The use of genetically engineered tryptophan to identify the movement of a domain of B. stearothermophilus lactate dehydrogenase with the process which limits the steady-state turnover of the enzyme

A general technique for monitoring the intramolecular motion of a protein is described. Genetic engineering is used to replace all the natural tryptophan residues with tyrosine. A single tryptophan residue is then inserted at a specific site within the protein where motion is then detected from the fluorescence characteristics of this fluorophore. This technique has been used in B. stearothermophilus lactate dehydrogenase mutant (W80Y, W150Y, W203Y, G106W) to correlate the slow closure of a surface loop of polypeptide (residues 98-110) with the maximum catalytic velocity of the enzyme.     

Probing the dynamics of a mobile loop above the active site of L1, a metallo-beta-lactamase from Stenotrophomonas maltophilia, via site-directed mutagenesis and stopped-flow fluorescence spectroscopy

A structural feature shared by the metallo-beta-lactamases is a flexible loop of amino acids that extends over their active sites and that has been proposed to move during the catalytic cycle of the enzymes, clamping down on substrate. To probe the movement of this loop (residues 152-164), a site-directed mutant of metallo-beta-lactamase L1 was engineered that contained a Trp residue on the loop to serve as a fluorescent probe. It was necessary first, however, to evaluate the contribution of each native Trp residue to the fluorescence changes observed during the catalytic cycle of wild-type L1. Five site-directed mutants of L1 (W39F, W53F, W204F, W206F, and W269F) were prepared and characterized using metal analyses, CD spectroscopy, steady-state kinetics, stopped-flow fluorescence, and fluorescence titrations. All mutants retained the wild-type tertiary structure and bound Zn(II) at levels comparable with wild type and exhibited only slight (<10-fold) decreases in k(cat) values as compared with wild-type L1 for all substrates tested. Fluorescence studies revealed a single mutant, W39F, to be void of the fluorescence changes observed with wild-type L1 during substrate binding and catalysis. Using W39F as a template, a Trp residue was added to the flexile loop over the active site of L1, to generate the double mutant, W39F/D160W. This double mutant retained all the structural and kinetic characteristics of wild-type L1. Stopped-flow fluorescence and rapid-scanning UV-visible studies revealed the motion of the loop (k(obs) = 27 +/- 2 s(-1)) to be similar to the formation rate of a reaction intermediate (k(obs) = 25 +/- 2 s(-1)).     

Tryptophan residues at subunit interfaces used as fluorescence probes to investigate homotropic and heterotropic regulation of aspartate transcarbamylase

The homotropic and heterotropic interactions in Escherichia coli aspartate transcarbamylase (EC 2.1.3.2) are accompanied by various structure modifications. The large quaternary structure change associated with the T to R transition, promoted by substrate binding, is accompanied by different local conformational changes. These tertiary structure modifications can be monitored by fluorescence spectroscopy, after introduction of a tryptophan fluorescence probe at the site of investigation. To relate unambiguously the fluorescence signals to structure changes in a particular region, both naturally occurring Trp residues in positions 209c and 284c of the catalytic chains were previously substituted with Phe residues. The regions of interest were the so-called 240's loop at position Tyr240c, which undergoes a large conformational change upon substrate binding, and the interface between the catalytic and regulatory chains in positions Asn153r and Phe145r supposed to play a role in the different regulatory processes. Each of these tryptophan residues presents a complex fluorescence decay with three to four independent lifetimes, suggesting that the holoenzyme exists in slightly different conformational states. The bisubstrate analogue N-phosphonacetyl-L-aspartate affects mostly the environment of tryptophans at position 240c and 145r, and the fluorescence signals were related to ligand binding and the quaternary structure transition, respectively. The binding of the nucleotide activator ATP slightly affects the distribution of the conformational substates as probed by tryptophan residues at position 240c and 145r, whereas the inhibitor CTP modifies the position of the C-terminal residues as reflected by the fluorescence properties of Trp153r. These results are discussed in correlation with earlier mutagenesis studies and mechanisms of the enzyme allosteric regulation.     

Role of tryptophan residues in interfacial binding of phosphatidylinositol-specific phospholipase C

The phosphatidylinositol-specific phospholipase C (PI-PLC) from Bacillus thuringiensis exhibits several types of interfacial activation. In the crystal structure of the closely related Bacillus cereus PI-PLC, the rim of the active site is flanked by a short helix B and a loop that show an unusual clustering of hydrophobic amino acids. Two of the seven tryptophans in PI-PLC are among the exposed residues. To test the importance of these residues in substrate and activator binding, we prepared several mutants of Trp-47 (in helix B) and Trp-242 (in the loop). Two other tryptophans, Trp-178 and Trp-280, which are not near the rim, were mutated as controls. Kinetic (both phosphotransferase and cyclic phosphodiesterase activities), fluorescence, and vesicle binding analyses showed that both Trp-47 and Trp-242 residues are important for the enzyme to bind to interfaces, both activating zwitterionic and substrate anionic surfaces. Partitioning of the enzyme to vesicles is decreased more than 10-fold for either W47A or W242A, and removal of both tryptophans (W47A/W242A) yields enzyme with virtually no affinity for phospholipid surfaces. Replacement of either tryptophan with phenylalanine or isoleucine has moderate effects on enzyme affinity for surfaces but yields a fully active enzyme. These results are used to describe how the enzyme is activated by interfaces.     

Substrate directs enzyme dynamics by bridging distal sites: UDP-galactopyranose mutase

UDP-Galactopyranose mutase (UGM) is a flavoenzyme that catalyzes interconversion of UDP-galactopyranose (UDP-Galp) and UDP-galactofuranose (UDP-Galf); its activity depends on FAD redox state. The enzyme is vital to many pathogens, not native to mammals, and is an important drug target. We have probed binding of substrate, UDP-Galp, and UDP to wild type and W160A UGM from K. pneumoniae, and propose that substrate directs recognition loop dynamics by bridging distal FAD and W160 sites; W160 interacts with uracil of the substrate and is functionally essential. Enhanced Trp fluorescence upon substrate binding to UGM indicates conformational changes remote from the binding site because the fluorescence is unchanged upon binding to W70F/W290F UGM where W160 is the sole Trp. MD simulations map these changes to recognition loop closure to coordinate substrate. This requires galactose-FAD interactions as Trp fluorescence is unchanged upon substrate binding to oxidized UGM, or binding of UDP to either form of the enzyme, and MD show heightened recognition loop mobility in complexes with UDP. Consistent with substrate-directed loop closure, UDP binds 10-fold more tightly to oxidized UGM, yet substrate binds tighter to reduced UGM. This requires the W160-U interaction because redox-switched binding affinity of substrate reverses in the W160A mutant where it only binds when oxidized. Without the anchoring W160-U interaction, an alternative binding mode for UDP is detected, and STD-NMR experiments show simultaneous binding of UDP-Galp and UDP to different subsites in oxidized W160A UGM: Substrate no longer directs recognition loop dynamics to coordinate tight binding to the reduced enzyme.     

The tryptophan residues of aspartate transcarbamylase: site-directed mutagenesis and time-resolved fluorescence spectroscopy.

Aspartate transcarbamylase (EC 2.1.3.2) contains two tryptophan residues in position 209 and 284 of the catalytic chains (c) and no such chromophore in the regulatory chains (r). Thus, as a dodecamer [(c3)2(r2)3] the native enzyme molecule contains 12 tryptophan residues. The present study of the regulatory conformational changes in this enzyme is based on the fluorescence properties of these intrinsic probes. Site-directed mutagenesis was used in order to differentiate the respective contributions of the two tryptophans to the fluorescence properties of the enzyme and to identify the mobility of their environment in the course of the different regulatory processes. Each of these tryptophan residues gives two independent fluorescence decays, suggesting that the catalytic subunit exists in two slightly different conformational states. The binding of the substrate analog N-phosphonacetyl-L-aspartate promotes the same fluorescence signal whether or not the catalytic subunits are associated with the regulatory subunits, suggesting that the substrate-induced conformational change of the catalytic subunit is the essential trigger for the quaternary structure transition involved in cooperativity. The binding of the substrate analog affects mostly the environment of tryptophan 284, while the binding of the activator ATP affects mostly the environment of tryptophan 209, confirming that this activator acts through a mechanism different from that involved in homotropic cooperativity.     

Catalytic activation of human glucokinase by substrate binding: residue contacts involved in the binding of D-glucose to the super-open form and conformational transitions

alpha-D-Glucose activates glucokinase (EC 2.7.1.1) on its binding to the active site by inducing a global hysteretic conformational change. Using intrinsic tryptophan fluorescence as a probe on the alpha-D-glucose induced conformational changes in the pancreatic isoform 1 of human glucokinase, key residues involved in the process were identified by site-directed mutagenesis. Single-site W-->F mutations enabled the assignment of the fluorescence enhancement (DeltaF/F(0)) mainly to W99 and W167 in flexible loop structures, but the biphasic time course of DeltaF/F(0) is variably influenced by all tryptophan residues. The human glucokinase-alpha-D-glucose association (K(d) = 4.8 +/- 0.1 mm at 25 degrees C) is driven by a favourable entropy change (DeltaS = 150 +/- 10 J.mol(-1).K(-1)). Although X-ray crystallographic studies have revealed the alpha-d-glucose binding residues in the closed state, the contact residues that make essential contributions to its binding to the super-open conformation remain unidentified. In the present study, we combined functional mutagenesis with structural dynamic analyses to identify residue contacts involved in the initial binding of alpha-d-glucose and conformational transitions. The mutations N204A, D205A or E256A/K in the L-domain resulted in enzyme forms that did not bind alpha-D-glucose at 200 mm and were essentially catalytically inactive. Our data support a molecular dynamic model in which a concerted binding of alpha-D-glucose to N204, N231 and E256 in the super-open conformation induces local torsional stresses at N204/D205 propagating towards a closed conformation, involving structural changes in the highly flexible interdomain connecting region II (R192-N204), helix 5 (V181-R191), helix 6 (D205-Y215) and the C-terminal helix 17 (R447-K460).     

Motion of aromatic side chains, picosecond fluorescence, and internal energy transfer in Escherichia coli thioredoxin studied by site-directed mutagenesis, time-resolved fluorescence spectroscopy, and molecular dynamics simulations

We have determined the picosecond fluorescence of the four aromatic amino acid residues (W28, W31, Y49, and Y70) in wild-type Escherichia coli thioredoxin (wt Trx) and a mutant Trx with W31 replaced by phenylalanine, Trx-W28-W31F. The internal motions of the four aromatic side chains were also analyzed. We examined the possibility of using internal energy transfer from tyrosine to tryptophan as a measure of long-range distances. The major features of the lifetime distribution of tryptophan fluorescence were unchanged in the W31F mutation, indicating that the environment of W28 is similar in both wt Trx and Trx-W28-W31F. However, the mutation of W31F changed the mobility of W28, situated close to the active-site disulfide/dithiol, but not the mobility of two tyrosines, Y49 and Y70, situated on the other side of the molecule. The mobility of the two tyrosine residues increased upon reduction of the active-site disulfide, indicating a looser structure with reduction. This increased motion could also be seen from molecular dynamics simulations. The change in energy transfer rates, as judged by tyrosine fluorescence lifetimes, was in agreement with energy transfer rates calculated from the molecular dynamics simulations. The anisotropy of tryptophan and tyrosine fluorescence could be separated in three parts: (I) overall rotation of the protein (10(-9)s), (II) internal mobility of side chains (10(-10)s), and (III) a very fast relaxation (10(-12)s). We can only experimentally detect this very fast relaxation when the internal motion is not present.     

Substitutions at tyrosine 66 of Escherichia coli uracil DNA glycosylase lead to characterization of an efficient enzyme that is recalcitrant to product inhibition

Uracil DNA glycosylase (UDG), a ubiquitous and highly specific enzyme, commences the uracil excision repair pathway. Structural studies have shown that the tyrosine in a highly conserved GQDPY water-activating loop of UDGs blocks the entry of thymine or purines into the active site pocket. To further understand the role of this tyrosine (Y66 in Escherichia coli UDG), we have overproduced and characterized Y66F, Y66H, Y66L and Y66W mutants. The complexes of the wild-type, Y66F, Y66H and Y66L UDGs with uracil DNA glycosylase inhibitor (Ugi) (a proteinaceous substrate mimic) were stable to 8 M urea. However, some dissociation of the complex involving the Y66W UDG occurred at this concentration of urea. The catalytic efficiencies (V_max / K_m) of the Y66L and Y66F mutants were similar to those of the wild-type UDG. However, the Y66W and Y66H mutants were ~7- and ~173-fold compromised, respectively, in their activities. Interestingly, the Y66W mutation has resulted in an enzyme which is resistant to product inhibition. Preferential utilization of a substrate enabling a long range contact between the –5 phosphate (upstream to the scissile uracil) and the enzyme, and the results of modeling studies showing that the uracil-binding cavity of Y66W is wider than those of the wild type and other mutant UDGs, suggest a weaker interaction between uracil and the Y66W mutant. Furthermore, the fluorescence spectroscopy of UDGs and their complexes with Ugi, in the presence of uracil or its analog, 5-bromouracil, suggests compromised binding of uracil in the active site pocket of the Y66W mutant. Lack of inhibition of the Y66W UDG by apyrimidinic DNA (AP-DNA) is discussed to highlight a potential additional role of Y66 in shielding the toxic effects of AP-DNA, by lowering the rate of its release for subsequent recognition by an AP endonuclease.     

Tryptophan-free human PNP reveals catalytic site interactions

Human purine nucleoside phosphorylase (PNP) is a homotrimer, containing three nonconserved tryptophan residues at positions 16, 94, and 178, all remote from the catalytic site. The Trp residues were replaced with Tyr to produce Trp-free PNP (Leuko-PNP). Leuko-PNP showed near-normal kinetic properties. It was used (1) to determine the tautomeric form of guanine that produces strong fluorescence when bound to PNP, (2) for thermodynamic binding analysis of binary and ternary complexes with substrates, (3) in temperature-jump perturbation of complexes for evidence of multiple conformational complexes, and (4) to establish the ionization state of a catalytic site tyrosine involved in phosphate nucleophile activation. The (13)C NMR spectrum of guanine bound to Leuko-PNP, its fluorescent properties, and molecular orbital electronic transition analysis establish that its fluorescence originates from the lowest singlet excited state of the N1H, 6-keto, N7H guanine tautomer. Binding of guanine and phosphate to PNP and Leuko-PNP are random, with decreased affinity for formation of ternary complexes. Pre-steady-state kinetics and temperature-jump studies indicate that the ternary complex (enzyme-substrate-phosphate) forms in single binding steps without kinetically significant protein conformational changes as monitored by guanine fluorescence. Spectral changes of Leuko-PNP upon phosphate binding establish that the hydroxyl of Tyr88 is not ionized to the phenolate anion when phosphate is bound. A loop region (residues 243-266) near the purine base becomes highly ordered upon substrate/inhibitor binding. A single Trp residue was introduced into the catalytic loop of Leuko-PNP (Y249W-Leuko-PNP) to determine effects on catalysis and to introduce a fluorescence catalytic site probe. Although Y249W-Leuko-PNP is highly fluorescent and catalytically active, substrate binding did not perturb the fluorescence. Thermodynamic boxes, constructed to characterize the binding of phosphate, guanine, and hypoxanthine to native, Leuko-, and Y249W-Leuko-PNPs, establish that Leuko-PNP provides a versatile protein scaffold for introduction of specific Trp catalytic site probes.     

Contribution of an active site cation-pi interaction to the spectroscopic properties and catalytic function of protein tyrosine kinase Csk

Csk is a soluble protein tyrosine kinase that phosphorylates and negatively regulates protein tyrosine kinases of the Src family. The spectral properties of the intrinsic Trp fluorescence of Csk and their underlying structural features were investigated in combination with urea denaturation and site-specific mutagenesis. It was found that W352 contributed approximately 35% of the total Trp fluorescence of Csk even though seven other Trp residues were present. The enhanced contribution by W352 to Csk fluorescence was due to an interaction between its indole ring and the positively charged guanidino group of R318. W352 is located on the peptide substrate binding P+1 loop, and R318 is located on the catalytic loop. The W352-R318 interaction, called a cation-pi interaction, uniquely couples the two loops in the active site. Mutations that disrupted this coupling resulted in varying levels of decreases in Csk activity, and consistent and significant increases in K(m) values for its physiological substrate, Src protein tyrosine kinase. These results indicated that structural coupling between the two loops by the cation-pi interaction played an important role in Csk substrate binding. Since both R318 and W352 are highly conserved among protein tyrosine kinases, this cation-pi interaction is likely a signature structural feature of most, if not all, PTKs. These studies elucidated the roles of two conserved signature residues in Csk and formed a baseline for further structure-function studies of Csk and other PTKs.     

Effect of denaturants on the structure and activity of 3-hydroxybenzoate-6-hydroxylase

The effect of denaturants such as urea, sodium dodecylsulphate (SDS), guanidinium hydrochloride (Gu.HCl) on the structure of enzyme 3-hydroxybenzoate-6-hydroxylase was studied using intrinsic fluorescence and far and near-UV-CD spectroscopic techniques. Also, activity profiles of the enzyme, as a function of increasing concentrations of denaturants were studied. The far-UV CD spectrum of the enzyme did not show appreciable alterations in the presence of urea, SDS or Gu.HCl, thereby suggesting that the protein does not undergo gross conformational changes in its alpha-helical secondary structure. The treatment of enzyme with 2 M urea resulted in almost complete loss of catalytic activity, accompanied by the reduction of emission fluorescence of enzyme. Similarly, treatment with 0.01% SDS also caused almost complete loss of activity and quenching of enzyme fluorescence as well as a red shift in the emission peak. In addition, reduction in the intensity of near-UV-CD spectrum, especially at 280 nm was observed. About 70% of the activity was lost by treatment with 20 mM Gu.HCl, accompanied by quenching of intrinsic fluorescence of the enzyme. The change in intrinsic fluorescence of the enzyme in the presence of 5 mM-100 mM Gu.HCI could be correlated to progressive loss of catalytic activity. Thus, intrinsic fluorescence (due to tryptophan residues) could be used as an effective probe to provide an insight into the relation between the activity and subtle conformational changes of the enzyme. The results suggested that denaturants caused very slight conformational changes in the enzyme that perturbed the microenvironment of aromatic amino acid residues such as tryptophan accompanied by reduction or loss of catalytic activity.     

Evidence for the involvement of tryptophan 38 in the active site of glutathione S-transferase P.

Glutathione S-transferase P (GST-P) exists as a homodimeric form and has two tryptophan residues, Trp28 and Trp38, in each subunit. In order to elucidate the role of the two tryptophan residues in catalytic function, we examined intrinsic fluorescence of tryptophan residues and effect of chemical modification by N-bromosuccinimide (NBS). The quenching of intrinsic fluorescence was observed by the addition of S-hexylglutathione, a substrate analogue, and the enzymatic activity was totally lost when single tryptophan residue was oxidized by NBS. To identify which tryptophan residue is involved in the catalytic function, each tryptophan was changed to histidine by site-directed mutagenesis. Trp28His GST-P mutant enzyme showed a comparable enzymatic activity with that of the wild type one. Trp38His mutant neither was bound to S-hexylglutathione-linked Sepharose nor exhibited any GST activity. These findings indicate that Trp38 is important for the catalytic function and substrate binding of GST-P.     

Unusual fluorescence of W168 in Plasmodium falciparum triosephosphate isomerase, probed by single-tryptophan mutants.

Plasmodium falciparum triosephosphate isomerase (PfTIM) contains two tryptophan residues, W11 and W168. One is positioned in the interior of the protein, and the other is located on the active-site loop 6. Two single-tryptophan mutants, W11F and W168F, were constructed to evaluate the contributions of each chromophore to the fluorescence of the wild-type (wt) protein and to probe the utility of the residues as spectroscopic reporters. A comparative analysis of the fluorescence spectra of PfTIMwt and the two mutant proteins revealed that W168 possesses an unusual, blue-shifted emission (321 nm) and exhibits significant red-edge excitation shift of fluorescence. In contrast, W11 emits at 332 nm, displays no excitation dependence of fluorescence, and behaves like a normal buried chromophore. W168 has a much shorter mean lifetime (2.7 ns) than W11 (4.6 ns). The anomalous fluorescence properties of W168 are abolished on unfolding of the protein in guanidinium chloride (GdmCl) or at low pH. Analysis of the tryptophan environment using a 1.1-A crystal structure established that W168 is rigidly held by a complex network of polar interactions including a strong hydrogen bond from Y164 to the indole NH group. The environment is almost completely polar, suggesting that electrostatic effects determine the unusually low emission wavelength of W168. To our knowledge this is a unique observation of a blue-shifted emission from a tryptophan in a polar environment in the protein. The wild-type and mutant proteins show similar levels of enzymatic activity and secondary and tertiary structure. However, the W11F mutation appreciably destabilizes the protein to unfolding by urea and GdmCl. The fluorescence of W168 is shown to be extremely sensitive to binding of the inhibitor, 2-phosphoglycolic acid.     

Identification of Tyr413 as an active site residue in the flavoprotein tryptophan 2-monooxygenase and analysis of its contribution to catalysis

The flavoenzyme tryptophan 2-monooxygenase catalyzes the oxidation of tryptophan to indoleacetamide, carbon dioxide, and water. The enzyme is a homologue of l-amino acid oxidase. In the structure of l-amino acid oxidase complexed with aminobenzoate, Tyr372 hydrogen bonds with the carboxylate of the inhibitor in the active site. All 10 conserved tyrosine residues in tryptophan 2-monooxygenase were mutated to phenylalanine; steady state kinetic characterization of the purified proteins identified Tyr413 as the residue homologous to Tyr372 of l-amino acid oxidase. Y413F and Y413A tryptophan 2-monooxygenase were characterized more completely with tryptophan as the substrate to probe the contribution of this residue to catalysis. Mutation of Tyr413 to phenylalanine results in a decrease in the value of the first-order rate constant for reduction of 35-fold and a decrease in the rate constant for oxidation of 11-fold. Mutation to alanine decreases the rate constant for reduction by 200-fold and that for oxidation by 33-fold. Both mutations increase the K(d) value for tryptophan and the K(i) values for the competitive inhibitors indoleacetamide and indole pyruvate by 5-10-fold. Both mutations convert the enzyme to an oxidase, in that the products of the catalytic reactions of both are indolepyruvate and hydrogen peroxide. The V/K(trp)-pH profiles for the Tyr413 mutant enzymes no longer show the pK(a) value of 9.9 seen in that for the wild-type enzyme, allowing identification of Tyr413 as the active site residue in the wild-type enzyme which must be protonated for catalysis. Substitution of Tyr413 abolishes the formation of the long wavelength charge transfer species observed in the wild-type enzyme. The data are consistent with the main role of Tyr413 being to maintain the correct orientation of tryptophan for effective hydride transfer and imino acid decarboxylation.     

Substitution of active site tyrosines with tryptophan alters the free energy for nucleotide flipping by human alkyladenine DNA glycosylase

Human alkyladenine DNA glycosylase (AAG) locates and excises a wide variety of structurally diverse alkylated and oxidized purine lesions from DNA to initiate the base excision repair pathway. Recognition of a base lesion requires flipping of the damaged nucleotide into a relatively open active site pocket between two conserved tyrosine residues, Y127 and Y159. We have mutated each of these amino acids to tryptophan and measured the kinetic effects on the nucleotide flipping and base excision steps. The Y127W and Y159W mutant proteins have robust glycosylase activity toward DNA containing 1,N(6)-ethenoadenine (εA), within 4-fold of that of the wild-type enzyme, raising the possibility that tryptophan fluorescence could be used to probe the DNA binding and nucleotide flipping steps. Stopped-flow fluorescence was used to compare the time-dependent changes in tryptophan fluorescence and εA fluorescence. For both mutants, the tryptophan fluorescence exhibited two-step binding with essentially identical rate constants as were observed for the εA fluorescence changes. These results provide evidence that AAG forms an initial recognition complex in which the active site pocket is perturbed and the stacking of the damaged base is disrupted. Upon complete nucleotide flipping, there is further quenching of the tryptophan fluorescence with coincident quenching of the εA fluorescence. Although these mutations do not have large effects on the rate constant for excision of εA, there are dramatic effects on the rate constants for nucleotide flipping that result in 40-100-fold decreases in the flipping equilibrium relative to wild-type. Most of this effect is due to an increased rate of unflipping, but surprisingly the Y159W mutation causes a 5-fold increase in the rate constant for flipping. The large effect on the equilibrium for nucleotide flipping explains the greater deleterious effects that these mutations have on the glycosylase activity toward base lesions that are in more stable base pairs.     

Segmental motion in catalysis: investigation of a hydrogen bond critical for loop closure in the reaction of triosephosphate isomerase.

A residue essential for proper closure of the active-site loop in the reaction catalyzed by triosephosphate isomerase is tyrosine-208, the hydroxyl group of which forms a hydrogen bond with the amide nitrogen of alanine-176, a component of the loop. Both residues are conserved, and mutagenesis of the tyrosine to phenylalanine results in a 2000-fold drop in the catalytic activity (kcat/Km) of the enzyme compared to the wild-type isomerase. The nature of the closure process has been elucidated from both viscosity dependence and primary isotope effects. The reaction catalyzed by the mutant enzyme shows a viscosity dependence using glycerol as the viscosogen. This dependence can be attributed to the rate-limiting motion of the active-site loop between the "open" and the "closed" conformations. Furthermore, a large primary isotope effect is observed with [1-2H]dihydroxyacetone phosphate as substrate [(kcat/Km)H/(kcat/Km)D = 6 +/- 1]. The range of isotopic experiments that were earlier used to delineate the energetics of the wild-type isomerase has provided the free energy profile of the mutant enzyme. Comparison of the energetics of the wild-type and mutant enzymes shows that only the transition states flanking the enediol intermediate have been substantially affected. The results suggest either that loop closure and deprotonation are coupled and occur in the same rate-limiting step or that these two processes happen sequentially but interdependently. This finding is consistent with structural information that indicates that the catalytic base glutamate-165 moves 2 A toward the substrate upon loop closure.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kynuramine, a fluorescent substrate and probe of plasma amine oxidase

The fluorescence substrate kynuramine was used as a probe of the catalytic site of plasma amine oxidase. Under anaerobic conditions, the binding of kynuramine causes several spectroscopic changes. The Stokes shift (deltav = 5326 cm-) associated with binding of the substrate to the enzyme can be attributed to nonpolar properties of the binding site, whereas the increase in emission anisotropy (A = 33) indicates rigid attachment of the substrate to the enzyme. The fluorescence enhancement that follows the binding of substrate was used to determine the association constant (Ka). The enzyme plasma amine oxidase binds only 1 molecule of substrate with a Ka = 1.8 X 10(5) M-1 under anaerobic conditions. The use of fluorescence substrates seems to offer the possibility of monitoring conformational changes occurring prior to the catalytic event.     

Probing the catalytic allosteric mechanism of rabbit muscle pyruvate kinase by tryptophan fluorescence quenching

Pyruvate kinase acts as an allosteric enzyme, playing a crucial role in the catalysis of the final step of the glycolytic pathway. In this study, site-specific mutagenesis and tryptophan fluorescence quenching were used to probe the catalytic allosteric mechanism of rabbit muscle pyruvate kinase. Movement of the B domain was found to be essential for the catalytic reaction. Rotation of the B domain in the opening of the cleft between domains B and A induced by the binding of activating cations allows substrates to bind, whereas substrate binding shifts the rotation of the B domain in the closure of the cleft. Trp-157 accounts for the differences in tryptophan fluorescence signal with and without activating cations and substrates. Trp-481 and Trp-514 are brought into an aqueous environment after phenylalanine binding.     

Role of W181 in modulating kinetic properties of Plasmodium falciparum hypoxanthine guanine xanthine phosphoribosyltransferase

Hypoxanthine‐guanine‐xanthine phosphoribosyltransference (HGXPRT), a key enzyme in the purine salvage pathway of the malarial parasite, Plasmodium falciparum (Pf), catalyses the conversion of hypoxanthine, guanine, and xanthine to their corresponding mononucleotides; IMP, GMP, and XMP, respectively. Out of the five active site loops (I, II, III, III', and IV) in PfHGXPRT, loop III' facilitates the closure of the hood over the core domain which is the penultimate step during enzymatic catalysis. PfHGXPRT mutants were constructed wherein Trp 181 in loop III' was substituted with Ser, Thr, Tyr, and Phe. The mutants (W181S, W181Y and W181F), when examined for xanthine phosphoribosylation activity, showed an increase in K_m for PRPP by 2.1‐3.4 fold under unactivated condition and a decrease in catalytic efficiency by more than 5‐fold under activated condition as compared to that of the wild‐type enzyme. The W181T mutant showed 10‐fold reduced xanthine phosphoribosylation activity. Furthermore, molecular dynamics simulations of WT and in silico W181S/Y/F/T PfHGXPRT mutants bound to IMP.PPi.Mg²⁺ have been carried out to address the effect of the mutation of W181 on the overall dynamics of the systems and identify local changes in loop III'. Dynamic cross‐correlation analyses show a communication between loop III' and the substrate binding site. Differential cross‐correlation maps indicate altered communication among different regions in the mutants. Changes in the local contacts and hydrogen bonding between residue 181 with the nearby residues cause altered substrate affinity and catalytic efficiency of the mutant enzymes. Proteins 2016; 84:1658–1669. © 2016 Wiley Periodicals, Inc.