Role of Glutamic Acid 109 in the Active Site of the β Subunit of Tryptophan Synthase from Salmonella Typhimurium in Controlling the Reaction Specificity and Substrate Specificity of the α2β2 Complex

The role of active-site residues in the dealkylation reaction in the PSCS diastereomer of 2-(3,3-dimethylbutyl)methylphosphonofluoridate (soman)-inhibited Torpedo californicaacetylcholinesterase (AChE) was investigated by full-scale molecular dynamics simulations using CHARMM: > 400ps equilibration was followed by 150–200ps production runs with the fully solvated tetracoordinate phosphonate adduct of the wild-type, Trp84Ala and Gly199Gln mutants of AChE. Parallel simulations were carried out with the tetrahedral intermediate formed between serine-200 Oγ of AChE and acetylcholine. We found that the NεH in histidine H+-440 is positioned to protonate the oxygen in choline and thus promote its departure. In contrast, NεH in histidine H+-440 is not aligned for a favourable proton transfer to the pinacolyl O to promote dealkylation, but electrostatic stabilization by histidine H+-440 of the developing anion on the phosphonate monoester occurs. Destabilizing interactions between residues and the alkyl fragment of the inhibitor enforce methyl migration from Cβ to Cα concerted with C—O bond breaking in soman-inhibited AChE. Tryptophan-84, phenyalanine-331 and glutamic acid-199 are within 3.7–3.9 Å (1 Å=10-10 m) from a methyl group in Cβ, 4.5–5.1 Å from Cβ and 4.8–5.8 Å from Cα, and can better stabilize the developing carbenium ion on Cβ than on Cα. The Trp84Ala mutation eliminates interactions between the incipient carbenium ion and the indole ring, but also reduces its interactions with phenylalanine-331 and aspartic acid-72. Tyrosine-130 promotes dealkylation by interacting with the indole ring of tryptophan-84. Glutamic acid-443 can influence the orientation of active-site residues through tyrosine-421, tyrosine-442 and histidine-440 in soman-inhibited AChE, and thus facilitate dealkylation.

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A theoretical study of hydrolysis by phospholipase A2: the catalytic role of the active site and substrate specificity

Journal of the Chemical Society Perkin Transactions 2 ◽

10.1039/p29900001259 ◽

1990 ◽

pp. 1259 ◽

Cited By ~ 14

Author(s):

Bohdan Waszkowycz ◽

Ian H. Hillier ◽

Nigel Gensmantel ◽

David W. Payling

Keyword(s):

Substrate Specificity ◽

Phospholipase A2 ◽

Active Site ◽

Theoretical Study ◽

Catalytic Role

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Structural Characterization of an S-enantioselective Imine Reductase from Mycobacterium Smegmatis

Biomolecules ◽

10.3390/biom10081130 ◽

2020 ◽

Vol 10 (8) ◽

pp. 1130

Author(s):

Timo Meyer ◽

Nadine Zumbrägel ◽

Christina Geerds ◽

Harald Gröger ◽

Hartmut H. Niemann

Keyword(s):

Substrate Specificity ◽

Active Site ◽

Mycobacterium Smegmatis ◽

Catalytic Mechanism ◽

Building Blocks ◽

Secondary Amines ◽

Hydrophobic Amino Acids ◽

High Degree

NADPH-dependent imine reductases (IREDs) are enzymes capable of enantioselectively reducing imines to chiral secondary amines, which represent important building blocks in the chemical and pharmaceutical industry. Since their discovery in 2011, many previously unknown IREDs have been identified, biochemically and structurally characterized and categorized into families. However, the catalytic mechanism and guiding principles for substrate specificity and stereoselectivity remain disputed. Herein, we describe the crystal structure of S-IRED-Ms from Mycobacterium smegmatis together with its cofactor NADPH. S-IRED-Ms belongs to the S-enantioselective superfamily 3 (SFam3) and is the first IRED from SFam3 to be structurally described. The data presented provide further evidence for the overall high degree of structural conservation between different IREDs of various superfamilies. We discuss the role of Asp170 in catalysis and the importance of hydrophobic amino acids in the active site for stereospecificity. Moreover, a separate entrance to the active site, potentially functioning according to a gatekeeping mechanism regulating access and, therefore, substrate specificity is described.

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Role of active-site residues Tyr55 and Tyr114 in catalysis and substrate specificity ofCorynebacterium diphtheriaeC-S lyase

Proteins Structure Function and Bioinformatics ◽

10.1002/prot.24707 ◽

2014 ◽

Vol 83 (1) ◽

pp. 78-90 ◽

Cited By ~ 3

Author(s):

Alessandra Astegno ◽

Alessandra Allegrini ◽

Stefano Piccoli ◽

Alejandro Giorgetti ◽

Paola Dominici

Keyword(s):

Substrate Specificity ◽

Active Site ◽

Active Site Residues

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Mapping the Substrate Binding Site of Phenylacetone Monooxygenase from Thermobifida fusca by Mutational Analysis

Applied and Environmental Microbiology ◽

10.1128/aem.00687-11 ◽

2011 ◽

Vol 77 (16) ◽

pp. 5730-5738 ◽

Cited By ~ 36

Author(s):

Hanna M. Dudek ◽

Gonzalo de Gonzalo ◽

Daniel E. Torres Pazmiño ◽

Piotr Stępniak ◽

Lucjan S. Wyrwicz ◽

...

Keyword(s):

Substrate Specificity ◽

Binding Site ◽

Active Site ◽

Structural Model ◽

Mutational Analysis ◽

Substrate Binding ◽

Thermobifida Fusca ◽

Content Type ◽

Substrate Binding Site

ABSTRACTBaeyer-Villiger monooxygenases catalyze oxidations that are of interest for biocatalytic applications. Among these enzymes, phenylacetone monooxygenase (PAMO) fromThermobifida fuscais the only protein showing remarkable stability. While related enzymes often present a broad substrate scope, PAMO accepts only a limited number of substrates. Due to the absence of a substrate in the elucidated crystal structure of PAMO, the substrate binding site of this protein has not yet been defined. In this study, a structural model of cyclopentanone monooxygenase, which acts on a broad range of compounds, has been prepared and compared with the structure of PAMO. This revealed 15 amino acid positions in the active site of PAMO that may account for its relatively narrow substrate specificity. We designed and analyzed 30 single and multiple mutants in order to verify the role of these positions. Extensive substrate screening revealed several mutants that displayed increased activity and altered regio- or enantioselectivity in Baeyer-Villiger reactions and sulfoxidations. Further substrate profiling resulted in the identification of mutants with improved catalytic properties toward synthetically attractive compounds. Moreover, the thermostability of the mutants was not compromised in comparison to that of the wild-type enzyme. Our data demonstrate that the positions identified within the active site of PAMO, namely, V54, I67, Q152, and A435, contribute to the substrate specificity of this enzyme. These findings will aid in more dedicated and effective redesign of PAMO and related monooxygenases toward an expanded substrate scope.

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Structures of substrate- and nucleotide-bound propionate kinase fromSalmonella typhimurium: substrate specificity and phosphate-transfer mechanism

Acta Crystallographica Section D Biological Crystallography ◽

10.1107/s1399004715009992 ◽

2015 ◽

Vol 71 (8) ◽

pp. 1640-1648 ◽

Cited By ~ 1

Author(s):

Ambika Mosale Venkatesh Murthy ◽

Subashini Mathivanan ◽

Sagar Chittori ◽

Handanahal Subbarao Savithri ◽

Mathur Ramabhadrashastry Narasimha Murthy

Keyword(s):

Substrate Specificity ◽

Crystal Structures ◽

Active Site ◽

Structural Data ◽

Transfer Mechanism ◽

Phosphoryl Group ◽

Phosphoryl Transfer ◽

Active Site Pocket ◽

Bipyramidal Structure

Kinases are ubiquitous enzymes that are pivotal to many biochemical processes. There are contrasting views on the phosphoryl-transfer mechanism in propionate kinase, an enzyme that reversibly transfers a phosphoryl group from propionyl phosphate to ADP in the final step of non-oxidative catabolism of L-threonine to propionate. Here, X-ray crystal structures of propionate- and nucleotide-boundSalmonella typhimuriumpropionate kinase are reported at 1.8–2.0 Å resolution. Although the mode of nucleotide binding is comparable to those of other members of the ASKHA superfamily, propionate is bound at a distinct site deeper in the hydrophobic pocket defining the active site. The propionate carboxyl is at a distance of ∼5 Å from the γ-phosphate of the nucleotide, supporting a direct in-line transfer mechanism. The phosphoryl-transfer reaction is likely to occurviaan associative SN2-like transition state that involves a pentagonal bipyramidal structure with the axial positions occupied by the nucleophile of the substrate and the O atom between the β- and the γ-phosphates, respectively. The proximity of the strictly conserved His175 and Arg236 to the carboxyl group of the propionate and the γ-phosphate of ATP suggests their involvement in catalysis. Moreover, ligand binding does not induce global domain movement as reported in some other members of the ASKHA superfamily. Instead, residues Arg86, Asp143 and Pro116-Leu117-His118 that define the active-site pocket move towards the substrate and expel water molecules from the active site. The role of Ala88, previously proposed to be the residue determining substrate specificity, was examined by determining the crystal structures of the propionate-bound Ala88 mutants A88V and A88G. Kinetic analysis and structural data are consistent with a significant role of Ala88 in substrate-specificity determination. The active-site pocket-defining residues Arg86, Asp143 and the Pro116-Leu117-His118 segment are also likely to contribute to substrate specificity.

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Multiple substitutions at position 104 of β-lactamase TEM-1: assessing the role of this residue in substrate specificity

Biochemical Journal ◽

10.1042/bj3050033 ◽

1995 ◽

Vol 305 (1) ◽

pp. 33-40 ◽

Cited By ~ 39

Author(s):

A Petit ◽

L Maveyraud ◽

F Lenfant ◽

J P Samama ◽

R Labia ◽

...

Keyword(s):

Substrate Specificity ◽

Active Site ◽

Kinetic Properties ◽

Third Generation ◽

Wild Type Enzyme ◽

Beta Lactamases ◽

Class A ◽

Extended Spectrum ◽

Third Generation Cephalosporins

Residue 104 is frequently mutated from a glutamic acid to a lysine in the extended-spectrum TEM beta-lactamases responsible for the resistance to third-generation cephalosporins in clinical Gram negative strains. Among class A beta-lactamases, it is the most variable residue within a highly conserved loop which delineates one side of the active site of the enzymes. To investigate the role of this residue in the extended-spectrum phenotype, it has been replaced by serine, threonine, lysine, arginine, tyrosine and proline. All these substitutions yield active enzymes, with no drastic changes in kinetic properties compared with the wild-type enzyme, except with cefaclor, but an overall improved affinity for second- and third-generation cephalosporins. Only mutant E104K exhibits a significant ability to hydrolyse cefotaxime. Molecular modelling shows that the substitutions have generally no impact on the conformation of the 101-111 loop as the side chains of residues at position 104 are all turned towards the solvent. Unexpectedly, the E104P mutant turns out to be the most efficient enzyme. All our results argue in favour of an indirect role for this residue 104 in the substrate specificity of the class A beta-lactamases. This residue contributes to the precise positioning of residues 130-132 which are involved in substrate binding and catalysis. Changing residue 104 could also modify slightly the local electrostatic potential in this part of the active site. The limited kinetic impact of the mutations at this position have to be analysed in the context of the microbiological problem of resistance to third-generation cephalosporins. Although mutation E104K improves the ability of the enzyme to hydrolyse these compounds, it is not sufficient to confer true resistance, and is always found in clinical isolates associated with at least one mutation at another part of the active site. It is the combined effect of the two mutations that synergistically enhances the hydrolytic capability of the enzyme towards third-generation cephalosporins.

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