Site-directed mutagenesis and functional analysis of an active site tryptophan of insect chitinase

Chitinase is an enzyme used by insects to degrade the structural polysaccharide, chitin, during the molting process. Tryptophan 145 (W145) of Manduca sexta (tobacco hornworm) chitinase is a highly conserved residue found within a second conserved region of family 18 chitinases. It is located between aspartate 144 (D144) and glutamate 146 (E146), which are putative catalytic residues. The role of the active site residue, W145, in M. sexta chitinase catalysis was investigated by site-directed mutagenesis. W145 was mutated to phenylalanine (F), tyrosine (Y), isoleucine (I), histidine (H), and glycine (G). Wild-type and mutant forms of M. sexta chitinases were expressed in a baculovirus-insect cell line system. The chitinases secreted into the medium were purified and characterized by analyzing their catalytic activity and substrate or inhibitor binding properties. The wild-type chitinase was most active in the alkaline pH range. Several of the mutations resulted in a narrowing of the range of pH over which the enzyme hydrolyzed the polymeric substrate, CM-Chitin-RBV, predominantly on the alkaline side of the pH optimum curve. The range was reduced by about 1 pH unit for W145I and W145Y and by about 2 units for W145H and W145F. The W145G mutation was inactive. Therefore, the hydrophobicity of W145 appears to be critical for maintaining an abnormal pKa of a catalytic residue, which extends the activity further into the alkaline range. All of the mutant enzymes bound to chitin, suggesting that W145 was not essential for binding to chitin. However, the small difference in Km's of mutated enzymes compared to Km values of the wild-type chitinase towards both the oligomeric and polymeric substrates suggested that W145 is not essential for substrate binding but probably influences the ionization of a catalytically important group(s). The variations in kcat's among the mutated enzymes and the IC50 for the transition state inhibitor analog, allosamidin, indicate that W145 also influences formation of the transition state during catalysis.     

Substrate inhibition of acetylcholinesterase: residues affecting signal transduction from the surface to the catalytic center.

Amino acids located within and around the 'active site gorge' of human acetylcholinesterase (AChE) were substituted. Replacement of W86 yielded inactive enzyme molecules, consistent with its proposed involvement in binding of the choline moiety in the active center. A decrease in affinity to propidium and a concomitant loss of substrate inhibition was observed in D74G, D74N, D74K and W286A mutants, supporting the idea that the site for substrate inhibition and the peripheral anionic site overlap. Mutations of amino acids neighboring the active center (E202, Y337 and F338) resulted in a decrease in the catalytic and the apparent bimolecular rate constants. A decrease in affinity to edrophonium was observed in D74, E202, Y337 and to a lesser extent in F338 and Y341 mutants. E202, Y337 and Y341 mutants were not inhibited efficiently by high substrate concentrations. We propose that binding of acetylcholine, on the surface of AChE, may trigger sequence of conformational changes extending from the peripheral anionic site through W286 to D74, at the entrance of the 'gorge', and down to the catalytic center (through Y341 to F338 and Y337). These changes, especially in Y337, could block the entrance/exit of the catalytic center and reduce the catalytic efficiency of AChE.     

Kinase domain mutants of Bcr-Abl exhibit altered transformation potency, kinase activity, and substrate utilization, irrespective of sensitivity to imatinib

Kinase domain (KD) mutations of Bcr-Abl interfering with imatinib binding are the major mechanism of acquired imatinib resistance in patients with Philadelphia chromosome-positive leukemia. Mutations of the ATP binding loop (p-loop) have been associated with a poor prognosis. We compared the transformation potency of five common KD mutants in various biological assays. Relative to unmutated (native) Bcr-Abl, the ATP binding loop mutants Y253F and E255K exhibited increased transformation potency, M351T and H396P were less potent, and the performance of T315I was assay dependent. The transformation potency of Y253F and M351T correlated with intrinsic Bcr-Abl kinase activity, whereas the kinase activity of E255K, H396P, and T315I did not correlate with transforming capabilities, suggesting that additional factors influence transformation potency. Analysis of the phosphotyrosine proteome by mass spectroscopy showed differential phosphorylation among the mutants, a finding consistent with altered substrate specificity and pathway activation. Mutations in the KD of Bcr-Abl influence kinase activity and signaling in a complex fashion, leading to gain- or loss-of-function variants. The drug resistance and transformation potency of mutants may determine the outcome of patients on therapy with Abl kinase inhibitors.     

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 beta-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.     

The aromatic "trapping" of the catalytic histidine is essential for efficient catalysis in acetylcholinesterase

While substitution of the aromatic residues (Phe295, Phe338), located in the vicinity of the catalytic His447 in human acetylcholinesterase (HuAChE) had little effect on catalytic activity, simultaneous replacement of both residues by aliphatic amino acids resulted in a 680-fold decrease in catalytic activity. Molecular simulations suggested that the activity decline is related to conformational destabilization of His447, similar to that observed for the hexamutant HuAChE which mimics the active center of butyrylcholinesterase. On the basis of model structures of other cholinesterases (ChEs), we predicted that catalytically nonproductive mobility of His447 could be restricted by introduction of aromatic residue in a different location adjacent to this histidine (Val407). Indeed, the F295A/F338A/V407F enzyme is 170-fold more reactive than the corresponding double mutant and only 3-fold less reactive than the wild-type HuAChE. However, analogous substitution of Val407 in the hexamutant HuAChE (generating the heptamutant Y72N/Y124Q/W286A/F295L/F297V/Y337A/V407F) did not enhance catalytic activity. Reactivity of these double, triple, hexa, and hepta mutant HuAChEs was monitored toward covalent ligands such as organophosphates and the transition state analogue TMFTA, which probe, respectively, the facility of the enzymes to accommodate Michaelis complexes and to undergo the acylation process. The findings suggest that in the F295A/F338A mutant the two His447 conformational states, which are essential for the different stages of the catalytic process, seem to be destabilized. On the other hand, in the F295A/F338A/V407F mutant only the state involved in acylation is impaired. Such differential effects on the His447 conformational properties demonstrate the general role of aromatic residues in cholinesterases, and probably in other serine hydrolases, in "trapping" of the catalytic histidine and thereby in optimization of catalytic activity.     

Identification of an inhibitor binding site of poly(ADP-ribose) glycohydrolase

Polymers of ADP-ribose involved in the maintenance of genomic integrity are converted to free ADP-ribose by the action of poly(ADP-ribose) glycohydrolase (PARG). As an approach to mapping functions of PARG onto the amino acid sequence of the protein, we report here experiments that identify an amino acid residue involved in the binding of potent PARG inhibitors. A photoreactive inhibitor, [alpha-(32)P]-8-azidoadenosine diphosphate (hydroxymethyl)pyrrolidinediol (8-N(3)-ADP-HPD), was used to photolabel a recombinant bovine PARG catalytic fragment (rPARG-CF). N-Terminal sequencing of tryptic and subtilitic peptides of photoderivatized rPARG-CF identified tyrosine 796 (Y796), a residue conserved in PARG across a wide range of organisms, as a site of photoderivatization. Site-directed mutants where this tyrosine residue was replaced with an alanine residue (Y796A) had a nearly 8-fold decrease in catalytic efficiency (k(cat)/K(M)), while replacement with a tryptophan residue (Y796W) had little effect on catalytic efficiency. Surface plasmon resonance spectroscopy using the PARG inhibitor 8-(aminohexyl)amino-ADP-HPD demonstrated that the binding constant of the inhibitor for Y796A was 21-fold lower (K(D) = 170 nM) than that of wild-type PARG (K(D) = 8.2 nM), while Y796W displayed a binding affinity similar to that of the wild-type enzyme. Our results indicate that Y796 is involved in inhibitor binding to PARG via a ring stacking interaction and identify a highly conserved region of the protein that putatively contains other residues involved in catalytic activity and/or substrate recognition.     

Angiotensin I-converting enzyme transition state stabilization by HIS1089: evidence for a catalytic mechanism distinct from other gluzincin metalloproteinases

Angiotensin (Ang) I-converting enzyme (ACE) is a member of the gluzincin family of zinc metalloproteinases that contains two homologous catalytic domains. Both the N- and C-terminal domains are peptidyl-dipeptidases that catalyze Ang II formation and bradykinin degradation. Multiple sequence alignment was used to predict His(1089) as the catalytic residue in human ACE C-domain that, by analogy with the prototypical gluzincin, thermolysin, stabilizes the scissile carbonyl bond through a hydrogen bond during transition state binding. Site-directed mutagenesis was used to change His(1089) to Ala or Leu. At pH 7.5, with Ang I as substrate, k(cat)/K(m) values for these Ala and Leu mutants were 430 and 4,000-fold lower, respectively, compared with wild-type enzyme and were mainly due to a decrease in catalytic rate (k(cat)) with minor effects on ground state substrate binding (K(m)). A 120,000-fold decrease in the binding of lisinopril, a proposed transition state mimic, was also observed with the His(1089) --> Ala mutation. ACE C-domain-dependent cleavage of AcAFAA showed a pH optimum of 8.2. H1089A has a pH optimum of 5.5 with no pH dependence of its catalytic activity in the range 6.5-10.5, indicating that the His(1089) side chain allows ACE to function as an alkaline peptidyl-dipeptidase. Since transition state mutants of other gluzincins show pH optima shifts toward the alkaline, this effect of His(1089) on the ACE pH optimum and its ability to influence transition state binding of the sulfhydryl inhibitor captopril indicate that the catalytic mechanism of ACE is distinct from that of other gluzincins.     

Importance of F1-ATPase residue alpha-Arg-376 for catalytic transition state stabilization

The functional role of essential residue alpha-Arg-376 in the catalytic site of F1-ATPase was studied. The mutants alpha R376C, alpha R376Q, and alpha R376K were constructed, and combined with the mutation beta Y331W, to investigate catalytic site nucleotide-binding parameters, and to assess catalytic transition state formation by measurement of MgADP-fluoroaluminate binding. Each mutation caused large impairment of ATP synthesis and hydrolysis. Despite the apparent proximity of alpha-Arg-376 to bound nucleoside di- and triphosphate in published X-ray structures, the mutations had little effect on MgADP or MgATP binding affinities, particularly at the highest affinity catalytic site, site 1. Both Cys and Gln mutants abolished transition state formation, demonstrating that alpha-Arg-376 is normally involved at this step of catalysis. A model of the F1-ATPase catalytic transition state structure is presented and discussed. The Lys mutant, although severely impaired, supported transition state formation, suggesting that an additional essential role for the alpha-Arg-376 guanidinium group exists, likely in alpha/beta conformational signal transmission required for steady-state catalysis. Parallels between alpha-Arg-376 and GAP/G-protein "arginine finger" residues are evident.     

Wild-type enzyme as a reporter of inhibitor binding by catalytically impaired mutant enzymes.

A method for the determination of inhibition constants for catalytically-debilitated mutant enzymes is described. The inhibitor is partitioned between the mutant and wild-type enzymes. Catalytic rates of the wild-type enzyme are used as the signal of inhibitor binding to the mutant enzyme. The method is validated with scytalone dehydratase, the Y50F mutant, and a potent inhibitor. The K(i) value for Y50F determined by this method is 0.49 +/- 0.10 nM. The K(i) value determined using the Y50F catalytic report for inhibitor binding in the absence of wild-type enzyme is 0.20 +/- 0.030 nM. The wild-type enzyme binds the inhibitor ten-fold less tightly, thus indicating that the hydrogen-bonding interaction between the Y50 hydroxyl group and the inhibitor (suggested by X-ray crystallography) is weak. The method is most useful when the catalytic activity of the wild-type enzyme is the most sensitive report of inhibitor binding and the mutant enzyme is greatly crippled in catalytic activity.     

Loss of serotonin oxidation as a component of the altered substrate specificity in the Y444F mutant of recombinant human liver MAO A.

To investigate the roles of tyrosyl residues located near the covalent 8alpha-S-cysteinyl FAD in monoamine oxidase A (MAO A) and to test the suggestion that MAO A and plant polyamine oxidase may have structural homology, tyrosyl to phenylalanyl mutants of MAO A at positions 377, 402, 407, 410, 419, and 444 were constructed and expressed in Saccharomyces cerevisiae. All mutant enzymes were expressed and exhibited lower specific activities as compared to WT MAO A using kynuramine as substrate. The lowest specific activities in this assay are exhibited by the Y407F and Y444F mutant enzymes. On purification and further characterization, these two mutants were found to each contain covalent FAD. Both mutant enzymes are irreversibly inhibited by the MAO A inhibitor clorgyline and exhibit binding stoichiometries of 0.54 (Y407F) and 0.95 (Y444F) as compared to 1.05 for WT MAO A. Y444F MAO A oxidizes kynuramine with a k(cat) <2% of WT enzyme and is greater than 100-fold slower in catalyzing the oxidation of phenylethylamine or of serotonin. In contrast, Y444F MAO A oxidizes p-CF(3)-benzylamine at a rate 25% that of WT enzyme. Steady state and reductive half-reaction stopped-flow data using a series of para-substituted benzylamine analogues show Y444F MAO A exhibits quantitative structure activity relationships (QSAR) properties on analogue binding and rates of substrate oxidation very similar to that exhibited by the WT enzyme (Miller and Edmondson (1999) Biochemistry 38, 13670): log K(d) = -(0.37 +/- ()()0.07)V(W)(x0.1) - 4.5 +/- 0.1; log k(red) = +(2.43 +/- 0.19)sigma + 0.17 +/- 0.05. The Y444F MAO A mutant also exhibits similar QSAR properties on the binding of phenylalkyl side chain amine analogues as WT enzyme: log K(i) = (4.37 +/- 0.51)E(S) + 1.21 +/- 0.77. These data show that mutation of Y444F in MAO A results in a mutant that has lost its ability to efficiently oxidize serotonin (its physiological substrate) but, however, exhibits unaltered quantitative structure-activity parameters in the binding and rate of benzylamine analogues. The mechanism of C-H abstraction is therefore unaltered. The suggestion that polyamine oxidase and monoamine oxidase may have structural homology appears to be valid as regards Y444 in MAO A and Y439 in plant polyamine oxidase.     

Characterization of the active site of histidine ammonia-lyase from Pseudomonas putida.

Elucidation of the 3D structure of histidine ammonia-lyase (HAL, EC 4.3.1.3) from Pseudomonas putida by X-ray crystallography revealed that the electrophilic prosthetic group at the active site is 3,5-dihydro-5-methylidene-4H-imidazol-4-one (MIO) [Schwede, T.F., Rétey, J., Schulz, G.E. (1999) Biochemistry, 38, 5355-5361]. To evaluate the importance of several amino-acid residues at the active site for substrate binding and catalysis, we mutated the following amino-acid codons in the HAL gene: R283, Y53, Y280, E414, Q277, F329, N195 and H83. Kinetic measurements with the overexpressed mutants showed that all mutations resulted in a decrease of catalytic activity. The mutants R283I, R283K and N195A were approximately 1640, 20 and 1000 times less active, respectively, compared to the single mutant C273A, into which all mutations were introduced. Mutants Y280F, F329A and Q277A exhibited approximately 55, 100 and 125 times lower activity, respectively. The greatest loss of activity shown was in the HAL mutants Y53F, E414Q, H83L and E414A, the last being more than 20 900-fold less active than the single mutant C273A, while H83L was 18 000-fold less active than mutant C273A. We propose that the carboxylate group of E414 plays an important role as a base in catalysis. To investigate a possible participation of active site amino acids in the formation of MIO, we used the chromophore formation upon treatment of HAL with l-cysteine and dioxygen at pH 10.5 as an indicator. All mutants, except F329A showed the formation of a 338-nm chromophore arising from a modified MIO group. The UV difference spectra of HAL mutant F329A with the MIO-free mutant S143A provide evidence for the presence of a MIO group in HAL mutant F329A also. For modelling of the substrate arrangement within the active site and protonation state of MIO, theoretical calculations were performed.     

Characterization of the side-chain hydroxyl moieties of residues Y56, Y111, Y238, Y338, and S339 as determinants of specificity in E. coli cystathionine β-lyase

Cystathionine β-lyase (CBL) catalyzes the hydrolysis of L-cystathionine (L-Cth) to produce L-homocysteine, pyruvate, and ammonia. A series of site-directed variants of Escherichia coli CBL (eCBL) was constructed to investigate the roles of the hydroxyl moieties of active-site residues Y56, Y111, Y238, Y338, and S339 as determinants of specificity. The effect of these conservative substitutions on the k(cat)/K(m)(L-Cth) for the α,β-elimination of L-Cth ranges from a change of only 1.1-fold for Y338F to a reduction of 3 orders of magnitude for the alanine replacement variant of S339. A novel role for residue S339 as a determinant of reaction specificity, via tethering of the catalytic base, K210, is demonstrated. Comparison of the kinetic parameters for L-Cth hydrolysis with those for the inhibition of eCBL by aminoethoxyvinylglycine (AVG) indicates that Y238 interacts with the distal carboxylate group of the substrate. The 22 and 50-fold increases in the K(m)(L-Cth) and K(i)(AVG) resulting from replacement of Y56 with phenylalanine suggest that this residue may interact with the distal amino group of these compounds, although an indirect role in binding is more likely. The near-native k(cat)/K(m)(L-Cth) and pH profile of the eCBL-Y111F variant demonstrate that residue Y111 does not play a role in proton transfer. The understanding of the eCBL active site and of the determinants of substrate and reaction specificity resulting from this work will facilitate the design of inhibitors, as antibacterial therapeutics, and the engineering of enzymes dependent on the catalytically versatile pyridoxal 5'-phosphate cofactor to modify reaction specificity.     

Rational design of cyclodextrin glycosyltransferase from Bacillus circulans strain 251 to increase alpha-cyclodextrin production

Cyclodextrin glycosyltransferases (CGTase) (EC 2.4.1.19) are extracellular bacterial enzymes that generate cyclodextrins from starch. All known CGTases produce mixtures of alpha, beta, and gamma-cyclodextrins. A maltononaose inhibitor bound to the active site of the CGTase from Bacillus circulans strain 251 revealed sugar binding subsites, distant from the catalytic residues, which have been proposed to be involved in the cyclodextrin size specificity of these enzymes. To probe the importance of these distant substrate binding subsites for the alpha, beta, and gamma-cyclodextrin product ratios of the various CGTases, we have constructed three single and one double mutant, Y89G, Y89D, S146P and Y89D/S146P, using site-directed mutagenesis. The mutations affected the cyclization, coupling; disproportionation and hydrolyzing reactions of the enzyme. The double mutant Y89D/S146P showed a twofold increase in the production of alpha-cyclodextrin from starch. This mutant protein was crystallized and its X-ray structure, in a complex with a maltohexaose inhibitor, was determined at 2.4 A resolution. The bound maltohexaose molecule displayed a binding different from the maltononaose inhibitor, allowing rationalization of the observed change in product specificity. Hydrogen bonds (S146) and hydrophobic contacts (Y89) appear to contribute strongly to the size of cyclodextrin products formed and thus to CGTase product specificity. Changes in sugar binding subsites -3 and -7 thus result in mutant proteins with changed cyclodextrin production specificity.     

Functional studies of active-site mutants from Drosophila melanogaster deoxyribonucleoside kinase. Investigations of the putative catalytic glutamate-arginine pair and of residues responsible for substrate specificity

The catalytic reaction mechanism and binding of substrates was investigated for the multisubstrate Drosophila melanogaster deoxyribonucleoside kinase. Mutation of E52 to D, Q and H plus mutations of R105 to K and H were performed to investigate the proposed catalytic reaction mechanism, in which E52 acts as an initiating base and R105 is thought to stabilize the transition state of the reaction. Mutant enzymes (E52D, E52H and R105H) showed a markedly decreased k(cat), while the catalytic activity of E52Q and R105K was abolished. The E52D mutant was crystallized with its feedback inhibitor dTTP. The backbone conformation remained unchanged, and coordination between D52 and the dTTP-Mg complex was observed. The observed decrease in k(cat) for E52D was most likely due to an increased distance between the catalytic carboxyl group and 5'-OH of deoxythymidine (dThd) or deoxycytidine (dCyd). Mutation of Q81 to N and Y70 to W was carried out to investigate substrate binding. The mutations primarily affected the K(m) values, whereas the k(cat) values were of the same magnitude as for the wild-type. The Y70W mutation made the enzyme lose activity towards purines and negative cooperativity towards dThd and dCyd was observed. The Q81N mutation showed a 200- and 100-fold increase in K(m), whereas k(cat) was decreased five- and twofold for dThd and dCyd, respectively, supporting a role in substrate binding. These observations give insight into the mechanisms of substrate binding and catalysis, which is important for developing novel suicide genes and drugs for use in gene therapy.     

Roles of tyrosine 158 and lysine 165 in the catalytic mechanism of InhA, the enoyl-ACP reductase from Mycobacterium tuberculosis.

The role of tyrosine 158 (Y158) and lysine 165 (K165) in the catalytic mechanism of InhA, the enoyl-ACP reductase from Mycobacterium tuberculosis, has been investigated. These residues have been identified as putative catalytic residues on the basis of structural and sequence homology with the short chain alcohol dehydrogenase family of enzymes. Replacement of Y158 with phenylalanine (Y158F) and with alanine (Y158A) results in 24- and 1500-fold decreases in k(cat), respectively, while leaving K(m) for the substrate, trans-2-dodecenoyl-CoA, unaffected. Remarkably, however, replacement of Y158 with serine (Y158S) results in an enzyme with wild-type activity. Kinetic isotope effect studies indicate that the transfer of a solvent-exchangeable proton is partially rate-limiting for the wild-type and Y158S enzymes, but not for the Y158A enzyme. These data indicate that Y158 does not function formally as a proton donor in the reaction but likely functions as an electrophilic catalyst, stabilizing the transition state for hydride transfer by hydrogen bonding to the substrate carbonyl. A conformational change involving rotation of the Y158 side chain upon binding of the enoyl substrate to the enzyme is proposed as an explanation for the inverse solvent isotope effect observed on V/K(DD-CoA) when either NADH or NADD is used as the reductant. These data are consistent with the recently published structure of a C16 fatty acid substrate bound to InhA that shows Y158 hydrogen bonded to the substrate carbonyl group and rotated from the position it occupies in the InhA-NADH binary complex [Rozwarski, D. A., Vilcheze, C., Sugantino, M., Bittman, R., and Sacchettini, J. C. (1999) J. Biol. Chem. 274, 15582-15589]. Finally, the role of K165 has been analyzed using site-directed mutagenesis. Replacement of K165 with glutamine (K165Q) and arginine (K165R) has no effect on the enzyme's catalytic ability or on its ability to bind NADH. However, the K165A and K165M enzymes are unable to bind NADH, indicating that K165 has a primary role in cofactor binding.     

Tyr275 and Lys279 stabilize NADPH within the catalytic site of NADPH:protochlorophyllide oxidoreductase and are involved in the formation of the enzyme photoactive state

Fluorescence spectroscopic and kinetic analysis of photochemical activity, cofactor and substrate binding, and enzyme denaturation studies were performed with highly purified, recombinant pea NADPH:protochlorophyllide oxidoreductase (POR) heterologously expressed in Escherichia coli. The results obtained with an individual stereoisomer of the substrate [C8-ethyl-C13(2)-(R)-protochlorophyllide] demonstrate that the enzyme photoactive state possesses a characteristic fluorescence maximum at 646 nm that is due to the presence of specific charged amino acids in the enzyme catalytic site. The photoactive state is converted directly into an intermediate having fluorescence at 685 nm in a reaction involving direct hydrogen transfer from the cofactor (NADPH). Site-directed mutagenesis of the highly conserved Tyr275 (Y275F) and Lys279 (K279I and K279R) residues in the enzyme catalytic pocket demonstrated that the presence of these two amino acids in the wild-type POR considerably increases the probability of photoactive state formation following cofactor and substrate binding by the enzyme. At the same time, the presence of these two amino acids destabilizes POR and increases the rate of enzyme denaturation. Neither Tyr275 nor Lys279 plays a crucial role in the binding of the substrate or cofactor by the enzyme. In addition, the presence of Tyr275 is absolutely necessary for the second step of the protochlorophyllide reduction reaction, "dark" conversion of the 685 nm fluorescence intermediate and the formation of the final product, chlorophyllide. We propose that Tyr275 and Lys279 participate in the proper coordination of NADPH and PChlide in the enzyme catalytic site and thereby control the efficiency of the formation of the POR photoactive state.     

Structural basis of hematopoietic prostaglandin D synthase activity elucidated by site-directed mutagenesis

Hematopoietic prostaglandin (PG) D synthase (PGDS) is the first identified vertebrate ortholog in the Sigma class of the glutathione S-transferase (GST) family and catalyzes both isomerization of PGH(2) to PGD(2) and conjugation of glutathione to 1-chloro-2, 4-dinitrobenzene. We introduced site-directed mutations of Tyr(8), Arg(14), Trp(104), Lys(112), Tyr(152), Cys(156), Lys(198), and Leu(199), which are presumed to participate in catalysis or PGH(2) substrate binding based on the crystallographic structure. Mutants were analyzed in terms of structure, GST and PGDS activities, and activation of the glutathione thiol group. Of all the mutants, only Y8F, W104I, K112E, and L199F showed minor but substantial differences in their far-UV circular dichroism spectra from the wild-type enzyme. Y8F, R14K/E, and W104I were completely inactive. C156L/Y selectively lost only PGDS activity. K112E reduced GST activity slightly and PGDS activity markedly, whereas K198E caused a selective decrease in PGDS activity and K(m) for glutathione and PGH(2) in the PGDS reaction. No significant changes were observed in the catalytic activities of Y152F and L199F, although their K(m) for glutathione was increased. Using 5,5'-dithiobis(2-nitrobenzoic acid) as an SH-selective agent, we found that only Y8F and R14E/K did not accelerate the reactivity of the glutathione thiol group under the low reactivity condition of pH 5.0. These results indicate that Lys(112), Cys(156), and Lys(198) are involved in the binding of PGH(2); Trp(104) is critical for structural integrity of the catalytic center for GST and PGDS activities; and Tyr(8) and Arg(14) are essential for activation of the thiol group of glutathione.     

Delineation of the roles of amino acids involved in the catalytic functions of Leuconostoc mesenteroides glucose 6-phosphate dehydrogenase

The roles of particular amino acids in substrate and coenzyme binding and catalysis of glucose-6-phosphate dehydrogenase of Leuconostoc mesenteroides have been investigated by site-directed mutagenesis, kinetic analysis, and determination of binding constants. The enzyme from this species has functional dual NADP(+)/NAD(+) specificity. Previous investigations in our laboratories determined the three-dimensional structure. Kinetic studies showed an ordered mechanism for the NADP-linked reaction while the NAD-linked reaction is random. His-240 was identified as the catalytic base, and Arg-46 was identified as important for NADP(+) but not NAD(+) binding. Mutations have been selected on the basis of the three-dimensional structure. Kinetic studies of 14 mutant enzymes are reported and kinetic mechanisms are reported for 5 mutant enzymes. Fourteen substrate or coenzyme dissociation constants have been measured for 11 mutant enzymes. Roles of particular residues are inferred from k(cat), K(m), k(cat)/K(m), K(d), and changes in kinetic mechanism. Results for enzymes K182R, K182Q, K343R, and K343Q establish Lys-182 and Lys-343 as important in binding substrate both to free enzyme and during catalysis. Studies of mutant enzymes Y415F and Y179F showed no significant contribution for Tyr-415 to substrate binding and only a small contribution for Tyr-179. Changes in kinetics for T14A, Q47E, and R46A enzymes implicate these residues, to differing extents, in coenzyme binding and discrimination between NADP(+) and NAD(+). By the same measure, Lys-343 is also involved in defining coenzyme specificity. Decrease in k(cat) and k(cat)/K(m) for the D374Q mutant enzyme defines the way Asp-374, unique to L. mesenteroides G6PD, modulates stabilization of the enzyme during catalysis by its interaction with Lys-182. The greatly reduced k(cat) values of enzymes P149V and P149G indicate the importance of the cis conformation of Pro-149 in accessing the correct transition state.     

Farnesyl protein transferase: identification of K164 alpha and Y300 beta as catalytic residues by mutagenesis and kinetic studies.

Farnesyl protein transferase (FPT) is an alpha/beta heterodimeric zinc enzyme that catalyzes posttranslational farnesylation of many key cellular regulatory proteins, including oncogenic Ras. On the basis of the recently reported crystal structure of FPT complexed with a CVIM peptide and alpha-hydroxyfarnesylphosphonic acid, site-directed mutagenesis of the FPT active site was performed so key residues that are responsible for substrate binding and catalysis could be identified. Eight single mutants, including K164N alpha, Y166F alpha, Y166A alpha, Y200F alpha, H201A alpha, H248A beta, Y300F beta, and Y361F beta, and a double mutant, H248A beta/Y300F beta, were prepared. Steady-state kinetic analysis along with structural evidence indicated that residues Y200 alpha, H201 alpha, H248 beta, and Y361 beta are mainly involved in substrate binding. In addition, biochemical results confirm structural observations which show that residue Y166 alpha plays a key role in stabilizing the active site conformation of several FPT residues through cation-pi interactions. Two mutants, K164N alpha and Y300F beta, have moderately decreased catalytic constants (kcat). Pre-steady-state kinetic analysis of these mutants from rapid quench experiments showed that the chemical step rate constant was reduced by 41- and 30-fold, respectively. The product-releasing rate for each dropped approximately 10-fold. In pH-dependent kinetic studies, Y300F beta was observed to have both acidic and basic pKa values shifted 1 log unit from those of the wild-type enzyme, consistent with a possible role for Y300 beta as an acid-base catalyst. K164N alpha had a pKa shift from 6.0 to 5.3, which suggests it may function as a general acid. On the basis of these results along with structural evidence, a possible FPT reaction mechanism is proposed with both Y300 beta and K164 alpha playing key catalytic roles in enhancing the reactivity of the farnesyl diphosphate leaving group.     

The mechanism of aubstrate eecognition of pyroglutamyl-peptidase I from Bacillus amyloliquefaciens as determined by X-ray crystallography and site-directed mutagenesis

Pyroglutamyl-peptidase is able to specifically remove the amino-terminal pyroglutamyl residue protecting proteins or peptides from aminopeptidases. To clarify the mechanism of substrate recognition for the unique structure of the pyrrolidone ring, x-ray crystallography and site-directed mutagenesis were applied. The crystal structure of pyroglutamyl-peptidase bound to a transition state analog inhibitor (Inh), pyroglutaminal, was determined. Two hydrogen bonds were located between the main chain of the enzyme and the inhibitor (71:O.H-N:Inh and Gln71:N-H.OE:Inh), and the pyrrolidone ring of the inhibitor was inserted into the hydrophobic pocket composed of Phe-10, Phe-13, Thr-45, Ile-92, Phe-142, and Val-143. To study in detail the hydrophobic pocket, Phe-10, Phe-13, and Phe-142 were selected for mutation experiments. The k(cat) value of the F10Y mutant decreased, but the two phenylalanine mutants F13Y and F142Y did not exhibit significant changes in kinetic parameters compared with the wild-type enzyme. The catalytic efficiencies (k(cat)/K(m)) for the F13A and F142A mutants were less than 1000-fold that of the wild-type enzyme. The x-ray crystallographic study of the F142A mutant showed no significant change except for a minor one in the hydrophobic pocket compared with the wild type. These findings indicate that the molecular recognition of pyroglutamic acid is achieved through two hydrogen bonds and an insertion in the hydrophobic pocket. In the pocket, Phe-10 is more important to the hydrophobic interaction than is Phe-142, and furthermore Phe-13 serves as an "induced fit" mechanism.