Mutation Of Active Site Residues Research Articles

Comparison of L-Threonine Aldolase Variants in the Aldol and Retro-Aldol Reactions

Most of biochemical and mutagenesis studies performed with L-threonine aldolases were done with respect to natural activity, the cleavage of L-threonine and sometimes L-β-phenylserine. However, the properties of variants and the impact of mutations on the product synthesis are more interesting from an applications point of view. Here we performed site-directed mutagenesis of active site residues of L-threonine aldolase from Aeromonas jandaei to analyze their impact on the retro-aldol activity and on the aldol synthesis of L-β-phenylserine and L-α-alkyl-β-phenylserines. Consequently, reduced retro-aldol activity upon mutation of catalytically important residues led to increased conversions and diastereoselectivities in the synthetic direction. Thus, L-β-phenylserine can be produced with conversions up to 60% and d.e.‘s up to 80% (syn) under kinetic control. Furthermorem, the donor specificity of L-threonine aldolase was increased upon mutation of active site residues, which enlarged the pocket size for an efficient binding and stabilization of donor molecules in the active site. This study broadens the knowledge about L-threonine aldolase catalyzed reactions and improves the synthetic protocols for the biocatalytic asymmetric synthesis of unnatural amino acids.

Structure-Function Studies of Artemisia tridentata Farnesyl Diphosphate Synthase and Chrysanthemyl Diphosphate Synthase by Site-Directed Mutagenesis and Morphogenesis.

The amino acid sequences of farnesyl diphosphate synthase (FPPase) and chrysanthemyl diphosphate synthase (CPPase) from Artemisia tridentata ssp. Spiciformis, minus their chloroplast targeting regions, are 71% identical and 90% similar. FPPase efficiently and selectively synthesizes the "regular" sesquiterpenoid farnesyl diphosphate (FPP) by coupling isopentenyl diphosphate (IPP) to dimethylallyl diphosphate (DMAPP) and then to geranyl diphosphate (GPP). In contrast, CPPase is an inefficient promiscuous enzyme, which synthesizes the "irregular" monoterpenes chrysanthemyl diphosphate (CPP), lavandulyl diphosphate (LPP), and trace quantities of maconelliyl diphosphate (MPP) from two molecules of DMAPP, and couples IPP to DMAPP to give GPP. A.tridentata FPPase and CPPase belong to the chain elongation protein family (PF00348), a subgroup of the terpenoid synthase superfamily (CL0613) whose members have a characteristic α terpene synthase α-helical fold. The active sites of A.tridentata FPPase and CPPase are located within a six-helix bundle containing amino acids 53 to 241. The two enzymes were metamorphosed into one another by sequentially replacing the loops and helices of the six-helix bundle from enzyme with those from the other. Chain elongation was the dominant activity during the N-terminal to C-terminal metamorphosis of FPPase to CPPase, with product selectivity gradually switching from FPP to GPP, until replacement of the final α-helix, whereupon cyclopropanation and branching activity competed with chain elongation. During the corresponding metamorphosis of CPPase to FPPase, cyclopropanation and branching activities were lost upon replacement of the first helix in the six-helix bundle. Mutations of active site residues in CPPase to the corresponding amino acids in FPPase enhanced chain-elongation activity, while similar mutations in the active site of FPPase failed to significantly promote formation of significant amounts of irregular monoterpenes. Our results indicate that CPPase, a promiscuous enzyme, is more plastic toward acquiring new activities, whereas FPPase is more resistant. Mutations of residues outside of the α terpene synthase fold are important for acquisition of FPPase activity for synthesis of CPP, LPP, and MPP.

Exported Epoxide Hydrolases Modulate Erythrocyte Vasoactive Lipids during Plasmodium falciparum Infection.

ABSTRACTErythrocytes are reservoirs of important epoxide-containing lipid signaling molecules, including epoxyeicosatrienoic acids (EETs). EETs function as vasodilators and anti-inflammatory modulators in the bloodstream. Bioactive EETs are hydrolyzed to less active diols (dihydroxyeicosatrienoic acids) by epoxide hydrolases (EHs). The malaria parasite Plasmodium falciparum infects host red blood cells (RBCs) and exports hundreds of proteins into the RBC compartment. In this study, we show that two parasite epoxide hydrolases, P. falciparum epoxide hydrolases 1 (PfEH1) and 2 (PfEH2), both with noncanonical serine nucleophiles, are exported to the periphery of infected RBCs. PfEH1 and PfEH2 were successfully expressed in Escherichia coli, and they hydrolyzed physiologically relevant erythrocyte EETs. Mutations in active site residues of PfEH1 ablated the ability of the enzyme to hydrolyze an epoxide substrate. Overexpression of PfEH1 or PfEH2 in parasite-infected RBCs resulted in a significant alteration in the epoxide fatty acids stored in RBC phospholipids. We hypothesize that the parasite disruption of epoxide-containing signaling lipids leads to perturbed vascular function, creating favorable conditions for binding and sequestration of infected RBCs to the microvascular endothelium.

Substrate Distortion and the Catalytic Reaction Mechanism of 5-Carboxyvanillate Decarboxylase.

5-Carboxyvanillate decarboxylase (LigW) catalyzes the conversion of 5-carboxyvanillate to vanillate in the biochemical pathway for the degradation of lignin. This enzyme was shown to require Mn2+ for catalytic activity and the kinetic constants for the decarboxylation of 5-carboxyvanillate by the enzymes from Sphingomonas paucimobilis SYK-6 (kcat = 2.2 s–1 and kcat/Km = 4.0 × 104 M–1 s–1) and Novosphingobium aromaticivorans (kcat = 27 s–1 and kcat/Km = 1.1 × 105 M–1 s–1) were determined. The three-dimensional structures of both enzymes were determined in the presence and absence of ligands bound in the active site. The structure of LigW from N. aromaticivorans, bound with the substrate analogue, 5-nitrovanillate (Kd = 5.0 nM), was determined to a resolution of 1.07 Å. The structure of this complex shows a remarkable enzyme-induced distortion of the nitro-substituent out of the plane of the phenyl ring by approximately 23°. A chemical reaction mechanism for the decarboxylation of 5-carboxyvanillate by LigW was proposed on the basis of the high resolution X-ray structures determined in the presence ligands bound in the active site, mutation of active site residues, and the magnitude of the product isotope effect determined in a mixture of H2O and D2O. In the proposed reaction mechanism the enzyme facilitates the transfer of a proton to C5 of the substrate prior to the decarboxylation step.

Steady State Fluorescence Studies of Wild Type Recombinant Cinnamoyl CoA Reductase (Ll-CCRH1) and its Active Site Mutants

Fluorescence quenching and time resolved fluorescence studies of wild type recombinant cinnamoyl CoA reductase (Ll-CCRH1), a multitryptophan protein from Leucaena leucocephala and 10 different active site mutants were carried out to investigate tryptophan environment. The enzyme showed highest affinity for feruloyl CoA (K(a) = 3.72 × 10(5) M(-1)) over other CoA esters and cinnamaldehydes, as determined by fluorescence spectroscopy. Quenching of the fluorescence by acrylamide for wild type and active site mutants was collisional with almost 100% of the tryptophan fluorescence accessible under native condition and remained same after denaturation of protein with 6 M GdnHCl. In wild type Ll-CCRH1, the extent of quenching achieved with iodide (f(a) = 1.0) was significantly higher than cesium ions (f(a) = 0.33) suggesting more density of positive charge around surface of trp conformers under native conditions. Denaturation of wild type protein with 6 M GdnHCl led to significant increase in the quenching with cesium (f(a) = 0.54), whereas quenching with iodide ion was decreased (f(a) = 0.78), indicating reorientation of charge density around trp from positive to negative and heterogeneity in trp environment. The Stern-Volmer plots for wild type and mutants Ll-CCRH1 under native and denatured conditions, with cesium ion yielded biphasic quenching profiles. The extent of quenching for cesium and iodide ions under native and denatured conditions observed in active site mutants was significantly different from wild type Ll-CCRH1 under the same conditions. Thus, single substitution type mutations of active site residues showed heterogeneity in tryptophan microenvironment and differential degree of conformation of protein under native or denatured conditions.

Human single‐chain urokinase is activated by the omptins PgtE of Salmonella enterica and Pla of Yersinia pestis despite mutations of active site residues

Fibrinolysis is important in cell migration and tightly regulated by specific inhibitors and activators; of the latter, urokinase (uPA) associates with enhancement of cell migration. Active uPA is formed through cleavage of the single-chain uPA (scuPA). The Salmonella enterica strain 14028R cleaved human scuPA at the peptide bond Lys158-Ile159, the site cleaved also by the physiological activator human plasmin. The cleavage led to activation of scuPA, while no cleavage or activation were detected with the mutant strain 14028R lacking the omptin protease PgtE. Complementation and expression studies confirmed the role of PgtE in scuPA activation. Similar cleavage and activation of scuPA were detected with recombinant Escherichia coli expressing the omptin genes pla from Yersinia pestis, ompT and ompP from E. coli, sopA from Shigella flexneri, and leo from Legionella pneumophila. For these omptins the activation of scuPA is the only shared function so far detected. Only poor cleavage and activation of scuPA were seen with YcoA of Y. pestis and YcoB of Yersinia pseudotuberculosis that are considered to be proteolytically inactive omptin variants. Point mutations of active site residues in Pla and PgtE had different effects on the proteolysis of plasminogen and of scuPA, indicating versatility in omptin proteolysis.

First-Principles Study of Non-Heme Fe(II) Halogenase SyrB2 Reactivity

We present here a computational study of reactions at a model complex of the SyrB2 enzyme active site. SyrB2, which chlorinates L-threonine in the syringomycin biosynthetic pathway, belongs to a recently discovered class of α-ketoglutarate, non-heme Fe(II)-dependent halogenases that shares structural and chemical similarities with hydroxylases. Halogenases and hydroxylases alike decarboxylate the αKG co-substrate, facilitating formation of a high-energy ferryl-oxo intermediate that abstracts a hydrogen from the reactant complex. The reaction mechanisms differ at this point, and mutation of active site residues fails to reproduce hydroxylating activity in SyrB2 or halogenating activity in similar hydroxylases. Using a density functional theory (DFT) approach with a recently implemented Hubbard U correction for accurate treatment of transition-metal chemistry, we explore probable reaction pathways and mechanisms via a model complex consisting only of the iron center and its direct ligands. We show that the first step, αKG decarboxylation, is barrierless and exothermic, while the subsequent hydrogen abstraction step has an energetic barrier consistent with that accessible under biological conditions. In the model complex we use, radical chlorination is barrierless and exothermic, while the analogous hydroxylation is found to have a small energetic barrier. The hydrogen abstraction and radical chlorination steps are strongly coupled: the barrier for the hydrogen abstraction step is reduced when carried out concomitantly with the exothermic chlorination step. Our work suggests that the lack of chlorination in mutant hydroxylases is most likely due to poor binding of chlorine in the active site, while mutant halogenases do not hydroxylate for energetic reasons. While secondary shell residues undoubtedly modulate the overall reactivity and binding of relevant substrates, we show that a small model compound consisting exclusively of the direct ligands to the metal can help explain reactivity heretofore not yet understood in the halogenase SyrB2.

First-principles study of non-heme Fe(II) halogenase SyrB2 reactivity.

We present here a computational study of reactions at a model complex of the SyrB2 enzyme active site. SyrB2, which chlorinates L-threonine in the syringomycin biosynthetic pathway, belongs to a recently discovered class of alpha-ketoglutarate (alphaKG), non-heme Fe(II)-dependent halogenases that share many structural and chemical similarities with hydroxylases. Namely, halogenases and hydroxylases alike decarboxylate the alphaKG co-substrate, facilitating formation of a high-energy ferryl-oxo intermediate that abstracts a hydrogen from the reactant complex. The reaction mechanisms differ at this point, and mutation of active site residues (Asp for the hydroxylase to Ala or Ala to Asp/Glu for halogenase) fails to reproduce hydroxylating activity in SyrB2 or halogenating activity in similar hydroxylases. Using a density functional theory approach with a recently implemented Hubbard U correction for accurate treatment of transition-metal chemistry, we explore probable reaction pathways and mechanisms via a model complex consisting of only the iron center and its direct ligands. We show that the first step, alphaKG decarboxylation, is barrierless and exothermic, but the subsequent hydrogen abstraction step has an energetic barrier consistent with that accessible under biological conditions. In the model complex we use, radical chlorination is barrierless and exothermic, whereas the analogous hydroxylation is found to have a small energetic barrier. The hydrogen abstraction and radical chlorination steps are strongly coupled: the barrier for the hydrogen abstraction step is reduced when carried out concomitantly with the exothermic chlorination step. Our work suggests that the lack of chlorination in mutant hydroxylases is most likely due to poor binding of chlorine in the active site, whereas mutant halogenases do not hydroxylate for energetic reasons. Although secondary shell residues undoubtedly modulate the overall reactivity and binding of relevant substrates, we show that a small model compound consisting exclusively of the direct ligands to the metal can help explain reactivity heretofore not yet understood in the halogenase SyrB2.

Structure and Active Site Residues of PglD, an N-Acetyltransferase from the Bacillosamine Synthetic Pathway Required for N-Glycan Synthesis in Campylobacter jejuni,

Campylobacter jejuni is highly unusual among bacteria in forming N-linked glycoproteins. The heptasaccharide produced by its pgl system is attached to protein Asn through its terminal 2,4-diacetamido-2,4,6-trideoxy-d-Glc (QuiNAc4NAc or N,N'-diacetylbacillosamine) moiety. The crucial, last part of this sugar's synthesis is the acetylation of UDP-2-acetamido-4-amino-2,4,6-trideoxy-d-Glc by the enzyme PglD, with acetyl-CoA as a cosubstrate. We have determined the crystal structures of PglD in CoA-bound and unbound forms, refined to 1.8 and 1.75 A resolution, respectively. PglD is a trimer of subunits each comprised of two domains, an N-terminal alpha/beta-domain and a C-terminal left-handed beta-helix. Few structural differences accompany CoA binding, except in the C-terminal region following the beta-helix (residues 189-195), which adopts an extended structure in the unbound form and folds to extend the beta-helix upon binding CoA. Computational molecular docking suggests a different mode of nucleotide-sugar binding with respect to the acetyl-CoA donor, with the molecules arranged in an "L-shape", compared with the "in-line" orientation in related enzymes. Modeling indicates that the oxyanion intermediate would be stabilized by the NH group of Gly143', with His125' the most likely residue to function as a general base, removing H+ from the amino group prior to nucleophilic attack at the carbonyl carbon of acetyl-CoA. Site-specific mutations of active site residues confirmed the importance of His125', Glu124', and Asn118. We conclude that Asn118 exerts its function by stabilizing the intricate hydrogen bonding network within the active site and that Glu124' may function to increase the pKa of the putative general base, His125'.

Modulation of individual steps in group I intron catalysis by a peripheral metal ion

Enzymes are complex macromolecules that catalyze chemical reactions at their active sites. Important information about catalytic interactions is commonly gathered by perturbation or mutation of active site residues that directly contact substrates. However, active sites are engaged in intricate networks of interactions within the overall structure of the macromolecule, and there is a growing body of evidence about the importance of peripheral interactions in the precise structural organization of the active site. Here, we use functional studies, in conjunction with published structural information, to determine the effect of perturbation of a peripheral metal ion binding site on catalysis in a well-characterized catalytic RNA, the Tetrahymena thermophila group I ribozyme. We perturbed the metal ion binding site by site-specifically introducing a phosphorothioate substitution in the ribozyme's backbone, replacing the native ligands (the pro-R (P) oxygen atoms at positions 307 and 308) with sulfur atoms. Our data reveal that these perturbations affect several reaction steps, including the chemical step, despite the absence of direct contacts of this metal ion with the atoms involved in the chemical transformation. As structural probing with hydroxyl radicals did not reveal significant change in the three-dimensional structure upon phosphorothioate substitution, the effects are likely transmitted through local, rather subtle conformational rearrangements. Addition of Cd(2+), a thiophilic metal ion, rescues some reaction steps but has deleterious effects on other steps. These results suggest that native interactions in the active site may have been aligned by the naturally occurring peripheral residues and interactions to optimize the overall catalytic cycle.

Mutation of active site residues in the chitin-binding domain ChBDChiA1 from chitinase A1 of Bacillus circulans alters substrate specificity: use of a green fluorescent protein binding assay

A fluorescent binding assay was developed to investigate the effects of mutagenesis on the binding affinity and substrate specificity of the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12. The chitin-binding domain was genetically fused to the N-terminus of a green fluorescent protein, and the polyhistidine-tagged hybrid protein was expressed in Escherichia coli. Residues likely to be involved in the binding site were mutated and their contributions to binding and substrate specificity were evaluated by affinity electrophoresis and depletion assays. The experimental binding isotherms were analyzed by non-linear regression using a modified Langmuir equation. Non-conservative substitution of tryptophan residue (W687) nearly abolished chitin-binding affinity and dramatically lowered chitosan binding while retaining the original level of curdlan binding. Double mutation E668K/P689A had altered specificity for several substrates and also impaired chitin binding significantly. Other substitutions in the binding site altered substrate specificity but had little effect on overall affinity for chitin. Interestingly, mutation T682A led to a higher specificity towards chitinous substrates than the wildtype. Furthermore, the ChBD-GFP hybrid protein was tested for use in diagnostic staining of cell walls of fungi and yeast and for the detection of fungal infections in tissue samples.

Mutation of active site residues in the chitin-binding domain ChBD ChiA1 from chitinase A1 of Bacillus circulans alters substrate specificity: use of a green fluorescent protein binding assay

A fluorescent binding assay was developed to investigate the effects of mutagenesis on the binding affinity and substrate specificity of the chitin-binding domain of chitinase A1 from Bacillus circulans WL-12. The chitin-binding domain was genetically fused to the N-terminus of a green fluorescent protein, and the polyhistidine-tagged hybrid protein was expressed in Escherichia coli. Residues likely to be involved in the binding site were mutated and their contributions to binding and substrate specificity were evaluated by affinity electrophoresis and depletion assays. The experimental binding isotherms were analyzed by non-linear regression using a modified Langmuir equation. Non-conservative substitution of tryptophan residue (W687) nearly abolished chitin-binding affinity and dramatically lowered chitosan binding while retaining the original level of curdlan binding. Double mutation E668K/P689A had altered specificity for several substrates and also impaired chitin binding significantly. Other substitutions in the binding site altered substrate specificity but had little effect on overall affinity for chitin. Interestingly, mutation T682A led to a higher specificity towards chitinous substrates than the wildtype. Furthermore, the ChBD-GFP hybrid protein was tested for use in diagnostic staining of cell walls of fungi and yeast and for the detection of fungal infections in tissue samples.

Mutation of active site residues of the puromycin-sensitive aminopeptidase: conversion of the enzyme into a catalytically inactive binding protein

The active site glutamate, Glu 309, of the puromycin-sensitive aminopeptidase was mutated to glutamine, alanine, and valine. These mutants were characterized with amino acid β-naphthylamides as substrates and dynorphin A(1-9) as an alternate substrate inhibitor. Conversion of glutamate 309 to glutamine resulted in a 5000- to 15,000-fold reduction in catalytic activity. Conversion of this residue to alanine caused a 25,000- to 100,000-fold decrease in activity, while the glutamate to valine mutation was the most dramatic, reducing catalytic activity 300,000- to 500,000-fold. In contrast to the dramatic effect on catalysis, all three mutations produced relatively small (1.5- to 4-fold) effects on substrate binding affinity. Mutation of a conserved tyrosine, Y394, to phenylalanine resulted in a 1000-fold decrease in k cat, with little effect on binding. Direct binding of a physiological peptide, dynorphin A(1-9), to the E309V mutant was demonstrated by gel filtration chromatography. Taken together, these data provide a quantitative assessment of the effect of mutating the catalytic glutamate, show that mutation of this residue converts the enzyme into an inactive binding protein, and constitute evidence that this residue acts a general acid/base catalyst. The effect of mutating tyrosine 394 is consistent with involvement of this residue in transition state stabilization.

Mutations in the ribonuclease H active site of HIV-RT reveal a role for this site in stabilizing enzyme-primer-template binding.

The RNase H activity of HIV-RT is coordinated by a catalytic triad (E478, D443, D498) of acidic residues that bind divalent cations. We examined the effect of RNase H deficient E(478)-->Q and D(549)-->N mutations that do not alter polymerase activity on binding of enzyme to various nucleic acid substrates. Binding of the mutant and wild-type enzymes to various nucleic acid substrates was examined by determining dissociation rate constants (k(off)) by titrating both Mg(2+) and salt concentrations. In agreement with the unaltered polymerase activity of the mutant, the k(off) values for the wild-type and mutant enzymes were essentially identical using DNA-DNA templates in the presence of 6 mM Mg(2+). However, with lower concentrations of Mg(2+) and in the absence of Mg(2+), although both enzymes dissociated more rapidly, the mutant enzymes dissociated several-fold more slowly than the wild type. This was also observed on RNA-DNA templates. These results indicate that alterations in residues essential for Mg(2+) binding have a pronounced positive effect on enzyme-template stability and that the negative residues in the RNase H region of the enzyme have a negative influence on binding in the absence of Mg(2+). In this regard RT is similar to other nucleic acid cleaving enzymes that show enhanced binding upon mutation of active site residues.

Functional Interrelationships in the Alkaline Phosphatase Superfamily: Phosphodiesterase Activity of Escherichia coli Alkaline Phosphatase

Escherichia coli alkaline phosphatase (AP) is a proficient phosphomonoesterase with two Zn(2+) ions in its active site. Sequence homology suggests a distant evolutionary relationship between AP and alkaline phosphodiesterase/nucleotide pyrophosphatase, with conservation of the catalytic metal ions. Furthermore, many other phosphodiesterases, although not evolutionarily related, have a similar active site configuration of divalent metal ions in their active sites. These observations led us to test whether AP could also catalyze the hydrolysis of phosphate diesters. The results described herein demonstrate that AP does have phosphodiesterase activity: the phosphatase and phosphodiesterase activities copurify over several steps; inorganic phosphate, a strong competitive inhibitor of AP, inhibits the phosphodiesterase and phosphatase activities with the same inhibition constant; a point mutation that weakens phosphate binding to AP correspondingly weakens phosphate inhibition of the phosphodiesterase activity; and mutation of active site residues substantially reduces both the mono- and diesterase activities. AP accelerates the rate of phosphate diester hydrolysis by 10(11)-fold relative to the rate of the uncatalyzed reaction [(k(cat)/K(m))/k(w)]. Although this rate enhancement is substantial, it is at least 10(6)-fold less than the rate enhancement for AP-catalyzed phosphate monoester hydrolysis. Mutational analysis suggests that common active site features contribute to hydrolysis of both phosphate monoesters and phosphate diesters. However, mutation of the active site arginine to serine, R166S, decreases the monoesterase activity but not the diesterase activity, suggesting that the interaction of this arginine with the nonbridging oxygen(s) of the phosphate monoester substrate provides a substantial amount of the preferential hydrolysis of phosphate monoesters. The observation of phosphodiesterase activity extends the previous observation that AP has a low level of sulfatase activity, further establishing the functional interrelationships among the sulfatases, phosphatases, and phosphodiesterases within the evolutionarily related AP superfamily. The catalytic promiscuity of AP could have facilitated divergent evolution via gene duplication by providing a selective advantage upon which natural selection could have acted.

Effects of mutations of active site residues and amino acids interacting with the Ω loop on substrate activation of butyrylcholinesterase

The peripheral anionic site (PAS) of human butyrylcholinesterase is involved in the mechanism of substrate activation by positively charged substrates and ligands. Two substrate binding loci, D70 in the PAS and W82 in the active site, are connected by the Ω loop. To determine whether the Ω loop plays a role in the signal transduction between the PAS and the active site, residues involved in stabilization of the loop, N83, K339 and W430, were mutated. Mutations N83A and N83Q caused loss of substrate activation, suggesting that N83 which interacts with the D70 backbone may be an element of the transducing system. The K339M and W430A mutant enzymes retained substrate activation. Residues W82, E197, and A328 in the active site gorge have been reported to be involved in substrate activation. At butyrylthiocholine concentrations greater then 2 mM, W82A showed apparent substrate activation. Mutations E197Q and E197G strongly reduced substrate activation, while mutation E197D caused a moderate effect, suggesting that the carboxylate of residue E197 is involved in substrate activation. Mutations A328F and A328Y showed no substrate activation, whereas A328G retained substrate activation. Substrate activation can result from an allosteric effect due to binding of the second substrate molecule on the PAS. Mutation W430A was of special interest because this residue hydrogen bonds to W82 and Y332. W430A had strongly reduced affinity for tetramethylammonium. The bimolecular rate constant for reaction with diisopropyl fluorophosphate was reduced 10 000-fold, indicating severe alteration in the binding area in W430A. The k cat values for butyrylthiocholine, o-nitrophenyl butyrate, and succinyldithiocholine were lower. This suggested that the mutation had caused misfolding of the active site gorge without altering the Ω loop conformation/dynamics. W430 as well as W231 and W82 appear to form the wall of the active site gorge. Mutation of any of these tryptophans disrupts the architecture of the active site.

Catalytic mechanism of scytalone dehydratase fromMagnaporthe grisea

The catalytic mechanism of scytalone dehydratase was examined by studying alternative substrates and site-directed mutations of active-site residues. Searches for an enol intermediate by looking for a half-reaction with authentic scytalone and 3,4-dihydro-6,8-dihydroxy-1-(2H)-2-[ 13 C]naphthalenone were negative. An alternative substrate, 2,3-dihydro-2,5-dihydroxy-4H-benzopyran-4-one (DDBO), was nearly equal to scytalone as substrate for the enzyme, and DDBO's anomeric effect in stabilizing a partial carbocation center at C3 does not substantially contribute to the mechanism. Kinetic analysis of site-directed mutations of active-site amino acid side chains within the enzyme's active site provided an account for the role of these residues in the enzyme-catalyzed dehydration reactions. A concerted E2 elimination for the catalytic mechanism is proposed.

Optimization of a macromolecular inhibitor of HIV-1 protease.

HIV protease (HIV PR) has been identified as a key target in the treatment of HIV infection, and antiviral drugs that block its proteolytic activity have been developed. However, there are numerous ways in which a drug can lose effectiveness during long-term therapy. In particular several protease-mediated mechanisms result in reduced antiviral sensitivity of the various anti HIV protease inhibitors. As with inhibitors of reverse transcriptase, protease inhibitors have shown a sensitivity to variations in the protease that weaken drug affinities, both in cell culture and in vivo [1,2]. These include: 1) mutations of active site residues that are direct substrate specificity determinants; 2) mutations of non-active site residues that indirectly interfere with inhibitor binding through long range structural changes; 3) mutations that increase enzyme catalysis; 4) mutations that increase enzyme stability and half-life; and 5) mutations that provide new substrate specificities with corresponding mutations in the gag—pol polyprotein precursor substrate. Since the binding modes of both the natural substrates for HIV protease and the substrate analog class of inhibitors are similar, amino acid substitutions that occur in the substrate binding pocket are among the more common resistance mutations that arise in response to HIV protease inhibitors. However, the structural basis for the loss of sensitivity of a viral protease to a drug is not always obvious or predictable. This inability to anticipate the variety of mechanisms of viral resistance to new protease inhibitors complicates the task of designing more effective drugs. In this work, we consider the possibility of creating a new class of inhibitors that can pose a greater challenge to the development of protease-mediated viral resistance.

Autophosphorylation of the catalytic subunit of cAMP-dependent protein kinase in Escherichia coli.

When the catalytic (rC) subunit of cAMP-dependent protein kinase (cAPK) is expressed in Escherichia coli, it is autophosphorylated at four sites, Ser10, Ser139, Ser338 and Thr197 (49). Three of these sites, Ser10, Ser338 and Thr197, are also found in the mammalian enzyme. To understand the functional importance of these phosphorylation sites, each was replaced with Ala, Glu or Asp. The expression, solubility and phosphorylation state of each mutant protein was characterized by immunoprecipitation following in vivo labeling with 32Pi. When possible, isoforms were resolved and kinetic properties were measured. The two stable phosphorylation sites in the mammalian enzyme, Ser338 and Thr197, were shown to play different roles. Ser338, which stabilizes a turn near the C-terminus, is important for stability. Both rC(S338A) and rC(S338E) were very labile; however, the kinetic properties of rC(S338E) were similar to the wild-type catalytic subunit (C-subunit). Ser338 most likely helps to anchor the C-terminus to the surface of the small lobe. Thr197 is in the activation loop near the cleft interface. Mutagenesis of T197 caused a significant loss of catalytic activity with increases in Kms for both peptide and MgATP, as well as a small decrease in k(cat) indicating that this phosphate is important for the correct orientation of catalytic residues at the active site. Replacement of Ser139, positioned at the beginning of the E-helix, with Ala had no effect on the kinetic parameters, stability or phosphorylation at the remaining sites. In contrast, mutation of Ser10, located at the beginning of the A-helix, produced mostly insoluble, inactive, unphosphorylated protein, suggesting that this region, though far removed from the active site, is structurally important at least for the expression of soluble phosphoprotein in E.coli. Since the mutation of active site residues as well as deletion mutants generate underphosphorylated proteins, these phosphorylations in E.coli all result from autophosphorylation.

Substrate binding and catalysis by L-arginine:glycine amidinotransferase--a mutagenesis and crystallographic study.

L-Arginine:glycine amidinotransferase catalyzes the committed step in the biosynthesis of creatine. Eight active-site mutants, D170N, D254N, H303V, D305A, R322E, S355A, C407S, and C410A of recombinant human L-arginine:glycine amidinotransferase were prepared by site-directed mutagenesis and enzymatically characterized. The crystal structures of the three mutants D170N, D254N, and C407S have been determined at 0.28-nm, 0.29-nm and 0.236-nm resolution, respectively. The mutation of active-site residues which are involved in substrate-binding yielded inactive mutants. Substitution of Asp254, which is not directly involved in substrate binding but is thought to transfer protons in concert with the His303 imidazole group, results in a strongly (2000-fold) reduced activity. However, the substitution of Cys410, a residue near the active site but not involved in catalysis or substrate binding, by Ala does not change the kinetic properties with respect to the wild-type enzyme. The loss of enzymatic activity of the D170N, D254N, C407S and likely all other mutants is solely due to the inserted point mutations, affecting substrate binding or transition-state stabilization, and not due to major conformational rearrangements of the protein. These results show that a His-Asp pair on one side of the substrate and a Cys on the other side are key residues for activity and are part of a disjoint triad. The imidazole ring of the His is proposed to act as a general acid/general base during catalysis whereas the Cys acts as a nucleophile analogous to Cys25 of papain-like cysteine proteinases.