A-type ATP binding consensus sequences are critical for the catalytic activity of the calmodulin-sensitive adenylyl cyclase from Bacillus anthracis

Analysis of the predicted amino acid sequence of Bacillus anthracis adenylyl cyclase revealed sequences with homology to consensus sequences for A- and B-type ATP binding domains found in many ATP binding proteins. Based on the analysis of nucleotide binding proteins, a conserved basic amino acid residue in the A-type consensus sequence and a conserved acidic amino acid residue in the B-type consensus sequence have been implicated in the binding of ATP. The putative ATP binding sequences in the B. anthracis adenylyl cyclase possess analogous lysine residues at positions 346 and 353 within two A-type consensus sequences and a glutamate residue at position 436 within a B-type consensus sequence. The two A-type consensus sequences overlap each other and have the opposite orientation. To determine whether Lys-346, Lys-353, or Glu-436 of the B. anthracis adenylyl cyclase are crucial for enzyme activity, Lys-346 and Lys-353 were replaced with methionine and Glu-436 with glutamine by oligonucleotide-directed mutagenesis. Furthermore, Lys-346 was also replaced with arginine. The genes encoding the wild type and mutant adenylyl cyclases were placed under the control of the lac promoter for expression in Escherichia coli, and extracts were assayed for adenylyl cyclase activity. In all cases, a 90-kDa polypeptide corresponding to the catalytic subunit of the enzyme was detected in E. coli extracts by rabbit polyclonal antibodies raised against the purified B. anthracis adenylyl cyclase. The proteins with the Lys-346 to methionine or arginine mutations exhibited no adenylyl cyclase activity, indicating that Lys-346 in the A-type ATP binding consensus sequence plays a critical role for enzyme catalysis. Furthermore, the enzyme with the Lys-353 to methionine mutation was also inactive, suggesting that Lys-353 may also directly contribute to enzyme catalysis. In contrast, the protein with the Glu-436 to glutamine mutation retained 75% of enzyme activity, suggesting that Glu-436 in the B-type ATP binding consensus sequence may not be directly involved in enzyme catalysis. It is concluded that Lys-346 and Lys-353 in B. anthracis adenylyl cyclase may interact directly with ATP and contribute to the binding of the nucleotide to the enzyme.     

Important amino acids in the phosphohydrolase module of Escherichia coli Orf135

The Escherichia coli Orf135 protein, a MutT-type enzyme, hydrolyzes 2-hydroxy-dATP and 8-hydroxy-dGTP, in addition to dCTP and 5-methyl-dCTP, and its deficiency causes increases in both the spontaneous and H(2)O(2)-induced mutation frequencies. In this study, the Gly-36, Gly-37, Lys-38, Glu-43, Arg-51, Glu-52, Leu-53, Glu-55, and Glu-56 residues of Orf135, which are conserved in the three MutT-type proteins (Orf135, MutT, and MTH1), were substituted, and the enzymatic activity of these mutant proteins was examined. The mutant proteins with a substitution at the 36th, 37th, 52nd, and 56th amino acid residues completely lost their activity. On the other hand, the mutant proteins with a substitution at the 38th, 43rd, 51st, 53rd, and 55th residues could hydrolyze 5-methyl-dCTP. Some mutants with detectable activity for 5-methyl-dCTP did not hydrolyze dCTP. Activities for known substrates (5-methyl-dCTP, dCTP, 2-hydroxy-dATP, and 8-hydroxy-dGTP) were examined in detail with the four mutants, K38R, E43A, L53A, and E55Q. These results indicate the essential residues for the activity of the Orf135 protein.     

Identification of active-site residues in Bradyrhizobium japonicum malonyl-coenzyme A synthetase

Malonyl-CoA synthetase (MCS) has been previously purified and characterized from Bradyrhizobium japonicum USDA 110. The gene encoding this enzyme is now cloned, sequenced, and expressed in Escherichia coli. The enzyme contains 509 amino acid residues, with a calculated molecular mass of 55,239 Da. The recombinant enzyme was also purified from the transformed E. coli. The enzyme was essentially indistinguishable from the MCS of B. japonicum by the criteria of polyacrylamide gel electrophoresis and biochemical properties. Based on inhibitor studies of Rhizobium trifolii MCS reported previously and database analysis, Arg173, Lys175, His211, and Glu308 were selected for site-directed mutagenesis in order to identify amino acid residues essential for substrate binding and/or catalysis. Five different mutant enzymes (R173G, K175M, H211L, K175M/H211L, and E308Q) were prepared and then subjected to steady-state kinetic studies. The kinetic data measured for the mutants suggest that Lys175 and His211 participate in the formation of malonyl-AMP, whereas Glu308 may play a role in malonate binding.     

Movement of the biotin carboxylase B-domain as a result of ATP binding

Acetyl-CoA carboxylase catalyzes the first committed step in fatty acid synthesis. In Escherichia coli, the enzyme is composed of three distinct protein components: biotin carboxylase, biotin carboxyl carrier protein, and carboxyltransferase. The biotin carboxylase component has served for many years as a paradigm for mechanistic studies devoted toward understanding more complicated biotin-dependent carboxylases. The three-dimensional x-ray structure of an unliganded form of E. coli biotin carboxylase was originally solved in 1994 to 2.4-A resolution. This study revealed the architecture of the enzyme and demonstrated that the protein belongs to the ATP-grasp superfamily. Here we describe the three-dimensional structure of the E. coli biotin carboxylase complexed with ATP and determined to 2.5-A resolution. The major conformational change that occurs upon nucleotide binding is a rotation of approximately 45(o) of one domain relative to the other domains thereby closing off the active site pocket. Key residues involved in binding the nucleotide to the protein include Lys-116, His-236, and Glu-201. The backbone amide groups of Gly-165 and Gly-166 participate in hydrogen bonding interactions with the phosphoryl oxygens of the nucleotide. A comparison of this closed form of biotin carboxylase with carbamoyl-phosphate synthetase is presented.     

Specific amino acid residues in both the PstB and PstC proteins are required for phosphate transport by the Escherichia coli Pst system.

Three mutant alleles of the pstC gene and one mutant allele of the pstB gene were produced by site-directed mutagenesis. The pstC gene encodes an integral membrane protein of the phosphate-specific transport (Pst) system of Escherichia coli. The amino acid substitutions resulting from the pstC gene mutations, Arg-237----Gln, Glu-240----Gln, or a combination of both, caused the loss of phosphate transport through the Pst system, but the alkaline phosphatase activity remained repressed. The pstB gene encodes a peripheral membrane protein of the Pst system which carries a putative nucleotide-binding site. The amino acid substitutions Gly-48----Ile and Lys-49----Gln, resulting from the pstB mutations, caused the loss of phosphate transport through the Pst system and the derepression of alkaline phosphatase activity. The residues Gly-48 and Lys-49 are key residues in the putative nucleotide-binding site.     

Glucose phosphorylation. Site-directed mutations which impair the catalytic function of hexokinase

Recent studies from this and other laboratories have resulted in the cloning and sequencing of hexokinases from a variety of tissues including yeast, human kidney, rat brain, rat liver, and mouse hepatoma. Significantly, studies on the hepatoma enzyme conducted in this laboratory (Arora, K.K., Fanciulli, M., and Pedersen, P.L. (1990) J. Biol. Chem. 265, 6481-6488) resulted also in its overexpression in Escherichia coli in active form. We have now used site-directed mutagenesis for the first time in studies of hexokinase to evaluate the role of amino acid residues predicted to interact with either glucose or ATP. Four amino acid residues (Ser-603, Asp-657, Glu-708, and Glu-742) believed to interact with glucose were mutated to alanine or glycine, whereas a lysine residue (Lys-558) thought to be directly involved in binding ATP was mutated to either methionine or arginine. Of all the mutations in residues believed to interact with glucose, the Asp-657----Ala mutation is the most profound, reducing the hexokinase activity to a level less than 1% of the wild type. The relative Vmax values for Ser-603----Ala, Glu-708----Ala, and Glu-742----Ala enzymes are 6, 10, and 6.5%, respectively, of the wild-type enzyme. Glu-708 and Glu-742 mutations increase the apparent Km for glucose 50- and 14-fold, respectively, while the Ser-603----Ala mutation decreases the apparent Km for glucose 5-fold. At the putative ATP binding site, the relative Vmax for Lys-558----Arg and Lys-558----Met enzymes are 70 and 29%, respectively, of the wild-type enzyme with no changes in the apparent Km for glucose. No changes were observed in the apparent Km for ATP with any mutation. These results support the view that all 4 residues predicted to interact with glucose from earlier x-ray studies may play a role in binding and/or catalysis. The Asp-657 and Ser-603 residues may be involved in both, while Glu-708 and Glu-742 clearly contribute to binding but are not essential for catalysis. In contrast, Lys-558 appears to be essential neither for binding nor catalysis.     

Charged amino acids of the N-terminal domain are involved in coupling binding and gating in alpha7 nicotinic receptors

Binding of agonists to nicotinic acetylcholine receptors generates a sequence of conformational changes resulting in channel opening. Previously, we have shown that the aspartate residue Asp-266 at the M2-M3 linker of the alpha7 nicotinic receptor is involved in connecting binding and gating. High resolution structural data suggest that this region could interact with the so-called loops 2 and 7 of the extracellular N-terminal region. In this case, certain charged amino acids present in these loops could integrate together with Asp-266 and other amino acids, a mechanism involved in channel activation. To test this hypothesis, all charged residues in these loops, Asp-42, Asp-44, Glu-45, Lys-46, Asp-128, Arg-130, and Asp-135, were substituted with other amino acids, and expression levels and electrophysiological responses of mutant receptors were determined. Mutants at positions Glu-45, Lys-46, and Asp-135 exhibited poor or null functional responses to different nicotinic agonists regardless of significant membrane expression, whereas D128A showed a gain of function effect. Because the double reverse charge mutant K46D/D266K did not restore receptor function, a gating mechanism controlled by the pairwise electrostatic interaction between these residues is not likely. Rather, a network of interactions formed by residues Lys-46, Asp-128, Asp-135, Asp-266, and possibly others appears to link agonist binding to channel gating.     

Site-directed mutagenesis reveals the essentiality of the conserved residues in the putative diiron active site of the trypanosome alternative oxidase.

Trypanosoma brucei possesses a non-cytochrome, salicylhydroxamic acid (SHAM)-sensitive ubiquinol:oxygen oxidoreductase known as trypanosome alternative oxidase (TAO). TAO and similar SHAM-sensitive alternative oxidases (AOXs) contain 2-3 conserved diiron-binding motifs (EXXH). Site-directed mutagenesis of residues H165A, E214A, E266A, and H269L within the conserved EXXH motif abolished the ability of TAO to complement the heme-deficient Escherichia coli strain GE1387. These mutations also reduced the growth of this E. coli auxotroph to about 85% of the control cells containing wild type TAO. In contrast, mutation of residues outside the EXXH motifs, e.g. V205A, L243A, C261A, and V271A, had little effect on complementation, and the reduction in the cell growth was about 5-10%. Mutations of the putative iron-binding residues within the EXXH motifs of TAO abolished the ability to confer SHAM-sensitive respiration to E. coli heme mutant, whereas mutations of the non-conserved/non-iron binding residues resulted in 20-30% reduction of SHAM-sensitive respiration of the E. coli auxotroph. Immunoblot analysis of the total cellular protein of transformed E. coli revealed that the expression level of mutated and wild type TAO (35 kDa) remained unaltered. Mutation at C261A produced a truncated but functional protein of 28 kDa. The addition of ortho-phenanthroline to the growth medium produces a non-functional TAO. The effect of ortho-phenanthroline on the activity of TAO was completely alleviated by the addition of iron in the medium, which suggests that iron is needed for the activity of TAO. This work demonstrates that His-165, Glu-214, Glu-266, and His-269 and the presence of iron are essential for the activity of TAO.     

Site-directed mutagenesis of Petunia hybrida 5-enolpyruvylshikimate-3-phosphate synthase: Lys-23 is essential for substrate binding

Chemical modification of Escherichia coli 5-enolpyruvylshikimate-3-phosphate synthase, a target for the nonselective herbicide glyphosate (N-phosphonomethylglycine), with pyridoxal 5'-phosphate suggested that Lys-22 (equivalent to Lys-23 of the Petunia hybrida enzyme) is a potential active site residue (Huynh, Q. K., Kishore, G. M., and Bild, G. S. (1988) J. Biol. Chem. 263, 735-739). To investigate the possible role of this residue in the reaction mechanism, we have used site-directed mutagenesis to replace Lys-23 of the P. hybrida enzyme with 3 other amino acid residues: Ala, Glu, and Arg. Analysis of these mutant enzymes indicates that of these only the Lys-23 to Arg mutant enzyme is active; the other two replacements (Ala and Glu) result in inactivation of the enzyme. Two of the mutant enzymes (Lys-23 to Arg and Ala) were purified to homogeneity and characterized. The purified Lys-23 to Arg mutant enzyme is less sensitive than the wild type enzyme to pyridoxal 5'-phosphate. It showed identical Km values for substrates and a 5-fold higher I50 value for glyphosate in comparison with those from the wild type enzyme. Binding studies using fluorescence measurements revealed that the substrate shikimate 3-phosphate and glyphosate were able to bind the purified Lys-23 to Arg mutant enzyme but not to the purified catalytically inactive Lys-23 to Ala mutant enzyme. The above results suggest that the cationic group at position 23 of the enzyme may play an important role in substrate binding.     

Identification of catalytic residues of Ca2+-independent 1,2-alpha-D-mannosidase from Aspergillus saitoi by site-directed mutagenesis

The roles of six conserved active carboxylic acids in the catalytic mechanism of Aspergillus saitoi 1,2-alpha-d-mannosidase were studied by site-directed mutagenesis and kinetic analyses. We estimate that Glu-124 is a catalytic residue based on the drastic decrease of kcat values of the E124Q and E124D mutant enzyme. Glu-124 may work as an acid catalyst, since the pH dependence of its mutants affected the basic limb. D269N and E411Q were catalytically inactive, while D269E and E411D showed considerable activity. This indicated that the negative charges at these points are essential for the enzymatic activity and that none of these residues can be a base catalyst in the normal sense. Km values of E273D, E414D, and E474D mutants were greatly increased to 17-31-fold wild type enzyme, and the kcat values were decreased, suggesting that each of them is a binding site of the substrate. Ca2+, essential for the mammalian and yeast enzymes, is not required for the enzymatic activity of A. saitoi 1,2-alpha-d-mannosidase. EDTA inhibits the Ca2+-free 1,2-alpha-d-mannosidase as a competitive inhibitor, not as a chelator. We deduce that the Glu-124 residue of A. saitoi 1,2-alpha-d-mannosidase is directly involved in the catalytic mechanism as an acid catalyst, whereas no usual catalytic base is directly involved. Ca2+ is not essential for the activity. The catalytic mechanism of 1,2-alpha-d-mannosidase may deviate from that typical glycosyl hydrolase.     

Mutational analysis of the glycine-rich region of the c subunit of the Escherichia coli F0F1 ATPase.

Eight strains carrying amino acid substitutions within the c subunit of the F0F1 ATPase of Escherichia coli have been constructed by using site-directed mutagenesis. Three strains carrying the substitutions Gly-23----Leu, Ala-24----Leu, and Gly-38----Leu, which reside in or near the highly conserved glycine-rich region of the c subunit, are unable to carry out oxidative phosphorylation. Membranes prepared from these strains possess basal levels of ATPase activity. In contrast, strains carrying the substitutions Ile-30----Phe, Gly-33----Leu, Gly-58----Leu, and Lys-34----Val and the Lys-34----Val, Glu-37----Gln double substitution were found to possess a coupled phenotype similar to that of the wild type.     

Role of the carboxyl terminal region of H(+)-ATPase (F0F1) a subunit from Escherichia coli.

The effects of amino acid substitutions in the carboxyl terminal region of the H(+)-ATPase a subunit (271 amino acid residues) of Escherichia coli were studied using a defined expression system for uncB genes coded by recombinant plasmids. The a subunits with the mutations, Tyr-263----end, Trp-231----end, Glu-219----Gln, and Arg-210----Lys (or Gln) were fully defective in ATP-dependent proton translocation, and those with Gln-252----Glu (or Leu), His-245----Glu, Pro-230----Leu, and Glu-219----His were partially defective. On the other hand, the phenotypes of the Glu-269----end, Ser-265----Ala (or end), and Tyr-263----Phe mutants were essentially similar to that of the wild-type. These results suggested that seven amino acid residues between Ser-265 and the carboxyl terminus were not required for the functional proton pathway but that all the other residues except Arg-210, Glu-219, and His-245 were required for maintaining the correct conformation of the proton pathway. The results were consistent with a report that Arg-210 is directly involved in proton translocation.     

Amino acids of the bacterial toxin SopE involved in G nucleotide exchange on Cdc42

RhoGTPases are central switches in all eukaryotic cells. There are at least two known families of guanine nucleotide exchange factors that can activate RhoGTPases: the Dbl-like eukaryotic G nucleotide exchange factors and the SopE-like toxins of pathogenic bacteria, which are injected into host cells to manipulate signaling. Both families have strikingly different sequences, structures, and catalytic core elements. This suggests that they have emerged by convergent evolution. Nevertheless, both families of G nucleotide exchange factors also share some similarities: (a) both rearrange the G nucleotide binding site of RhoGTPases into virtually identical conformations, and (b) two SopE residues (Gln-109SopE and Asp-124SopE) engage Cdc42 in a similar way as equivalent residues of Dbl-like G nucleotide exchange factors (i.e. Asn-810Dbs and Glu-639Dbs). The functional importance of these observations has remained unclear. Here, we have analyzed the effect of amino acid substitutions at selected SopE residues implicated in catalysis (Asp-124SopE, Gln-109SopE, Asp-103SopE, Lys-198SopE, and Gly-168SopE) on in vitro catalysis of G nucleotide release from Cdc42 and on in vivo activity. Substitutions at Asp-124SopE, Gln-109SopE, and Gly-168SopE severely reduced the SopE activity. Slight defects were observed with Asp-103SopE variants, whereas Lys-198SopE was not found to be required in vitro or in vivo. Our results demonstrate that G nucleotide exchange by SopE involves both catalytic elements unique to the SopE family (i.e. 166GAGA169 loop, Asp-103SopE) and amino acid contacts resembling those of key residues of Dbl-like guanine nucleotide exchange factors. Therefore, besides all of the differences, the catalytic mechanisms of the SopE and the Dbl families share some key functional aspects.     

Identification of amino acid residues essential for the catalytic reaction of Bacillus kaustophilus leucine aminopeptidase

The functional significance of amino acid residues Lys-265, Asp-270, Lys-277, Asp-288, Asp-347, Glu-349, and Arg-351 of Bacillus kaustophilus leucine aminopeptidase was explored by site-directed mutagenesis. Variants with an apparent molecular mass of approximately 54 kDa were overexpressed in Escherichia coli and purified to homogeneity by nickel-chelate chromatography. The purified mutant enzymes had no LAP activity, implying that these residues are important for the catalytic reaction of the enzyme.     

Identification of amino acid residues critical for biological activity in human interleukin-18

Interleukin-18 (IL-18) is a pro-inflammatory cytokine, and IL-18-binding protein (IL-18BP) is a naturally occurring protein that binds IL-18 and neutralizes its biological activities. Computer modeling of human IL-18 identified two charged residues, Glu-42 and Lys-89, which interact with oppositely charged amino acid residues buried in a large hydrophobic pocket of IL-18BP. The cell surface IL-18 receptor alpha chain competes with IL-18BP for IL-18 binding, although the IL-18 receptor alpha chain does not share significant homology to IL-18BP. In the present study, Glu-42 was mutated to Lys and Lys-89 to Glu; Glu-42 and Lys-89 were also deleted separately. The deletion mutants (E42X and K89X) were devoid of biological activity, and the K89E mutant lost 95% of its activity. In contrast, compared with wild-type (WT) IL-18, the E42K mutant exhibited a 2-fold increase in biological activity and required a 4-fold greater concentration of IL-18BP for neutralization. The binding of WT IL-18 and its various mutants to human natural killer cells was evaluated by competition assays. The mutant E42K was more effective than WT IL-18 in inhibiting the binding of (125)I-IL-18 to natural killer cells, whereas the three inactive mutants E42X, K89E, and K89X were unable to compete with (125)I-IL-18 for binding. Similarly, WT IL-18 and the E42K mutant induced degradation of Ikappa-Balpha, whereas the three biologically inactive mutants did not induce degradation. The present study reveals that Glu-42 and Lys-89 are critical amino acid residues for the integrity of IL-18 structure and are important for binding to cell surface receptors, for signal transduction, and for neutralization by IL-18BP.     

Deconstruction of the catalytic array within the amidotransferase subunit of carbamoyl phosphate synthetase

Carbamoyl phosphate synthetase from Escherichia coli catalyzes the formation of carbamoyl phosphate from bicarbonate, glutamine, and two molecules of ATP. The enzyme consists of a large synthetase subunit, and a small amidotransferase subunit, which belongs to the Triad family of glutamine amidotransferases. Previous studies have established that the reaction mechanism of the small subunit proceeds through the formation of a gamma-glutamyl thioester with Cys-269. The roles in the hydrolysis of glutamine played by the conserved residues, Glu-355, Ser-47, Lys-202, and Gln-273, were determined by mutagenesis. In the X-ray crystal structure of the H353N mutant, Ser-47 and Gln-273 interact with the gamma-glutamyl thioester intermediate [Thoden, J. B., Miran, S. G., Phillips, J. C., Howard, A. J., Raushel, F. M., and Holden, H. M. (1998) Biochemistry 37, 8825-8831]. The mutants E355D and E355A have elevated values of K(m) for glutamine, but the overall carbamoyl phosphate synthesis reaction is unperturbed. E355Q does not significantly affect the bicarbonate-dependent ATPase or glutaminase partial reactions. However, this mutation almost completely uncouples the two partial reactions such that no carbamoyl phosphate is produced. The partial recovery of carbamoyl phosphate synthesis activity in the double mutant E355Q/K202M argues that the loss of activity in E355Q is at least partly due to additional interactions between Gln-355 and Lys-202 in E355Q. The mutants S47A and Q273A have elevated K(m) values for glutamine while the V(max) values are comparable to that of the wild-type enzyme. It is concluded that contrary to the original proposal for the catalytic triad, Glu-355 is not an essential residue for catalysis. The results are consistent with Ser-47 and Gln-273 playing significant roles in the binding of glutamine.     

Site-directed alteration of the active-site residues of histidine decarboxylase from Clostridium perfringens

To clarify the mechanism of biogenesis and catalysis by the pyruvoyl-dependent histidine decarboxylase (HisDCase) from Clostridium perfringens, 12 mutant genes encoding amino acid substitutions at the active site of this enzyme were constructed and expressed in Escherichia coli. The resulting mutant proteins were purified to homogeneity, characterized, and subjected to kinetic analysis. The results (a) exclude all polar amino acid residues in the active site except Glu-214 as donor of the proton that replaces the carboxyl group of histidine during decarboxylation and, since E214I and E214H are nearly inactive, indicate that Glu-214 is the essential proton donor; (b) demonstrate the importance to substrate binding of hydrophobic interactions between Phe-98, Ile-74, and the imidazole ring of histidine, and of hydrogen bonding between Asp-78 and N2 of the substrate; and (c) demonstrate a significant unidentified role for Glu-81 in the maintenance of the active-site structure. The proposed roles of these amino acid residues are consistent with those assigned on the basis of crystallographic evidence to the corresponding residues at the active site of the related HisDCase from Lactobacillus 30a [Gallagher, T., Snell, E. E., & Hackert, M. L. (1989) J. Biol. Chem. 264, 12737-12743]. Of the residues altered, only Ser-97 was essential for the autocatalytic serinolysis reaction by which this HisDCase, (alpha beta)6, is derived from its inactive, pyruvate-free precursor, proHisDCase, pi 6.(ABSTRACT TRUNCATED AT 250 WORDS)     

Structure of a fructose-1,6-bis(phosphate) aldolase liganded to its natural substrate in a cleavage-defective mutant at 2.3 A(,).

Class I fructose-1,6-bis(phosphate) aldolase is a glycolytic enzyme that catalyzes the cleavage of fructose 1,6-bis(phosphate) through a covalent Schiff base intermediate. Although the atomic structure of this enzyme is known, assigning catalytic roles to the various enzymic active-site residues has been hampered by the lack of a structure for the enzyme-substrate complex. A mutant aldolase, K146A, is unable to cleave the C3-C4 bond of the hexose while retaining the ability to form the covalent intermediate, although at a greatly diminished rate. The structure of rabbit muscle K146A-aldolase A, in complex with its native substrate, fructose 1,6-bis(phosphate), is determined to 2.3 A resolution by molecular replacement. The density at the hexose binding site differs between subunits of the tetramer, in that two sites show greater occupancy relative to the other two. The hexose is bound in its linear, open conformation, but not covalently linked to the Schiff base-forming Lys-229. Therefore, this structure most likely represents the bound complex of hexose just after hemiketal hydrolysis and prior to Schiff base formation. The C1-phosphate binding site involves the three backbone nitrogens of Ser-271, Gly-272, and Gly-302, and the epsilon-amino group of Lys-229. This is the same binding site previously found for the analogous phosphate of the product DHAP. The C6-phosphate binding site involves three basic side chains, Arg-303, Arg-42, and Lys-41. The residues closest to Lys-229 were relatively unchanged in position when compared to the unbound wild-type structure. The major differences between the bound and unbound enzyme structures were observed in the positions of Lys-107, Arg-303, and Arg-42, with the greatest difference in the change in conformation of Arg-303. Site-directed mutagenesis was performed on those residues with different conformations in bound versus unbound enzyme. The kinetic constants of these mutant enzymes with the substrates fructose 1, 6-bis(phosphate) and fructose 1-phosphate are consistent with their ligand interactions as revealed by the structure reported here, including differing effects on k(cat) and K(m) between the two substrates depending on whether the mutations affect C6-phosphate binding. In the unbound state, Arg-303 forms a salt bridge with Glu-34, and in the liganded structure it interacts closely with the substrate C6-phosphate. The position of the sugar in the binding site would require a large movement prior to achieving the proper position for covalent catalysis with the Schiff base-forming Lys-229. The movement most likely involves a change in the location of the more loosely bound C6-phosphate. This result suggests that the substrate has one position in the Michaelis complex and another in the covalent complex. Such movement could trigger conformational changes in the carboxyl-terminal region, which has been implicated in substrate specificity.     

A double residue substitution in the coenzyme-binding site accounts for the different kinetic properties between yeast and human formaldehyde dehydrogenases

Glutathione-dependent formaldehyde dehydrogenase (FALDH) is the main enzymatic system for formaldehyde detoxification in all eukaryotic and many prokaryotic organisms. The enzyme of yeasts and some bacteria exhibits about 10-fold higher k(cat) and K(m) values than those of the enzyme from animals and plants. Typically Thr-269 and Glu-267 are found in the coenzyme-binding site of yeast FALDH, but Ile-269 and Asp-267 are present in the FALDH of animals. By site-directed mutagenesis we have prepared the T269I and the D267E mutants and the D267E/T269I double mutant of Saccharomyces cerevisiae FALDH with the aim of investigating the role of these residues in the kinetics. The T269I and the D267E mutants have identical kinetic properties as compared with the wild-type enzyme, although T269I is highly unstable. In contrast, the D267E/T269I double mutant is stable and shows low K(m) (2.5 microM) and low k(cat) (285 min(-1)) values with S-hydroxymethylglutathione, similar to those of the human enzyme. Therefore, the simultaneous exchange at both residues is the structural basis of the two distinct FALDH kinetic types. The local structural perturbations imposed by the substitutions are suggested by molecular modeling studies. Finally, we have studied the effect of FALDH deletion and overexpression on the growth of S. cerevisiae. It is concluded that the FALDH gene is not essential but enhances the resistance against formaldehyde (0.3-1 mM). Moreover, the wild-type enzyme (with high k(cat) and K(m)) provides more resistance than the double mutant (with low k(cat) and K(m)).     

Mutational, kinetic, and NMR studies of the roles of conserved glutamate residues and of lysine-39 in the mechanism of the MutT pyrophosphohydrolase

The MutT enzyme catalyzes the hydrolysis of nucleoside triphosphates (NTP) to NMP and PP(i) by nucleophilic substitution at the rarely attacked beta-phosphorus. The solution structure of the quaternary E-M(2+)-AMPCPP-M(2+) complex indicated that conserved residues Glu-53, -56, -57, and -98 are at the active site near the bound divalent cation possibly serving as metal ligands, Lys-39 is positioned to promote departure of the NMP leaving group, and Glu-44 precedes helix I (residues 47-59) possibly stabilizing this helix which contributes four catalytic residues to the active site [Lin, J. , Abeygunawardana, C., Frick, D. N., Bessman, M. J., and Mildvan, A. S. (1997) Biochemistry 36, 1199-1211]. To test these proposed roles, the effects of mutations of each of these residues on the kinetic parameters and on the Mn(2+), Mg(2+), and substrate binding properties were examined. The largest decreases in k(cat) for the Mg(2+)-activated enzyme of 10(4.7)- and 10(2.6)-fold were observed for the E53Q and E53D mutants, respectively, while 97-, 48-, 25-, and 14-fold decreases were observed for the E44D, E56D, E56Q, and E44Q mutations, respectively. Smaller effects on k(cat) were observed for mutations of Glu-98 and Lys-39. For wild type MutT and its E53D and E44D mutants, plots of log(k(cat)) versus pH exhibited a limiting slope of 1 on the ascending limb and then a hump, i.e., a sharply defined maximum near pH 8 followed by a plateau, yielding apparent pK(a) values of 7.6 +/- 0.3 and 8.4 +/- 0.4 for an essential base and a nonessential acid catalyst, respectively, in the active quaternary MutT-Mg(2+)-dGTP-Mg(2+) complex. The pK(a) of 7.6 is assigned to Glu-53, functioning as a base catalyst in the active quaternary complex, on the basis of the disappearance of the ascending limb of the pH-rate profile of the E53Q mutant, and its restoration in the E53D mutant with a 10(1.9)-fold increase in (k(cat))(max). The pK(a) of 8.4 is assigned to Lys-39 on the basis of the disappearance of the descending limb of the pH-rate profile of the K39Q mutant, and the observation that removal of the positive charge of Lys-39, by either deprotonation or mutation, results in the same 8.7-fold decrease in k(cat). Values of k(cat) of both wild type MutT and the E53Q mutant were independent of solvent viscosity, indicating that a chemical step is likely to be rate-limiting with both. A liganding role for Glu-53 and Glu-56, but not Glu-98, in the binary E-M(2+) complex is indicated by the observation that the E53Q, E53D, E56Q, and E56D mutants bound Mn(2+) at the active site 36-, 27-, 4.7-, and 1.9-fold weaker, and exhibited 2.10-, 1.50-, 1.12-, and 1.24-fold lower enhanced paramagnetic effects of Mn(2+), respectively, than the wild type enzyme as detected by 1/T(1) values of water protons, consistent with the loss of a metal ligand. However, the K(m) values of Mg(2+) and Mn(2+) indicate that Glu-56, and to a lesser degree Glu-98, contribute to metal binding in the active quaternary complex. Mutations of the more distant but conserved residue Glu-44 had little effect on metal binding or enhancement factors in the binary E-M(2+) complexes. Two-dimensional (1)H-(15)N HSQC and three-dimensional (1)H-(15)N NOESY-HSQC spectra of the kinetically damaged E53Q and E56Q mutants showed largely intact proteins with structural changes near the mutated residues. Structural changes in the kinetically more damaged E44D mutant detected in (1)H-(15)N HSQC spectra were largely limited to the loop I-helix I motif, suggesting that Glu-44 stabilizes the active site region. (1)H-(15)N HSQC titrations of the E53Q, E56Q, and E44D mutants with dGTP showed changes in chemical shifts of residues lining the active site cleft, and revealed tighter nucleotide binding by these mutants, indicating an intact substrate binding site. (ABSTRACT TRUNCATED)