Mutations of muscle glycogen synthase that disable activation by glucose 6-phosphate.

Glycogen synthase, an enzyme of historical importance in the field of reversible protein modification, is inactivated by phosphorylation and allosterically activated by glucose 6-phosphate (glucose-6-P). Previous analysis of yeast glycogen synthase had identified a conserved and highly basic 13-amino-acid segment in which mutation of Arg residues resulted in loss of activation by glucose-6-P. The equivalent mutations R578R579R581A (all three of the indicated Arg residues mutated to Ala) and R585R587R590A were introduced into rabbit muscle glycogen synthase. Whether expressed transiently in COS-1 cells or produced in and purified from Escherichia coli, both mutant enzymes were insensitive to activation by glucose-6-P. The effect of phosphorylation was studied in two ways. Purified, recombinant glycogen synthase was directly phosphorylated by casein kinase 2 and glycogen synthase kinase 3, under conditions that inactivate the wild-type enzyme. In addition, phosphorylation sites were converted to Ala by mutagenesis in wild-type and in the glucose-6-P desensitized mutants expressed in COS-1 cells. Phosphorylation inactivated the R578R579R581A mutant but had little effect on the R585R587R590A. This result was surprising since phosphorylation had the opposite effects on the corresponding yeast enzyme mutants. The results confirm that the region of glycogen synthase, Arg-578-Arg-590, is required for activation by glucose-6-P and suggest that it is part of a sensitive and critical switch involved in transitions between different conformational states. However, the role must differ subtly between the mammalian and the yeast enzymes.     

Glycogen synthase sensitivity to glucose-6-P is important for controlling glycogen accumulation in Saccharomyces cerevisiae

Glycogen is a storage form of glucose utilized as an energy reserve by many organisms. Glycogen synthase, which is essential for synthesizing this glucose polymer, is regulated by both covalent phosphorylation and the concentration of glucose-6-P. With the yeast glycogen synthase Gsy2p, we recently identified two mutants, R579A/R580A/R582A [corrected] and R586A/R588A/R591A, in which multiple arginine residues were mutated to alanine that were completely insensitive to activation by glucose-6-P in vitro (Pederson, B. A., Cheng, C., Wilson, W. A., and Roach, P. J. (2000) J. Biol. Chem. 275, 27753-27761). We report here the expression of these mutants in Saccharomyces cerevisiae and, as expected from our findings in vitro, they were not activated by glucose-6-P. The R579A/R580A/R582A [corrected] mutant, which is also resistant to inhibition by phosphorylation, caused hyperaccumulation of glycogen. In contrast, the mutant R586A/R588A/R591A, which retains the ability to be inactivated by phosphorylation, resulted in lower glycogen accumulation when compared with wild-type cells. When intracellular glucose-6-P levels were increased by mutating the PFK2 gene, glycogen storage due to the wild-type enzyme was increased, whereas that associated with R579A/R580A/R582A [corrected] was not greatly changed. This is the first direct demonstration that activation of glycogen synthase by glucose-6-P in vivo is necessary for normal glycogen accumulation.     

Substrate Targeting of the Yeast Cyclin-Dependent Kinase Pho85p by the Cyclin Pcl10p

In Saccharomyces cerevisiae, PHO85 encodes a cyclin-dependent protein kinase (Cdk) catalytic subunit with multiple regulatory roles thought to be specified by association with different cyclin partners (Pcls). Pcl10p is one of four Pcls with little sequence similarity to cyclins involved in cell cycle control. It has been implicated in specifying the phosphorylation of glycogen synthase (Gsy2p). We report that recombinant Pho85p and Pcl10p produced in Escherichia coli reconstitute an active Gsy2p kinase in vitro. Gsy2p phosphorylation required Pcl10p, occurred at physiologically relevant sites, and resulted in inactivation of Gsy2p. The activity of the reconstituted enzyme was even greater than Pho85p-Pcl10p isolated from yeast, and we conclude that, unlike many Cdks, Pho85p does not require phosphorylation for activity. Pcl10p formed complexes with Gsy2p, as judged by (i) gel filtration of recombinant Pcl10p and Gsy2p, (ii) coimmunoprecipitation from yeast cell lysates, and (iii) enzyme kinetic behavior consistent with Pcl10p binding the substrate. Synthetic peptides modeled on the sequences of known Pho85p sites were poor substrates with high K(m) values, and we propose that Pcl10p-Gsy2p interaction is important for substrate selection. Gel filtration of yeast cell lysates demonstrated that most Pho85p was present as a monomer, although a portion coeluted in high-molecular-weight fractions with Pcl10p and Gsy2p. Overexpression of Pcl10p sequestered most of the Pho85p into association with Pcl10p. We suggest a model for Pho85p function in the cell whereby cyclins like Pcl10p recruit Pho85p from a pool of monomers, both activating the kinase and targeting it to substrate.     

Frog oocyte glycogen synthase: enzyme regulation under in vitro and in vivo conditions

Frog oocyte glycogen synthase properties differ significantly under in vitro or in vivo conditions. The K(mapp) for UDP-glucose in vivo was 1.4mM (in the presence or absence of glucose-6-P). The in vitro value was 6mM and was reduced by glucose-6-P to 0.8mM. Under both conditions (in vitro and in vivo) V(max) was 0.2 m Units per oocyte in the absence of glucose-6-P. V(max) in vivo was stimulated 2-fold by glucose-6-P, whereas, in vitro, a 10-fold increase was obtained. Glucose-6-P required for 50% activation in vivo was 15 microM and, depending on substrate concentrations, 50-100 microM in vitro. The prevailing enzyme obtained in vitro was the glucose-6-P-dependent form, which may be converted to the independent species by dephosphorylation. This transformation could not be observed in vivo. We suggest that enzyme activation by glucose-6-P in vivo is due to allosteric effects rather than to dephosphorylation of the enzyme. Regulatory mechanisms other than allosteric activation and covalent phosphorylation are discussed.     

Mutagenesis of the phosphatase sequence motif in diacylglycerol pyrophosphate phosphatase from Saccharomyces cerevisiae.

Diacylglycerol pyrophosphate (DGPP) phosphatase, encoded by the DPP1 gene, is a membrane-associated enzyme in the yeast Saccharomyces cerevisiae. The enzyme removes the beta phosphate from DGPP to form phosphatidate. The substrate and product of the DGPP phosphatase reaction play roles in lipid signaling and in cell metabolism. The deduced primary structure of the DGPP phosphatase protein contains a three-domain phosphatase sequence motif. In this work, we examined the hypothesis that the phosphatase sequence motif in the enzyme is involved in the DGPP phosphatase reaction. The amino acid residues Arg(125), His(169), and His(223) in domains 1, 2, and 3, respectively, of the phosphatase sequence motif were changed to alanine residues by site-directed mutagenesis. The mutant DPP1(R125A), DPP1(H169A), and DPP1(H223A) alleles were cloned into a yeast shuttle vector and then expressed in a dpp1Delta lpp1Delta double mutant that lacks DGPP phosphatase activity. Northern blot and immunoblot analyses showed that the mutations in the phosphatase sequence motif did not affect the expression of the enzyme. The DGPP phosphatase activities of the R125A, the H169A, and the H223A mutant enzymes were 0.05, 9, and 0.03%, respectively, of the DGPP phosphatase activity of the wild-type enzyme. Enzymes with mutations in more than one domain of the phosphatase sequence motif had no measurable DGPP phosphatase activity. The R125A and H233A mutant DGPP phosphatase enzymes had reduced V(max) and elevated K(m) values for DGPP when compared with the wild-type enzyme. The H169A mutant enzyme had reduced V(max) and K(m) values when compared with the control. The specificity constants (V(max)/K(m)()) for DGPP of the R125A mutant and H233A mutant enzymes were 4610-fold and 15 367-fold lower, respectively, when compared to the wild-type enzyme. The studies reported here indicated that the phosphatase sequence motif played an important role in the reaction catalyzed by the S. cerevisiae DGPP phosphatase.     

The region from phenylalanine-17 to phenylalanine-28 of a yeast mitochondrial ATPase inhibitor is essential for its ATPase inhibitory activity.

Mitochondrial ATP synthase (F(1)F(o)-ATPase) is regulated by an intrinsic ATPase inhibitor protein. In the present study, we investigated the structure-function relationship of the yeast ATPase inhibitor by amino acid replacement. A total of 22 mutants were isolated and characterized. Five mutants (F17S, R20G, R22G, E25A, and F28S) were entirely inactive, indicating that the residues, Phe17, Arg20, Arg22, Glu25, and Phe28, are essential for the ATPase inhibitory activity of the protein. The activity of 7 mutants (A23G, R30G, R32G, Q36G, L37G, L40S, and L44G) decreased, indicating that the residues, Ala23, Arg30, Arg32, Gln36, Leu37, Leu40, and Leu44, are also involved in the activity. Three mutants, V29G, K34Q, and K41Q, retained normal activity at pH 6.5, but were less active at pH 7.2, indicating that the residues, Val29, Lys34, and Lys41, are required for the protein's action at higher pH. The effects of 6 mutants (D26A, E35V, H39N, H39R, K46Q, and K49Q) were slight or undetectable, and the residues Asp26, Glu35, His39, Lys46, and Lys49 thus appear to be dispensable. The mutant E21A retained normal ATPase inhibitory activity but lacked pH-sensitivity. Competition experiments suggested that the 5 inactivated mutants (F17S, R20G, R22G, E25A, and F28S) could still bind to the inhibitory site on F(1)F(o)-ATPase. These results show that the region from the position 17 to 28 of the yeast inhibitor is the most important for its activity and is required for the inhibition of F(1), rather than binding to the enzyme.     

Multiple glycogen-binding sites in eukaryotic glycogen synthase are required for high catalytic efficiency toward glycogen

Glycogen synthase is a rate-limiting enzyme in the biosynthesis of glycogen and has an essential role in glucose homeostasis. The three-dimensional structures of yeast glycogen synthase (Gsy2p) complexed with maltooctaose identified four conserved maltodextrin-binding sites distributed across the surface of the enzyme. Site-1 is positioned on the N-terminal domain, site-2 and site-3 are present on the C-terminal domain, and site-4 is located in an interdomain cleft adjacent to the active site. Mutation of these surface sites decreased glycogen binding and catalytic efficiency toward glycogen. Mutations within site-1 and site-2 reduced the V(max)/S(0.5) for glycogen by 40- and 70-fold, respectively. Combined mutation of site-1 and site-2 decreased the V(max)/S(0.5) for glycogen by >3000-fold. Consistent with the in vitro data, glycogen accumulation in glycogen synthase-deficient yeast cells (Δgsy1-gsy2) transformed with the site-1, site-2, combined site-1/site-2, or site-4 mutant form of Gsy2p was decreased by up to 40-fold. In contrast to the glycogen results, the ability to utilize maltooctaose as an in vitro substrate was unaffected in the site-2 mutant, moderately affected in the site-1 mutant, and almost completely abolished in the site-4 mutant. These data show that the ability to utilize maltooctaose as a substrate can be independent of the ability to utilize glycogen. Our data support the hypothesis that site-1 and site-2 provide a "toehold mechanism," keeping glycogen synthase tightly associated with the glycogen particle, whereas site-4 is more closely associated with positioning of the nonreducing end during catalysis.     

Maize phosphoenolpyruvate carboxylase. Mutations at the putative binding site for glucose 6-phosphate caused desensitization and abolished responsiveness to regulatory phosphorylation

Phosphoenolpyruvate carboxylases (PEPC, EC 4.1.1.31) from higher plants are regulated by both allosteric effects and reversible phosphorylation. Previous x-ray crystallographic analysis of Zea mays PEPC has revealed a binding site for sulfate ion, speculated to be the site for an allosteric activator, glucose 6-phosphate (Glc-6-P) (Matsumura, H., Xie, Y., Shirakata, S., Inoue, T., Yoshinaga, T., Ueno, Y., Izui, K., and Kai, Y. (2002) Structure (Lond.) 10, 1721-1730). Because kinetic experiments have also supported this notion, each of the four basic residues (Arg-183, -184, -231, and -372' on the adjacent subunit) located at or near the binding site was replaced by Gln, and the kinetic properties of recombinant mutant enzymes were investigated. Complete desensitization to Glc-6-P was observed for R183Q, R184Q, R183Q/R184Q (double mutant), and R372Q, as was a marked decrease in the sensitivity for R231Q. The heterotropic effect of Glc-6-P on an allosteric inhibitor, l-malate, was also abolished, but sensitivity to Gly, another allosteric activator of monocot PEPC, was essentially not affected, suggesting the distinctness of their binding sites. Considering the kinetic and structural data, Arg-183 and Arg-231 were suggested to be involved directly in the binding with phosphate group of Glc-6-P, and the residues Arg-184 and Arg-372 were thought to be involved in making up the site for Glc-6-P and/or in the transmission of an allosteric regulatory signal. Most unexpectedly, the mutant enzymes had almost lost responsiveness to regulatory phosphorylation at Ser-15. An apparent lack of kinetic competition between the phosphate groups of Glc-6-P and of phospho-Ser at 15 suggested the distinctness of their binding sites. The possible roles of these Arg residues are discussed.     

Highly organized but pliant active site of DNA polymerase beta: compensatory mechanisms in mutant enzymes revealed by dynamics simulations and energy analyses

To link conformational transitions noted for DNA polymerases with kinetic results describing catalytic efficiency and fidelity, we investigate the role of key DNA polymerase beta residues on subdomain motion through simulations of five single-residue mutants: Arg-283-Ala, Tyr-271-Ala, Asp-276-Val, Arg-258-Lys, and Arg-258-Ala. Since a movement toward a closed state was only observed for R258A, we suggest that Arg(258) is crucial in modulating motion preceding chemistry. Analyses of protein/DNA interactions in the mutant active site indicate distinctive hydrogen bonding and van der Waals patterns arising from compensatory structural adjustments. By comparing closed mutant complexes with the wild-type enzyme, we interpret experimentally derived nucleotide binding affinities in molecular terms: R283A (decreased), Y271A (increased), D276V (increased), and R258A (decreased). Thus, compensatory interactions (e.g., in Y271A with adjacent residues Phe(272), Asn(279), and Arg(283)) increase the overall binding affinity for the incoming nucleotide although direct interactions may decrease. Together with energetic analyses, we predict that R258G might increase the rate of nucleotide insertion and maintain enzyme fidelity as R258A; D276L might increase the nucleotide binding affinity more than D276V; and R283A/K280A might decrease the nucleotide binding affinity and increase misinsertion more than R283A. The combined observations regarding key roles of specific residues (e.g., Arg(258)) and compensatory interactions echo the dual nature of polymerase active site, namely versatility (to accommodate various basepairs) and specificity (for preserving fidelity) and underscore an organized but pliant active site essential to enzyme function.     

Structural basis of substrate recognition in thiopurine s-methyltransferase

Thiopurine S-methyltransferase (TPMT) modulates the cytotoxic effects of thiopurine prodrugs such as 6-mercaptopurine by methylating them in a reaction using S-adenosyl- l-methionine as the donor. Patients with TPMT variant allozymes exhibit diminished levels of protein and/or enzyme activity and are at risk for thiopurine drug-induced toxicity. We have determined two crystal structures of murine TPMT, as a binary complex with the product S-adenosyl- l-homocysteine and as a ternary complex with S-adenosyl- l-homocysteine and the substrate 6-mercaptopurine, to 1.8 and 2.0 A resolution, respectively. Comparison of the structures reveals that an active site loop becomes ordered upon 6-mercaptopurine binding. The positions of the two ligands are consistent with the expected S N2 reaction mechanism. Arg147 and Arg221, the only polar amino acids near 6-mercaptopurine, are highlighted as possible participants in substrate deprotonation. To probe whether these residues are important for catalysis, point mutants were prepared in the human enzyme. Substitution of Arg152 (Arg147 in murine TPMT) with glutamic acid decreases V max and increases K m for 6-mercaptopurine but not K m for S-adenosyl- l-methionine. Substitution at this position with alanine or histidine and similar substitutions of Arg226 (Arg221 in murine TPMT) result in no effect on enzyme activity. The double mutant Arg152Ala/Arg226Ala exhibits a decreased V max and increased K m for 6-mercaptopurine. These observations suggest that either Arg152 or Arg226 may participate in some fashion in the TPMT reaction, with one residue compensating when the other is altered, and that Arg152 may interact with substrate more directly than Arg226, consistent with observations in the murine TPMT crystal structure.     

Purification and characterization of glycogen synthase from a glycogen-deficient strain of Saccharomyces cerevisiae

Chromatography of wild-type yeast extracts on DEAE-cellulose columns resolves two populations of glycogen synthase I (glucose-6-P-independent) and D (glucose-6-P-dependent) (Huang, K. P., Cabib, E. (1974) J. Biol. Chem. 249, 3851-3857). Extracts from a glycogen-deficient mutant strain, 22R1 (glc7), yielded only the D form of glycogen synthase. Glycogen synthase D purified from either wild-type yeast or from this glycogen-deficient mutant displayed two polypeptides with molecular masses of 76 and 83 kDa on sodium dodecyl sulfate-gel electrophoresis in a protein ratio of about 4:1. Phosphate analysis showed that glycogen synthase D from either strain of yeast contained approximately 3 phosphates/subunit. The 76- and 83-kDa bands of the mutant strain copurified through a variety of procedures including nondenaturing gel electrophoresis. These two polypeptides showed immunological cross-reactivity and similar peptide maps indicating that they are structurally related. The relative amounts of these two forms remained constant during purification and storage of the enzyme and after treatment with cAMP-dependent protein kinase or with protein phosphatases. The two polypeptides were phosphorylated to similar extent in vitro by the catalytic subunit of mammalian cyclic AMP-dependent protein kinase. Phosphorylation of the enzyme in the presence of labeled ATP followed by tryptic digestion and reversed phase high performance liquid chromatography yielded two labeled peptides from each of the 76- and 83-kDa subunits. Treatment of wild-type yeast with Li+ increased the glycogen synthase activity, measured in the absence of glucose-6-P, by approximately 2-fold, whereas similar treatment of the glc7 mutant had no effect. The results of this study indicate that the GLC7 gene is involved in a pathway that regulates the phosphorylation state of glycogen synthase.     

Roles of active site residues in Pseudomonas aeruginosa phosphomannomutase/phosphoglucomutase

In Pseudomonas aeruginosa, the dual-specificity enzyme phosphomannomutase/phosphoglucomutase catalyzes the transfer of a phosphoryl group from serine 108 to the hydroxyl group at the 1-position of the substrate, either mannose 6-P or glucose 6-P. The enzyme must then catalyze transfer of the phosphoryl group on the 6-position of the substrate back to the enzyme. Each phosphoryl transfer is expected to require general acid-base catalysis, provided by amino acid residues at the enzyme active site. An extensive survey of the active site residues by site-directed mutagenesis failed to identify a single key residue that mediates the proton transfers. Mutagenesis of active site residues Arg20, Lys118, Arg247, His308, and His329 to residues that do not contain ionizable groups produced proteins for which V(max) was reduced to 4-12% of that of the wild type. The fact that no single residue decreased catalytic activity more significantly, and that several residues had similar effects on V(max), suggested that the ensemble of active site amino acids act by creating positive electrostatic potential, which serves to depress the pK of the substrate hydroxyl group so that it binds in ionized form at the active site. In this way, the necessity of positioning the reactive hydroxyl group near a specific amino acid residue is avoided, which may explain how the enzyme is able to promote catalysis of both phosphoryl transfers, even though the 1- and 6-positions do not occupy precisely the same position when the substrate binds in the two different orientations in the active site. When Ser108 is mutated, the enzyme retains a surprising amount of activity, which has led to the suggestion that an alternative residue becomes phosphorylated in the absence of Ser108. (31)P NMR spectra of the S108A protein confirm that it is phosphorylated. Although the S108A/H329N protein had no detectable catalytic activity, the (31)P NMR spectra were not consistent with a phosphohistidine residue.     

Probing the mechanism of the Archaeoglobus fulgidus inositol-1-phosphate synthase

myo-Inositol-1-phosphate synthase (mIPS) catalyzes the conversion of glucose-6-phosphate (G-6-P) to inositol-1-phosphate. In the sulfate-reducing archaeon Archaeoglobus fulgidus it is a metal-dependent thermozyme that catalyzes the first step in the biosynthetic pathway of the unusual osmolyte di-myo-inositol-1,1'-phosphate. Several site-specific mutants of the archaeal mIPS were prepared and characterized to probe the details of the catalytic mechanism that was suggested by the recently solved crystal structure and by the comparison to the yeast mIPS. Six charged residues in the active site (Asp225, Lys274, Lys278, Lys306, Asp332, and Lys367) and two noncharged residues (Asn255 and Leu257) have been changed to alanine. The charged residues are located at the active site and were proposed to play binding and/or direct catalytic roles, whereas noncharged residues are likely to be involved in proper binding of the substrate. Kinetic studies showed that only N255A retains any measurable activity, whereas two other mutants, K306A and D332A, can carry out the initial oxidation of G-6-P and reduction of NAD+ to NADH. The rest of the mutant enzymes show major changes in binding of G-6-P (monitored by the 31P line width of inorganic phosphate when G-6-P is added in the presence of EDTA) or NAD+ (detected via changes in the protein intrinsic fluorescence). Characterization of these mutants provides new twists on the catalytic mechanism previously proposed for this enzyme.     

Characterization of Gac1p, a regulatory subunit of protein phosphatase type I involved in glycogen accumulation in Saccharomyces cerevisiae

GAC1 and GLC7 encode regulatory and catalytic subunits, respectively, of a type 1 phosphatase (PP1) in Saccharomyces cerevisiae that controls glycogen synthesis by regulating the phosphorylation state of glycogen synthase (Gsy2p). To investigate the role of Gac1p in this process, a set of GAC1 deletions were tested for their ability to complement a gac1 null mutation and to associate with Glc7p and with Gsy2p. The N-terminal 93 amino acids of Gaclp are necessary and sufficient for the interaction with Glc7p, whereas a region spanning residues 130-502 is required for Gsy2p binding. Both domains are required for full activity in vivo, although the Glc7p-binding domain retains some residual activity and can alter the phosphorylase a phosphatase activity of Glc7p in vitro. Further mutational analysis showed that Val71 and Phe73 of Gaclp are necessary for binding to Glc7p, while Asn356 and Tyr357 of Gaclp are necessary for binding to Gsy2p. These results suggest that Gac1p targets PPI to its substrate Gsy2p and that Gac1p may alter the catalytic activity of PP . Our data also show that overexpression of Gac1p affects glucose repression and ion homeostasis, two additional targets of GLC7, suggesting that multiple regulatory subunits compete for Glc7p binding in vivo.     

Modulation of charge in the phosphate binding site of Escherichia coli ATP synthase

This paper presents a study of the role of positive charge in the P(i) binding site of Escherichia coli ATP synthase, the enzyme responsible for ATP-driven proton extrusion and ATP synthesis by oxidative phosphorylation. Arginine residues are known to occur with high propensity in P(i) binding sites of proteins generally and in the P(i) binding site of the betaE catalytic site of ATP synthase specifically. Removal of natural betaArg-246 (betaR246A mutant) abrogates P(i) binding; restoration of P(i) binding was achieved by mutagenesis of either residue betaAsn-243 or alphaPhe-291 to Arg. Both residues are located in the P(i) binding site close to betaArg-246 in x-ray structures. Insertion of one extra Arg at beta-243 or alpha-291 in presence of betaArg-246 retained P(i) binding, but insertion of two extra Arg, at both positions simultaneously, abrogated it. Transition state stabilization was measured using phosphate analogs fluoroaluminate and fluoroscandium. Removal of betaArg-246 in betaR246A caused almost complete loss of transition state stabilization, but partial rescue was achieved in betaN243R/betaR246A and alphaF291R/betaR246A. BetaArg-243 or alphaArg-291 in presence of betaArg-246 was less effective; the combination of alphaF291R/betaN243R with natural betaArg-246 was just as detrimental as betaR246A. The data demonstrate that electrostatic interaction is an important component of initial P(i) binding in catalytic site betaE and later at the transition state complex. However, since none of the mutants showed significant function in growth tests, ATP-driven proton pumping, or ATPase activity assays, it is apparent that specific stereochemical interactions of catalytic site Arg residues are paramount.     

Identification of arginine residues important for the activity of Escherichia coli signal peptidase I

Escherichia coil signal peptidase I (leader peptidase, SPase I) is an integral membrane serine protease that catalyzes the cleavage of signal (leader) peptides from pre-forms of membrane or secretory proteins. We previously demonstrated that E. coil SPase I was significantly inactivated by reaction with phenylglyoxal with concomitant modification of three to four of the total 17 arginine residues in the enzyme. This result indicated that several arginine residues are important for the optimal activity of the enzyme. In the present study, we have constructed 17 mutants of the enzyme by site-directed mutagenesis to investigate the role of individual arginine residues in the enzyme. Mutation of Arg127, Arg146, Arg198, Arg199, Arg226, Arg236, Arg275, Arg282, and Arg295 scarcely affected the enzyme activity in vivo and in vitro. However, the enzymatic activity toward a synthetic substrate was significantly decreased by replacements of Arg77, Arg222, Arg315, or Arg318 with alanine/lysine. The kcat values of the R77A, R77K, R222A, R222K, R315A, R318A, and R318K mutant enzymes were about 5.5-fold smaller than that of the wild-type enzyme, whereas the Km values of these mutant enzymes were almost identical with that of the wild-type. Moreover, the complementing abilities in E. Arg222, Arg315, coil IT41 were lost completely when Arg77, or Arg318 was replaced with alanine/lysine. The circular dichroism spectra and other enzymatic properties of these mutants were comparable to those of the wild-type enzyme, indicating no global conformational changes. However, the thermostability of R222A, R222K, R315A, and R318K was significantly lower compared to the wild type. Therefore, Arg77, Arg222, Arg315, and Arg318 are thought to be important for maintaining the proper and stable conformation of SPase I.     

Communication between the two active sites of glutathione S-transferase A1-1, probed using wild-type-mutant heterodimers

To study the communication between the two active sites of dimeric glutathione S-transferase A1-1, we used heterodimers containing one wild-type (WT) active site and one active site with a single mutation at either Tyr9, Arg15, or Arg131. Tyr9 and Arg15 are part of the active site of the same subunit, while Arg131 contributes to the active site of the opposite subunit. The V(max) values of Tyr9 and Arg15 mutant enzymes were less than 2% that of WT, indicating their importance in catalysis. In contrast, V(max) values of Arg131 mutant enzymes were about 50-90% of that of WT enzyme while K(m)(GSH) values were approximately 3-8 times that of WT, suggesting that Arg131 plays a role in glutathione binding. The mutant enzyme (with a His(6) tag) and the WT enzyme (without a His(6) tag) were used to construct heterodimers (WT-Y9F, WT-Y9T, WT-R15Q, WT-R131M, WT-R131Q, and WT-R131E) by incubation of a mixture of wild-type and mutant enzyme at pH 7.5 in buffer containing 1,6-hexanediol, followed by dialysis against buffer lacking the organic solvent. The resultant heterodimers were separated from the wild-type and mutant homodimers using chromatography on nickel-nitrilotriacetic acid agarose. The V(max) values of all heterodimers were lower than expected for independent active sites. Our experiments demonstrate that mutation of an amino acid residue in one active site affects the activity in the other active site. Modeling studies show that key amino acid residues and water molecules connect the two active sites. This connectivity is responsible for the cross-talk between the active sites.     

The phosphate site of trehalose phosphorylase from Schizophyllum commune probed by site-directed mutagenesis and chemical rescue studies

Schizophyllum communealpha,alpha-trehalose phosphorylase utilizes a glycosyltransferase-like catalytic mechanism to convert its disaccharide substrate into alpha-d-glucose 1-phosphate and alpha-d-glucose. Recruitment of phosphate by the free enzyme induces alpha,alpha-trehalose binding recognition and promotes the catalytic steps. Like the structurally related glycogen phosphorylase and other retaining glycosyltransferases of fold family GT-B, the trehalose phosphorylase contains an Arg507-XXXX-Lys512 consensus motif (where X is any amino acid) comprising key residues of its putative phosphate-binding sub-site. Loss of wild-type catalytic efficiency for reaction with phosphate (kcat/Km=21,000 m(-1).s(-1)) was dramatic (>or=10(7)-fold) in purified Arg507-->Ala (R507A) and Lys512-->Ala (K512A) enzymes, reflecting a corresponding change of comparable magnitude in kcat (Arg507) and Km (Lys512). External amine and guanidine derivatives selectively enhanced the activity of the K512A mutant and the R507A mutant respectively. Analysis of the pH dependence of chemical rescue of the K512A mutant by propargylamine suggested that unprotonated amine in combination with H2PO4-, the protonic form of phosphate presumably utilized in enzymatic catalysis, caused restoration of activity. Transition state-like inhibition of the wild-type enzyme A by vanadate in combination with alpha,alpha-trehalose (Ki=0.4 microm) was completely disrupted in the R507A mutant but only weakened in the K512A mutant (Ki=300 microm). Phosphate (50 mm) enhanced the basal hydrolase activity of the K512A mutant toward alpha,alpha-trehalose by 60% but caused its total suppression in wild-type and R507A enzymes. The results portray differential roles for the side chains of Lys512 and Arg507 in trehalose phosphorylase catalysis, reactant state binding of phosphate and selective stabilization of the transition state respectively.     

Parallel analysis of mutant human glucose 6-phosphate dehydrogenase in yeast using PCR colonies

We demonstrate a highly parallel strategy to analyze the impact of single nucleotide mutations on protein function. Using our method, it is possible to screen a population and quickly identify a subset of functionally interesting mutants. Our method utilizes a combination of yeast functional complementation, growth competition of mutant pools, and polymerase colonies. A defined mutant human glucose-6-phosphate-dehydrogenase library was constructed which contains all possible single nucleotide missense mutations in the eight-residue glucose-6-phosphate binding peptide of the enzyme. Mutant human enzymes were expressed in a zwf1 (gene encoding yeast homologue) deletion strain of Saccharomyces cerevisiae. Growth rates of the 54 mutant strains arising from this library were measured in parallel in conditions selective for active hG6PD. Several residues were identified which tolerated no mutations (Asp200, His201 and Lys205) and two (Ile199 and Leu203) tolerated several substitutions. Arg198, Tyr202, and Gly204 tolerated only 1-2 specific substitutions. Generalizing from the positions of tolerated and non-tolerated amino acid substitutions, hypotheses were generated about the functional role of specific residues, which could, potentially, be tested using higher resolution/lower throughput methods.     

Isomerase activity of the C-terminal fructose-6-phosphate binding domain of glucosamine-6-phosphate synthase from Escherichia coli

The isomerase activity of the C-terminal fructose-6P binding domain (residues 241-608) of glucosamine-6-phosphate synthase from Escherichia coli has been studied. The equilibrium constant of the C-terminal domain k(eq) ([glucose-6P]/[fructose-6-P]) = 5.0. A non-competitive product inhibition of the isomerase activity by the reaction product glucose-6-P has been detected. The existence of more than one binding and reaction sites for the substrate fructose-6P on the molecule of glucosamine-6-phosphate synthase can be expected. The fructose-6P binding domain possibly includes a regulatory site, different from the catalytic center of the enzyme.