Your search keyword '"Hydrolases genetics"' showing total 76 results

1. Increasing the Soluble Expression and Whole-Cell Activity of the Plastic-Degrading Enzyme MHETase through Consensus Design.

Author

Saunders JW, Damry AM, Vongsouthi V, Spence MA, Frkic RL, Gomez C, Yates PA, Matthews DS, Tokuriki N, McLeod MD, and Jackson CJ

Subjects

Phthalic Acids metabolism, Phthalic Acids chemistry, Hydrolases metabolism, Hydrolases genetics, Hydrolases chemistry, Solubility, Polyethylene Terephthalates metabolism, Polyethylene Terephthalates chemistry, Recombinant Proteins metabolism, Recombinant Proteins genetics, Recombinant Proteins chemistry, Protein Engineering methods, Protein Folding, Escherichia coli genetics, Escherichia coli metabolism, Bacterial Proteins metabolism, Bacterial Proteins genetics, Bacterial Proteins chemistry, Models, Molecular, Burkholderiales enzymology, Burkholderiales genetics, Burkholderiales metabolism

Abstract

The mono(2-hydroxyethyl) terephthalate hydrolase (MHETase) from Ideonella sakaiensis carries out the second step in the enzymatic depolymerization of poly(ethylene terephthalate) (PET) plastic into the monomers terephthalic acid (TPA) and ethylene glycol (EG). Despite its potential industrial and environmental applications, poor recombinant expression of MHETase has been an obstacle to its industrial application. To overcome this barrier, we developed an assay allowing for the medium-throughput quantification of MHETase activity in cell lysates and whole-cell suspensions, which allowed us to screen a library of engineered variants. Using consensus design, we generated several improved variants that exhibit over 10-fold greater whole-cell activity than wild-type (WT) MHETase. This is revealed to be largely due to increased soluble expression, which biochemical and structural analysis indicates is due to improved protein folding.

Published

2024

2. Structural Insights of a cis -Epoxysuccinate Hydrolase Facilitate the Development of Robust Biocatalysts for the Production of l-(+)-Tartrate.

Author

Han Y, Luo Y, Ma BD, Li J, Xu JH, and Kong XD

Subjects

Catalytic Domain, Crystallography, X-Ray, Hydrolases chemistry, Hydrolases metabolism, Hydrolases genetics, Models, Molecular, Protein Conformation, Tartrates metabolism, Tartrates chemistry, Biocatalysis

Abstract

l-(+)-Tartaric acid plays important roles in various industries, including pharmaceuticals, foods, and chemicals. cis -Epoxysuccinate hydrolases (CESHs) are crucial for converting cis -epoxysuccinate to l-(+)-tartrate in the industrial production process. There is, however, a lack of detailed structural and mechanistic information on CESHs, limiting the discovery and engineering of these industrially relevant enzymes. In this study, we report the crystal structures of Ro CESH and Ko CESH-l-(+)-tartrate complex. These structures reveal the key amino acids of the active pocket and the catalytic triad residues and elucidate a dynamic catalytic process involving conformational changes of the active site. Leveraging the structural insights, we identified a robust Bm CESH (550 ± 20 U·mg -1 ) with sustained catalytic activity even at a 3 M substrate concentration. After six batches of transformation, immobilized cells with overexpressed Bm CESH maintained 69% of their initial activity, affording an overall productivity of 200 g/L/h. These results provide valuable insights into the development of high-efficiency CESHs and the optimization of biotransformation processes for industrial uses.

Published

2024

3. Cg10062 Catalysis Forges a Link between Acetylenecarboxylic Acid and Bacterial Metabolism.

Author

Mathes Hewage A, Nayebi Gavgani H, Chi D, Qiu B, Geiger JH, and Draths K

Subjects

Amino Acid Substitution, Bacterial Proteins chemistry, Bacterial Proteins genetics, Bacterial Proteins metabolism, Biocatalysis, Biomass, Carbon Cycle, Catalytic Domain genetics, Corynebacterium glutamicum enzymology, Corynebacterium glutamicum genetics, Hydrolases chemistry, Hydrolases genetics, Kinetics, Models, Biological, Models, Molecular, Mutagenesis, Site-Directed, Alkynes metabolism, Bacteria metabolism, Fatty Acids, Unsaturated metabolism, Hydrolases metabolism

Abstract

The reliance of biocatalysis on plant-derived carbon for the synthesis of fuels and chemicals places it in direct competition with food production for resources. A potential solution to this problem is development of a metabolic link between alternative carbon sources and bacterial metabolism. Acetylenecarboxylic acid, which can be synthesized from methane and carbon dioxide, could enable this connection. It was previously shown that the enzyme Cg10062 catalyzes hydration of acetylenecarboxylate to afford malonate semialdehyde. Subsequent hydration-dependent decarboxylation to form acetaldehyde (81%), which was also observed, limits its biocatalytic usefulness. Several Cg10062 variants including E114Q and E114D do not catalyze decarboxylation and provide malonate semialdehyde as the sole product, albeit with substantially reduced catalytic activity. To identify an efficient enzyme capable of catalyzing acetylenecarboxylate hydration without decarboxylation, we undertook a mechanistic investigation of Cg10062 using mutagenesis, kinetic characterization, and X-ray crystallography. Cg10062 is a member of the tautomerase superfamily of enzymes, characterized by their β-α-β protein fold and an N-terminal proline residue situated at the center of the enzyme active site. Along with Pro-1, five additional active site residues (His-28, Arg-70, Arg-73, Tyr-103, and Glu-114) are required for Cg10062 activity. Incubation of crystals of four catalytically slow variants of Cg10062 with acetylenecarboxylate resulted in atomic resolution structures of Pro-1 bound to a complete set of intermediates, fully elaborating the detailed mechanism of the enzyme and establishing the process to involve covalent catalysis. Further, the intermediate-bound E114D structure explains the mechanism governing decarboxylation suppression. Together, these studies provide the most detailed picture of the catalytic mechanism of a tautomerase enzyme to date.

Published

2021

4. Variant Bacterial Riboswitches Associated with Nucleotide Hydrolase Genes Sense Nucleoside Diphosphates.

Author

Sherlock ME, Sadeeshkumar H, and Breaker RR

Subjects

Bacterial Proteins genetics, Base Sequence, Enterobacteriaceae metabolism, Hydrolases genetics, Leuconostoc mesenteroides metabolism, Nucleic Acid Conformation, RNA, Bacterial genetics, Bacterial Proteins metabolism, Hydrolases metabolism, Phosphoribosyl Pyrophosphate metabolism, RNA, Bacterial metabolism, Riboswitch genetics

Abstract

The ykkC RNA motif was a long-standing orphan riboswitch candidate that has recently been proposed to encompass at least five distinct bacterial riboswitch classes. Most ykkC RNAs belong to the subtype 1 group, which are guanidine-I riboswitches that regulate the expression of guanidine-specific carboxylase and transporter proteins. The remaining ykkC RNAs have been organized into at least four major categories called subtypes 2a-2d. Subtype 2a RNAs are riboswitches that sense the bacterial alarmone ppGpp and typically regulate amino acid biosynthesis genes. Subtype 2b riboswitches sense the purine biosynthetic intermediate PRPP and frequently partner with guanine riboswitches to regulate purine biosynthesis genes. In this study, we examined ykkC subtype 2c RNAs, which are found upstream of genes encoding hydrolase enzymes that cleave the phosphoanhydride linkages of nucleotide substrates. Subtype 2c representatives mostly recognize adenosine and cytidine 5'-diphosphate molecules in either their ribose or deoxyribose forms (ADP, dADP, CDP, and dCDP). Other nucleotide-containing compounds, especially nucleoside 5'-triphosphates, are strongly rejected by some members of this putative riboswitch class. High ligand concentrations in vivo are predicted to turn on expression of hydrolase enzymes, which presumably function to balance cellular nucleotide pools. These results further showcase the striking functional diversity derived from the structural scaffold shared among all ykkC motif RNAs, which has been adapted to sense at least five different types of natural ligands. Moreover, riboswitches for nucleoside diphosphates provide additional examples of the numerous partnerships observed between natural RNA aptamers and nucleotide-derived ligands, including metabolites, coenzymes, and signaling molecules.

Published

2019

5. Folding Determinants of Transmembrane β-Barrels Using Engineered OMP Chimeras.

Author

Chaturvedi D and Mahalakshmi R

Subjects

Bacterial Outer Membrane Proteins genetics, Escherichia coli genetics, Escherichia coli Proteins genetics, Hydrolases genetics, Micelles, Protein Engineering, Recombinant Fusion Proteins genetics, Yersinia pestis genetics, Bacterial Outer Membrane Proteins chemistry, Escherichia coli chemistry, Escherichia coli Proteins chemistry, Hydrolases chemistry, Protein Folding, Recombinant Fusion Proteins chemistry, Yersinia pestis chemistry

Abstract

Transmembrane β-barrel proteins (OMPs) are highly robust structures for engineering and development of nanopore channels, surface biosensors, and display libraries. Expanding the applications of designed OMPs requires the identification of elements essential for β-barrel scaffold formation and stability. Here, we have designed chimeric 8-stranded OMPs composed of strand hybrids of Escherichia coli OmpX and Yersinia pestis Ail, and identified molecular motifs essential for β-barrel scaffold formation. For the OmpX/Ail chimeras, we find that the central hairpin strands β4-β5 in tandem are vital for β-barrel folding. We also show that the central hairpin can facilitate OMP assembly even when present as the N- or C-terminal strands. Further, the C-terminal β-signal and strand length are important but neither sufficient nor mutually exclusive for β-barrel assembly. Our results point to a nonstochastic model for assembly of chimeric β-barrels in lipidic micelles. The assembly likely follows a predefined nucleation at the central hairpin only when presented in tandem, with some influence from its absolute position in the barrel. Our findings can lead to the design of engineered barrels that retain the OMP assembly elements necessary to attain well-folded, stable, yet malleable scaffolds, for bionanotechnology applications.

Published

2018

6. Precision Electrophile Tagging in Caenorhabditis elegans.

Author

Long MJC, Urul DA, Chawla S, Lin HY, Zhao Y, Haegele JA, Wang Y, and Aye Y

Subjects

Aldehydes chemistry, Animals, Animals, Genetically Modified, Bacterial Proteins chemistry, Bacterial Proteins genetics, Caenorhabditis elegans ultrastructure, Caenorhabditis elegans Proteins genetics, Electrochemistry, Hydrolases chemistry, Hydrolases genetics, Kelch-Like ECH-Associated Protein 1 chemistry, Kelch-Like ECH-Associated Protein 1 genetics, Longevity, Luminescent Proteins analysis, Luminescent Proteins chemistry, Luminescent Proteins genetics, Oxidation-Reduction, Photochemistry, Protein Processing, Post-Translational, Recombinant Fusion Proteins chemistry, Recombinant Fusion Proteins genetics, Transgenes, Red Fluorescent Protein, Caenorhabditis elegans metabolism, Caenorhabditis elegans Proteins analysis

Abstract

Adduction of an electrophile to privileged sensor proteins and the resulting phenotypically dominant responses are increasingly appreciated as being essential for metazoan health. Functional similarities between the biological electrophiles and electrophilic pharmacophores commonly found in covalent drugs further fortify the translational relevance of these small-molecule signals. Genetically encodable or small-molecule-based fluorescent reporters and redox proteomics have revolutionized the observation and profiling of cellular redox states and electrophile-sensor proteins, respectively. However, precision mapping between specific redox-modified targets and specific responses has only recently begun to be addressed, and systems tractable to both genetic manipulation and on-target redox signaling in vivo remain largely limited. Here we engineer transgenic Caenorhabditis elegans expressing functional HaloTagged fusion proteins and use this system to develop a generalizable light-controlled approach to tagging a prototypical electrophile-sensor protein with native electrophiles in vivo. The method circumvents issues associated with low uptake/distribution and toxicity/promiscuity. Given the validated success of C. elegans in aging studies, this optimized platform offers a new lens with which to scrutinize how on-target electrophile signaling influences redox-dependent life span regulation.

Published

2018

7. Structural and Functional Basis for Targeting Campylobacter jejuni Agmatine Deiminase To Overcome Antibiotic Resistance.

Author

Shek R, Dattmore DA, Stives DP, Jackson AL, Chatfield CH, Hicks KA, and French JB

Subjects

Aminoglycosides pharmacology, Campylobacter jejuni drug effects, Catalytic Domain, Crystallography, X-Ray, Hydrolases chemistry, Hydrolases genetics, Hydrolases metabolism, Kinetics, Protein Conformation, Campylobacter jejuni enzymology, Drug Resistance, Bacterial drug effects, Hydrolases antagonists & inhibitors

Abstract

Campylobacter jejuni is the most common bacterial cause of gastroenteritis and a major contributor to infant mortality in the developing world. The increasing incidence of antibiotic-resistant C. jejuni only adds to the urgency to develop effective therapies. Because of the essential role that polyamines play, particularly in protection from oxidative stress, enzymes involved in the biosynthesis of these metabolites are emerging as promising antibiotic targets. The recent description of an alternative pathway for polyamine synthesis, distinct from that in human cells, in C. jejuni suggests this pathway could be a target for novel therapies. To that end, we determined X-ray crystal structures of C. jejuni agmatine deiminase (CjADI) and demonstrated that loss of CjADI function contributes to antibiotic sensitivity, likely because of polyamine starvation. The structures provide details of key molecular features of the active site of this protein. Comparison of the unliganded structure (2.1 Å resolution) to that of the CjADI-agmatine complex (2.5 Å) reveals significant structural rearrangements that occur upon substrate binding. The shift of two helical regions of the protein and a large conformational change in a loop near the active site generate a narrow binding pocket around the bound substrate. This change optimally positions the substrate for catalysis. In addition, kinetic analysis of this enzyme demonstrates that CjADI is an iminohydrolase that effectively deiminates agmatine. Our data suggest that C. jejuni agmatine deiminase is a potentially important target for combatting antibiotic resistance, and these results provide a valuable framework for guiding future drug development.

Published

2017

8. The Cation-π Interaction Enables a Halo-Tag Fluorogenic Probe for Fast No-Wash Live Cell Imaging and Gel-Free Protein Quantification.

Author

Liu Y, Miao K, Dunham NP, Liu H, Fares M, Boal AK, Li X, and Zhang X

Subjects

Cations, Cloning, Molecular, Escherichia coli genetics, Escherichia coli metabolism, Gene Expression, HEK293 Cells, Humans, Hydrolases metabolism, Kinetics, Plasmids chemistry, Plasmids metabolism, Recombinant Fusion Proteins metabolism, Staining and Labeling methods, Transfection, Tryptophan chemistry, Fluorescent Dyes chemistry, Hydrolases genetics, Molecular Imaging methods, Molecular Probes chemistry, Recombinant Fusion Proteins genetics, Thiadiazoles chemistry

Abstract

The design of fluorogenic probes for a Halo tag is highly desirable but challenging. Previous work achieved this goal by controlling the chemical switch of spirolactones upon the covalent conjugation between the Halo tag and probes or by incorporating a "channel dye" into the substrate binding tunnel of the Halo tag. In this work, we have developed a novel class of Halo-tag fluorogenic probes that are derived from solvatochromic fluorophores. The optimal probe, harboring a benzothiadiazole scaffold, exhibits a 1000-fold fluorescence enhancement upon reaction with the Halo tag. Structural, computational, and biochemical studies reveal that the benzene ring of a tryptophan residue engages in a cation-π interaction with the dimethylamino electron-donating group of the benzothiadiazole fluorophore in its excited state. We further demonstrate using noncanonical fluorinated tryptophan that the cation-π interaction directly contributes to the fluorogenicity of the benzothiadiazole fluorophore. Mechanistically, this interaction could contribute to the fluorogenicity by promoting the excited-state charge separation and inhibiting the twisting motion of the dimethylamino group, both leading to an enhanced fluorogenicity. Finally, we demonstrate the utility of the probe in no-wash direct imaging of Halo-tagged proteins in live cells. In addition, the fluorogenic nature of the probe enables a gel-free quantification of fusion proteins expressed in mammalian cells, an application that was not possible with previously nonfluorogenic Halo-tag probes. The unique mechanism revealed by this work suggests that incorporation of an excited-state cation-π interaction could be a feasible strategy for enhancing the optical performance of fluorophores and fluorogenic sensors.

Published

2017

9. Structural Basis for the Strict Substrate Selectivity of the Mycobacterial Hydrolase LipW.

Author

McKary MG, Abendroth J, Edwards TE, and Johnson RJ

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Biocatalysis, Catalytic Domain, Crystallography, X-Ray, Enzyme Stability, Esters chemistry, Hydrolases chemistry, Hydrolases genetics, Hydrophobic and Hydrophilic Interactions, Kinetics, Models, Molecular, Molecular Structure, Mutation, Mycobacterium marinum genetics, Protein Binding, Protein Domains, Serine chemistry, Serine genetics, Serine metabolism, Substrate Specificity, Temperature, Valine chemistry, Valine genetics, Valine metabolism, Bacterial Proteins metabolism, Esters metabolism, Hydrolases metabolism, Mycobacterium marinum enzymology

Abstract

The complex life cycle of Mycobacterium tuberculosis requires diverse energy mobilization and utilization strategies facilitated by a battery of lipid metabolism enzymes. Among lipid metabolism enzymes, the Lip family of mycobacterial serine hydrolases is essential to lipid scavenging, metabolic cycles, and reactivation from dormancy. On the basis of the homologous rescue strategy for mycobacterial drug targets, we have characterized the three-dimensional structure of full length LipW from Mycobacterium marinum, the first structure of a catalytically active Lip family member. LipW contains a deep, expansive substrate-binding pocket with only a narrow, restrictive active site, suggesting tight substrate selectivity for short, unbranched esters. Structural alignment reinforced this strict substrate selectivity of LipW, as the binding pocket of LipW aligned most closely with the bacterial acyl esterase superfamily. Detailed kinetic analysis of two different LipW homologues confirmed this strict substrate selectivity, as each homologue selected for unbranched propionyl ester substrates, irrespective of the alcohol portion of the ester. Using comprehensive substitutional analysis across the binding pocket, the strict substrate selectivity of LipW for propionyl esters was assigned to a narrow funnel in the acyl-binding pocket capped by a key hydrophobic valine residue. The polar, negatively charged alcohol-binding pocket also contributed to substrate orientation and stabilization of rotameric states in the catalytic serine. Together, the structural, enzymatic, and substitutional analyses of LipW provide a connection between the structure and metabolic properties of a Lip family hydrolase that refines its biological function in active and dormant tuberculosis infection.

Published

2016

10. An Atypical α/β-Hydrolase Fold Revealed in the Crystal Structure of Pimeloyl-Acyl Carrier Protein Methyl Esterase BioG from Haemophilus influenzae.

Author

Shi J, Cao X, Chen Y, Cronan JE, and Guo Z

Subjects

Acyl Carrier Protein chemistry, Acyl Carrier Protein metabolism, Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Biosynthetic Pathways genetics, Biotin biosynthesis, Biotin chemistry, Circular Dichroism, Crystallography, X-Ray, Electrophoresis, Polyacrylamide Gel, Escherichia coli Proteins chemistry, Escherichia coli Proteins genetics, Escherichia coli Proteins metabolism, Esterases chemistry, Esterases genetics, Haemophilus influenzae genetics, Haemophilus influenzae metabolism, Hydrolases chemistry, Hydrolases genetics, Models, Molecular, Molecular Structure, Mutation, Pimelic Acids chemistry, Pimelic Acids metabolism, Protein Domains, Protein Folding, Protein Structure, Secondary, Sequence Homology, Amino Acid, Bacterial Proteins metabolism, Esterases metabolism, Haemophilus influenzae enzymology, Hydrolases metabolism

Abstract

Pimeloyl-acyl carrier protein (ACP) methyl esterase is an α/β-hydrolase that catalyzes the last biosynthetic step of pimeloyl-ACP, a key intermediate in biotin biosynthesis. Intriguingly, multiple nonhomologous isofunctional forms of this enzyme that lack significant sequence identity are present in diverse bacteria. One such esterase, Escherichia coli BioH, has been shown to be a typical α/β-hydrolase fold enzyme. To gain further insights into the role of this step in biotin biosynthesis, we have determined the crystal structure of another widely distributed pimeloyl-ACP methyl esterase, Haemophilus influenzae BioG, at 1.26 Å. The BioG structure is similar to the BioH structure and is composed of an α-helical lid domain and a core domain that contains a central seven-stranded β-pleated sheet. However, four of the six α-helices that flank both sides of the BioH core β-sheet are replaced with long loops in BioG, thus forming an unusual α/β-hydrolase fold. This structural variation results in a significantly decreased thermal stability of the enzyme. Nevertheless, the lid domain and the residues at the lid-core interface are well conserved between BioH and BioG, in which an analogous hydrophobic pocket for pimelate binding as well as similar ionic interactions with the ACP moiety are retained. Biochemical characterization of site-directed mutants of the residues hypothesized to interact with the ACP moiety supports a similar substrate interaction mode for the two enzymes. Consequently, these enzymes package the identical catalytic function under a considerably different protein surface.

Published

2016

11. Active Site Desolvation and Thermostability Trade-Offs in the Evolution of Catalytically Diverse Triazine Hydrolases.

Author

Sugrue E, Carr PD, Scott C, and Jackson CJ

Subjects

Actinobacteria genetics, Bacterial Proteins chemistry, Bacterial Proteins genetics, Biocatalysis, Crystallization, Crystallography, X-Ray, Enzyme Stability, Evolution, Molecular, Glutamic Acid chemistry, Glutamic Acid genetics, Glutamic Acid metabolism, Hydrolases chemistry, Hydrolases genetics, Hydrophobic and Hydrophilic Interactions, Kinetics, Models, Molecular, Molecular Structure, Mutation, Protein Binding, Protein Domains, Temperature, Triazines chemistry, Actinobacteria enzymology, Bacterial Proteins metabolism, Catalytic Domain, Hydrolases metabolism, Triazines metabolism

Abstract

The desolvation of ionizable residues in the active sites of enzymes and the subsequent effects on catalysis and thermostability have been studied in model systems, yet little about how enzymes can naturally evolve to include active sites with highly reactive and desolvated charges is known. Variants of triazine hydrolase (TrzN) with significant differences in their active sites have been isolated from different bacterial strains: TrzN from Nocardioides sp. strain MTD22 contains a catalytic glutamate residue (Glu241) that is surrounded by hydrophobic and aromatic second-shell residues (Pro214 and Tyr215), whereas TrzN from Nocardioides sp. strain AN3 has a noncatalytic glutamine residue (Gln241) at an equivalent position, surrounded by hydrophilic residues (Thr214 and His215). To understand how and why these variants have evolved, a series of TrzN mutants were generated and characterized. These results show that desolvation by second-shell residues increases the pK a of Glu241, allowing it to act as a general acid at neutral pH. However, significant thermostability trade-offs are required to incorporate the ionizable Glu241 in the active site and to then enclose it in a hydrophobic microenvironment. Analysis of high-resolution crystal structures shows that there are almost no structural changes to the overall configuration of the active site due to these mutations, suggesting that the changes in activity and thermostability are purely based on the altered electrostatics. The natural evolution of these enzyme isoforms provides a unique system in which to study the fundamental process of charged residue desolvation in enzyme catalysis and its relative contribution to the creation and evolution of an enzyme active site.

Published

2016

12. Stabilization of an α/β-Hydrolase by Introducing Proline Residues: Salicylic Acid Binding Protein 2 from Tobacco.

Author

Huang J, Jones BJ, and Kazlauskas RJ

Subjects

Amino Acid Substitution, Catalytic Domain, Enzyme Stability, Esterases genetics, Hydrolases genetics, Models, Molecular, Plant Proteins genetics, Proline genetics, Protein Conformation, Protein Denaturation, Protein Unfolding, Nicotiana genetics, Esterases chemistry, Hydrolases chemistry, Plant Proteins chemistry, Proline chemistry, Nicotiana chemistry

Abstract

α/β-Hydrolases are important enzymes for biocatalysis, but their stability often limits their application. We investigated a plant esterase, salicylic acid binding protein 2 (SABP2), as a model α/β-hydrolase. SABP2 shows typical stability to urea (unfolding free energy 6.9 ± 1.5 kcal/mol) and to heat inactivation (T1/2 15min 49.2 ± 0.5 °C). Denaturation in urea occurs in two steps, but heat inactivation occurs in a single step. The first unfolding step in urea eliminates catalytic activity. Surprisingly, we found that the first unfolding likely corresponds to the unfolding of the larger catalytic domain. Replacing selected amino acid residues with proline stabilized SABP2. Proline restricts the flexibility of the unfolded protein, thereby shifting the equilibrium toward the folded conformation. Seven locations for proline substitution were chosen either by amino acid sequence alignment with a more stable homologue or by targeting flexible regions in SABP2. Introducing proline in the catalytic domain stabilized SABP2 to the first unfolding in urea for three of five cases: L46P (+0.2 M urea), S70P (+0.1), and E215P (+0.9). Introducing proline in the cap domain did not stabilize SABP2 (two of two cases), supporting the assignment that the first unfolding corresponds to the catalytic domain. Proline substitutions in both domains stabilized SABP2 to heat inactivation: L46P (ΔT1/2 15min = +6.4 °C), S70P (+5.4), S115P (+1.8), S141P (+4.9), and E215P (+4.2). Combining substitutions did not further increase the stability to urea denaturation, but dramatically increased resistance to heat inactivation: L46P−S70P ΔT1/2 15min = +25.7 °C. This straightforward proline substitution approach may also stabilize other α/β-hydrolases.

Published

2015

13. Formiminoglutamase from Trypanosoma cruzi is an arginase-like manganese metalloenzyme.

Author

Hai Y, Dugery RJ, Healy D, and Christianson DW

Subjects

Amino Acid Sequence, Amino Acid Substitution, Apoenzymes chemistry, Apoenzymes genetics, Apoenzymes metabolism, Arginase chemistry, Arginase metabolism, Asparagine chemistry, Binding Sites, Conserved Sequence, Cysteine chemistry, Hydrolases genetics, Hydrolases metabolism, Manganese analysis, Manganese chemistry, Manganese metabolism, Metalloproteins genetics, Metalloproteins metabolism, Molecular Sequence Data, Mutant Proteins chemistry, Mutant Proteins metabolism, Protein Conformation, Protozoan Proteins genetics, Protozoan Proteins metabolism, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Alignment, Formiminoglutamic Acid metabolism, Hydrolases chemistry, Metalloproteins chemistry, Models, Molecular, Protozoan Proteins chemistry, Trypanosoma cruzi enzymology

Abstract

The crystal structure of formiminoglutamase from Trypanosoma cruzi (TcFIGase) is reported at 1.85 Å resolution. Although the structure of this enzyme was previously determined by the Structural Genomics of Pathogenic Protozoa Consortium (PDB accession code 2A0M), this structure was determined at low pH and lacked bound metal ions; accordingly, the protein was simply annotated as "arginase superfamily protein" with undetermined function. We show that reconstitution of this protein with Mn²⁺ confers maximal catalytic activity in the hydrolysis of formiminoglutamate to yield glutamate and formamide, thereby demonstrating that this protein is a metal-dependent formiminoglutamase. Equilibration of TcFIGase crystals with MnCl₂ at higher pH yields a binuclear manganese cluster similar to that observed in arginase, except that the histidine ligand to the Mn²⁺(A) ion of arginase is an asparagine ligand (N114) to the Mn²⁺(A) ion of TcFIGase. The crystal structure of N114H TcFIGase reveals a binuclear manganese cluster essentially identical to that of arginase, but the mutant exhibits a modest 35% loss of catalytic efficiency (k(cat)/K(M)). Interestingly, when TcFIGase is prepared and crystallized in the absence of reducing agents at low pH, a disulfide linkage forms between C35 and C242 in the active site. When reconstituted with Mn²⁺ at higher pH, this oxidized enzyme exhibits a modest 33% loss of catalytic efficiency. Structure determinations of the metal-free and metal-bound forms of oxidized TcFIGase reveal that although disulfide formation constricts the main entrance to the active site, other structural changes open alternative channels to the active site that may help sustain catalytic activity.

Published

2013

14. The lid domain of the MCP hydrolase DxnB2 contributes to the reactivity toward recalcitrant PCB metabolites.

Author

Ruzzini AC, Bhowmik S, Yam KC, Ghosh S, Bolin JT, and Eltis LD

Subjects

Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites genetics, Burkholderia enzymology, Burkholderia genetics, Crystallography, X-Ray, Fatty Acids, Unsaturated chemistry, Hydrolases chemistry, Hydrolases genetics, Hydrolysis, Hydrophobic and Hydrophilic Interactions, Models, Chemical, Models, Molecular, Molecular Sequence Data, Molecular Structure, Mutation, Polychlorinated Biphenyls chemistry, Protein Multimerization, Protein Structure, Tertiary, Sequence Homology, Amino Acid, Spectrophotometry, Sphingomonas enzymology, Sphingomonas genetics, Bacterial Proteins metabolism, Fatty Acids, Unsaturated metabolism, Hydrolases metabolism, Polychlorinated Biphenyls metabolism

Abstract

DxnB2 and BphD are meta-cleavage product (MCP) hydrolases that catalyze C-C bond hydrolysis of the biphenyl metabolite 2-hydroxy-6-oxo-6-phenylhexa-2,4-dienoic acid (HOPDA). BphD is a bottleneck in the bacterial degradation of polychlorinated biphenyls (PCBs) by the Bph catabolic pathway due in part to inhibition by 3-Cl HOPDAs. By contrast, DxnB2 from Sphingomonas wittichii RW1 catalyzes the hydrolysis of 3-Cl HOPDAs more efficiently. X-ray crystallographic studies of the catalytically inactive S105A variant of DxnB2 complexed with 3-Cl HOPDA revealed a binding mode in which C1 through C6 of the dienoate are coplanar. The chlorine substituent is accommodated by a hydrophobic pocket that is larger than the homologous site in BphDLB400 from Burkholderia xenovorans LB400. The planar binding mode observed in the crystalline complex was consistent with the hyper- and hypsochromically shifted absorption spectra of 3-Cl and 3,9,11-triCl HOPDA, respectively, bound to S105A in solution. Moreover, ES(red), an intermediate possessing a bathochromically shifted spectrum observed in the turnover of HOPDA, was not detected, suggesting that substrate destabilization was rate-limiting in the turnover of these PCB metabolites. Interestingly, electron density for the first α-helix of the lid domain was poorly defined in the dimeric DxnB2 structures, unlike in the tetrameric BphDLB400. Structural comparison of MCP hydrolases identified the NC-loop, connecting the lid to the α/β-hydrolase core domain, as a determinant in the oligomeric state and suggests its involvement in catalysis. Finally, an increased mobility of the DxnB2 lid may contribute to the enzyme's ability to hydrolyze PCB metabolites, highlighting how lid architecture contributes to substrate specificity in α/β-hydrolases.

Published

2013

15. A pre-steady state kinetic analysis of the αY60W mutant of trans-3-chloroacrylic acid dehalogenase: implications for the mechanism of the wild-type enzyme.

Author

Huddleston JP, Schroeder GK, Johnson KA, and Whitman CP

Subjects

Base Sequence, Catalytic Domain, DNA Primers, Hydrolases genetics, Kinetics, Polymerase Chain Reaction, Hydrolases metabolism, Mutation

Abstract

The bacterial degradation of the nematicide 1,3-dichloropropene, an isomeric mixture, requires the action of trans- and cis-3-chloroacrylic acid dehalogenase (CaaD and cis-CaaD, respectively). Both enzymes are tautomerase superfamily members and share a core catalytic mechanism for the hydrolytic dehalogenation of the respective isomer of 3-haloacrylate. The observation that cis-CaaD requires two additional residues raises the question of how CaaD conducts a comparable reaction with fewer catalytic residues. As part of an effort to determine the basis for the apparently simpler CaaD-catalyzed reaction, the kinetic mechanism was determined by stopped-flow and chemical-quench techniques using a fluorescent mutant form of the enzyme, αY60W-CaaD, and trans-3-bromoacrylate as the substrate. The data from these experiments as well as bromide inhibition studies are best accommodated by a six-step model that provides individual rate constants for substrate binding, chemistry, and a proposed conformational change occurring after chemistry followed by release of malonate semialdehyde and bromide. The conformational change and product release rates are comparable, and together they limit the rate of turnover. The kinetic analysis and modeling studies validate the αY60W-CaaD mutant as an accurate reporter of active site events during the course of the enzyme-catalyzed reaction. The kinetic mechanism for the αY60W-CaaD-catalyzed reaction is comparable to that obtained for the cis-CaaD-catalyzed reaction. The kinetic model and the validated αY60W-CaaD mutant set the stage for an analysis of active site mutants to explore the contributions of individual catalytic residues and the basis for the simplicity of the reaction.

Published

2012

16. Catalytic zinc site and mechanism of the metalloenzyme PR-AMP cyclohydrolase.

Author

D'Ordine RL, Linger RS, Thai CJ, and Davisson VJ

Subjects

Amino Acid Sequence, Catalytic Domain, Cysteine chemistry, Cysteine genetics, Cysteine metabolism, Dithionitrobenzoic Acid pharmacology, Hydrolases antagonists & inhibitors, Hydrolases chemistry, Hydrolases genetics, Magnesium metabolism, Metalloproteins antagonists & inhibitors, Metalloproteins chemistry, Metalloproteins genetics, Methanococcus chemistry, Methanococcus genetics, Models, Molecular, Molecular Sequence Data, Point Mutation, Sequence Alignment, Hydrolases metabolism, Metalloproteins metabolism, Methanococcus enzymology, Zinc metabolism

Abstract

The enzyme N(1)-(5'-phosphoribosyl) adenosine-5'-monophosphate cyclohydrolase (PR-AMP cyclohydrolase) is a Zn(2+) metalloprotein encoded by the hisI gene. It catalyzes the third step of histidine biosynthesis, an uncommon ring-opening of a purine heterocycle for use in primary metabolism. A three-dimensional structure of the enzyme from Methanobacterium thermoautotrophicum has revealed that three conserved cysteine residues occur at the dimer interface and likely form the catalytic site. To investigate the functions of these cysteines in the enzyme from Methanococcus vannielii, a series of biochemical studies were pursued to test the basic hypothesis regarding their roles in catalysis. Inactivation of the enzyme activity by methyl methane thiosulfonate (MMTS) or 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) also compromised the Zn(2+) binding properties of the protein inducing loss of up to 90% of the metal. Overall reaction stoichiometry and the potassium cyanide (KCN) induced cleavage of the protein suggested that all three cysteines were modified in the process. The enzyme was protected from DTNB-induced inactivation by inclusion of the substrate N(1)-(5'-phosphoribosyl)adenosine 5'-monophosphate; (PR-AMP), while Mg(2+), a metal required for catalytic activity, enhanced the rate of inactivation. Site-directed mutations of the conserved C93, C109, C116 and the double mutant C109/C116 were prepared and analyzed for catalytic activity, Zn(2+) content, and reactivity with DTNB. Substitution of alanine for each of the conserved cysteines showed no measurable catalytic activity, and only the C116A was still capable of binding Zn(2+). Reactions of DTNB with the C109A/C116A double mutant showed that C93 is completely modified within 0.5 s. A model consistent with these data involves a DTNB-induced mixed disulfide linkage between C93 and C109 or C116, followed by ejection of the active site Zn(2+) and provides further evidence that the Zn(2+) coordination site involves the three conserved cysteine residues. The C93 reactivity is modulated by the presence of the Zn(2+) and Mg(2+) and substantiates the role of this residue as a metal ligand. In addition, Mg(2+) ligand binding site(s) indicated by the structural analysis were probed by site-directed mutagenesis of three key aspartate residues flanking the conserved C93 which were shown to have a functional impact on catalysis, cysteine activation, and metal (zinc) binding capacity. The unique amino acid sequence, the dynamic properties of the cysteine ligands involved in Zn(2+) coordination, and the requirement for a second metal (Mg(2+)) are discussed in the context of their roles in catalysis. The results are consistent with a Zn(2+)-mediated activation of H(2)O mechanism involving histidine as a general base that has features similar to but distinct from those of previously characterized purine and pyrimidine deaminases.

Published

2012

17. Autodeimination of protein arginine deiminase 4 alters protein-protein interactions but not activity.

Author

Slack JL, Jones LE Jr, Bhatia MM, and Thompson PR

Subjects

Enzyme Activation genetics, HL-60 Cells, Histone Deacetylase 1 genetics, Histone Deacetylase 1 metabolism, Histones metabolism, Humans, Hydrolases antagonists & inhibitors, Hydrolases genetics, Protein Processing, Post-Translational, Protein-Arginine Deiminase Type 4, Protein-Arginine Deiminases, Protein-Arginine N-Methyltransferases genetics, Recombinant Proteins genetics, Recombinant Proteins metabolism, Repressor Proteins genetics, Hydrolases metabolism, Imines metabolism, Protein Interaction Domains and Motifs, Protein-Arginine N-Methyltransferases metabolism, Repressor Proteins metabolism

Abstract

The protein arginine deiminases (PAD), which catalyze the hydrolysis of peptidyl-arginine to form peptidyl-citrulline, play important roles in a variety of cell signaling pathways, including apoptosis, differentiation, and transcriptional regulation. In addition to these important cellular roles, PAD activity is dysregulated in multiple human diseases [e.g., rheumatoid arthritis (RA), cancer, and colitis], and significantly, PAD inhibition with Cl-amidine has been shown to reduce disease severity in the collagen-induced arthritis model of RA. Although these enzymes play important roles in human cell signaling and disease, the mechanisms that regulate PAD activity under both physiological and pathological conditions are poorly understood. One possible mechanism for regulating PAD activity is autodeimination, to which PAD4 has been shown by us and others to be subjected in vitro and in vivo. Herein, we demonstrate that PAD4 autodeimination does not alter the activity, substrate specificity, or calcium dependence of this isozyme. However, the results of these studies indicate a novel role for autodeimination in modulating the ability of PAD4 to interact with histone deacetylase 1 (HDAC1), citrullinated histone H3 (Cit H3), and protein arginine methyltransferase 1 (PRMT1).

Published

2011

18. Characterization of a newly identified mycobacterial tautomerase with promiscuous dehalogenase and hydratase activities reveals a functional link to a recently diverged cis-3-chloroacrylic acid dehalogenase.

Author

Baas BJ, Zandvoort E, Wasiel AA, Quax WJ, and Poelarends GJ

Subjects

Acrylates chemistry, Acrylates metabolism, Amino Acid Sequence, Bacterial Proteins chemistry, Bacterial Proteins genetics, Binding Sites, Biocatalysis, Catalytic Domain, Fatty Acids, Unsaturated chemistry, Fatty Acids, Unsaturated metabolism, Hydro-Lyases chemistry, Hydro-Lyases genetics, Hydro-Lyases metabolism, Hydrolases chemistry, Hydrolases genetics, Intramolecular Oxidoreductases chemistry, Intramolecular Oxidoreductases genetics, Kinetics, Magnetic Resonance Spectroscopy, Models, Chemical, Molecular Sequence Data, Molecular Structure, Mycobacterium smegmatis genetics, Sequence Homology, Amino Acid, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Stereoisomerism, Substrate Specificity, Bacterial Proteins metabolism, Hydrolases metabolism, Intramolecular Oxidoreductases metabolism, Mycobacterium smegmatis enzymology

Abstract

The enzyme cis-3-chloroacrylic acid dehalogenase (cis-CaaD) is found in a bacterial pathway that degrades a synthetic nematocide, cis-1,3-dichloropropene, introduced in the 20th century. The previously determined crystal structure of cis-CaaD and its promiscuous phenylpyruvate tautomerase (PPT) activity link this dehalogenase to the tautomerase superfamily, a group of homologous proteins that are characterized by a catalytic amino-terminal proline and a β-α-β structural fold. The low-level PPT activity of cis-CaaD, which may be a vestige of the function of its progenitor, prompted us to search the databases for a homologue of cis-CaaD that was annotated as a putative tautomerase and test both its PPT and cis-CaaD activity. We identified a mycobacterial cis-CaaD homologue (designated MsCCH2) that shares key sequence and active site features with cis-CaaD. Kinetic and 1H NMR spectroscopic studies show that MsCCH2 functions as an efficient PPT and exhibits low-level promiscuous dehalogenase activity, processing both cis- and trans-3-chloroacrylic acid. To further probe the active site of MsCCH2, the enzyme was incubated with 2-oxo-3-pentynoate (2-OP). At pH 8.5, MsCCH2 is inactivated by 2-OP due to the covalent modification of Pro-1, suggesting that Pro-1 functions as a nucleophile at pH 8.5 and attacks 2-OP in a Michael-type reaction. At pH 6.5, however, MsCCH2 exhibits hydratase activity and converts 2-OP to acetopyruvate, which implies that Pro-1 is cationic at pH 6.5 and not functioning as a nucleophile. At pH 7.5, the hydratase and inactivation reactions occur simultaneously. From these results, it can be inferred that Pro-1 of MsCCH2 has a pKa value that lies in between that of a typical tautomerase (pKa of Pro-1∼6) and that of cis-CaaD (pKa of Pro-1∼9). The shared activities and structural features, coupled with the intermediate pKa of Pro-1, suggest that MsCCH2 could be characteristic of an evolutionary intermediate along the past route for the divergence of cis-CaaD from an unknown superfamily tautomerase. This makes MsCCH2 an ideal candidate for laboratory evolution of its promiscuous dehalogenase activity, which could identify additional features necessary for a fully active cis-CaaD. Such results will provide insight into pathways that could lead to the rapid divergent evolution of an efficient cis-CaaD enzyme.

Published

2011

19. Divergence of biochemical function in the HAD superfamily: D-glycero-D-manno-heptose-1,7-bisphosphate phosphatase (GmhB).

Author

Wang L, Huang H, Nguyen HH, Allen KN, Mariano PS, and Dunaway-Mariano D

Subjects

Alphaproteobacteria enzymology, Bacteroides enzymology, Bordetella bronchiseptica enzymology, Catalysis, Escherichia coli genetics, Escherichia coli Proteins genetics, Heptoses chemistry, Heptoses genetics, Histidinol-Phosphatase chemistry, Histidinol-Phosphatase genetics, Hydrolases genetics, Phosphoric Monoester Hydrolases genetics, Substrate Specificity genetics, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Hydrolases chemistry, Multigene Family, Phosphoric Monoester Hydrolases chemistry

Abstract

D-Glycero-d-manno-heptose-1,7-bisphosphate phosphatase (GmhB) is a member of the histidinol-phosphate phosphatase (HisB) subfamily of the haloalkanoic acid dehalogenase (HAD) enzyme superfamily. GmhB supports two divergent biochemical pathways in bacteria: the d-glycero-d-manno-heptose-1alpha-GDP pathway (in S-layer glycoprotein biosynthesis) and the l-glycero-d-manno-heptose-1beta-ADP pathway (in lipid A biosynthesis). Herein, we report the comparative analysis of substrate recognition in selected GmhB orthologs. The substrate specificity of the l-glycero-d-manno-heptose-1beta-ADP pathway GmhB from Escherichia coli K-12 was evaluated using hexose and heptose bisphosphates, histidinol phosphate, and common organophosphate metabolites. Only d-glycero-d-manno-heptose 1beta,7-bisphosphate (k(cat)/K(m) = 7 x 10(6) M(-1) s(-1)) and d-glycero-d-manno-heptose 1alpha,7-bisphosphate (k(cat)/K(m) = 7 x 10(4) M(-1) s(-1)) displayed physiologically significant substrate activity. (31)P NMR analysis demonstrated that E. coli GmhB selectively removes the C(7) phosphate. Steady-state kinetic inhibition studies showed that d-glycero-d-manno-heptose 1beta-phosphate (K(is) = 60 microM, and K(ii) = 150 microM) and histidinol phosphate (K(is) = 1 mM, and K(ii) = 6 mM), while not hydrolyzed, do in fact bind to E. coli GmhB, which leads to the conclusion that nonproductive binding contributes to substrate discrimination. High catalytic efficiency and a narrow substrate range are characteristic of a well-evolved metabolic enzyme, and as such, E. coli GmhB is set apart from most HAD phosphatases (which are typically inefficient and promiscuous). The specialization of the biochemical function of GmhB was examined by measuring the kinetic constants for hydrolysis of the alpha- and beta-anomers of d-glycero-d-manno-heptose 1beta,7-bisphosphate catalyzed by the GmhB orthologs of the l-glycero-d-manno-heptose 1beta-ADP pathways operative in Bordetella bronchiseptica and Mesorhizobium loti and by the GmhB of the d-glycero-d-manno-heptose 1alpha-GDP pathway operative in Bacteroides thetaiotaomicron. The results show that although each of these representatives possesses physiologically significant catalytic activity toward both anomers, each displays substantial anomeric specificity. Like E. coli GmhB, B. bronchiseptica GmhB and M. loti GmhB prefer the beta-anomer, whereas B. thetaiotaomicron GmhB is selective for the alpha-anomer. By determining the anomeric configuration of the physiological substrate (d-glycero-d-manno-heptose 1,7-bisphosphate) for each of the four GmhB orthologs, we discovered that the anomeric specificity of GmhB correlates with that of the pathway kinase. The conclusion drawn from this finding is that the evolution of the ancestor to GmhB in the HisB subfamily provided for specialization toward two distinct biochemical functions.

Published

2010

20. Structural determinants of substrate recognition in the HAD superfamily member D-glycero-D-manno-heptose-1,7-bisphosphate phosphatase (GmhB) .

Author

Nguyen HH, Wang L, Huang H, Peisach E, Dunaway-Mariano D, and Allen KN

Subjects

Apoenzymes chemistry, Apoenzymes genetics, Bordetella bronchiseptica enzymology, Bordetella bronchiseptica genetics, Crystallography, X-Ray, Escherichia coli genetics, Escherichia coli Proteins genetics, Histidinol-Phosphatase chemistry, Histidinol-Phosphatase genetics, Hydrolases genetics, Mutagenesis, Site-Directed, Phosphoric Monoester Hydrolases genetics, Protein Binding genetics, Protein Structure, Tertiary genetics, Substrate Specificity genetics, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Hydrolases chemistry, Multigene Family, Phosphoric Monoester Hydrolases chemistry

Abstract

The haloalkanoic acid dehalogenase (HAD) enzyme superfamily is the largest family of phosphohydrolases. In HAD members, the structural elements that provide the binding interactions that support substrate specificity are separated from those that orchestrate catalysis. For most HAD phosphatases, a cap domain functions in substrate recognition. However, for the HAD phosphatases that lack a cap domain, an alternate strategy for substrate selection must be operative. One such HAD phosphatase, GmhB of the HisB subfamily, was selected for structure-function analysis. Herein, the X-ray crystallographic structures of Escherichia coli GmhB in the apo form (1.6 A resolution), in a complex with Mg(2+) and orthophosphate (1.8 A resolution), and in a complex with Mg(2+) and d-glycero-d-manno-heptose 1beta,7-bisphosphate (2.2 A resolution) were determined, in addition to the structure of Bordetella bronchiseptica GmhB bound to Mg(2+) and orthophosphate (1.7 A resolution). The structures show that in place of a cap domain, the GmhB catalytic site is elaborated by three peptide inserts or loops that pack to form a concave, semicircular surface around the substrate leaving group. Structure-guided kinetic analysis of site-directed mutants was conducted in parallel with a bioinformatics study of sequence diversification within the HisB subfamily to identify loop residues that serve as substrate recognition elements and that distinguish GmhB from its subfamily counterpart, the histidinol-phosphate phosphatase domain of HisB. We show that GmhB and the histidinol-phosphate phosphatase domain use the same design of three substrate recognition loops inserted into the cap domain yet, through selective residue usage on the loops, have achieved unique substrate specificity and thus novel biochemical function.

Published

2010

21. Structure elucidation and preliminary assessment of hydrolase activity of PqsE, the Pseudomonas quinolone signal (PQS) response protein.

Author

Yu S, Jensen V, Seeliger J, Feldmann I, Weber S, Schleicher E, Häussler S, and Blankenfeldt W

Subjects

Bacterial Proteins genetics, Calorimetry, Crystallography, X-Ray, Electron Spin Resonance Spectroscopy, Gene Expression Regulation, Bacterial genetics, Gene Expression Regulation, Bacterial physiology, Hydrolases genetics, Kinetics, Models, Genetic, Phosphoric Diester Hydrolases genetics, Phosphoric Diester Hydrolases metabolism, Protein Structure, Secondary, Pseudomonas aeruginosa genetics, Quinolones metabolism, Quorum Sensing physiology, Recombinant Proteins genetics, Signal Transduction genetics, Signal Transduction physiology, Thiolester Hydrolases genetics, Thiolester Hydrolases metabolism, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Hydrolases metabolism, Pseudomonas aeruginosa metabolism, Recombinant Proteins chemistry, Recombinant Proteins metabolism

Abstract

In bacteria, the transcription of virulence genes is usually controlled by a cell density-dependent process known as "quorum sensing" (QS). QS relies on small diffusible signaling molecules that cross the bacterial cell wall and activate target transcription factors after a threshold concentration has been reached. Besides two hierarchical QS circuits based on N-acylhomoserine lactones, the human opportunistic pathogen Pseudomonas aeruginosa integrates a signaling system that depends on 2-heptyl-3-hydroxy-4-quinolone, termed "Pseudomonas quinolone signal" (PQS). PQS is produced from genes encoded in the pqs operon, which in addition to the biosynthetic enzymes PqsA-D contains a fifth gene, pqsE, that is not required for production of PQS but whose disruption leads to loss of signal transduction in several but not all pqs operon-dependent processes. PqsE was hence termed "PQS response protein", but its exact mechanism of action is unknown. We have determined the crystal structure of recombinant PqsE and show that it possesses a metallo-beta-lactamase fold with an Fe(II)Fe(III) center in the active site. A copurified ligand was assigned as benzoate and may indicate that PqsE exerts its regulatory effect by converting a chorismate-derived molecule. Further, PqsE was found to slowly hydrolyze phosphodiesters including single- and double-stranded DNA as well as mRNA and also the thioester S-(4-nitrobenzoyl)mercaptoethane. Higher activity was observed after incubation with Co(2+) and, to lesser entent, Mn(2+), suggesting that the Fe(II)Fe(III) center of recombinant PqsE may be an artifact of heterologous expression. A crystal complex of the E182A mutant with bis-pNPP was obtained and suggests a catalytic mechanism for hydrolysis.

Published

2009

22. Inactivation of Cg10062, a cis-3-chloroacrylic acid dehalogenase homologue in Corynebacterium glutamicum, by (R)- and (S)-oxirane-2-carboxylate: analysis and implications.

Author

Robertson BA, Johnson WH, Lo HH Jr, and Whitman CP

Subjects

Enzyme Inhibitors chemistry, Ethylene Oxide chemistry, Hydrolases chemistry, Hydrolases metabolism, Molecular Structure, Peptide Mapping, Spectrometry, Mass, Electrospray Ionization, Substrate Specificity, Time Factors, Corynebacterium glutamicum enzymology, Enzyme Inhibitors pharmacology, Ethylene Oxide analogs & derivatives, Ethylene Oxide pharmacology, Hydrolases antagonists & inhibitors, Hydrolases genetics

Abstract

( R)- and ( S)-oxirane-2-carboxylate were determined to be active site-directed irreversible inhibitors of the cis-3-chloroacrylic acid dehalogenase ( cis-CaaD) homologue Cg10062 found in Corynebacterium glutamicum. Kinetic analysis indicates that the ( R) enantiomer binds more tightly and is the more potent inhibitor, likely reflecting more favorable interactions with active site residues. Pro-1 is the sole site of covalent modification by the ( R) and ( S) enantiomers. Pro-1, Arg-70, Arg-73, and Glu-114, previously identified as catalytic residues in Cg10062, have also been implicated in the inactivation mechanism. Pro-1, Arg-70, and Arg-73 are essential residues for the process as indicated by the observation that the enzymes with the corresponding alanine mutations are not covalently modified by either enantiomer. The E114Q mutant slows covalent modification of Cg10062 but does not prevent it. The results are comparable to those found for the irreversible inactivation of cis-CaaD by ( R)-oxirane-2-carboxylate with two important distinctions: the alkylation of cis-CaaD is stereospecific, and Glu-114 does not take part in the cis-CaaD inactivation mechanism. Cg10062 exhibits low-level cis-CaaD and trans-3-chloroacrylic acid dehalogenase (CaaD) activities, with the cis-CaaD activity predominating. Hence, the preference of Cg10062 for the cis isomer correlates with the observation that the ( R) enantiomer is the more potent inactivator. Moreover, the factors responsible for the relaxed substrate specificity of Cg10062 may account for the stereoselective inactivation by the enantiomeric epoxides. Delineation of these factors would provide a more complete picture of the substrate specificity determinants for cis-CaaD. This study represents an important step toward this goal by setting the stage for a crystallographic analysis of inactivated Cg10062.

Published

2008

23. Characterization of Cg10062 from Corynebacterium glutamicum: implications for the evolution of cis-3-chloroacrylic acid dehalogenase activity in the tautomerase superfamily.

Author

Poelarends GJ, Serrano H, Person MD, Johnson WH Jr, and Whitman CP

Subjects

Bacterial Proteins chemistry, Bacterial Proteins genetics, Corynebacterium glutamicum genetics, Evolution, Molecular, Fatty Acids, Unsaturated chemistry, Fatty Acids, Unsaturated metabolism, Hydro-Lyases chemistry, Hydro-Lyases genetics, Hydrolases chemistry, Hydrolases genetics, Isomerism, Kinetics, Magnetic Resonance Spectroscopy, Molecular Structure, Mutation, Polymerase Chain Reaction, Spectrometry, Mass, Electrospray Ionization, Bacterial Proteins metabolism, Corynebacterium glutamicum enzymology, Hydro-Lyases metabolism, Hydrolases metabolism

Abstract

A 149-amino acid protein designated Cg10062 is encoded by a gene from Corynebacterium glutamicum. The physiological function of Cg10062 is unknown, and the gene encoding this protein has no obvious genomic context. Sequence analysis links Cg10062 to the cis-3-chloroacrylic acid dehalogenase ( cis-CaaD) family, one of the five known families of the tautomerase superfamily. The characterized tautomerase superfamily members have two distinctive characteristics: a beta-alpha-beta structure motif and a catalytic amino-terminal proline. Pro-1 is present in the Cg10062 amino acid sequence along with His-28, Arg-70, Arg-73, Tyr-103, and Glu-114, all of which have been implicated as critical residues for cis-CaaD activity. The gene for Cg10062 has been cloned and the protein overproduced, purified, and subjected to kinetic and mechanistic characterization. Like cis-CaaD, Cg10062 functions as a hydratase: it converts 2-oxo-3-pentynoate to acetopyruvate and processes 3-bromopropiolate to a species that inactivates the enzyme by acylation of Pro-1. Kinetic and (1)H NMR spectroscopic studies also show that Cg10062 processes both isomers of 3-chloroacrylic acid at low levels with a clear preference for the cis isomer. Pro-1 is critical for the dehalogenase and hydratase activities because the P1A mutant no longer catalyzes either reaction. The presence of the six key catalytic residues and the hydratase activity coupled with the absence of an efficient cis-CaaD activity and the lack of isomer specificity implicate factors beyond this core set of residues in cis-CaaD catalysis and specificity. This work sets the stage for in-depth mechanistic and structural studies of Cg10062, which could identify the additional features necessary for a fully active and highly specific cis-CaaD. Such results will also shed light on how cis-CaaD emerged in the tautomerase superfamily because Cg10062 could be characteristic of an intermediate along the evolutionary pathway for this dehalogenase.

Published

2008

24. Cyanolysis and azidolysis of epoxides by haloalcohol dehalogenase: theoretical study of the reaction mechanism and origins of regioselectivity.

Author

Hopmann KH and Himo F

Subjects

Binding Sites, Catalysis, Computational Biology, Hydrolases genetics, Mutation, Quantum Theory, Stereoisomerism, Substrate Specificity, Azides metabolism, Cyanides metabolism, Epoxy Compounds chemistry, Epoxy Compounds metabolism, Hydrolases metabolism, Models, Biological

Abstract

Haloalcohol dehalogenase HheC catalyzes the reversible dehalogenation of vicinal haloalcohols to form epoxides and free halides. In addition, HheC is able to catalyze the irreversible and highly regioselective ring-opening of epoxides with nonhalide nucleophiles, such as CN (-) and N 3 (-). For azidolysis of aromatic epoxides, the regioselectivity observed with HheC is opposite to the regioselectivity of the nonenzymatic epoxide-opening. This, together with a relatively broad substrate specificity, makes HheC a promising tool for biocatalytic applications. We have designed large quantum chemical models of the HheC active site and used density functional theory to study the reaction mechanism of the HheC-catalyzed ring-opening of ( R)-styrene oxide with the nucleophiles CN (-) and N 3 (-). Both the cyanolysis and the azidolysis reactions are shown to take place in a single concerted step. The results support the suggested role of the putative Ser132-Tyr145-Arg149 catalytic triad, where Tyr145 acts as a general acid, donating a proton to the substrate, and Arg149 interacts with Tyr145 and facilitates proton abstraction, while Ser132 positions the substrate and reduces the barrier for epoxide opening through interaction with the emerging oxyanion of the substrate. We have also studied the regioselectivity of ( R)-styrene oxide opening for both the cyanolysis and the azidolysis reactions. The employed active site model was shown to be able to reproduce the experimentally observed beta-regioselectivity of HheC. In silico mutations of various groups in the HheC active site model were performed to elucidate the important factors governing the regioselectivity.

Published

2008

25. The electrostatic driving force for nucleophilic catalysis in L-arginine deiminase: a combined experimental and theoretical study.

Author

Li L, Li Z, Wang C, Xu D, Mariano PS, Guo H, and Dunaway-Mariano D

Subjects

Binding Sites, Catalysis, Cysteine chemistry, Enzyme Activation drug effects, Enzyme Inhibitors pharmacology, Hydrogen-Ion Concentration, Hydrolases antagonists & inhibitors, Hydrolases genetics, Hydrolysis, Kinetics, Models, Molecular, Molecular Structure, Pseudomonas aeruginosa enzymology, Pseudomonas aeruginosa genetics, Spectrophotometry, Static Electricity, Sulfhydryl Compounds chemistry, Hydrolases chemistry, Hydrolases metabolism

Abstract

L-arginine deiminase (ADI) catalyzes the hydrolysis of L-arginine to form L-citrulline and ammonia via two partial reactions. A working model of the ADI catalytic mechanism assumes nucleophilic catalysis by a stringently conserved active site Cys and general acid-general base catalysis by a stringently conserved active site His. Accordingly, in the first partial reaction, the Cys attacks the substrate guanidino C zeta atom to form a tetrahedral covalent adduct, which is protonated by the His at the departing ammonia group to facilitate the formation of the Cys- S-alkylthiouronium intermediate. In the second partial reaction, the His activates a water molecule for nucleophilic addition at the thiouronium C zeta atom to form the second tetrahedral intermediate, which eliminates the Cys in formation of the L-citrulline product. The absence of a basic residue near the Cys thiol suggested that the electrostatic environment of the Cys thiol, in the enzyme-substrate complex, stabilizes the Cys thiolate anion. The studies described in this paper explore the mechanism of stabilization of the Cys thiolate. First, the log(k(cat)/K(m)) and log k(cat) pH rate profiles were measured for several structurally divergent ADIs to establish the pH range for ADI catalysis. All ADIs were optimally active at pH 5, which suggested that the Cys pKa is strongly perturbed by the prevailing electrostatics of the ADI active site. The p K a of the Bacillus cereus ADI (BcADI) was determined by UV-pH titration to be 9.6. In contrast, the pKa determined by iodoacetamide Cys alkylation is 6.9. These results suggest that the negative electrostatic field from the two opposing Asp carboxylates perturbs the Cys pKa upward in the apoenzyme and that the binding of the iodoacetamide (a truncated analogue of the citrulline product) between the Cys thiol and the two Asp carboxylates shields the Cys thiol, thereby reducing its pKa. It is hypothesized that the bound positively charged guanidinium group of the L-arginine substrate further stabilizes the Cys thiolate. The so-called "substrate-assisted" Cys ionization, first reported by Fast and co-workers to operate in the related enzyme dimethylarginine dimethylaminohydrolase [Stone, E. M., Costello, A. L., Tierney, D. L., and Fast, W. (2006) Biochemistry 45, 5618-5630], was further explored computationally in ADI by using an ab initio quantum mechanics/molecular mechanics method. The energy profiles for formation of the tetrahedral intermediate in the first partial reaction were calculated for three different reaction scenarios. From these results, we conclude that catalytic turnover commences from the active configuration of the ADI(L-arginine) complex which consists of the Cys thiolate (nucleophile) and His imidazolium ion (general acid) and that the energy barriers for the nucleophilic addition of Cys thiolate to the thiouronium C zeta atom and His imidazolium ion-assisted elimination from the tetrahedral intermediate are small.

Published

2008

26. A trade-off between catalytic power and substrate inhibition in TCHQ dehalogenase.

Author

Warner JR, Behlen LS, and Copley SD

Subjects

Amino Acid Sequence, Catalysis, Disulfides chemistry, Disulfides metabolism, Hydrolases genetics, Hydroquinones chemistry, Hydroquinones metabolism, Kinetics, Models, Chemical, Molecular Sequence Data, Molecular Structure, Mutation, Sequence Homology, Amino Acid, Substrate Specificity, Sulfhydryl Compounds chemistry, Sulfhydryl Compounds metabolism, Hydrolases chemistry, Hydrolases metabolism

Abstract

Tetrachlorohydroquinone (TCHQ) dehalogenase is profoundly inhibited by its aromatic substrates, TCHQ and trichlorohydroquinone (TriCHQ). Surprisingly, mutations that change Ile12 to either Ser or Ala give an enzyme that shows no substrate inhibition. We have previously shown that TriCHQ is a noncompetitive inhibitor of the thiol-disulfide exchange reaction between glutathione and ESSG, a covalent adduct between Cys13 and glutathione formed during dehalogenation of the substrate. Substrate inhibition of the thiol-disulfide exchange reaction is less severe in the I12S and I12A mutant enzymes, primarily due to weaker binding of TriCHQ to ESSG. These mutations also result in a decrease in the rate of dehalogenation. Because the rate-limiting step in the I12S and I12A enzymes is dehalogenation, rather than the thiol-disulfide exchange reaction, the relatively modest inhibition of the thiol-disulfide exchange reaction does not affect the overall rate of turnover.

Published

2008

27. Phenylpyruvate tautomerase activity of trans-3-chloroacrylic acid dehalogenase: evidence for an enol intermediate in the dehalogenase reaction?

Author

Poelarends GJ, Johnson WH Jr, Serrano H, and Whitman CP

Subjects

Acrylates chemistry, Acrylates metabolism, Animals, Binding Sites, Catalysis, Hydrolases genetics, Intramolecular Oxidoreductases genetics, Kinetics, Macrophage Migration-Inhibitory Factors chemistry, Macrophage Migration-Inhibitory Factors genetics, Macrophage Migration-Inhibitory Factors metabolism, Mutation, Phenylpyruvic Acids chemistry, Stereoisomerism, Substrate Specificity, Hydrolases chemistry, Intramolecular Oxidoreductases chemistry

Abstract

The enzymatic conversion of cis- or trans-3-chloroacrylic acid to malonate semialdehyde is a key step in the bacterial degradation of the nematocide 1,3-dichloropropene. Two mechanisms have been proposed for the isomer-specific hydrolytic dehalogenases, cis- and trans-3-chloroacrylic acid dehalogenase (cis-CaaD and CaaD, respectively), responsible for this step. In one mechanism, the enol isomer of malonate semialdehyde is produced by the alpha,beta-elimination of HCl from an initial halohydrin species. Phenylenolpyruvate has now been found to be a substrate for CaaD with a kcat/Km value that approaches the one determined for the CaaD reaction using trans-3-chloroacrylate. Moreover, the reaction is stereoselective, generating the 3S isomer of [3-2H]phenylpyruvate in a 1.8:1 ratio in 2H2O. These two observations and a kinetic analysis of active site mutants of CaaD suggest that the active site of CaaD is responsible for the phenylpyruvate tautomerase (PPT) activity. The activity is a striking example of catalytic promiscuity and could reflect the presence of an enol intermediate in CaaD-mediated dehalogenation of trans-3-chloroacrylate. CaaD and cis-CaaD represent different families in the tautomerase superfamily, a group of structurally homologous proteins characterized by a core beta-alpha-beta building block and a catalytic Pro-1. The eukaryotic immunoregulatory protein known as macrophage migration inhibitory factor (MIF), also a tautomerase superfamily member, exhibits a PPT activity, but the biological relevance is unknown. In addition to the mechanistic implications, these results establish a functional link between CaaD and the superfamily tautomerases, highlight the catalytic and binding promiscuity of the beta-alpha-beta scaffold, and suggest that the PPT activity of MIF could reflect a partial reaction in an unknown MIF-catalyzed reaction.

Published

2007

28. Crystal structure of Homo sapiens kynureninase.

Author

Lima S, Khristoforov R, Momany C, and Phillips RS

Subjects

Amino Acid Sequence, Crystallization, Humans, Hydrolases genetics, Hydrolases metabolism, Kinetics, Models, Molecular, Protein Conformation, Pseudomonas fluorescens chemistry, Pseudomonas fluorescens enzymology, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Substrate Specificity, Hydrolases chemistry, Kynurenine metabolism

Abstract

Kynureninase is a member of a large family of catalytically diverse but structurally homologous pyridoxal 5'-phosphate (PLP) dependent enzymes known as the aspartate aminotransferase superfamily or alpha-family. The Homo sapiens and other eukaryotic constitutive kynureninases preferentially catalyze the hydrolytic cleavage of 3-hydroxy-l-kynurenine to produce 3-hydroxyanthranilate and l-alanine, while l-kynurenine is the substrate of many prokaryotic inducible kynureninases. The human enzyme was cloned with an N-terminal hexahistidine tag, expressed, and purified from a bacterial expression system using Ni metal ion affinity chromatography. Kinetic characterization of the recombinant enzyme reveals classic Michaelis-Menten behavior, with a Km of 28.3 +/- 1.9 microM and a specific activity of 1.75 micromol min-1 mg-1 for 3-hydroxy-dl-kynurenine. Crystals of recombinant kynureninase that diffracted to 2.0 A were obtained, and the atomic structure of the PLP-bound holoenzyme was determined by molecular replacement using the Pseudomonas fluorescens kynureninase structure (PDB entry 1qz9) as the phasing model. A structural superposition with the P. fluorescens kynureninase revealed that these two structures resemble the "open" and "closed" conformations of aspartate aminotransferase. The comparison illustrates the dynamic nature of these proteins' small domains and reveals a role for Arg-434 similar to its role in other AAT alpha-family members. Docking of 3-hydroxy-l-kynurenine into the human kynureninase active site suggests that Asn-333 and His-102 are involved in substrate binding and molecular discrimination between inducible and constitutive kynureninase substrates.

Published

2007

29. Mechanistic characterization of N-formimino-L-glutamate iminohydrolase from Pseudomonas aeruginosa.

Author

Martí-Arbona R and Raushel FM

Subjects

Binding Sites, Hydrogen-Ion Concentration, Hydrolases genetics, Kinetics, Models, Molecular, Mutation genetics, Protein Structure, Tertiary, Pseudomonas aeruginosa genetics, Bacterial Proteins metabolism, Glutamic Acid metabolism, Hydrolases chemistry, Hydrolases metabolism, Pseudomonas aeruginosa enzymology

Abstract

N-Formimino-l-glutamate iminohydrolase (HutF) from Pseudomonas aeruginosa catalyzes the deimination of N-formimino-l-glutamate in the histidine degradation pathway. An amino acid sequence alignment between HutF and members of the amidohydrolase superfamily containing mononuclear metal centers indicated that residues Glu-235, His-269, and Asp-320 are involved in substrate binding and activation of the nucleophilic water molecule. The purified enzyme contained up to one equivalent of zinc. The metal was removed by dialysis against the metal chelator dipicolinate with the complete loss of catalytic activity. Enzymatic activity was restored by incubation of the apoprotein with Zn2+, Cd2+, Ni2+, or Cu2+. The mutation of Glu-235, His-269, or Asp-320 resulted in the diminution of catalytic activity by two to six orders of magnitude. Bell-shaped profiles were observed for kcat and kcat/Km as a function of pH. The pKa of the group that must be unprotonated for catalytic activity was consistent with the ionization of His-269. This residue is proposed to function as a general base in the abstraction of a proton from the metal-bound water molecule. In the proposed catalytic mechanism, the reaction is initiated by the abstraction of a proton from the metal-bound water molecule by the side chain imidazole of His-269 to generate a tetrahedral intermediate of the substrate. The collapse of the tetrahedral intermediate commences with the abstraction of a second proton via the side chain carboxylate of Asp-320. The C-N bond of the substrate is subsequently cleaved with proton transfer from His-269 to form ammonia and the N-formyl product. The postulated role of the invariant Glu-235 is to ion pair with the positively charged formimino group of the substrate.

Published

2006

30. Evidence for a gem-diol reaction intermediate in bacterial C-C hydrolase enzymes BphD and MhpC from 13C NMR spectroscopy.

Author

Li JJ, Li C, Blindauer CA, and Bugg TD

Subjects

Amino Acid Substitution, Base Sequence, Burkholderia enzymology, Burkholderia genetics, DNA, Bacterial genetics, Escherichia coli enzymology, Escherichia coli genetics, Escherichia coli Proteins genetics, Genes, Bacterial, Hydrolases genetics, Kinetics, Magnetic Resonance Spectroscopy, Mutagenesis, Site-Directed, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Substrate Specificity, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Hydrolases chemistry, Hydrolases metabolism

Abstract

C-C hydrolase enzymes MhpC and BphD catalyze the hydrolytic C-C cleavage of meta-ring fission intermediates on the Escherichia coli phenylpropionic acid and Burkholderia xenovorans LB400 biphenyl degradation pathways and are both members of the alpha/beta-hydrolase family containing a Ser-His-Asp catalytic triad. The catalytic mechanism of this family of enzymes is thought to proceed via a gem-diol reaction intermediate, which has not been observed directly. Site-directed single mutants of BphD in which catalytic residues His-265 and Ser-112 were replaced with Ala were found to possess 10(4)-fold reduced k(cat) values, and in each case, the C-C cleavage step was shown by pre-steady-state kinetic analysis to be rate-limiting. The processing of a 6-(13)C-labeled aryl-containing substrate by these H265A or S112A mutant BphD enzymes was monitored directly by (13)C NMR spectroscopy. A new line-broadened signal was observed at 128 ppm for each enzyme, corresponding to the proposed gem-diol reaction intermediate, over a time scale of 1-24 h. A similar signal was observed upon incubation of the (13)C-labeled substrate with an H114A MhpC mutant, which is able to accept the 6-phenyl-containing substrate, on a shorter time scale. The direct observation of a gem-diol intermediate provides further evidence that supports a general base mechanism for this family of enzymes.

Published

2006

31. Catalytic role for arginine 188 in the C-C hydrolase catalytic mechanism for Escherichia coli MhpC and Burkholderia xenovorans LB400 BphD.

Author

Li C, Li JJ, Montgomery MG, Wood SP, and Bugg TD

Subjects

Amino Acid Sequence, Amino Acid Substitution, Arginine chemistry, Base Sequence, Burkholderia genetics, Catalytic Domain genetics, Crystallography, X-Ray, DNA, Bacterial genetics, Escherichia coli genetics, Escherichia coli Proteins genetics, Hydrolases genetics, Kinetics, Models, Molecular, Molecular Sequence Data, Mutagenesis, Site-Directed, Protein Conformation, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Sequence Homology, Amino Acid, Burkholderia enzymology, Escherichia coli enzymology, Escherichia coli Proteins chemistry, Escherichia coli Proteins metabolism, Hydrolases chemistry, Hydrolases metabolism

Abstract

The alpha/beta-hydrolase superfamily, comprised mainly of esterase and lipase enzymes, contains a family of bacterial C-C hydrolases, including MhpC and BphD which catalyze the hydrolytic C-C cleavage of meta-ring fission intermediates on the Escherichia coli phenylpropionic acid pathway and Burkholderia xenovorans LB400 biphenyl degradation pathway, respectively. Five active site amino acid residues (Arg-188, Asn-109, Phe-173, Cys-261, and Trp-264) were identified from sequence alignments that are conserved in C-C hydrolases, but not in enzymes of different function. Replacement of Arg-188 in MhpC with Gln and Lys led to 200- and 40-fold decreases, respectively, in k(cat); the same replacements for Arg-190 of BphD led to 400- and 700-fold decreases, respectively, in k(cat). Pre-steady-state kinetic analysis of the R188Q MhpC mutant revealed that the first step of the reaction, keto-enol tautomerization, had become rate-limiting, indicating that Arg-188 has a catalytic role in ketonization of the dienol substrate, which we propose is via substrate destabilization. Mutation of nearby residues Phe-173 and Trp-264 to Gly gave 4-10-fold reductions in k(cat) but 10-20-fold increases in K(m), indicating that these residues are primarily involved in substrate binding. The X-ray structure of a succinate-H263A MhpC complex shows concerted movements in the positions of both Phe-173 and Trp-264 that line the approach to Arg-188. Mutation of Asn-109 to Ala and His yielded 200- and 350-fold reductions, respectively, in k(cat) and pre-steady-state kinetic behavior similar to that of a previous S110A mutant, indicating a role for Asn-109 is positioning the active site loop containing Ser-110. The catalytic role of Arg-188 is rationalized by a hydrogen bond network close to the C-1 carboxylate of the substrate, which positions the substrate and promotes substrate ketonization, probably via destabilization of the bound substrate.

Published

2006

32. Annotating enzymes of unknown function: N-formimino-L-glutamate deiminase is a member of the amidohydrolase superfamily.

Author

Martí-Arbona R, Xu C, Steele S, Weeks A, Kuty GF, Seibert CM, and Raushel FM

Subjects

Amino Acid Sequence, Glutamates pharmacology, Hydrolases antagonists & inhibitors, Hydrolases genetics, Kinetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Pseudomonas aeruginosa enzymology, Sequence Alignment, Substrate Specificity, Amidohydrolases metabolism, Hydrolases metabolism

Abstract

The functional assignment of enzymes that catalyze unknown chemical transformations is a difficult problem. The protein Pa5106 from Pseudomonas aeruginosa has been identified as a member of the amidohydrolase superfamily by a comprehensive amino acid sequence comparison with structurally authenticated members of this superfamily. The function of Pa5106 has been annotated as a probablechlorohydrolase or cytosine deaminase. A close examination of the genomic content of P. aeruginosa reveals that the gene for this protein is in close proximity to genes included in the histidine degradation pathway. The first three steps for the degradation of histidine include the action of HutH, HutU, and HutI to convert L-histidine to N-formimino-L-glutamate. The degradation of N-formimino-L-glutamate to L-glutamate can occur by three different pathways. Three proteins in P. aeruginosa have been identified that catalyze two of the three possible pathways for the degradation of N-formimino-L-glutamate. The protein Pa5106 was shown to catalyze the deimination of N-formimino-L-glutamate to ammonia and N-formyl-L-glutamate, while Pa5091 catalyzed the hydrolysis of N-formyl-L-glutamate to formate and L-glutamate. The protein Pa3175 is dislocated from the hut operon and was shown to catalyze the hydrolysis of N-formimino-L-glutamate to formamide and L-glutamate. The reason for the coexistence of two alternative pathways for the degradation of N-formimino-L-glutamate in P. aeruginosa is unknown.

Published

2006

33. Kinetic analysis of Pseudomonas aeruginosa arginine deiminase mutants and alternate substrates provides insight into structural determinants of function.

Author

Lu X, Li L, Wu R, Feng X, Li Z, Yang H, Wang C, Guo H, Galkin A, Herzberg O, Mariano PS, Martin BM, and Dunaway-Mariano D

Subjects

Binding Sites physiology, Catalysis, Crystallography, X-Ray, Evolution, Molecular, Guanidines chemistry, Guanidines metabolism, Hydrogen-Ion Concentration, Hydrolases genetics, Hydrolases physiology, Kinetics, Models, Molecular, Molecular Sequence Data, Protein Conformation, Pseudomonas aeruginosa chemistry, Pseudomonas aeruginosa genetics, Recombinant Proteins metabolism, Substrate Specificity, Time Factors, Hydrolases chemistry, Hydrolases pharmacokinetics, Mutation physiology, Pseudomonas aeruginosa enzymology, Structure-Activity Relationship

Abstract

L-Arginine deiminase from Pseudomonas aeruginosa (PaADI) catalyzes the hydrolysis of arginine to citrulline and ammonia. PaADI belongs to the guanidino group-modifying enzyme superfamily (GMSF), which conserves backbone fold and a Cys-, His-, and Asp-based catalytic core. In this paper the contributions made by the PaADI core residues Cys406, His278, and Asp166 and the contribution from the neighboring Asp280 (conserved in most but not all GMSF members) to catalysis of the formation and hydrolysis of the Cys406-alkyluronium intermediate were accessed by kinetic analysis of site-directed mutants. In addition, solution hydrolysis in a chemical model of the S-alkylthiouronium intermediate was examined to reveal the importance of general base catalysis in the enzymatic reaction. Substitutions of the active site gating residue Arg401, the l-arginine C(alpha)NH(3)(+)(COO(-)) binding residues, Arg185, Arg243, and Asn160, or the His278 hydrogen bond partner, Glu224, were found to cause dramatic reductions in the enzyme turnover rate. These results are interpreted to suggest that electrostatic interactions play a dominant role in PaADI catalysis. Structural variations observed in P. aeruginosa GMSF enzymes PaADI, agmatine deiminase (PaAgDI), and N(omega),N(omega)-dimethylarginine dimethylaminohydrolase (PaDDAH) indicate an early divergence of the encoding genes. Arginine analogues that are known substrates for PaAgDI and PaDDAH were tested with PaADI to define clear boundaries of biochemical function in the three hydrolases. The conservation of a catalytic core associated with the common chemical function and the divergence of substrate-binding residues (as well as one key catalytic residue) to expand the substrate range provide insight into the evolution of the catalysts that form the GMSF.

Published

2006

34. Contributions of long-range electrostatic interactions to 4-chlorobenzoyl-CoA dehalogenase catalysis: a combined theoretical and experimental study.

Author

Wu J, Xu D, Lu X, Wang C, Guo H, and Dunaway-Mariano D

Subjects

Amino Acid Substitution, Amino Acids, Aromatic chemistry, Amino Acids, Aromatic genetics, Amino Acids, Aromatic metabolism, Aspartic Acid chemistry, Aspartic Acid genetics, Aspartic Acid metabolism, Catalysis, Glutamine chemistry, Glutamine genetics, Glutamine metabolism, Hydrolases chemistry, Hydrolases genetics, Ligands, Mutation, Quantum Theory, Static Electricity, Substrate Specificity, Thermodynamics, Time Factors, Hydrolases metabolism, Models, Chemical

Abstract

It is well established that electrostatic interactions play a vital role in enzyme catalysis. In this work, we report theory-guided mutation experiments that identified strong electrostatic contributions of a remote residue, namely, Glu232 located on the adjacent subunit, to 4-chlorobenzoyl-CoA dehalogenase catalysis. The Glu232Asp mutant was found to bind the substrate analogue 4-methylbenzoyl-CoA more tightly than does the wild-type dehalogenase. In contrast, the kcat for 4-chlorobenzoyl-CoA conversion to product was reduced 10000-fold in the mutant. UV difference spectra measured for the respective enzyme-ligand complexes revealed an approximately 3-fold shift in the equilibrium of the two active site conformers away from that inducing strong pi-electron polarization in the ligand benzoyl ring. Increased substrate binding, decreased ring polarization, and decreased catalytic efficiency indicated that the repositioning of the point charge in the Glu232Asp mutant might affect the orientation of the Asp145 carboxylate with respect to the substrate aromatic ring. The time course for formation and reaction of the arylated enzyme intermediate during a single turnover was measured for wild-type and Glu232Asp mutant dehalogenases. The accumulation of arylated enzyme in the wild-type dehalogenase was not observed in the mutant. This indicates that the reduced turnover rate in the mutant is the result of a slow arylation of Asp145, owing to decreased efficiency in substrate nucleophilic attack by Asp145. To rationalize the experimental observations, a theoretical model is proposed, which computes the potential of mean force for the nucleophilic aromatic substitution step using a hybrid quantum mechanical/molecular mechanical method. To this end, the removal or reorientation of the side chain charge of residue 232, modeled respectively by the Glu232Gln and Glu232Asp mutants, is shown to increase the rate-limiting energy barrier. The calculated 23.1 kcal/mol free energy barrier for formation of the Meisenheimer intermediate in the Glu232Asp mutant represents an increase of 6 kcal/mol relative to that of the wild-type enzyme, consistent with the 5.6 kcal/mol increase calculated from the difference in experimentally determined rate constants. On the basis of the combination of the experimental and theoretical evidence, we hypothesize that the Glu232(B) residue contributes to catalysis by providing an electrostatic force that acts on the Asp145 nucleophile.

Published

2006

35. Inactivation of two diverse enzymes in the amidinotransferase superfamily by 2-chloroacetamidine: dimethylargininase and peptidylarginine deiminase.

Author

Stone EM, Schaller TH, Bianchi H, Person MD, and Fast W

Subjects

Amidohydrolases genetics, Amidohydrolases metabolism, Amino Acid Sequence, Base Sequence, Binding Sites, Catalytic Domain, Cloning, Molecular, DNA Primers, Hydrolases genetics, Hydrolases metabolism, Mass Spectrometry, Protein-Arginine Deiminases, Amidines pharmacology, Amidohydrolases antagonists & inhibitors, Enzyme Inhibitors pharmacology, Hydrolases antagonists & inhibitors

Abstract

The enzymes dimethylargininase [dimethylarginine dimethylaminohydrolase (DDAH); EC 3.5.3.18] and peptidylarginine deiminase (PAD; EC 3.5.3.15) catalyze hydrolysis of substituted arginines. Due to their role in normal physiology and pathophysiology, both enzymes have been identified as potential drug targets, but few useful inhibitors have been reported. Here, we find that 2-chloroacetamidine irreversibly inhibits both DDAH from Pseudomonas aeruginosa and human PAD4 in a time- and concentration-dependent manner, despite the nonoverlapping substrate specificities and low levels of amino acid identity of their catalytic domains. Substrate protection experiments indicate that inactivation occurs by modification at the active site, albeit with modest affinity. Mass spectral analysis demonstrates that irreversible inactivation of DDAH occurs through selective formation of a covalent thioether bond with the active-site Cys249 residue. The mechanism of inactivation by 2-chloroacetamidine is analogous to that of chloromethyl ketones, a set of inhibitors that have found wide application because of their specific covalent modification of active-site residues in serine and cysteine proteases. Likewise, 2-chloroacetamidine may potentially find wide applicability as a general pharmacophore useful in delineating characteristics of the amidinotransferase superfamily.

Published

2005

36. Kinetic characterization of protein arginine deiminase 4: a transcriptional corepressor implicated in the onset and progression of rheumatoid arthritis.

Author

Kearney PL, Bhatia M, Jones NG, Yuan L, Glascock MC, Catchings KL, Yamada M, and Thompson PR

Subjects

Amino Acid Sequence, Ammonia metabolism, Arginine analogs & derivatives, Arginine chemistry, Arginine metabolism, Arthritis, Rheumatoid physiopathology, Calcium chemistry, Catalysis, Disease Progression, Histones chemistry, Histones metabolism, Humans, Hydrogen-Ion Concentration, Hydrolases genetics, Hydrolases metabolism, Hydrolysis, Kinetics, Methylation, Molecular Sequence Data, Peptides chemistry, Peptides metabolism, Protein-Arginine Deiminase Type 4, Protein-Arginine Deiminases, Recombinant Proteins chemistry, Recombinant Proteins metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Substrate Specificity, Arthritis, Rheumatoid enzymology, Hydrolases chemistry, Repressor Proteins chemistry

Abstract

Protein arginine deiminase 4 (PAD4) is a Ca(2+)-dependent enzyme that catalyzes the posttranslational conversion of arginine to citrulline (Arg --> Cit) in a number of proteins, including histones. While the gene encoding this enzyme has been implicated in the pathophysiology of rheumatoid arthritis (RA), little is known about its mechanism of catalysis, its in vivo role, or its role in the pathophysiology of RA; however, recent reports suggest that this enzyme can act as a transcriptional corepressor for the estrogen receptor. Herein, we report our initial kinetic and mechanistic characterization of human PAD4. Specifically, these studies confirm that PAD4 catalyzes the hydrolytic deimination of Arg residues to produce Cit and ammonia. The metal dependence of PAD4 has also been evaluated, and the results indicate that PAD4 activity is highly specific for calcium. Calcium activation of PAD4 catalysis exhibits positive cooperativity with K(0.5) values in the mid to high micromolar range. Evidence indicating that calcium binding causes a conformational change is also presented. Additionally, the steady-state kinetic parameters for a number of histone H4-based peptide substrates and benzoylated Arg derivatives have been determined. K(m) values for these compounds are in the high micromolar to the low millimolar range with k(cat) values ranging from 2.8 to 6.6 s(-)(1). The ability of PAD4 to catalyze the deimination of methylated Arg residues has also been evaluated, and the results indicate that these compounds are poor PAD4 substrates (V/K

Published

2005

37. Mutational, structural, and kinetic evidence for a dissociative mechanism in the GDP-mannose mannosyl hydrolase reaction.

Author

Xia Z, Azurmendi HF, Lairson LL, Withers SG, Gabelli SB, Bianchet MA, Amzel LM, and Mildvan AS

Subjects

Arginine genetics, Arginine metabolism, Aspartic Acid genetics, Aspartic Acid metabolism, Crystallography, X-Ray, Enzyme Inhibitors chemistry, Enzyme Inhibitors pharmacology, Guanosine Diphosphate Fucose metabolism, Hydrogen-Ion Concentration, Hydrolases antagonists & inhibitors, Hydrolases genetics, Hydrolysis, Kinetics, Nuclear Magnetic Resonance, Biomolecular, Substrate Specificity, Tyrosine genetics, Tyrosine metabolism, Guanosine Diphosphate Mannose metabolism, Hydrolases chemistry, Hydrolases metabolism, Mutation genetics

Abstract

GDP-mannose hydrolase (GDPMH) catalyzes the hydrolysis of GDP-alpha-d-sugars by nucleophilic substitution with inversion at the anomeric C1 atom of the sugar, with general base catalysis by H124. Three lines of evidence indicate a mechanism with dissociative character. First, in the 1.3 A X-ray structure of the GDPMH-Mg(2+)-GDP.Tris(+) complex [Gabelli, S. B., et al. (2004) Structure 12, 927-935], the GDP leaving group interacts with five catalytic components: R37, Y103, R52, R65, and the essential Mg(2+). As determined by the effects of site-specific mutants on k(cat), these components contribute factors of 24-, 100-, 309-, 24-, and >/=10(5)-fold, respectively, to catalysis. Both R37 and Y103 bind the beta-phosphate of GDP and are only 5.0 A apart. Accordingly, the R37Q/Y103F double mutant exhibits partially additive effects of the two single mutants on k(cat), indicating cooperativity of R37 and Y103 in promoting catalysis, and antagonistic effects on K(m). Second, the conserved residue, D22, is positioned to accept a hydrogen bond from the C2-OH group of the sugar undergoing substitution at C1, as was shown by modeling an alpha-d-mannosyl group into the sugar binding site. The D22A and D22N mutations decreased k(cat) by factors of 10(2.1) and 10(2.6), respectively, for the hydrolysis of GDP-alpha-d-mannose, and showed smaller effects on K(m), suggesting that the D22 anion stabilizes a cationic oxocarbenium transition state. Third, the fluorinated substrate, GDP-2F-alpha-d-mannose, for which a cationic oxocarbenium transition state would be destabilized by electron withdrawal, exhibited a 16-fold decrease in k(cat) and a smaller, 2.5-fold increase in K(m). The D22A and D22N mutations further decreased the k(cat) with GDP-2F-alpha-d-mannose to values similar to those found with GDP-alpha-d-mannose, and decreased the K(m) of the fluorinated substrate. The choice of histidine as the general base over glutamate, the preferred base in other Nudix enzymes, is not due to the greater basicity of histidine, since the pK(a) of E124 in the active complex (7.7) exceeded that of H124 (6.7), and the H124E mutation showed a 10(2.2)-fold decrease in k(cat) and a 4.0-fold increase in K(m) at pH 9.3. Similarly, the catalytic triad detected in the X-ray structure (H124- - -Y127- - -P120) is unnecessary for orienting H124, since the Y127F mutation had only 2-fold effects on k(cat) and K(m) with either H124 or E124 as the general base. Hence, a neutral histidine rather than an anionic glutamate may be necessary to preserve electroneutrality in the active complex.

Published

2005

38. Improved catalytic properties of halohydrin dehalogenase by modification of the halide-binding site.

Author

Tang L, Torres Pazmiño DE, Fraaije MW, de Jong RM, Dijkstra BW, and Janssen DB

Subjects

Asparagine genetics, Bacterial Proteins genetics, Bacterial Proteins metabolism, Binding Sites genetics, Bromides metabolism, Chlorides metabolism, Hydrolases genetics, Hydrolases metabolism, Kinetics, Ligands, Mutagenesis, Site-Directed, Phenylalanine genetics, Protein Binding genetics, Rhizobium enzymology, Rhizobium genetics, Spectrometry, Fluorescence, Stereoisomerism, Tryptophan genetics, Tyrosine genetics, Bacterial Proteins chemistry, Bromides chemistry, Catalytic Domain genetics, Chlorides chemistry, Hydrolases chemistry

Abstract

Halohydrin dehalogenase (HheC) from Agrobacterium radiobacter AD1 catalyzes the dehalogenation of vicinal haloalcohols by an intramolecular substitution reaction, resulting in the formation of the corresponding epoxide, a halide ion, and a proton. Halide release is rate-limiting during the catalytic cycle of the conversion of (R)-p-nitro-2-bromo-1-phenylethanol by the enzyme. The recent elucidation of the X-ray structure of HheC showed that hydrogen bonds between the OH group of Tyr187 and between the Odelta1 atom of Asn176 and Nepsilon1 atom of Trp249 could play a role in stabilizing the conformation of the halide-binding site. The possibility that these hydrogen bonds are important for halide binding and release was studied using site-directed mutagenesis. Steady-state kinetic studies revealed that mutant Y187F, which has lost both hydrogen bonds, has a higher catalytic activity (k(cat)) with two of the three tested substrates compared to the wild-type enzyme. Mutant W249F also shows an enhanced k(cat) value with these two substrates, as well as a remarkable increase in enantiopreference for (R)-p-nitro-2-bromo-1-phenylethanol. In case of a mutation at position 176 (N176A and N176D), a 1000-fold lower catalytic efficiency (k(cat)/K(m)) was obtained, which is mainly due to an increase of the K(m) value of the enzyme. Pre-steady-state kinetic studies showed that a burst of product formation precedes the steady state, indicating that halide release is still rate-limiting for mutants Y187F and W249F. Stopped-flow fluorescence experiments revealed that the rate of halide release is 5.6-fold higher for the Y187F mutant than for the wild-type enzyme and even higher for the W249F enzyme. Taken together, these results show that the disruption of two hydrogen bonds around the halide-binding site increases the rate of halide release and can enhance the overall catalytic activity of HheC.

Published

2005

39. Crystal structure of S-ribosylhomocysteinase (LuxS) in complex with a catalytic 2-ketone intermediate.

Author

Rajan R, Zhu J, Hu X, Pei D, and Bell CE

Subjects

Alanine genetics, Arginine genetics, Bacillus subtilis genetics, Bacterial Proteins genetics, Binding Sites genetics, Carbon-Sulfur Lyases, Catalysis, Cobalt chemistry, Crystallization, Crystallography, X-Ray, Cysteine genetics, Ferrous Compounds chemistry, Histidine genetics, Homocysteine metabolism, Hydrolases genetics, Ketones chemistry, Models, Molecular, Mutagenesis, Site-Directed, Serine genetics, Spectrophotometry, Ultraviolet, Substrate Specificity genetics, Vibrio enzymology, Vibrio genetics, Bacillus subtilis enzymology, Bacterial Proteins chemistry, Bacterial Proteins metabolism, Hydrolases chemistry, Hydrolases metabolism, Ketones metabolism

Abstract

S-Ribosylhomocysteinase (LuxS) is an Fe(2+)-dependent metalloenzyme that catalyzes the cleavage of the thioether bond in S-ribosylhomocysteine (SRH) to produce homocysteine (Hcys) and 4,5-dihydroxy-2,3-pentanedione (DPD), the precursor of type II bacterial quorum-sensing molecule. The proposed mechanism involves an initial metal-catalyzed aldose-ketose isomerization reaction, which results in the migration of the ribose carbonyl group from its C1 to C2 position and the formation of a 2-ketone intermediate. A repetition of the isomerization reaction shifts the carbonyl group to the C3 position. Subsequent beta-elimination reaction at the C4 and C5 positions completes the catalytic cycle. In this work, a catalytically inactive mutant (C84A) of Co(2+)-substituted Bacillus subtilis LuxS was cocrystallized with the 2-ketone intermediate and the structure was determined to 1.8 A resolution. The structure reveals that the C2 carbonyl oxygen is directly coordinated with the metal ion, providing strong support for the proposed Lewis acid function of the metal ion during catalysis. Cys-84 and Glu-57 are optimally positioned to act as general acids/bases during the isomerization and elimination reactions. In addition, Ser-6, His-11, and Arg-39 are involved in substrate/ intermediate binding through hydrogen bonding interactions. The above conclusions are further confirmed by site-directed mutagenesis and visible absorption spectroscopic studies.

Published

2005

40. Investigation of metal ion binding in phosphonoacetaldehyde hydrolase identifies sequence markers for metal-activated enzymes of the HAD enzyme superfamily.

Author

Zhang G, Morais MC, Dai J, Zhang W, Dunaway-Mariano D, and Allen KN

Subjects

Alanine metabolism, Amino Acid Motifs, Amino Acid Sequence, Amino Acid Substitution, Aspartic Acid metabolism, Bacillus cereus enzymology, Binding Sites, Conserved Sequence, Crystallography, X-Ray, Enzyme Activation, Hydrogen Bonding, Hydrolases chemistry, Hydrolases genetics, Kinetics, Ligands, Magnesium metabolism, Models, Molecular, Protein Structure, Tertiary, Substrate Specificity, Water chemistry, Hydrolases metabolism, Metals metabolism

Abstract

The 2-haloalkanoic acid dehalogenase (HAD) family, which contains both carbon and phosphoryl transferases, is one of the largest known enzyme superfamilies. HAD members conserve an alpha,beta-core domain that frames the four-loop active-site platform. Each loop contributes one or more catalytic groups, which function in mediating the core chemistry (i.e., group transfer). In this paper, we provide evidence that the number of carboxylate residues on loop 4 and their positions (stations) on the loop are determinants, and therefore reliable sequence markers, for metal ion activation among HAD family members. Using this predictor, we conclude that the vast majority of the HAD members utilize a metal cofactor. Analysis of the minimum requirements for metal cofactor binding was carried out using Mg(II)-activated Bacillus cereus phosphonoacetaldehyde hydrolase (phosphonatase) as an experimental model for metal-activated HAD members. Mg(II) binding occurs via ligation to the loop 1 Asp12 carboxylate and Thr14 backbone carbonyl and to the loop 4 Asp186 carboxylate. The loop 4 Asp190 forms a hydrogen bond to the Mg(II) water ligand. X-ray structure determination of the D12A mutant in the presence of the substrate phosphonoacetaldehyde showed that replacement of the loop 1 Asp, common to all HAD family members, with Ala shifts the position of Mg(II), thereby allowing innersphere coordination to Asp190 and causing a shift in the position of the substrate. Kinetic analysis of the loop 4 mutants showed that Asp186 is essential to cofactor binding while Asp190 simply enhances it. Within the phosphonatase subfamily, Asp186 is stringently conserved, while either position 185 or position 190 is used to position the second loop 4 Asp residue. Retention of a high level of catalytic activity in the G185D/D190G phosphonatase mutant demonstrated the plasticity of the metal binding loop, reflected in the variety of combinations in positioning of two or three Asp residues along the seven-residue motif of the 2700 potential HAD sequences that were examined.

Published

2004

41. The roles of active-site residues in the catalytic mechanism of trans-3-chloroacrylic acid dehalogenase: a kinetic, NMR, and mutational analysis.

Author

Azurmendi HF, Wang SC, Massiah MA, Poelarends GJ, Whitman CP, and Mildvan AS

Subjects

Acrylates chemistry, Arginine chemistry, Binding Sites genetics, Catalysis, DNA Mutational Analysis, Glycine chemistry, Hydrogen-Ion Concentration, Intramolecular Oxidoreductases chemistry, Kinetics, Models, Chemical, Nitrogen Isotopes chemistry, Nuclear Magnetic Resonance, Biomolecular, Peptide Fragments chemistry, Peptide Fragments genetics, Proline chemistry, Protein Subunits chemistry, Protein Subunits genetics, Protons, Pseudomonas enzymology, Pseudomonas genetics, Solvents, Catalytic Domain genetics, Glycine analogs & derivatives, Hydrolases chemistry, Hydrolases genetics, Mutagenesis, Site-Directed

Abstract

trans-3-Chloroacrylic acid dehalogenase (CaaD) converts trans-3-chloroacrylic acid to malonate semialdehyde by the addition of H(2)O to the C-2, C-3 double bond, followed by the loss of HCl from the C-3 position. Sequence similarity between CaaD, an (alphabeta)(3) heterohexamer (molecular weight 47,547), and 4-oxalocrotonate tautomerase (4-OT), an (alpha)(6) homohexamer, distinguishes CaaD from those hydrolytic dehalogenases that form alkyl-enzyme intermediates. The recently solved X-ray structure of CaaD demonstrates that betaPro-1 (i.e., Pro-1 of the beta subunit), alphaArg-8, alphaArg-11, and alphaGlu-52 are at or near the active site, and the >or=10(3.4)-fold decreases in k(cat) on mutating these residues implicate them as mechanistically important. The effect of pH on k(cat)/K(m) indicates a catalytic base with a pK(a) of 7.6 and an acid with a pK(a) of 9.2. NMR titration of (15)N-labeled wild-type CaaD yielded pK(a) values of 9.3 and 11.1 for the N-terminal prolines, while the fully active but unstable alphaP1A mutant showed a pK(a) of 9.7 (for the betaPro-1), implicating betaPro-1 as the acid catalyst, which may protonate C-2 of the substrate. These results provide the first evidence for an amino-terminal proline, conserved in all known tautomerase superfamily members, functioning as a general acid, rather than as a general base as in 4-OT. Hence, a reasonable candidate for the general base in CaaD is the active site residue alphaGlu-52. CaaD has 10 arginine residues, six in the alpha-subunit (Arg-8, Arg-11, Arg-17, Arg-25, Arg-35, and Arg-43), and four in the beta-subunit (Arg-15, Arg-21, Arg-55, and Arg-65). (1)H-(15)N-heteronuclear single quantum coherence (HSQC) spectra of CaaD showed seven to nine Arg-NepsilonH resonances (denoted R(A) to R(I)) depending on the protein concentration and pH. One of these signals (R(D)) disappeared in the spectrum of the largely inactive alphaR11A mutant (deltaH = 7.11 ppm, deltaN = 89.5 ppm), and another one (R(G)) disappeared in the spectrum of the inactive alphaR8A mutant (deltaH = 7.48 ppm, deltaN = 89.6 ppm), thereby assigning these resonances to alphaArg-11NepsilonH, and alphaArg-8NepsilonH, respectively. (1)H-(15)N-HSQC titration of the enzyme with the substrate analogue 3-chloro-2-butenoic acid (3-CBA), a competitive inhibitor (K(I)(slope) = 0.35 +/- 0.06 mM), resulted in progressive downfield shifts of the alphaArg-8Nepsilon resonance yielding a K(D) = 0.77 +/- 0.44 mM, comparable to the (K(I)(slope), suggestive of active site binding. Increasing the pH of free CaaD to 8.9 at 5 degrees C resulted in the disappearance of all nine Arg-NepsilonH resonances due to base-catalyzed NepsilonH exchange. Saturating the enzyme with 3-CBA (16 mM) induced the reappearance of two NepsilonH signals, those of alphaArg-8 and alphaArg-11, indicating that the binding of the substrate analogue 3-CBA selectively slows the NepsilonH exchange rates of these two arginine residues. The kinetic and NMR data thus indicate that betaPro-1 is the acid catalyst, alphaGlu-52 is a reasonable candidate for the general base, and alphaArg-8 and alphaArg-11 participate in substrate binding and in stabilizing the aci-carboxylate intermediate in a Michael addition mechanism.

Published

2004

42. Analysis of the substrate specificity loop of the HAD superfamily cap domain.

Author

Lahiri SD, Zhang G, Dai J, Dunaway-Mariano D, and Allen KN

Subjects

Amino Acid Substitution genetics, Bacillus cereus enzymology, Bacillus cereus genetics, Catalysis, Crystallization, Crystallography, X-Ray, Glycine genetics, Hydrolases genetics, Hydrolases isolation & purification, Lactococcus lactis enzymology, Lactococcus lactis genetics, Mutagenesis, Site-Directed, Phosphoglucomutase genetics, Proline genetics, Protein Conformation, Protein Structure, Tertiary genetics, Structural Homology, Protein, Substrate Specificity genetics, Hydrolases chemistry, Phosphoglucomutase chemistry

Abstract

The haloacid dehalogenase (HAD) superfamily includes a variety of enzymes that catalyze the cleavage of substrate C-Cl, P-C, and P-OP bonds via nucleophilic substitution pathways. All members possess the alpha/beta core domain, and many also possess a small cap domain. The active site of the core domain is formed by four loops (corresponding to sequence motifs 1-4), which position substrate and cofactor-binding residues as well as the catalytic groups that mediate the "core" chemistry. The cap domain is responsible for the diversification of chemistry within the family. A tight beta-turn in the helix-loop-helix motif of the cap domain contains a stringently conserved Gly (within sequence motif 5), flanked by residues whose side chains contribute to the catalytic site formed at the domain-domain interface. To define the role of the conserved Gly in the structure and function of the cap domain loop of the HAD superfamily members phosphonoacetaldehyde hydrolase and beta-phosphoglucomutase, the Gly was mutated to Pro, Val, or Ala. The catalytic activity was severely reduced in each mutant. To examine the impact of Gly substitution on loop 5 conformation, the X-ray crystal structure of the Gly50Pro phosphonoacetaldehyde hydrolase mutant was determined. The altered backbone conformation at position 50 had a dramatic effect on the spatial disposition of the side chains of neighboring residues. Lys53, the Schiff Base forming lysine, had rotated out of the catalytic site and the side chain of Leu52 had moved to fill its place. On the basis of these studies, it was concluded that the flexibility afforded by the conserved Gly is critical to the function of loop 5 and that it is a marker by which the cap domain substrate specificity loop can be identified within the amino acid sequence of HAD family members.

Published

2004

43. Three-dimensional structure of kynureninase from Pseudomonas fluorescens.

Author

Momany C, Levdikov V, Blagova L, Lima S, and Phillips RS

Subjects

Alanine genetics, Amino Acid Sequence, Aspartic Acid genetics, Bacterial Proteins chemistry, Binding Sites genetics, Crystallization, Crystallography, X-Ray, Glutamic Acid genetics, Humans, Hydrolases genetics, Hydrolases isolation & purification, Molecular Sequence Data, Mutagenesis, Site-Directed, Protein Folding, Pseudomonas fluorescens genetics, Pyridoxal Phosphate chemistry, Sequence Alignment, Sequence Homology, Amino Acid, Hydrolases chemistry, Pseudomonas fluorescens enzymology

Abstract

Kynureninase [E.C. 3.7.1.3] is a pyridoxal-5'-phosphate (PLP)-dependent enzyme that catalyzes the hydrolytic cleavage of l-kynurenine to anthranilic acid and l-alanine. Sequence alignment with other PLP-dependent enzymes indicated that kynureninase is in subgroup IVa of the aminotransferases, along with nifS, CsdB, and serine-pyruvate aminotransferase, which suggests that kynureninase has an aminotransferase fold. Crystals of Pseudomonas fluorescens kynureninase were obtained, and the structure was solved by molecular replacement using the CsdB coordinates combined with multiple isomorphous heavy atom replacement. The coordinates were deposited in the PDB (ID code 1QZ9). The structure, refined to an R factor of 15.5% to 1.85 A resolution, is dimeric and has the aminotransferase fold. The structure also confirms the prediction from sequence alignment that Lys-227 is the PLP-binding residue in P. fluorescens kynureninase. The conserved Asp-201, expected for an aminotransferase fold, is located near the PLP nitrogen, but Asp-132 is also strictly conserved and at a similar distance from the pyridinium nitrogen. Mutagenesis of both conserved aspartic acids shows that both contribute equally to PLP binding, but Asp-201 has a greater role in catalysis. The structure shows that Tyr-226 donates a hydrogen bond to the phosphate of PLP. Unusual among PLP-dependent enzymes, Trp-256, which is also strictly conserved in kynureninases from bacteria to humans, donates a hydrogen bond to the phosphate through the indole N1-hydrogen.

Published

2004

44. Cloning, expression, and characterization of a cis-3-chloroacrylic acid dehalogenase: insights into the mechanistic, structural, and evolutionary relationship between isomer-specific 3-chloroacrylic acid dehalogenases.

Author

Poelarends GJ, Serrano H, Person MD, Johnson WH Jr, Murzin AG, and Whitman CP

Subjects

Amino Acid Sequence, Arginine genetics, Cloning, Molecular methods, Corynebacterium enzymology, Corynebacterium genetics, Enzyme Inhibitors chemistry, Glutamic Acid genetics, Hydrolases antagonists & inhibitors, Hydrolases biosynthesis, Isomerases chemistry, Isomerases genetics, Kinetics, Molecular Sequence Data, Multigene Family, Mutagenesis, Site-Directed, Nuclear Magnetic Resonance, Biomolecular, Peptide Fragments chemistry, Peptide Fragments genetics, Proline genetics, Protein Structure, Secondary, Protons, Sequence Homology, Amino Acid, Spectrometry, Mass, Electrospray Ionization, Substrate Specificity, Evolution, Molecular, Hydrolases genetics, Hydrolases isolation & purification

Abstract

The gene encoding the cis-3-chloroacrylic acid dehalogenase (cis-CaaD) from coryneform bacterium strain FG41 has been cloned and overexpressed, and the enzyme has been purified to homogeneity and subjected to kinetic and mechanistic characterization. Kinetic studies show that cis-CaaD processes cis-3-haloacrylates, but not trans-3-haloacrylates, with a turnover number of approximately 10 s(-1). The product of the reaction is malonate semialdehyde, which was confirmed by its characteristic 1H NMR spectrum. The enzyme shares low but significant sequence similarity with the previously studied trans-3-chloroacrylic acid dehalogenase (CaaD) and with other members of the 4-oxalocrotonate tautomerase (4-OT) family. While 4-OT and CaaD function as homo- and heterohexamers, respectively, cis-CaaD appears to be a homotrimeric protein as assessed by gel filtration chromatography. On the basis of the known three-dimensional structures and reaction mechanisms of CaaD and 4-OT, a sequence alignment implicated Pro-1, Arg-70, Arg-73, and Glu-114 as important active-site residues in cis-CaaD. Subsequent site-directed mutagenesis experiments confirmed these predictions. The acetylene compounds, 2-oxo-3-pentynoate and 3-bromo- and 3-chloropropiolate, were processed by cis-CaaD to products consistent with an enzyme-catalyzed hydration reaction previously established for CaaD. Hydration of 2-oxo-3-pentynoate afforded acetopyruvate, while the 3-halopropiolates became irreversible inhibitors that modified Pro-1. The results of this work revealed that cis-CaaD and CaaD have different primary and quaternary structures, and display different substrate specificity and catalytic efficiencies, but likely share a highly conserved catalytic mechanism. The mechanism may have evolved independently because sequence analysis indicates that cis-CaaD is not a 4-OT family member, but represents the first characterized member of a new family in the tautomerase superfamily that probably resulted from an independent duplication of a 4-OT-like sequence. The discovery of a fifth family of enzymes within this superfamily further demonstrates the diversity of activities and structures that can be created from 4-OT-like sequences.

Published

2004

45. Steady-state kinetics and tryptophan fluorescence properties of halohydrin dehalogenase from Agrobacterium radiobacter. Roles of W139 and W249 in the active site and halide-induced conformational change.

Author

Tang L, van Merode AE, Lutje Spelberg JH, Fraaije MW, and Janssen DB

Subjects

Acrylamide chemistry, Amino Acid Sequence, Bacterial Proteins genetics, Binding Sites genetics, Catalysis, Hydrogen-Ion Concentration, Hydrolases genetics, Kinetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Phenylalanine genetics, Protein Binding genetics, Protein Conformation, Rhizobium genetics, Spectrometry, Fluorescence methods, Stereoisomerism, Substrate Specificity genetics, Tryptophan genetics, Bacterial Proteins chemistry, Bromides chemistry, Hydrolases chemistry, Rhizobium enzymology, Tryptophan chemistry

Abstract

Halohydrin dehalogenase (HheC) from Agrobacterium radiobacter AD1 is a homotetrameric protein containing four tryptophan residues per subunit. The fluorescence properties of the enzyme are strongly influenced by halide binding. To examine the role of the tryptophans (W139, W192, W238, and W249) in halide binding and catalysis, they were individually mutated to a phenylalanine. All mutations, except for W238F, influenced the enzymatic properties. Mutating W192 to phenylalanine inactivated the enzyme and led to dissociation into dimers and monomers. In the structure of HheC, residue W139 and residue W249 from the opposite subunit are close to the active site of the enzyme. Substitution of W139 mainly affected K(m) values with all tested substrates and reduced the enantiopreference for p-nitro-2-bromo-1-phenylethanol. Replacing W249 increased both k(cat) and K(m) values with all tested substrates except for the (S)-enantiomer of p-nitro-2-bromo-1-phenylethanol, for which k(cat) was 3-fold decreased, resulting in a 6-fold increase of the enantioselectivity. Fluorescence measurements revealed that in the ligand-free state the intrinsic protein fluorescence of mutant W139F is higher than that of the wild-type enzyme, while the fluorescence intensity of mutants W238F and W249F was lower. The fluorescence intensities of the W238F and W249F enzymes were increased when they were unfolded or when bromide was added, whereas the fluorescence of mutant W139F was not increased by unfolding or addition of bromide. These results demonstrate that the fluorescence of residues W238 and W249 is partially quenched in the folded ligand-free state, and that W139 is completely quenched and acts as an energy acceptor for the other tryptophan residues as well. Changes of the maximum fluorescence emission wavelength of the HheC variants and the results of acrylamide quenching experiments confirmed that bromide binding induces a local conformational change around the active site, resulting in residue W139 and the quencher group being separated.

Published

2003

46. Structure and mechanism of Pseudomonas aeruginosa PhzD, an isochorismatase from the phenazine biosynthetic pathway.

Author

Parsons JF, Calabrese K, Eisenstein E, and Ladner JE

Subjects

Catalytic Domain, Chorismic Acid chemistry, Chorismic Acid metabolism, Crystallography, X-Ray, Cyclohexenes, Dimerization, Hydrolases genetics, Kinetics, Models, Molecular, Molecular Structure, Mutagenesis, Site-Directed, Phenazines chemistry, Protein Conformation, Protein Structure, Quaternary, Pseudomonas aeruginosa genetics, Recombinant Proteins chemistry, Recombinant Proteins genetics, Recombinant Proteins metabolism, Hydrolases chemistry, Hydrolases metabolism, Phenazines metabolism, Pseudomonas aeruginosa enzymology

Abstract

PhzD from Pseudomonas aeruginosa is an isochorismatase involved in phenazine biosynthesis. Phenazines are antimicrobial compounds that provide Pseudomonas with a competitive advantage in certain environments and may be partly responsible for the persistence of Pseudomonas infections. In vivo, PhzD catalyzes the hydrolysis of the vinyl ether functional group of 2-amino-2-deoxyisochorismate, yielding pyruvate and trans-2,3-dihydro-3-hydroxyanthranilic acid, which is then utilized in the phenazine biosynthetic pathway. PhzD also catalyzes hydrolysis of the related vinyl ethers isochorismate, chorismate, and 4-amino-4-deoxychorismate. Here we report the 1.5 A crystal structure of native PhzD, and the 1.6 A structure of the inactive D38A variant in complex with isochorismate. The structures reveal that isochorismate binds to the PhzD active site in a trans-diaxial conformation, and superposition of the structures indicates that the methylene pyruvyl carbon of isochorismate is adjacent to the side chain carboxylate of aspartate 38. The proximity of aspartate 38 to isochorismate and the complete loss of activity resulting from the conversion of aspartate 38 to alanine suggest a mechanism in which the carboxylate acts as a general acid to protonate the substrate, yielding a carbocation/oxocarbonium ion that is then rapidly hydrated to form a hemiketal intermediate, which then decomposes spontaneously to products. The structure of PhzD is remarkably similar to other structures from a subfamily of alpha/beta-hydrolase enzymes that includes pyrazinamidase and N-carbamoylsarcosine amidohydrolase. However, PhzD catalyzes unrelated chemistry and lacks a nucleophilic cysteine found in its close structural relatives. The vinyl ether hydrolysis catalyzed by PhzD represents yet another example of the catalytic diversity seen in the alpha/beta-hydrolase family, whose members are also known to hydrolyze amides, phosphates, phosphonates, epoxides, and C-X bonds.

Published

2003

47. Halide-stabilizing residues of haloalkane dehalogenases studied by quantum mechanic calculations and site-directed mutagenesis.

Author

Bohác M, Nagata Y, Prokop Z, Prokop M, Monincová M, Tsuda M, Koca J, and Damborský J

Subjects

Amino Acids genetics, Anions chemistry, Asparagine genetics, Glutamic Acid genetics, Histidine genetics, Isoleucine genetics, Leucine genetics, Mathematical Computing, Models, Chemical, Phenylalanine genetics, Proline genetics, Static Electricity, Tryptophan genetics, Valine genetics, Amino Acids chemistry, Halogens chemistry, Hydrolases chemistry, Hydrolases genetics, Mutagenesis, Site-Directed, Quantum Theory

Abstract

Haloalkane dehalogenases catalyze cleavage of the carbon-halogen bond in halogenated aliphatic compounds, resulting in the formation of an alcohol, a halide, and a proton as the reaction products. Three structural features of haloalkane dehalogenases are essential for their catalytic performance: (i) a catalytic triad, (ii) an oxyanion hole, and (iii) the halide-stabilizing residues. Halide-stabilizing residues are not structurally conserved among different haloalkane dehalogenases. The level of stabilization of the transition state structure of S(N)2 reaction and halide ion provided by each of the active site residues in the enzymes DhlA, LinB, and DhaA was quantified by quantum mechanic calculations. The residues that significantly stabilize the halide ion were assigned as the primary (essential) or the secondary (less important) halide-stabilizing residues. Site-directed mutagenesis was conducted with LinB enzyme to confirm location of its primary halide-stabilizing residues. Asn38Asp, Asn38Glu, Asn38Phe, Asn38Gln, Trp109Leu, Phe151Leu, Phe151Trp, Phe151Tyr, and Phe169Leu mutants of LinB were constructed, purified, and kinetically characterized. The following active site residues were classified as the primary halide-stabilizing residues: Trp125 and Trp175 of DhlA; Asn38 and Trp109 of LinB; and Asn41 and Trp107 of DhaA. All these residues make a hydrogen bond with the halide ion released from the substrate molecule, and their substitution results in enzymes with significantly modified catalytic properties. The following active site residues were classified as the secondary halide-stabilizing residues: Phe172, Pro223, and Val226 of DhlA; Trp207, Pro208, and Ile211 of LinB; and Phe205, Pro206, and Ile209 of DhaA. The differences in the halide stabilizing residues of three haloalkane dehalogenases are discussed in the light of molecular adaptation of these enzymes to their substrates.

Published

2002

48. Kinetic evidence for a substrate-induced fit in phosphonoacetaldehyde hydrolase catalysis.

Author

Zhang G, Mazurkie AS, Dunaway-Mariano D, and Allen KN

Subjects

Acetylation, Amino Acid Sequence, Bacillus cereus genetics, Binding Sites genetics, Catalysis, Crystallography, X-Ray, Enzyme Inhibitors chemistry, Hydrogen-Ion Concentration, Hydrolases analysis, Hydrolases antagonists & inhibitors, Hydrolases genetics, Kinetics, Ligands, Lysine genetics, Molecular Sequence Data, Mutagenesis, Site-Directed, Peptide Fragments analysis, Peptide Fragments genetics, Phenylacetates chemistry, Protein Structure, Tertiary genetics, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Substrate Specificity genetics, Bacillus cereus enzymology, Hydrolases chemistry

Abstract

Phosphonoacetaldehyde hydrolase (phosphonatase) from Bacillus cereus catalyzes hydrolytic P-C bond cleavage of phosphonoacetaldehyde (Pald) via a Schiff base intermediate formed with Lys53. A single turnover requires binding of Pald to the active site of the core domain, closure of the cap domain containing the Lys53 over the core domain, and dissociation of the products following catalysis. The ligand binding and dissociation steps occur from the "open conformer" (domains are separated and the active site is solvent-exposed), while catalysis occurs from the "closed conformer" (domains are bound together and the active site is sequestered from solvent). To test the hypothesis that bound substrate stabilizes the closed conformer, thus facilitating catalysis, the rates of chemical modification of Lys53 in the presence and absence of inert substrate and/or product analogues were compared. Acetylation of Lys53 with 2,4-dinitrophenylacetate (DNPA) resulted in the loss of enzyme activity. The pseudo-first-order rate constant for inactivation varied with pH. The pH profile of inactivation is consistent with a pK(a) of 9.3 for Lys53. The inhibitors tungstate and vinyl sulfonate, which are known to bind to active site residues comprising the core domain, protected Lys53 from acetylation. These results are consistent with a dynamic equilibrium between the open and closed conformations of phosphonatase and the hypothesis that ligand binding stabilizes the closed conformation required for catalytic turnover.

Published

2002

49. Hint, Fhit, and GalT: function, structure, evolution, and mechanism of three branches of the histidine triad superfamily of nucleotide hydrolases and transferases.

Author

Brenner C

Subjects

Animals, Evolution, Molecular, Hydrolases chemistry, Hydrolases genetics, Neoplasm Proteins chemistry, Neoplasm Proteins genetics, Protein Conformation, Structure-Activity Relationship, UTP-Hexose-1-Phosphate Uridylyltransferase chemistry, UTP-Hexose-1-Phosphate Uridylyltransferase genetics, Acid Anhydride Hydrolases, Hydrolases metabolism, Neoplasm Proteins metabolism, UTP-Hexose-1-Phosphate Uridylyltransferase metabolism

Abstract

HIT (histidine triad) proteins, named for a motif related to the sequence HphiHphiHphiphi (phi, a hydrophobic amino acid), are a superfamily of nucleotide hydrolases and transferases, which act on the alpha-phosphate of ribonucleotides, and contain a approximately 30 kDa domain that is typically either a homodimer of approximately 15 kDa polypeptides with two active-sites or an internally, imperfectly repeated polypeptide that retains a single HIT active site. On the basis of sequence, substrate specificity, structure, evolution, and mechanism, HIT proteins can be classified into the Hint branch, which consists of adenosine 5'-monophosphoramide hydrolases, the Fhit branch, which consists of diadenosine polyphosphate hydrolases, and the GalT branch, which consists of specific nucleoside monophosphate transferases, including galactose-1-phosphate uridylyltransferase, diadenosine tetraphosphate phosphorylase, and adenylyl sulfate:phosphate adenylytransferase. At least one human representative of each branch is lost in human diseases. Aprataxin, a Hint branch hydrolase, is mutated in ataxia-oculomotor apraxia syndrome. Fhit is lost early in the development of many epithelially derived tumors. GalT is deficient in galactosemia. Additionally, ASW is an avian Hint family member that has evolved to have unusual gene expression properties and the complete loss of its nucleotide binding site. The potential roles of ASW and Hint in avian sexual development are discussed elsewhere. Here we review what is known about biological activities of HIT proteins, the structural and biochemical bases for their functions, and propose a new enzyme mechanism for Hint and Fhit that may account for the differences between HIT hydrolases and transferases.

Published

2002

50. Contributions of active site residues to the partial and overall catalytic activities of human S-adenosylhomocysteine hydrolase.

Author

Elrod P, Zhang J, Yang X, Yin D, Hu Y, Borchardt RT, and Schowen RL

Subjects

Adenosylhomocysteinase, Binding Sites genetics, Catalysis, Humans, Hydrolases chemistry, Hydrolases genetics, Models, Chemical, Mutagenesis, Site-Directed, Oxidation-Reduction, Point Mutation, Protein Structure, Quaternary genetics, Protein Structure, Secondary genetics, Recombinant Proteins chemistry, Recombinant Proteins isolation & purification, Recombinant Proteins metabolism, Thermodynamics, Hydrolases metabolism

Abstract

Residues glutamate 156 (E156), aspartate 190 (D190), asparagine 181 (N181), lysine 186 (K186), and asparagine 191 (N191) in the active site of S-adenosylhomocysteine (AdoHcy) hydrolase have been mutated to alanine (A). AdoHcy hydrolase achieves catalysis of AdoHcy hydrolysis to adenosine (Ado) and homocysteine (Hcy) by means of a redox partial reaction (3'-oxidation of AdoHcy at the beginning and 3'-reduction of Ado at the end of the catalytic cycle) spanning an elimination/addition partial reaction (elimination of Hcy from the oxidized substrate and addition of water to generate the oxidized product), with the enzyme in an open NAD(+) form in the ligand-free state and in a closed NADH form during the elimination/addition partial reaction. Mutation K186A reduces the rate of a model enzymatic reaction for the redox partial reaction by a factor of 280000 and the rate of a model reaction for the elimination/addition partial reaction by a factor of 24000, consistent with a primary catalytic role in both partial reactions as a proton donor/acceptor at the 3'-OH/3'-keto center. Secondary roles for N181 and N191 in localizing the flexible side chain of K186 in a catalytically effective position are supported by rate reduction factors for N181A of 2500 (redox) and 240 (elimination/addition) and for N191A of 730 (redox) and 340 (elimination/addition). A role of D190 in orienting the substrate for effective transition-state stabilization is consistent with rate reduction factors of 1300 (redox) and 30 (elimination/addition) for D190A. Residue E156 may act to maintain K186 in the desired protonation state: rate deduction factors are 1100 (redox) and 70 (elimination/addition). The mutational increases in free energy barriers for k(cat)/K(M) are described by a linear combination of the effects for the partial reactions with the coefficients equal to the fractional degree that each partial reaction determines the rate for k(cat)/K(M). A similar linear equation for k(cat) overestimates the barrier increase by a uniform 5 kJ/mol, probably reflecting reactant-state stabilization by the wild-type enzyme that is abolished by the mutations.

Published

2002