Homology of Escherichia coli B glutathione synthetase with dihydrofolate reductase in amino acid sequence and substrate binding site

Glutathione synthetase from Escherichia coli B showed amino acid sequence homology with mammalian and bacterial dihydrofolate reductases over 40 residues, although these two enzymes are different in their reaction mechanisms and ligand requirements. The effects of ligands of dihydrofolate reductase on the reaction of E. coli B glutathione synthetase were examined to find resemblances in catalytic function to dihydrofolate reductase. The E. coli B enzyme was potently inhibited by 7,8-dihydrofolate, methotrexate, and trimethoprim. Methotrexate was studied in detail and proved to bind to an ATP binding site of the E. coli B enzyme with K1 value of 0.1 mM. The homologous portion of the amino acid sequence in dihydrofolate reductases, which corresponds to the portion coded by exon 3 of mammalian dihydrofolate reductase genes, provided a binding site of the adenosine diphosphate moiety of NADPH in the crystal structure of dihydrofolate reductase. These analyses would indicate that the homologous portion of the amino acid sequence of the E. coli B enzyme provides the ATP binding site. This report gives experimental evidence that amino acid sequences related by sequence homology conserve functional similarity even in enzymes which differ in their catalytic mechanisms.     

Fluorescent probes for measuring the binding constants and distances between the metal ions bound to Escherichia coli glutamine synthetase.

TNS, 2-p-toluidinylnaphthalene-6-sulfonate, has been used as a fluorescent probe to determine the binding constants of metal ions to the two binding sites of Escherichia coli glutamine synthetase (GS). TNS fluorescence is enhanced dramatically when bound to proteins due to its high quantum yield resulting from its interactions with hydrophobic regions in proteins. The fluorescence energy transfer from a hydrophobic tryptophan residue of GS to TNS has been detected as an excitation band centered at 280 nm. Therefore, TNS is believed to be bound to a hydrophobic site on the GS surface other than the active site and is located near a hydrophobic Trp residue of GS. GS binds lanthanide ions [Ln(III)] more tightly than either Mn(II) or Mg(II), and the binding constants of several lanthanide ions were determined to be in the range (2.1-4.6) x 10(10) and (1.4-3.0) x 10(8) M-1 to the two metal binding sites of GS, respectively. The intermetal distances between the two metal binding sites of GS were also determined by measuring the efficiencies of energy transfer from Tb(III) to other Ln(III) ions. The intermetal distances of Tb(III)-Ho(III) and Tb(III)-Nd(III) were 7.9 and 6.8 A, respectively.     

Exploring structural motifs necessary for substrate binding in the active site of Escherichia coli pantothenate kinase

The coenzyme A (CoA) biosynthetic enzymes have been used to produce various CoA analogues, including mechanistic probes of CoA-dependent enzymes such as those involved in fatty acid biosynthesis. These enzymes are also important for the activation of the pantothenamide class of antibacterial agents, and of a recently reported family of antibiotic resistance inhibitors. Herein we report a study on the selectivity of pantothenate kinase, the first and rate limiting step of CoA biosynthesis. A robust synthetic route was developed to allow rapid access to a small library of pantothenate analogs diversified at the β-alanine moiety, the carboxylate or the geminal dimethyl group. All derivatives were tested as substrates of Escherichia coli pantothenate kinase (EcPanK). Four derivatives, all N-aromatic pantothenamides, proved to be equivalent to the benchmark N-pentylpantothenamide (N5-pan) as substrates of EcPanK, while two others, also with N-aromatic groups, were some of the best substrates reported for this enzyme. This collection of data provides insight for the future design of PanK substrates in the production of useful CoA analogues.     

L-aspartase from Escherichia coli: substrate specificity and role of divalent metal ions

The enzyme L-aspartase from Escherichia coli has an absolute specificity for its amino acid substrate. An examination of a wide range of structural analogues of L-aspartic acid did not uncover any alternate substrates for this enzyme. A large number of competitive inhibitors of the enzyme have been characterized, with inhibition constants ranging over 2 orders of magnitude. A divalent metal ion is required for enzyme activity above pH 7, and this requirement is met by many transition and alkali earth metals. The binding stoichiometry has been established to be one metal ion bound per subunit. Paramagnetic relaxation studies have shown that the divalent metal ion binds at the recently discovered activator site on L-aspartase and not at the enzyme active site. Enzyme activators are bound within 5 A of the enzyme-bound divalent metal ion. The activator site is remote from the active site of the enzyme, since the relaxation of inhibitors that bind at the active site is not affected by paramagnetic metal ions bound at the activator site.     

Effectors of the stringent response target the active site of Escherichia coli adenylosuccinate synthetase.

Guanosine 5'-diphosphate 3'-diphosphate (ppGpp), a pleiotropic effector of the stringent response, potently inhibits adenylosuccinate synthetase from Escherichia coli as an allosteric effector and/or as a competitive inhibitor with respect to GTP. Crystals of the synthetase grown in the presence of IMP, hadacidin, NO3-, and Mg2+, then soaked with ppGpp, reveal electron density at the GTP pocket which is consistent with guanosine 5'-diphosphate 2':3'-cyclic monophosphate. Unlike ligand complexes of the synthetase involving IMP and GDP, the coordination of Mg2+ in this complex is octahedral with the side chain of Asp13 in the inner sphere of the cation. The cyclic phosphoryl group interacts directly with the side chain of Lys49 and indirectly through bridging water molecules with the side chains of Asn295 and Arg305. The synthetase either directly facilitates the formation of the cyclic nucleotide or scavenges trace amounts of the cyclic nucleotide from solution. Regardless of its mode of generation, the cyclic nucleotide binds far more tightly to the active site than does ppGpp. Conceivably, synthetase activity in vivo during the stringent response may be sensitive to the relative concentrations of several effectors, which together exercise precise control over the de novo synthesis of AMP.     

Spatial proximity of two divalent metal ions at the active site of S-adenosylmethionine synthetase

S-Adenosylmethionine synthetase from Escherichia coli is shown to require 2 divalent metal ions/enzyme subunit for maximal enzymatic activity. In the absence of substrate, the tetrameric enzyme binds 1 Mn(II) ion/subunit, whereas in the presence of a nucleotide substrate, adenylylimidodiphosphate, or the product pyrophosphate, there are two Mn(II)-binding sites/subunit. Electron paramagnetic resonance spectra of Mn(II) bound to the enzyme reveal a spin exchange interaction between 2 Mn(II) ions in complexes of enzyme and Mn(II) which also contain adenosylmethionine, K+, and either pyrophosphate or imidotriphosphate. Since a spin exchange interaction requires orbital overlap between the 2 ions, the metal ions must be bound close to one another, and they may share a common ligand.     

Sequences near the active site in chimeric penicillin binding proteins 5 and 6 affect uniform morphology of Escherichia coli

Penicillin binding protein (PBP) 5, a DD-carboxypeptidase that removes the terminal D-alanine from peptide side chains of peptidoglycan, plays an important role in creating and maintaining the uniform cell shape of Escherichia coli. PBP 6, a highly similar homologue, cannot substitute for PBP 5 in this respect. Previously, we localized the shape-maintaining characteristics of PBP 5 to the globular domain that contains the active site (domain I), where PBPs 5 and 6 share substantial identity. To identify the specific segment of domain I responsible for shape control, we created a set of hybrids and determined which ones complemented the aberrant morphology of a misshapen PBP mutant, E. coli CS703-1. Fusion proteins were constructed in which 47, 199 and 228 amino-terminal amino acids of one PBP were fused to the corresponding carboxy-terminal amino acids of the other. The morphological phenotype was reversed only by hybrid proteins containing PBP 5 residues 200 to 228, which are located next to the KTG motif of the active site. Because residues 220 to 228 were identical in these proteins, the morphological effect was determined by alterations in amino acids 200 to 219. To confirm the importance of this segment, we constructed mosaic proteins in which these 20 amino acids were grafted from PBP 5 into PBP 6 and vice versa. The PBP 6/5/6 mosaic complemented the aberrant morphology of CS703-1, whereas PBP 5/6/5 did not. Site-directed mutagenesis demonstrated that the Asp(218) and Lys(219) residues were important for shape maintenance by these mosaic PBPs, but the same mutations in wild-type PBP 5 did not eliminate its shape-promoting activity. Homologous enzymes from five other bacteria also complemented the phenotype of CS703-1. The overall conclusion is that creation of a bacterial cell of regular diameter and uniform contour apparently depends primarily on a slight alteration of the enzymatic activity or substrate accessibility at the active site of E. coli PBP 5.     

Affinity labeling of Escherichia coli phenylalanyl-tRNA synthetase at the binding site for tRNAPhe

Periodate-oxidized tRNA(Phe) (tRNA(oxPhe)) behaves as a specific affinity label of tetrameric Escherichia coli phenylalanyl-tRNA synthetase (PheRS). Reaction of the alpha 2 beta 2 enzyme with tRNA(oxPhe) results in the loss of tRNAPhe aminoacylation activity with covalent attachment of 2 mol of tRNA dialdehyde/mol of enzyme, in agreement with the stoichiometry of tRNA binding. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis of the PheRS-[14C]tRNA(oxPhe) covalent complex indicates that the large (alpha, Mr 87K) subunit of the enzyme interacts with the 3'-adenosine of tRNA(oxPhe). The [14C]tRNA-labeled chymotryptic peptides of PheRS were purified by both gel filtration and reverse-phase high-performance liquid chromatography. The radioactivity was almost equally distributed among three peptides: Met-Lys[Ado]-Phe, Ala-Asp-Lys[Ado]-Leu, and Lys-Ile-Lys[Ado]-Ala. These sequences correspond to residues 1-3, 59-62, and 104-107, respectively, in the N-terminal region of the 795 amino acid sequence of the alpha subunit. It is noticeable that the labeled peptide Ala-Asp-Lys-Leu is adjacent to residues 63-66 (Arg-Val-Thr-Lys). The latter sequence was just predicted to resemble the proposed consensus tRNA CCA binding region Lys-Met-Ser-Lys-Ser, as deduced from previous affinity labeling studies on E. coli methionyl- and tyrosyl-tRNA synthetases [Hountondji, C., Dessen, P., & Blanquet, S. (1986) Biochimie 68, 1071-1078].     

Probing the nucleotide-binding site of Escherichia coli succinyl-CoA synthetase.

Succinyl-CoA synthetase (SCS) catalyzes the reversible interchange of purine nucleoside diphosphate, succinyl-CoA, and Pi with purine nucleoside triphosphate, succinate, and CoA via a phosphorylated histidine (H246alpha) intermediate. Two potential nucleotide-binding sites were predicted in the beta-subunit, and have been differentiated by photoaffinity labeling with 8-N3-ATP and by site-directed mutagenesis. It was demonstrated that 8-N3-ATP is a suitable analogue for probing the nucleotide-binding site of SCS. Two tryptic peptides from the N-terminal domain of the beta-subunit were labeled with 8-N3-ATP. These corresponded to residues 107-119beta and 121-146beta, two regions lying along one side of an ATP-grasp fold. A mutant protein with changes on the opposite side of the fold (G53betaV/R54betaE) was unable to be phosphorylated using ATP or GTP, but could be phosphorylated by succinyl-CoA and Pi. A mutant protein designed to probe nucleotide specificity (P20betaQ) had a Km(app) for GTP that was more than 5 times lower than that of wild-type SCS, whereas parameters for the other substrates remained unchanged. Mutations of residues in the C-terminal domain of the beta-subunit designed to distrupt one loop of the Rossmann fold (I322betaA, and R324betaN/D326betaA) had the greatest effect on the binding of succinate and CoA. They did not disrupt the phosphorylation of SCS with nucleotides. It was concluded that the nucleotide-binding site is located in the N-terminal domain of the beta-subunit. This implies that there are two active sites approximately 35 A apart, and that the H246alpha loop moves between them during catalysis.     

Site-directed mutagenesis of Escherichia coli succinyl-CoA synthetase. beta-Cys325 is a nonessential active site residue

Chemical modification experiments have shown that sulfhydryl groups play an important role in the mechanism of action of Escherichia coli succinyl-CoA synthetase. One of these sulfhydryl groups has been localized in the beta-subunit of the enzyme using the coenzyme A affinity analog, CoA disulfide-S,S-dioxide (Collier, G. E., and Nishimura, J. S. (1978) J. Biol. Chem. 253, 4938-4943). Recently, it has been shown that the reactive sulfhydryl group resides in Cys325 (Nishimura, J. S., Mitchell, T., Ybarra, J., and Matula, J. M., submitted to Eur. J. Biochem. for publication). In the present study, we have changed Cys325 to a glycine residue using the technique of site-directed mutagenesis and have purified the mutant enzyme to homogeneity. The resulting mutant enzyme is 83% as active as wild type enzyme. In contrast to wild type succinyl-CoA synthetase, the mutant is refractory to chemical modification by CoA disulfide-S,S-dioxide and methyl methanethiolsulfonate. It is also less reactive with N-ethylmaleimide. Thus, beta-Cys325 is a nonessential active site residue.     

Evidence for a second histidine at the active site of succinyl-CoA synthetase from Escherichia coli.

Ethoxyformic anhydride was used to demonstrate the existence of a second important histidine in succinyl-CoA synthetase from Escherichia coli. Differential labeling of the enzyme by [3H]ethoxyformic anhydride gave a stoichiometry of one important histidine per alpha beta catalytic unit. Data are presented suggesting that this residue and an important thiol group on the beta subunit (Collier, G., and Nishimura, J.S. (1978) J. Biol. Chem. 253, 4938-4943) interact with each other during catalysis. A mechanism of action involving these 2 residues is proposed for one of the partial reactions catalyzed by succinyl-CoA synthetase.     

The P4 metal binding site in RNase P RNA affects active site metal affinity through substrate positioning

Although helix P4 in the catalytic domain of the RNase P ribozyme is known to coordinate magnesium ions important for activity, distinguishing between direct and indirect roles in catalysis has been difficult. Here, we provide evidence for an indirect role in catalysis by showing that while the universally conserved bulge of helix P4 is positioned 5 nt downstream of the cleavage site, changes in its structure can still purturb active site metal binding. Because changes in helix P4 also appear to alter its position relative to the pre-tRNA cleavage site, these data suggest that P4 contributes to catalytic metal ion binding through substrate positioning.     

Substrate specificity and catalysis by the editing active site of Alanyl-tRNA synthetase from Escherichia coli

Aminoacyl-tRNA synthetases (ARSs) enhance the fidelity of protein synthesis through multiple mechanisms, including hydrolysis of the adenylate and cleavage of misacylated tRNA. Alanyl-tRNA synthetase (AlaRS) limits misacylation with glycine and serine by use of a dedicated editing domain, and a mutation in this activity has been genetically linked to a mouse model of a progressive neurodegenerative disease. Using the free-standing Pyrococcus horikoshii AlaX editing domain complexed with serine as a model and both Ser-tRNA(Ala) and Ala-tRNA(Ala) as substrates, the deacylation activities of the wild type and five different Escherichia coli AlaRS editing site substitution mutants were characterized. The wild-type AlaRS editing domain deacylated Ser-tRNA(Ala) with a k(cat)/K(M) of 6.6 × 10(5) M(-1) s(-1), equivalent to a rate enhancement of 6000 over the rate of enzyme-independent deacylation but only 12.2-fold greater than the rate with Ala-tRNA(Ala). While the E664A and T567G substitutions only minimally decreased k(cat)/K(M,) Q584H, I667E, and C666A AlaRS were more compromised in activity, with decreases in k(cat)/K(M) in the range of 6-, 6.6-, and 15-fold. C666A AlaRS was 1.7-fold more active on Ala-tRNA(Ala) relative to Ser-tRNA(Ala), providing the only example of a true reversal of substrate specificity and highlighting a potential role of the coordinated zinc in editing substrate specificity. Along with the potentially serious physiological consequences of serine misincorporation, the relatively modest specificity of the AlaRS editing domain may provide a rationale for the widespread phylogenetic distribution of AlaX free-standing editing domains, thereby contributing a further mechanism to lower concentrations of misacylated tRNA(Ala).     

Structure prediction and active site analysis of the metal binding determinants in gamma -glutamylcysteine synthetase

gamma-Glultamylcysteine synthetase (gamma-GCS) catalyzes the first step in the de novo biosynthesis of glutathione. In trypanosomes, glutathione is conjugated to spermidine to form a unique cofactor termed trypanothione, an essential cofactor for the maintenance of redox balance in the cell. Using extensive similarity searches and sequence motif analysis we detected homology between gamma-GCS and glutamine synthetase (GS), allowing these proteins to be unified into a superfamily of carboxylate-amine/ammonia ligases. The structure of gamma-GCS, which was previously poorly understood, was modeled using the known structure of GS. Two metal-binding sites, each ligated by three conserved active site residues (n1: Glu-55, Glu-93, Glu-100; and n2: Glu-53, Gln-321, and Glu-489), are predicted to form the catalytic center of the active site, where the n1 site is expected to bind free metal and the n2 site to interact with MgATP. To elucidate the roles of the metals and their ligands in catalysis, these six residues were mutated to alanine in the Trypanosoma brucei enzyme. All mutations caused a substantial loss of activity. Most notably, E93A was able to catalyze the l-Glu-dependent ATP hydrolysis but not the peptide bond ligation, suggesting that the n1 metal plays an important role in positioning l-Glu for the reaction chemistry. The apparent K(m) values for ATP were increased for both the E489A and Q321A mutant enzymes, consistent with a role for the n2 metal in ATP binding and phosphoryl transfer. Furthermore, the apparent K(d) values for activation of E489A and Q321A by free Mg(2+) increased. Finally, substitution of Mn(2+) for Mg(2+) in the reaction rescued the catalytic deficits caused by both mutations, demonstrating that the nature of the metal ligands plays an important role in metal specificity.     

Affinity labeling of the active site of Escherichia coli glutamine synthetase by 5'-p-fluorosulfonylbenzoyladenosine

The interaction of Escherichia coli glutamine synthetase with the adenosine 5'-triphosphate analogue, 5'-p-fluorosulfonylbenzoyladenosine (5'-FSO2BzAdo), has been studied. This interaction results in the covalent attachment of the 5'-FSO2BzAdo to the enzyme with concomitant loss of catalytic activity. Although adenine nucleotides interact with glutamine synthetase at three distinct sites--a noncovalent AMP effector site, a regulatory site of covalent adenylylation, and the catalytic ATP/ADP binding site--our studies suggest that reaction with 5'-FSO2BzAdo occurs only at the active center. When glutamine synthetase was incubated with 5'-FSO2BzAdo, the decrease in catalytic activity obeyed pseudo-first order kinetics. The plot of the observed rate constant of inactivation versus the concentration of 5'-FSO2BzAdo was hyperbolic, consistent with reversible binding of the analogue to the enzyme prior to covalent attachment. Protection against inactivation was afforded by ATP and ADP; L-glutamate did not protect the enzyme against inactivation, but rather enhanced the rate of inactivation, consistent with the observations of others (Timmons, R. B., Rhee, S. G., Luterman, D. L., and Chock, P. B. (1974) Biochemistry 13, 4479-4485) that there is synergism in the binding of the two substrates to the enzyme. The incorporation of approximately 1.09 mol of the 5'-FSO2BzAdo/mol of glutamine synthetase subunit resulted in the total loss of enzymatic activity. The results suggest that 5'-FSO2BzAdo occupies the ATP binding site at the active center of glutamine synthetase and binds covalently to an amino acid residue nearby.     

tRNA recognition site of Escherichia coli methionyl-tRNA synthetase

We have previously shown that anticodon bases are essential for specific recognition of tRNA substrates by Escherichia coli methionyl-tRNA synthetase (MetRS) [Schulman, L. H., & Pelka, H. (1983) Proc. Natl. Acad. Sci. U.S.A. 80, 6755-6759] and that the enzyme tightly binds to C34 at the wobble position of E. coli initiator methionine tRNA (tRNAfMet) [Pelka, H., & Schulman, L. H. (1986) Biochemistry 25, 4450-4456]. We have also previously demonstrated that an affinity labeling derivative of tRNAfMet can be quantitatively cross-linked to the tRNA binding site of MetRS [Valenzuela, D., & Schulman, L. H. (1986) Biochemistry 25, 4555-4561]. Here, we have determined the site in MetRS which is cross-linked to the anticodon of tRNAfMet, as well as the location of four additional cross-links. Only a single peptide, containing Lys465, is covalently coupled to C34, indicating that the recognition site for the anticodon is close to this sequence in the three-dimensional structure of MetRS. The D loop at one corner of the tRNA molecule is cross-linked to three peptides, containing Lys402, Lys439, and Lys596. The 5' terminus of the tRNA is cross-linked to Lys640, near the carboxy terminus of the enzyme. Since the 3' end of tRNAfMet is positioned close to the active site in the N-terminal domain [Hountondji, C., Blanquet, S., & Lederer, F. (1985) Biochemistry 24, 1175-1180], this result indicates that the carboxy ends of the two polypeptide chains of native dimeric MetRS are folded back toward the N-terminal domain of each subunit.