation within approximately 250 ps. After equilibration, the conformation and orientation of the peptides, the solvation of both the backbone and the side chain of the residues, hydrogen bonding, and the dynamics of the peptides were analyzed from trajectories obtained in the RMD or the subsequent free MD (where the NOE restraints were removed). These analyses showed that the peptide backbone of nearly all residues are either solvated by water or are hydrogen-bonded. This is seen to be an important factor against the insertion mode of interaction. Most of the interactions with the hydrophobic phase come from the hydrophobic interactions of the side chains of Pro-4, Phe-7, Phe-8, Leu-10, and Met-11 for SP, and Phe-7, Leu-10, Met-11 and, to a lesser extent, Tyr-8 in SP-Y8. Concerted conformational transitions took place in the time frame of hundreds of picoseconds. The concertedness of the transition was due to the tendency of the peptide to maintain the necessary secondary structure to position the peptide properly with respect to the water/CCl4 interface.

Published

1999

42. Orf6: Biochemical Characterization of a Putative Thioesterase from a Polyunsaturated Fatty Acid Synthase

Author

Maria M Rodriguez-Guilbe, Abel Baerga-Ortiz, Troy Wymore, Eric Screiter, and Ricardo González-Méndez

Subjects

chemistry.chemical_classification, Fatty acid synthase, chemistry, Biochemistry, Thioesterase, biology, ATP synthase, Genetics, biology.protein, Molecular Biology, Biotechnology, Polyunsaturated fatty acid

Published

2012

43. Adverse effects on plasma polymerized films due to previous oxygen etching in an ‘‘electrodeless’’ reactor

Author

Troy Wymore and Michael F. Nichols

Subjects

Materials science, Analytical chemistry, Surfaces and Interfaces, Condensed Matter Physics, Plasma polymerization, Surfaces, Coatings and Films, Amorphous solid, Carbon film, Polymerization, Chemical engineering, Etching (microfabrication), Thin film, Forming gas, Plasma processing

Abstract

Amorphous hydrogenated carbon (a‐C:H) films prepared by plasma polymerization can contain chemical species due not only to the process gas species, but species from prior processes in the deposition chamber. Our studies showed that standard O2 etching/ cleaning processes done prior to plasma film formation will affect future film deposition rate measurements and carbonyl group formation. Additionally, substrate etching by polymer forming gas species is shown through the 956 cm−1 negative peak in the IR spectrum.

Published

1994

44. A Mechanism for Evolving Novel Plant Sesquiterpene Synthase Function

Author

Charles L. Brooks, Troy Wymore, Alexander J. Ropelewski, Hugh B. Nicholas, and Brian Y. Chen

Subjects

biology, ATP synthase, Phylogenetic tree, Stereochemistry, Organic Chemistry, Active site, Computer Science Applications, Catalytic cycle, Structural Biology, Molecular evolution, Phylogenetics, Drug Discovery, biology.protein, Plant defense against herbivory, Molecular Medicine, Function (biology)

Abstract

Plant sesquiterpene synthases, a subset of the terpene synthase superfamily, are a mechanistically diverse family of enzymes capable of synthesizing hundreds of complex compounds with high regio- and stereospecificity and are of biological importance due to their role in plant defense mechanisms. In the current report we describe a large-scale, high-resolution phylogenetic analysis of ∼200 plant sesquiterpene synthases integrated with structural and experimental data that address these issues. We observe that all sequences that cluster together on the phylogenetic tree into well-defined groups share at least the first reaction in the catalytic mechanism subsequent to the initial ionization step and many share steps beyond this down to proton transfers between the enzyme and substrate. Most significant is the previously unreported high conservation of an Asp-Tyr-Asp triad. Due to its high conservation, patterns in the phylogenetic tree as well as experimental and modeling results, we suggest that this Asp-Tyr-Asp triad is an important functional element responsible for many proton transfers to and from the substrate and intermediates along the plant sesquiterpene synthase catalytic cycle and whose position can be tuned by residues outside the active site that can lead to the evolution of novel enzyme function.

Published

2011

45. A quantum chemical study of the mechanism of action of Vitamin K carboxylase (VKC) III. Intermediates and transition states

Author

Charles H, Davis, David, Deerfield, Troy, Wymore, Darrel W, Stafford, and Lee G, Pedersen

Subjects

Models, Molecular, Vitamin K, Carbon-Carbon Ligases, Models, Chemical, Molecular Structure, Quantum Theory, Hydroquinones

Abstract

A reaction path including transition states is generated for the Dowd mechanism [P. Dowd, R. Hershlne, S.W. Ham, S. Naganathan. Vitamin K and energy transduction: a base strength amplification mechanism. Science 269 (2005) 1684-1691] of action for Vitamin K carboxylase (VKC) using quantum chemical methods (B3LYP/6-311G**). VKC, an essential enzyme in mammalian systems, catalyzes the conversion of hydroquinone form of Vitamin K to the epoxide form in the presence of oxygen. An intermediate species of the oxidation of Vitamin K, an alkoxide, acts apparently to abstract the gamma hydrogen from specifically located glutamate residues. We are able to follow the Dowd proposed path to generate this alkoxide species. The geometries of the proposed model intermediates and transition states in the mechanism are energy optimized. We find that the most energetic step in the mechanism is the uni-deprotonation of the hydroquinone - once this occurs, there is only a small barrier of 3.5kcal/mol for the interaction of oxygen with the carbon to be attacked - and then the reaction proceeds downhill in free energy to form the critical alkoxide species. The results are consistent with the idea that the enzyme probably acts to facilitate the formation of the epoxide by reducing the energy required to deprotonate the hydroquinone form.

Published

2006

46. A quantum chemical study of the mechanism of action of Vitamin K epoxide reductase (VKOR) II. Transition states

Author

Charles H, Davis, David, Deerfield, Troy, Wymore, Darrel W, Stafford, and Lee G, Pedersen

Subjects

Models, Molecular, Vitamin K, Models, Chemical, Molecular Structure, Vitamin K Epoxide Reductases, Epoxy Compounds, Quantum Theory, Thermodynamics, Water, Protons, Mixed Function Oxygenases

Abstract

A reaction path including transition states is generated for the Silverman mechanism [R.B. Silverman, Chemical model studies for the mechanism of Vitamin K epoxide reductase, J. Am. Chem. Soc. 103 (1981) 5939-5941] of action for Vitamin K epoxide reductase (VKOR) using quantum mechanical methods (B3LYP/6-311G**). VKOR, an essential enzyme in mammalian systems, acts to convert Vitamin K epoxide, formed by Vitamin K carboxylase, to its (initial) quinone form for cellular reuse. This study elaborates on a prior work that focused on the thermodynamics of VKOR [D.W. Deerfield II, C.H. Davis, T. Wymore, D.W. Stafford, L.G. Pedersen, Int. J. Quant. Chem. 106 (2006) 2944-2952]. The geometries of proposed model intermediates and transition states in the mechanism are energy optimized. We find that once a key disulfide bond is broken, the reaction proceeds largely downhill. An important step in the conversion of the epoxide back to the quinone form involves initial protonation of the epoxide oxygen. We find that the source of this proton is likely a free mercapto group rather than a water molecule. The results are consistent with the current view that the widely used drug Warfarin likely acts by blocking binding of Vitamin K at the VKOR active site and thereby effectively blocking the initiating step. These results will be useful for designing more complete QM/MM studies of the enzymatic pathway once three-dimensional structural data is determined and available for VKOR.

Published

2006

47. Molecular recognition of aldehydes by aldehyde dehydrogenase and mechanism of nucleophile activation

Author

Troy, Wymore, John, Hempel, Samuel S, Cho, Alexander D, Mackerell, Hugh B, Nicholas, and David W, Deerfield

Subjects

Models, Molecular, Aldehydes, Binding Sites, Protein Conformation, Benzaldehydes, Computer Simulation, Hydrogen Bonding, Aldehyde Dehydrogenase, Protein Binding

Abstract

Experimental structural data on the state of substrates bound to class 3 Aldehyde Dehydrogenases (ALDH3A1) is currently unknown. We have utilized molecular mechanics (MM) simulations, in conjunction with new force field parameters for aldehydes, to study the atomic details of benzaldehyde binding to ALDH3A1. Our results indicate that while the nucleophilic Cys243 must be in the neutral state to form what are commonly called near-attack conformers (NACs), these structures do not correlate with increased complexation energy calculated with the MM-Generalized Born Molecular Volume (GBMV) method. The negatively charged Cys243 (thiolate form) of ALDH3A1 also binds benzaldehyde in a stable conformation but in this complex the sulfur of Cys243 is oriented away from benzaldehyde yet yields the most favorable MM-GBMV complexation energy. The identity of the general base, Glu209 or Glu333, in ALDHs remains uncertain. The MM simulations reveal structural and possible functional roles for both Glu209 and Glu333. Structures from the MM simulations that would support either glutamate residue as the general base were further examined with Hybrid Quantum Mechanical (QM)/MM simulations. These simulations show that, with the PM3/OPLS potential, Glu209 must go through a step-wise mechanism to activate Cys243 through an intervening water molecule while Glu333 can go through a more favorable concerted mechanism for the same activation process.

Published

2004

48. An algorithm for identification and ranking of family-specific residues, applied to the ALDH3 family

Author

Troy Wymore, John Perozich, Hugh B. Nicholas, and John Hempel

Subjects

Models, Molecular, Protein family, Dimer, Lysine, General Medicine, Biology, Protein superfamily, Aldehyde Dehydrogenase, Toxicology, Ranking (information retrieval), chemistry.chemical_compound, Catalytic cycle, chemistry, Catalytic Domain, Identification (biology), Amino acid residue, Amino Acids, Algorithm, Algorithms

Abstract

An algorithm for detecting amino acid residues characteristic of individual protein families from within aligned collections of paralogous sequences, and its application to the ALDH3 family versus the rest of the ALDH extended family is described. Residues illuminated by this analysis include a key intramolecular tether, a lysine that makes an intersubunit contact at the dimer interface, three residues in close association with the substrate-binding funnel, and a pair of residues suggested to participate in proton relay during the catalytic cycle.

Published

2003

49. Multiscale modeling of nerve agent hydrolysis mechanisms: a tale of two Nobel Prizes

Author

Troy Wymore and Martin J. Field

Subjects

Chemical Warfare Agents, Chemical warfare, Nobel prizes, Nanotechnology, Biochemical engineering, Condensed Matter Physics, Multiscale modeling, Mathematical Physics, Atomic and Molecular Physics, and Optics, Chemical weapon

Abstract

The 2013 Nobel Prize in Chemistry was awarded for the development of multiscale models for complex chemical systems, whereas the 2013 Peace Prize was given to the Organisation for the Prohibition of Chemical Weapons for their efforts to eliminate chemical warfare agents. This review relates the two by introducing the field of multiscale modeling and highlighting its application to the study of the biological mechanisms by which selected chemical weapon agents exert their effects at an atomic level.

Published

2014

50. Combining neutron crystallography, high-performance computing for enzyme design

Author

Paul Langan, Amandeep K. Sangha, David E. Graham, Matt Challacombe, Trevor Forsyth, Jerry M. Parks, David A. Keen, Andrey Kovalevsky, Sax A. Mason, and Troy Wymore

Subjects

Inorganic Chemistry, Crystallography, Materials science, Structural Biology, General Materials Science, Neutron, Physical and Theoretical Chemistry, Condensed Matter Physics, Supercomputer, Biochemistry

Abstract

Enzymes continue to expand their role in industry as a "green" option for the synthesis of value-added products. They are targeted for the design of drugs in pharmaceutical applications and also for protein engineering in industry to improve their efficiency, stability, and specificity. Knowledge of the exact mechanisms of enzymatic reactions may provide essential information for more effective drug design and enzyme engineering. For the first time, we are employing a joint X-ray/neutron (XN) protein crystallographic technique in combination with high-performance computing, including QM and QM/MM calculations, MD and Rosetta simulations, to investigate the mechanisms of several enzymes that are important to renewable energy and chemical synthesis. D-xylose isomerase (XI) is an enzyme which can be used to increase the production of biofuels from lignocellulosic biomass and also to synthesize rare sugars for pharmaceutical industry. XI catalyzes the reversible multi-stage sugar inter-conversion reaction facilitated by the presence of two divalent metal cations in its active site. It primarily catalyzes the isomerization of the aldo-sugar D-xylose to the keto-isomer D-xylulose, but can also epimerize L-arabinose into L-ribose, albeit much less efficiently. The reaction involves moving hydrogen atoms between the protein residues, sugar and water molecules, and can only be understood if hydrogen atoms are visualized at each reaction stage. We have obtained a number of joint XN structures of XI complexes representing snapshots along the reaction path with D-glucose, D-xylose and L-arabinose. The suggested reaction mechanism has been verified by QM calculations using the novel O(N) methodology. We are using this structural and mechanistic information to re-design XI to be more efficient on D-xylose and L-arabinose for biofuels and biomedical applications by employing QM/MM, MD, and Rosetta methodologies.

Published

2014