Catalytic role of enzymes: Short strong H-bond-induced partial proton shuttles and charge redistributions

Kim, Kwang S.; Oh, Keun Sang; Lee, Jin Yong

doi:10.1073/pnas.97.12.6373

Cited by 104 publications

(59 citation statements)

References 55 publications

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“…In the crystal structure, determined at pH 4.6, His-138 forms a short 2.46-Å hydrogen bond with one of the phosphate oxygens of 3PG. Similar short hydrogen bonds are observed in the active sites of a number of enzymes, and they are proposed to play a variety of significant roles in catalysis (21)(22)(23). At physiological pH, the His-138 side chain and the glyphosate phosphonate group are likely in a deprotonated state.…”

Section: Mechanism Of Glyphosate Nacetylation By Gatmentioning

confidence: 85%

The Molecular Basis of Glyphosate Resistance by an Optimized Microbial Acetyltransferase

Siehl

Castle

Gorton

et al. 2007

Journal of Biological Chemistry

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GAT is an N-acetyltransferase from Bacillus licheniformis that was optimized by gene shuffling for acetylation of the broad spectrum herbicide, glyphosate, forming the basis of a novel mechanism of glyphosate tolerance in transgenic plants ( Glyphosate (N-phosphonomethylglycine) is a widely used herbicide that acts nonselectively through inhibition of 5-enolpyruvylshikimate-3-phosphate (EPSP) 4 synthase in the aromatic biosynthesis pathway (2). Its efficacy against all plant species, low cost, low mammalian toxicity, and benign environmental impact favor its use in crops that have a transgenic tolerance mechanism (3). The predominant transgene currently in use encodes a bacterial EPSP synthase that is nearly insensitive to inhibition by glyphosate (2). We reported an alternative strategy for glyphosate resistance involving enzymatic conversion of glyphosate to N-acetylglyphosate (NAG) (1). Because the acetylated form of glyphosate has low affinity for the active site of EPSP synthase, it is nonherbicidal. Three variants of an enzyme that catalyzes N-acetylation of the secondary amine of glyphosate were discovered from Bacillus licheniformis. These GAT 5 enzymes are 17 kDa in size, are most active at pH 6.8, and have a K m for acetyl coenzyme A (AcCoA) of 1-2 M. The native enzymes are very poor catalysts for acetylation of glyphosate, with a k cat of 5.3 min Ϫ1 and K m,GPJ of 1.3 mM (for ST401 GAT, referred to hereafter as native GAT). 6 The B. licheniformis enzymes belong to a diverse family of largely uncharacterized bacterial N-acetyltransferases sharing between 30 and 64% amino acid identity to native GAT (Fig. 1). Despite extensive screening of biological amines, including amino acids, nucleotides and antibiotics, the physiological substrates for the native enzymes are unknown (4).To develop gat as a transgene for glyphosate resistance in crops, we subjected the three B. licheniformis enzymes to 11 rounds of gene shuffling and obtained optimized variants with up to a 4,500-fold increase in catalytic efficiency (k cat /K m ) relative to the native enzyme. This was achieved through a combination of improvements in k cat (190-fold) and K m,GPJ (24-fold). When introduced into plants, optimized gat genes confer robust tolerance to glyphosate (1).To gain insight into the molecular mechanism of glyphosate N-acetylation by GAT, we determined the structure of a 7th round GAT variant (termed R7 GAT) in ternary complex with AcCoA and the competitive inhibitor 3-phosphoglycerate (3PG) and in binary complex with oxidized CoA. We also car-* The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact. The atomic coordinates and structure factors (code 2JDC, 2JDD) have been deposited in the Protein

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Section: Mechanism Of Glyphosate Nacetylation By Gatmentioning

confidence: 85%

The Molecular Basis of Glyphosate Resistance by an Optimized Microbial Acetyltransferase

Siehl

Castle

Gorton

et al. 2007

Journal of Biological Chemistry

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“…In the catalytic reaction of serine proteases, the well‐ordered residues aspartate, histidine, and serine are of great importance. The preorganization of the catalytic triads are the requirement for many of the catalytic activities38 inducing the acylation39 and short strong H‐bonds (SSHBs),40 along with proton shuttle and electron rearrangements 41. The hydroxyl group is made more nucleophilic by the neighboring histidine that extracts the hydroxyl hydrogen—a process that is facilitated by the polarizing effects of aspartate 42.…”

Section: Resultsmentioning

confidence: 99%

Homology modeling and molecular dynamics study of West Nile virus NS3 protease: A molecular basis for the catalytic activity increased by the NS2B cofactor

2006

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The West Nile virus (WNV) NS3 serine protease, which plays an important role in assembly of infective virion, is an attractive target for anti-WNV drug development. Cofactors NS2B and NS4A increase the catalytic activity of NS3 in dengue virus and Hepatitis C virus, respectively. Recent studies on the WNV-NS3 characterize the catalytically active form of NS3 by tethering the 40-residue cofactor NS2B. It is suggested that NS2B is essential for the NS3 activity in WNV, while there is no information of the WNV-NS3-related crystal structure. To understand the role of NS2B/substrate in the NS3 catalytic activity, we built a series of models: WNV-NS3 and WNV-NS3-NS2B and WNV-NS3-NS2B-substrate using homology modeling and molecular modeling techniques. Molecular dynamics (MD) simulations were performed for 2.75 ns on each model, to investigate the structural stabilization and catalytic triad motion of the WNV NS3 protease with and without NS2B/substrate. The simulations show that the NS3 rearrangement occurs upon the NS2B binding, resulting in the stable D75-OD1...H51-NH hydrogen bonding. After the substrate binds to the NS3-NS2B active site, the NS3 protease becomes more stable, and the catalytic triad is formed. These results provide a structural basis for the activation and stabilization of the enzyme by its cofactor and substrate.

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“…Short strong hydrogen bonds (SSHB)<2.7 Å are observed within some residues, ( (Table 4 and SV, Supplementary Material), which may strengthen the H-bond strength and sometimes show the catalytic effect in certain biosystems (Kim, Kim, Lee, Tarakeshwar, & Oh, 2002;Kim, Oh, & Lee, 2000). Moreover, all SSHBs forms triadic HBs (marked in Table 4 and SV, Supplementary Material) and we can safely predict that these residues play a very important role in the interaction.…”

Section: Binding Site Identificationmentioning

confidence: 89%

Modelling family 2 cystatins and their interaction with papain

Nandy

Bhuyan

Seal

2013

Journal of Biomolecular Structure and Dynamics

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Cystatins are extensively studied cysteine protease inhibitors, found in wide range of organisms with highly conserved structural folds. S-type of cystatins is well known for their abundance in saliva, high selectivity and poorer activity towards host cysteine proteases in comparison to their immediate ancestor cystatin C. Despite more than 90% sequence similarity, the members of this group show highly dissimilar binding affinity towards papain. Cystatin M/E is a potent inhibitor of legumain and papain like cysteine proteases and recognized for its involvement in skin barrier formation and potential role as a tumor suppressor gene. However, the structures of these proteins and their complexes with papain or legumain are still unknown. In the present study, we have employed computational methods to get insight into the interactions between papain and cystatins. Three-dimensional structures of the cystatins are generated by homology modelling, refined with molecular dynamics simulation, validated through numerous web servers and finally complexed with papain using ZDOCK algorithm in Discovery Studio. A high degree of shape complementarity is observed within the complexes, stabilized by numerous hydrogen bonds (HB) and hydrophobic interactions. Using interaction energy, HB and solvent accessible surface area analyses, we have identified a series of key residues that may be involved in papain-cystatin interaction. Differential approaches of cystatins towards papain are also noticed which are possibly responsible for diverse inhibitory activity within the group. These findings will improve our understanding of fundamental inhibitory mechanisms of cystatin and provide clues for further research.

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Catalytic role of enzymes: Short strong H-bond-induced partial proton shuttles and charge redistributions

Cited by 104 publications

References 55 publications

The Molecular Basis of Glyphosate Resistance by an Optimized Microbial Acetyltransferase

The Molecular Basis of Glyphosate Resistance by an Optimized Microbial Acetyltransferase

Homology modeling and molecular dynamics study of West Nile virus NS3 protease: A molecular basis for the catalytic activity increased by the NS2B cofactor

Modelling family 2 cystatins and their interaction with papain

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