Identification and characterization of the core region of protein phosphatase-1

PP1, PP2A and PP2B all belong to PPP family of serine/threonine protein phosphatases. Their primary structures are highly conserved, particularly in the catalytic domain. In order to obtain correlative information about this conserved region, we constructed N-, C-deletion and N/C double-deletion mutants. We found that the N- and Csingle-deletion mutants exhibited higher enzymatic activities, while specific activity of N/C double-deletion mutant PP1 (9-306) did not notably change. The results of kinetics analysis showed that k_cat and k_cat/K_m increased about 16-fold in the single-deletion mutants; while the two parameters of the double-deletion were lower than the single-deletions. We further explored stability of all mutants in existing denaturant guanidine hydrochloride (GdnHCl). It was noticeable that stability of PP1-(9-306) in all mutants was the highest. We speculated that PP1-(9-306) maybe retains a compact spherical structure, thus accordingly affected molecular catalysis. On the other hand the structures of single-deletion mutants were relatively relaxed, which were able to bind substrate easily, so activities of single-deletion mutants were higher than that of double-deletion mutant. We therefore deduced that PP1-(9-306) may be close to core region of PP1 molecule. In order to further solidify this idea, we used fluorescence spectra method to explore changes of space conformation. We found that emission peaks of all single-deletions were blue shifted in different degree in the absence of denaturant, while emission peak of N/C double-deletion mutant did not change obviously compared with that of the wild-type PP1. Conformation change of N/C double-deletion mutant was significantly less than those of single-deletion mutants in different GdnHCl concentration.     

Altering substrate specificity of phosphatidylcholine-preferring phospholipase C of Bacillus cereus by random mutagenesis of the headgroup binding site

PLC(Bc) is a 28.5 kDa monomeric enzyme that catalyzes the hydrolysis of the phosphodiester bond of phosphatidylcholine, phosphatidylethanolamine, and phosphatidylserine to provide a diacylglycerol and the corresponding phosphorylated headgroup. Because single replacements of Glu4, Tyr56, and Phe66 in the headgroup binding pocket led to changes in substrate specificity [Martin et al. (2000) Biochemistry 39, 3410-3415], a combinatorial library of approximately 6000 maltose binding protein-PLC(Bc) fusion protein mutants containing random permutations of these three residues was generated to identify PLC(Bc) mutants with altered specificity profiles and high catalytic activities. Members of this library were screened for hydrolytic activity toward the water soluble substrates C6PC, C6PE, and C6PS using a novel protocol that was conducted in a 96-well format and featured the in situ cleavage of the fusion protein to release the mutant PLC(Bc)s. Ten mutant enzymes that exhibited significant preferences toward C6PE or C6PS were selected and analyzed by steady-state kinetics to determine their specificity constants, k(cat)/K(M). The C6PS selective clones E4G, E4Q/Y56T/F66Y, and E4K/Y56V exhibited higher specificity constants toward C6PS than wt, whereas Y56T, F66Y, and Y56T/F66Y were C6PE selective and had comparable or higher specificity constants than wt for C6PE. The corresponding wt residues were singly reinserted back into the E4Q/Y56T/F66Y and E4K/Y56V mutants via site-directed mutagenesis, and the E4Q/F66Y mutant thus obtained exhibited a 10-fold higher specificity constant toward C6PS than wt, a value significantly higher than other PLC(Bc) mutants. On the basis of available data, an aromatic residue at position 66 appears important for significant catalytic activity toward all three substrates, especially C6PC and C6PE. The charge of residue 4 also appears to be a determinant of enzyme specificity as a negatively charged residue at this position endows the enzyme with C6PC and C6PE preference, whereas a polar neutral or positively charged residue results in C6PS selectivity. Replacing Tyr56 with Val, Ala, Thr, or Ser greatly reduces activity toward C6PC. Thus, the substrate specificity of PLC(Bc) can be modulated by varying three of the amino acid residues that constitute the headgroup binding pocket, and it is now apparent that this enzyme is not evolutionarily optimized to hydrolyze phospholipids with ethanolamine or serine headgroups.     

Analysis of conserved residues of the human puromycin-sensitive aminopeptidase

The puromycin-sensitive aminopeptidase (ApPS) is a zinc metallopeptidase involved in the degradation of neuropeptides. Putative catalytic residues of the enzyme, Cys146, Glu338, and Lys396 were mutated, and the resultant mutant enzymes characterized. ApPS C146S exhibited normal catalytic activity, ApPS E338A exhibited decreased substrate binding, and ApPS K396I exhibited decreases in both substrate binding and catalysis. ApPS K396I and ApPS Y394F were analyzed with respect to transition state inhibitor binding. No effect was seen with the K396I mutation, but ApPS Y394F exhibited a 3.3-fold lower affinity for RB-3014, a transition state inhibitor, indicating that Tyr394 is involved in transition state stabilization.     

Evidence for a catalytic dyad in the active site of homocitrate synthase from Saccharomyces cerevisiae

Homocitrate synthase (acetyl-coenzyme A: 2-ketoglutarate C-transferase; E.C. 2.3.3.14) (HCS) catalyzes the condensation of acetyl-CoA (AcCoA) and alpha-ketoglutarate (alpha-KG) to give homocitrate and CoA. Although the structure of an HCS has not been solved, the structure of isopropylmalate synthase (IPMS), a homologue, has been solved (Koon, N., Squire, C. J., and Baker, E. N. (2004) Proc. Natl. Acad. Sci. U.S.A. 101, 8295-8300). Three active site residues in IPMS, Glu-218, His-379, and Tyr-410, were proposed as candidates for catalytic residues involved in deprotonation of the methyl group of AcCoA prior to the Claisen condensation to give homocitrylCoA. All three of the active site residues in IPMS are conserved in the HCS from Saccharomyces cerevisiae. Site-directed mutagenesis has been carried out to probe the role of the homologous residues, Glu-155, His-309, and Tyr-320, in the S. cerevisiae HCS. No detectable activity was observed for the H309A and H309N mutant enzyme, but a slight increase in activity was observed for H309A in the presence of 300 mM imidazole, which is still 1000-fold lower than that of wild type (wt). The E155Q and E155A mutant enzymes exhibited 1000-fold lower activity than wt. The activity of E155A, but not of E155Q, could be partially rescued by formate; a K act of 60 mM with a modest 4-fold maximum activation was observed. In the presence of formate, E155A gives k cat, K AcCoA, and K alpha-KG values of 0.0031 s (-1), 13 muM, and 39 microM, respectively, while a primary kinetic deuterium isotope effect of about 1.4 was obtained on V, with deuterium in the methyl of AcCoA. The pH dependence of k cat for E155A in the presence of formate gave a p K a of 7.9 for a group that must be protonated for optimum activity, similar to that observed for the wt enzyme. However, a partial change was observed on the acid side of the profile, compared to the all or none change observed for wt giving a p K a of about 6.7. The k cat for E155Q decreased at high pH, similar to the wt enzyme, but was pH independent at low pH. The Y320F mutant enzyme only lost 25-fold activity compared to that of the wt, giving k cat, K AcCoA, and K alpha-KG values of 0.039 s (-1), 33 microM, and 140 microM, respectively, and a primary kinetic deuterium isotope effect of 1.3 and 1.8 on V/ K AcCoA and V, respectively; the pH dependence of k cat was similar to that of the wt. These data, combined with a constant pH molecular dynamics simulation study, suggest that a catalytic dyad comprising Glu-155 and His-309 acts to deprotonate the methyl group of AcCoA, while Tyr320 is likely not directly involved in catalysis, but may aid in orienting the reactant and/or the catalytic dyad.     

Regulation of the catalytic domain of protein phosphatase 1 by the terminal region of protein phosphatase 2B

C-terminal regions of the protein phosphatases PP1 and PP2B were seldom studied. C-terminal 24 amino acids of PP1 was deleted, its enzymatic activity increased 3-fold while its stability declined. When the truncated PP1 was fused with the terminal (residues 483-511) of PP2B, both its enzymatic activity and its stability remained low. This indicates that the termini of PP2B and PP1 have inhibitory effect on the catalytic domain of PP1. PP1-(1-306) and PP1wt differ in their activation by metal ions, showing that the sites interacting with metal ions are not located in its C-terminus; while metal ions activated notably to PP1/PP2B chimera. In addition, the sensitivity results of PP1-(1-306) to the inhibitors, TM and NCTD, proved that these two inhibitors also did not bind to the C-terminus. However, the IC(50)s of PP1/PP2B chimera were higher than for PP1-(1-306), indicating that the C-terminal region interferes interactions with these inhibitors to some extent. Although 483-511 segment of PP2B was not the functional domain, it played important role in interaction with metal ions and inhibitors. It further indicates although PP1 and PP2B have high sequence identity, their non-conserved termini have different roles.     

Critical role of Lys212 and Tyr140 in porcine NADP-dependent isocitrate dehydrogenase

Lys212 and Tyr140 are close to the enzyme-bound isocitrate in the recently determined crystal structure of porcine NADP-specific isocitrate dehydrogenase (Ceccarelli, C., Grodsky, N. B., Ariyaratne, N., Colman, R. F., and Bahnson, B. J. (2002) J. Biol. Chem. 277, 43454-43462). We have constructed mutant enzymes in which Lys212 is replaced by Gln, Tyr, and Arg, and Tyr140 is replaced by Phe, Thr, Glu, and Lys. Wild type and mutant enzymes were each expressed in Escherichia coli and purified to homogeneity. At pH 7.4, the specific activity is decreased in K212Q, K212Y, and K212R, respectively, to 0.01-9% of wild type. The most striking change is in the pH-V(max) curves. Wild type depends on the deprotonated form of a group of pKaes 5.7, whereas this pKaes is increased to 7.4 in neutral K212Q and to 8.3 in K212Y. In contrast, the positive K212R has a pKaes of 5.9. These results indicate that (by electrostatic repulsion) a positively charged residue at position 212 lowers the pK of the nearby ionizable group in the enzyme-substrate complex. Lys212 may also stabilize the carbanion formed initially on substrate decarboxylation. The Tyr140 mutants have specific activities at pH 7.4 that are reduced to 0.2-0.5% of those of wild type, whereas their Km values for isocitrate and NADP are not increased. Most notable are the altered pH-V(max) profiles. V(max) is constant from pH 5.3 to 8 for Y140F and Y140T and increases as pH is decreased for Y140E and Y140K. These results suggest that in wild type enzyme, Tyr140 is the general acid that protonates the substrate after decarboxylation and that the carboxyl and ammonium forms of Y140E and Y140K provide partial substitutes. Relative to wild type, the Y140T enzyme is specifically activated 106-fold by exogenous addition of acetic acid and 88-fold by added phenol; and the K212Q enzyme is activated 4-fold by added ethylamine. These chemical rescue experiments support the conclusion that Tyr140 and Lys212 are required for the catalytic activity of porcine NADP-dependent isocitrate dehydrogenase.     

Structural and biochemical characterization of glycoside hydrolase family 79 β-glucuronidase from Acidobacterium capsulatum

We present the first structure of a glycoside hydrolase family 79 β-glucuronidase from Acidobacterium capsulatum, both as a product complex with β-D-glucuronic acid (GlcA) and as its trapped covalent 2-fluoroglucuronyl intermediate. This enzyme consists of a catalytic (β/α)(8)-barrel domain and a β-domain with irregular Greek key motifs that is of unknown function. The enzyme showed β-glucuronidase activity and trace levels of β-glucosidase and β-xylosidase activities. In conjunction with mutagenesis studies, these structures identify the catalytic residues as Glu(173) (acid base) and Glu(287) (nucleophile), consistent with the retaining mechanism demonstrated by (1)H NMR analysis. Glu(45), Tyr(243), Tyr(292)-Gly(294), and Tyr(334) form the catalytic pocket and provide substrate discrimination. Consistent with this, the Y292A mutation, which affects the interaction between the main chains of Gln(293) and Gly(294) and the GlcA carboxyl group, resulted in significant loss of β-glucuronidase activity while retaining the side activities at wild-type levels. Likewise, although the β-glucuronidase activity of the Y334F mutant is ~200-fold lower (k(cat)/K(m)) than that of the wild-type enzyme, the β-glucosidase activity is actually 3 times higher and the β-xylosidase activity is only 2.5-fold lower than the equivalent parameters for wild type, consistent with a role for Tyr(334) in recognition of the C6 position of GlcA. The involvement of Glu(45) in discriminating against binding of the O-methyl group at the C4 position of GlcA is revealed in the fact that the E45D mutant hydrolyzes PNP-β-GlcA approximately 300-fold slower (k(cat)/K(m)) than does the wild-type enzyme, whereas 4-O-methyl-GlcA-containing oligosaccharides are hydrolyzed only 7-fold slower.     

Inhibition of the Escherichia coli pyruvate dehydrogenase complex E1 subunit and its tyrosine 177 variants by thiamin 2-thiazolone and thiamin 2-thiothiazolone diphosphates. Evidence for reversible tight-binding inhibition

Variants of the pyruvate dehydrogenase subunit (E1; EC ) of the Escherichia coli pyruvate dehydrogenase multienzyme complex with Y177A and Y177F substitutions were created. Both variants displayed pyruvate dehydrogenase multienzyme complex activity at levels of 11% (Y177A E1) and 7% (Y177F E1) of the parental enzyme. The K(m) values for thiamin diphosphate (ThDP) were 1.58 microm (parental E1) and 6.65 microm (Y177A E1), whereas the Y177F E1 variant was not saturated at 200 microm. According to fluorescence studies, binding of ThDP was unaffected by the Tyr(177) substitutions. The ThDP analogs thiamin 2-thiazolone diphosphate (ThTDP) and thiamin 2-thiothiazolone diphosphate (ThTTDP) behaved as tight-binding inhibitors of parental E1 (K(i) = 0.003 microm for ThTDP and K(i) = 0.064 microm for ThTTDP) and the Y177A and Y177F variants. This analysis revealed that ThTDP and ThTTDP bound to parental E1 via a two-step mechanism, but that ThTDP bound to the Y177A variant via a one-step mechanism. Binding of ThTDP was affected and that of ThTTDP was unaffected by substitutions at Tyr(177). Addition of ThDP or ThTDP to parental E1 resulted in similar CD spectral changes in the near-UV region. In contrast, binding of ThTTDP to either parental E1 or the Y177A and Y177F variants was accompanied by the appearance of a positive band at 330 nm, indicating that ThTTDP was bound in a chiral environment. In combination with x-ray structural evidence on the location of Tyr(177), the kinetic and spectroscopic data suggest that Tyr(177) has a role in stabilization of some transition state(s) in the reaction pathway, starting with the free enzyme and culminating with the first irreversible step (decarboxylation), as well as in reductive acetylation of the dihydrolipoamide acetyltransferase component.     

Identification of tyrosine 79 in the tocopherol binding site of glutathione S-transferase pi

Alpha-tocopherol, the most abundant form of vitamin E present in humans, is a noncompetitive inhibitor of glutathione S-transferase pi (GST pi), but its binding site had not been located. Tocopherol iodoacetate (TIA), a reactive analogue, produces a time-dependent inactivation of GST pi to a limit of 25% residual activity. The rate constant for inactivation, k(obs), exhibits a nonlinear dependence on reagent concentration, with K(I) = 19 microM and k(max) = 0.158 min(-)(1). Complete protection against inactivation is provided by tocopherol and tocopherol acetate, whereas glutathione derivatives, electrophilic substrate analogues, buffers, or nonsubstrate hydrophobic ligands have little effect on k(obs). These results indicate that TIA reacts as an affinity label of a distinguishable tocopherol binding site. Loss of activity occurs concomitant with incorporation of about 1 mol of reagent/mol of enzyme subunit when the enzyme is maximally inactivated. Isolation of the labeled peptide from the tryptic digest shows that Tyr(79) is the only enzymic amino acid modified. The Y79F, Y79S, and Y79A mutant enzymes were generated, expressed, and purified. Changing Tyr(79) to Ser or Ala, but not Phe, renders the enzyme insensitive to inhibition by either tocopherol or tocopherol acetate as demonstrated by increases of at least 49-fold in K(I) values as compared to the wild-type enzyme. These results and examination of the crystal structure of GST pi suggest that tocopherols bind at a novel site, where an aromatic residue at position 79 is essential for binding.     

Influence of the aglycone region of the substrate binding cleft of Pseudomonas xylanase 10A on catalysis.

Pseudomonas cellulosa xylanase 10A (Pc Xyn10A) contains an extended substrate binding cleft comprising three glycone (-1 to -3) and four aglycone (+1 to +4) subsites and, typical of retaining glycoside hydrolases, exhibits transglycosylation activity at elevated substrate concentrations. In a previous study [Charnock, S. J., et al. (1997) J. Biol. Chem. 272, 2942-2951], it was demonstrated that the -2 subsite mutations E43A and N44A caused a 100-fold reduction in activity against xylooligosaccharides, but did not influence xylanase activity. This led to the proposal that the low activity of these mutants against xylooligosaccharides was due to nonproductive complex formation between these small substrates and the extended aglycone region of the active site. To test this hypothesis, key residues at the +2 (Asn182), +3 (Tyr255), and +4 (Tyr220) subsites were substituted for alanine, and the activity of the mutants against polysaccharides and oligosaccharides was evaluated. All the aglycone mutants exhibited greatly reduced or no transglycosylating activity, and the triple mutants, E43A/Y220A/Y255A and E43A/N182A/Y255A, had activity against xylotriose similar to that of E43A. The aglycone mutations caused an increase in both k(cat) and K(m) against xylan, with N182A/Y220A/Y255A and N182A/Y255A exhibiting 25- and 15-fold higher k(cat) values, respectively, than wild-type Pc Xyn10A. These data indicate that Glu43 plays a role in binding xylooligosaccharides, but not xylan, suggesting that the mechanisms by which Pc Xyn10A binds polysaccharides and oligosaccharides are distinct. The increased k(cat) of the mutants against xylan indicates that the aglycone region of wild-type Pc Xyn10A restricts the rate of catalysis by limiting diffusion of the cleaved substrate, generated at the completion of the k(2) step, out of the active site.     

Tyrosine residues serve as proton donor in the catalytic mechanism of epoxide hydrolase from Agrobacterium radiobacter

Epoxide hydrolase from Agrobacterium radiobacter catalyzes the hydrolysis of epoxides to their diols via an alkyl-enzyme intermediate. The recently solved X-ray structure of the enzyme shows that two tyrosine residues (Tyr152 and Tyr215) are positioned close to the nucleophile Asp107 in such a way that they can serve as proton donor in the alkylation reaction step. The role of these tyrosines, which are conserved in other epoxide hydrolases, was studied by site-directed mutagenesis. Mutation of Tyr215 to Phe and Ala and mutation of Tyr152 to Phe resulted in mutant enzymes of which the k(cat) values were only 2-4-fold lower than for wild-type enzyme, whereas the K(m) values for the (R)-enantiomers of styrene oxide and p-nitrostyrene oxide were 3 orders of magnitude higher than the K(m) values of wild-type enzyme, showing that the alkylation half-reaction is severely affected by the mutations. Pre-steady-state analysis of the conversion of (R)-styrene oxide by the Y215F and Y215A mutants showed that the 1000-fold elevated K(m) values were mainly caused by a 15-40-fold increase in K(S) and a 20-fold reduction in the rate of alkylation. The rates of hydrolysis of the alkyl-enzyme intermediates were not significantly affected by the mutations. The double mutant Y152F+Y215F showed only a low residual activity for (R)-styrene oxide, with a k(cat)/K(m) value that was 6 orders of magnitude lower than with wild-type enzyme and 3 orders of magnitude lower than with the single tyrosine mutants. This indicates that the effects of the mutations were cumulative. The side chain of Gln134 is positioned in the active site of the X-ray structure of epoxide hydrolase. Mutation of Gln134 to Ala resulted in an active enzyme with slightly altered steady-state kinetic parameters compared to wild-type enzyme, indicating that Gln134 is not essential for catalysis and that the side chain of Gln134 mimics bound substrate. Based upon this observation, the inhibitory potential of various unsubstituted amides was tested, resulting in the identification of phenylacetamide as a competitive inhibitor with an inhibition constant of 30 microM.     

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.     

A conserved tyrosine residue of Saccharomyces cerevisiae leukotriene A4 hydrolase stabilizes the transition state of the peptidase activity

Saccharomyces cerevisiae leukotriene A4 hydrolase (LTA4H) is a bifunctional aminopeptidase/epoxide hydrolase and a member of the M1 family of metallopeptidases. In order to obtain a more thorough understanding of the aminopeptidase activity of the enzyme, two conserved tyrosine residues, Tyr244 and Tyr456, were altered to phenylalanine and the mutant proteins characterized by determining KM and kcat for various amino acid beta-naphthylamide substrates. While mutation of Tyr456 exhibited minimal effect on catalysis, mutation of Tyr244 caused an overall 25-100-fold reduction in catalytic activity for all substrates tested. Furthermore, LTA4H Y244F exhibited a 40-fold decrease in affinity for RB-3014, a transition state analog inhibitor, implicating Tyr244 in transition state stabilization.     

Specific characterization of substrate and inhibitor binding sites of a glycosyl hydrolase family 11 xylanase from Aspergillus niger

The importance of aromatic and charged residues at the surface of the active site of a family 11 xylanase from Aspergillus niger was evaluated using site-directed mutagenesis. Ten mutant proteins were heterologously produced in Pichia pastoris, and their biochemical properties and kinetic parameters were determined. The specific activity of the Y6A, Y10A, Y89A, Y164A, and W172A mutant enzymes was drastically reduced. The low specific activities of Y6A and Y89A were entirely accounted for by a change in k(cat) and K(m), respectively, whereas the lower values of Y10A, Y164A, and W172A were due to a combination of increased K(m) and decreased k(cat). Tyr(6), Tyr(10), Tyr(89), Tyr(164), and Trp(172) are proposed as substrate-binding residues, a finding consistent with structural sequence alignments of family 11 xylanases and with the three-dimensional structure of the A. niger xylanase in complex with the modeled xylobiose. All other variants, D113A, D113N, N117A, E118A, and E118Q, retained full wild-type activity. Only N117A lost its sensitivity to xylanase inhibitor protein I (XIP-I), a protein inhibitor isolated from wheat, and this mutation did not affect the fold of the xylanase as revealed by circular dichroism. The N117A variant showed kinetics, pH stability, hydrolysis products pattern, substrate specificity, and structural properties identical to that of the wild-type xylanase. The loss of inhibition, as measured in activity assays, was due to abolition of the interaction between XIP-I and the mutant enzyme, as demonstrated by surface plasmon resonance and electrophoretic titration. A close inspection of the three-dimensional structure of A. niger xylanase suggests that the binding site of XIP-I is located at the conserved "thumb" hairpin loop of family 11 xylanases.     

The beta12-beta13 loop of protein phosphatase-1 is involved in activity regulation

Protein phosphatase-1 (PP1) is a member of the eukaryotic serine/threonine phosphatase gene family. The beta12-beta13 loop is a prominent non-conserved region among the family, and extends from the surface and overhangs the active site. To investigate the function of the beta12-beta13 loop of PP1, we systematically examined all residues by site-directed deletion mutation. Deleting residues Y272, E275 or F276, caused enzyme activity to increase, while deleting residue C273, caused enzyme activity to decrease, when G274 was deleted no remarkable activity increase was observed, and almost all activity was lost when D277, N278 or A279 were deleted. These observations implied that each amino acid has a different effect on the activity of phosphatase, which may result from their different side chains and locations. The activity change of these PP1 mutants, from Y272 to A279, was comparable to that of calcineurin mutants, from Y311 to K318. By comparison, except for D277 (N316) and A279 (K318) of PP1 (calcineurin), each pair of equivalent mutants in the beta12-beta13 loop of PP1 and calcineurin have coincident activity change although they are non-conserved, which suggests that the beta12-beta13 loop of PP1 is not only involved in activity regulation but also involved in regulation similar to that of calcineurin.     

Enhancement of lipocalin-type prostaglandin D synthase enzyme activity by guanidine hydrochloride

The characterization of unfolding of mouse recombinant lipocalin-type prostaglandin D synthase (L-PGDS) by guanidine hydrochloride (GdnHCl) was carried out. In the presence of low concentrations of GdnHCl (up to 0.75 M), enhancement of the enzyme activity was observed. However, above a 1 M concentration of GdnHCl, the enzyme activity was reduced in a concentration-dependent manner. The maximum enzyme activity induced by GdnHCl was approximately 1. 5-fold compared with the activity under physiological conditions without GdnHCl. The ellipticity in circular dichroism (CD) spectrum of the L-PGDS at 218 nm, reflecting the beta-sheet content, was decreased by GdnHCl (up to 0.75 M), and the minimum ellipticity was observed at 0.5 M GdnHCl. The fluorescence quenching of the intrinsic tryptophan of L-PGDS due to the binding of bilirubin in the presence or absence of GdnHCl was measured. The K(d) values obtained in the presence and absence of 0.5 M GdnHCl were 447 and 115 nM, respectively, indicating lower affinity of the L-PGDS for bilirubin with GdnHCl than without it. Further, an NMR study revealed that the reorganization of hydrogen-bond network in the L-PGDS was observed in the presence of 0.5 M GdnHCl. These results, taken together, indicate that the enzyme activity of L-PGDS is enhanced by the conformational change, especially by the change in the secondary structure.     

Removing a hydrogen bond in the dimer interface of Escherichia coli manganese superoxide dismutase alters structure and reactivity

Among manganese superoxide dismutases, residues His30 and Tyr174 are highly conserved, forming part of the substrate access funnel in the active site. These two residues are structurally linked by a strong hydrogen bond between His30 NE2 from one subunit and Tyr174 OH from the other subunit of the dimer, forming an important element that bridges the dimer interface. Mutation of either His30 or Tyr174 in Escherichia coli MnSOD reduces the superoxide dismutase activity to 30--40% of that of the wt enzyme, which is surprising, since Y174 is quite remote from the active site metal center. The 2.2 A resolution X-ray structure of H30A-MnSOD shows that removing the Tyr174-->His30 hydrogen bond from the acceptor side results in a significant displacement of the main-chain segment containing the Y174 residue, with local rearrangement of the protein. The 1.35 A resolution structure of Y174F-MnSOD shows that disruption of the same hydrogen bond from the donor side has much greater consequences, with reorientation of F174 having a domino effect on the neighboring residues, resulting in a major rearrangement of the dimer interface and flipping of the His30 ring. Spectroscopic studies on H30A, H30N, and Y174F mutants show that (like the previously characterized Y34F mutant of E. coli MnSOD) all lack the high pH transition of the wt enzyme. This observation supports assignment of the pH sensitivity of MnSOD to coordination of hydroxide ion at high pH rather than to ionization of the phenolic group of Y34. Thus, mutations near the active site, as in the Y34F mutant, as well as at remote positions, as in Y174F, similarly affect the metal reactivity and alter the effective pK(a) for hydroxide ion binding. These results imply that hydrogen bonding of the H30 imidazole N--H group plays a key role in substrate binding and catalysis.     

The role of tryptophan-48 in catalysis and binding of inhibitors of Plasmodium falciparum dihydrofolate reductase

Dihydrofolate reductases (DHFRs) from Plasmodium falciparum (Pf) and various species of both prokaryotic and eukaryotic organisms have a conserved tryptophan (Trp) at position 48 in the active site. The role in catalysis and binding of inhibitors of the conserved Trp48 of PfDHFR has been analysed by site-specific mutagenesis, enzyme kinetics and use of a bacterial surrogate system. All 19 mutant enzymes showed undetectable or very low specific activities, with the highest value of k(cat)/K(m) from the Tyr48 (W48Y) mutant (0.12 versus 11.94M(-1)s(-1)), of about 1% of the wild-type enzyme. The inhibition constants for pyrimethamine, cycloguanil and WR99210 of the W48Y mutants are 2.5-5.3 times those of the wild-type enzyme. All mutants, except W48Y, failed to support the growth of Escherichia coli transformed with the parasite gene in the presence of trimethoprim, indicating the loss of functional activity of the parasite enzyme. Hence, Trp48 plays a crucial role in catalysis and inhibitor binding of PfDHFR. Interestingly, W48Y with an additional mutation at Asn188Tyr (N188Y) was found to promote bacterial growth and yielded a higher amount of purified enzyme. However, the kinetic parameters of the purified W48Y+N188Y enzyme were comparable with W48Y and the binding affinities for DHFR inhibitors were also similar to the wild-type enzyme. Due to its conserved nature, Trp48 of PfDHFR is a potential site for interaction with antimalarial inhibitors which would not be compromised by its mutations.     

Maintenance of alpha-helical structures by phenyl rings in the active-site tyrosine triad contributes to catalysis and stability of ketosteroid isomerase from Pseudomonas putida biotype B.

Ketosteroid isomerase (KSI) from Pseudomonas putida biotype B is a homodimeric enzyme catalyzing an allylic rearrangement of Delta5-3-ketosteroids at rates comparable with the diffusion-controlled limit. The tyrosine triad (Tyr14.Tyr55.Tyr30) forming a hydrogen-bond network in the apolar active site of KSI has been characterized in an effort to identify the roles of the phenyl rings in catalysis, stability, and unfolding of the enzyme. The replacement of Tyr14, a catalytic residue, with serine resulted in a 33-fold decrease of kcat, while the replacements of Tyr30 and Tyr55 with serine decreased kcat by 4- and 51-fold, respectively. The large decrease of kcat for Y55S could be due to the structural perturbation of alpha-helix A3, which results in the reorientation of the active-site residues as judged by the crystal structure of Y55S determined at 2.2 A resolution. Consistent with the analysis of the Y55S crystal structure, the far-UV circular dichroism spectra of Y14S, Y30S, and Y55S indicated that the elimination of the phenyl ring of the tyrosine reduced significantly the content of alpha-helices. Urea-induced equilibrium unfolding experiments revealed that the DeltaG(U)H2O values of Y14S, Y30S, and Y55S were significantly decreased by 11.9, 13.7, and 9.5 kcal/mol, respectively, as compared with that of the wild type. A characterization of the unfolding kinetics based on PhiU-value analysis indicates that the interactions mediated by the tyrosine triad in the native state are very resistant to unfolding. Taken together, our results demonstrate that the internal packing by the phenyl rings in the active-site tyrosine triad contributes to the conformational stability and catalytic activity of KSI by maintaining the structural integrity of the alpha-helices.