Vancomycin resistance: structure of D-alanine:D-alanine ligase at 2.3 A resolution

Active-site mutants of the VanC2 D-alanyl-D-serine ligase, characteristic of one vancomycin-resistant bacterial phenotype, revert towards wild-type D-alanyl-D-alanine ligases

BACKGROUND

The rising number of vancomycin-resistant enterococci (VREs) is a major concern to modern medicine because vancomycin is currently the 'last resort' drug for life-threatening infections. The D-alanyl-D-X ligases (where X is an hydroxy or amino acid) of bacteria catalyze a critical step in bacterial cell-wall peptidoglycan assembly. In bacteria that produce glycopeptide antibiotics and in opportunistic pathogens, including VREs, D-, D-ligases serve as switches that confer antibiotic resistance on the bacteria themselves. Peptidoglycans in vancomycin-sensitive bacteria end in D-alanyl-D-alanine, whereas in vancomycin-resistant bacteria they end in D-alanyl-D-lactate or D-alanyl-D-serine.

RESULTS

We demonstrate that the selective utilization of D-serine by the Enterococcus casseliflavus VanC2 ligase can be altered by mutagenesis of one of two residues identified by homology to the X-ray structure of the Escherichia coli D-alanyl-Dalanine ligase (DdlB). The Arg322-->Met (R322M) and Phe250-->Tyr (F250Y) ligase mutants show a 36-44-fold decrease in the use of D-serine, as well as broadened specificity for utilization of other D-amino acids in place of D-serine. The F250Y R322M double mutant is effectively disabled as a D-alanyl-D-serine ligase and retains 10% of the catalytic activity of wild-type D-alanyl-D-alanine ligases, reflecting a 6,000-fold switch to the D-alanyl-D-alanine peptide. Correspondingly, the Leu282-->Arg mutant of the wild-type E. coli DdlB produced a 560-fold switch towards D-alanyl-D-serine formation.

CONCLUSIONS

Single-residue changes in the active-site regions of D-, D-ligases can cause substantial changes in recognition and activation of hydroxy or amino acids that have consequences for glycopeptide antibiotic efficacy. The observations reported here should provide an approach for combatting antibiotic-resistant bacteria.

The structure of SAICAR synthase: an enzyme in the de novo pathway of purine nucleotide biosynthesis

BACKGROUND

The biosynthesis of key metabolic components is of major interest to biologists. Studies of de novo purine synthesis are aimed at obtaining a deeper understanding of this central pathway and the development of effective chemotherapeutic agents. Phosphoribosylaminoimidazolesuccinocarboxamide (SAICAR) synthase catalyses the seventh step out of ten in the biosynthesis of purine nucleotides. To date, only one structure of an enzyme involved in purine biosynthesis has been reported: adenylosuccinate synthetase, which catalyses the first committed step in the synthesis of AMP from IMP.

RESULTS

We report the first three-dimensional structure of a SAICAR synthase, from Saccharomyces cerevisiae. It is a monomer with three domains. The first two domains consist of antiparallel beta sheets and the third is composed of two alpha helices. There is a long deep cleft made up of residues from all three domains. Comparison of SAICAR synthases by alignment of their sequences reveals a number of conserved residues, mostly located in the cleft. The presence of two sulphate ions bound in the cleft, the structure of SAICAR synthase in complex with ATP and a comparison of this structure with that of other ATP-dependent proteins point to the interdomain cleft as the location of the active site.

CONCLUSIONS

The topology of the first domain of SAICAR synthase resembles that of the N-terminal domain of proteins belonging to the cyclic AMP-dependent protein kinase family. The fold of the second domain is similar to that of members of the D-alanine:D-alanine ligase family. Together these enzymes form a new superfamily of mononucleotide-binding domains. There appears to be no other enzyme, however, which is composed of the same combination of three domains, with the individual topologies found in SAICAR synthase.

Synapsin I is structurally similar to ATP-utilizing enzymes

Synapsins are abundant synaptic vesicle proteins with an essential regulatory function in the nerve terminal. We determined the crystal structure of a fragment (synC) consisting of residues 110-420 of bovine synapsin I; synC coincides with the large middle domain (C-domain), the most conserved domain of synapsins. SynC molecules are folded into compact domains and form closely associated dimers. SynC monomers are strikingly similar in structure to a family of ATP-utilizing enzymes, which includes glutathione synthetase and D-alanine:D-alanine ligase. SynC binds ATP in a Ca2+-dependent manner. The crystal structure of synC in complex with ATPgammaS and Ca2+ explains the preference of synC for Ca2+ over Mg2+. Our results suggest that synapsins may also be ATP-utilizing enzymes.

A diverse superfamily of enzymes with ATP-dependent carboxylate-amine/thiol ligase activity

The recently developed PSI-BLAST method for sequence database search and methods for motif analysis were used to define and expand a superfamily of enzymes with an unusual nucleotide-binding fold, referred to as palmate, or ATP-grasp fold. In addition to D-alanine-D-alanine ligase, glutathione synthetase, biotin carboxylase, and carbamoyl phosphate synthetase, enzymes with known three-dimensional structures, the ATP-grasp domain is predicted in the ribosomal protein S6 modification enzyme (RimK), urea amidolyase, tubulin-tyrosine ligase, and three enzymes of purine biosynthesis. All these enzymes possess ATP-dependent carboxylate-amine ligase activity, and their catalytic mechanisms are likely to include acylphosphate intermediates. The ATP-grasp superfamily also includes succinate-CoA ligase (both ADP-forming and GDP-forming variants), malate-CoA ligase, and ATP-citrate lyase, enzymes with a carboxylate-thiol ligase activity, and several uncharacterized proteins. These findings significantly extend the variety of the substrates of ATP-grasp enzymes and the range of biochemical pathways in which they are involved, and demonstrate the complementarity between structural comparison and powerful methods for sequence analysis.

Novel mechanism for carbamoyl-phosphate synthetase: a nucleotide switch for functionally equivalent domains

Carbamoyl-phosphate synthetases (CPSs) utilize two molecules of ATP at two internally duplicated domains, B and C. Domains B and C have recently been shown to be structurally [Thoden, J. B., Holden, H. M., Wesenberg, G., Raushel, F. M. & Rayment, I. (1997) Biochemistry 36, 6305-6316] and functionally [Guy, H. I. & Evans, D. R. (1996) J. Biol. Chem. 271, 13762-13769] equivalent. We have carried out a site-directed mutagenic analysis that is consistent with ATP binding to a palmate motif rather than to a Walker A/B motif in domains B and C. To accommodate our present findings, as well as the other recent findings of structural and functional equivalence, we are proposing a novel mechanism for CPS. In this mechanism utilization of ATP bound to domain C is coupled to carbamoyl-phosphate synthesis at domain B via a nucleotide switch, with the energy of ATP hydrolysis at domain C allowing domain B to cycle between two alternative conformations.

Bacterial resistance to vancomycin: overproduction, purification, and characterization of VanC2 from Enterococcus casseliflavus as a D-Ala-D-Ser ligase

The VanC phenotype for clinical resistance of enterococci to vancomycin is exhibited by Enterococcus gallinarum and Enterococcus casseliflavus. Based on the detection of the cell precursor UDP-N-acetylmuramic acid pentapeptide intermediate terminating in D-Ala-D-Ser instead of D-Ala-D-Ala, it has been predicted that the VanC ligase would be a D-Ala-D-Ser rather than a D-Ala-D-Ala ligase. Overproduction of the E. casseliflavus ATCC 25788 vanC2 gene in Escherichia coli and its purification to homogeneity allowed demonstration of ATP-dependent D-Ala-D-Ser ligase activity. The kcat/Km2 (Km2 = Km for D-Ser or C-terminal D-Ala) ratio for D-Ala-D-Ser/D-Ala-D-Ala dipeptide formation is 270/0.69 for a 400-fold selection against D-Ala in the C-terminal position. VanC2 also has substantial D-Ala-D-Asn ligase activity (kcat/Km2 = 74 mM-1min-1).

Crystal structure of UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase from Escherichia coli

UDP-N-acetylmuramoyl-L-alanine:D-glutamate ligase (MurD) is a cytoplasmic enzyme involved in the biosynthesis of peptidoglycan which catalyzes the addition of D-glutamate to the nucleotide precursor UDP-N-acetylmuramoyl-L-alanine (UMA). The crystal structure of MurD in the presence of its substrate UMA has been solved to 1.9 A resolution. Phase information was obtained from multiple anomalous dispersion using the K-shell edge of selenium in combination with multiple isomorphous replacement. The structure comprises three domains of topology each reminiscent of nucleotide-binding folds: the N- and C-terminal domains are consistent with the dinucleotide-binding fold called the Rossmann fold, and the central domain with the mononucleotide-binding fold also observed in the GTPase family. The structure reveals the binding site of the substrate UMA, and comparison with known NTP complexes allows the identification of residues interacting with ATP. The study describes the first structure of the UDP-N-acetylmuramoyl-peptide ligase family.

D-Ala-D-Ala ligases from glycopeptide antibiotic-producing organisms are highly homologous to the enterococcal vancomycin-resistance ligases VanA and VanB

The crisis in antibiotic resistance has resulted in an increasing fear of the emergence of untreatable organisms. Resistance to the glycopeptide antibiotic vancomycin in the enterococci, and the spread of these pathogens throughout the environment, has shown that this scenario is a matter of fact rather than fiction. The basis for vancomycin resistance is the manufacture of the depsipeptide D-Ala-D-lactate, which is incorporated into the peptidoglycan cell wall in place of the vancomycin target D-Ala-D-Ala. Pivotal to the resistance mechanism is the production of a D-Ala-D-Ala ligase capable of ester formation. Two highly efficient depsipeptide ligases have been cloned from vancomycin-resistant enterococci: VanA and VanB. These ligases show high amino acid sequence similarity to each other ( approximately 75%), but less so to other D-Ala-D-X ligases (<30%). We have cloned ddls from two glycopeptide-producing organisms, the vancomycin producer Amycolatopsis orientalis and the A47934 producer Streptomyces toyocaensis. These ligases show strong predicted amino acid homology to VanA and VanB (>60%) but not to other D-Ala-D-X ligases (<35%). The D-Ala-D-Ala ligase from S. toyocaensis shows D-Ala-D-lactate synthase activity in cell-free extracts of S. lividans transformed with the ddl gene and confirms the predicted enzymatic activity. These results imply a close evolutionary relationship between resistance mechanisms in the clinics and in drug-producing bacteria.

D-Alanyl-D-lactate and D-alanyl-D-alanine synthesis by D-alanyl-D-alanine ligase from vancomycin-resistant Leuconostoc mesenteroides. Effects of a phenylalanine 261 to tyrosine mutation

The Gram-positive bacterium Leuconostoc mesenteroides, ATCC 8293, is intrinsically resistant to the antibiotic vancomycin. This phenotype correlates with substitution of D-Ala-D-lactate (D-Ala-D-Lac) termini for D-Ala-D-Ala termini in peptidoglycan intermediates in which the depsipeptide has much lower affinity than the dipeptide for vancomycin binding. Overproduction of the L. mesenteroides D-Ala-D-Ala ligase (LmDdl) 2 in E. coli and its purification to approximately 90% homogeneity allow demonstration that the LmDdl2 does have both depsipeptide and dipeptide ligase activity. Recently, we reported that mutation of an active site tyrosine (Tyr), Tyr216, to phenylalanine (Phe) in the E. coli DdlB leads to gain of D-Ala-D-Lac depsipeptide ligase activity in that enzyme. The vancomycin-resistant LmDdl2 has a Phe at the equivalent site, Phe261. To test the prediction that a Tyr residue predicts dipeptide ligase while an Phe residue predicts both depsipeptide and dipeptide ligase activity, the F261Y mutant protein of LmDdl2 was constructed and purified to approximately 90% purity. F216Y LmDdl2 showed complete loss of the ability to couple D-Lac but retained D-Ala-D-Ala dipeptide ligase activity. The Tyr-->Phe substitution on the active site omega-loop in D-Ala-D-Ala ligases is thus a molecular indicator of both the ability to make D-Ala-D-Lac and intrinsic resistance to the vancomycin class of glycopeptide antibiotics.

Structure of UDP-N-acetylglucosamine enolpyruvyl transferase, an enzyme essential for the synthesis of bacterial peptidoglycan, complexed with substrate UDP-N-acetylglucosamine and the drug fosfomycin

BACKGROUND

UDP-N-acetylglucosamine enolpyruvyl transferase (MurA), catalyses the first committed step of bacterial cell wall biosynthesis and is a target for the antibiotic fosfomycin. The only other known enolpyruvyl transferase is 5-enolpyruvylshikimate-3-phosphate (EPSP) synthase, an enzyme involved in the shikimic acid pathway and the target for the herbicide glyphosate. Inhibitors of enolpyruvyl transferases are of biotechnological interest as MurA and EPSP synthase are found exclusively in plants and microbes.

RESULTS

The crystal structure of Escherichia coli MurA complexed with UDP-N-acetylglucosamine (UDP-GlcNAc) and fosfomycin has been determined at 1.8 A resolution. The structure consists of two domains with the active site located between them. The domains have a very similar secondary structure, and the overall protein architecture is similar to that of EPSP synthase. The fosfomycin molecule is covalently bound to the cysteine residue Cys115, whereas UDP-GlcNAc makes several hydrogen-bonding interactions with residues from both domains.

CONCLUSIONS

The present structure reveals the mode of binding of the natural substrate UDP-GlcNAc and of the drug fosfomycin, and provides information on the residues involved in catalysis. These results should aid the design of inhibitors which would interfere with enzyme-catalyzed reactions in the early stage of the bacterial cell wall biosynthesis. Furthermore, the crystal structure of MurA provides a model for predicting active-site residues in EPSP synthase that may be involved in catalysis and substrate binding.

Determination of the nucleotide binding site within Clostridium symbiosum pyruvate phosphate dikinase by photoaffinity labeling, site-directed mutagenesis, and structural analysis

Clostridium symbiosum pyruvate phosphate dikinase (PPDK) catalyzes the interconversion of adenosine 5'-triphosphate (ATP), orthophosphate (P(i)), and pyruvate with adenosine 5'-monophosphate (AMP), pyrophosphate (PP(i)), and phosphoenolpyruvate (PEP). The nucleotide binding site of this enzyme was labeled using the photoaffinity reagent [32P]-8-azidoadenosine 5'-triphosphate ([32P]-8-azidoATP). Subtilisin cleavage of the [alpha-32P]-8-azidoATP-photolabeled PPDK into domain-sized fragments, prior to SDS-PAGE analysis, allowed us to identify two sites of modification: one between residues 1 and 226 and the other between residues 227 and 334. Saturation of the ATP binding site with adenylyl imidodiphosphate afforded protection against photolabeling. Next, small peptide fragments of [gamma-32P]- 8-azidoATP-photolabeled PPDK were generated by treating the denatured protein with trypsin or alpha-chymotrypsin. A pair of overlapping radiolabeled peptide fragments were separated from the two digests, DMQDMEFTIEEGK (positions 318-330 in trypsin-treated PPDK) and RDMQDMEFTIEEGKL (positions 317-331 in alpha-chymotrypsin-treated PPDK), thus locating one of the positions of covalent modification. Next, catalysis by site-directed mutants generated by amino acid replacement of invariant residues of the PPDK N-terminal domain was tested. K163L, D168A, D170A, D175A, K177L, and G248I PPDK mutants retained substantial catalytic activity while G254I, R337L, and E323L PPDK mutants were inhibited. Comparison of the steady-state kinetic constants measured (at pH 6.8, 25 degrees C) for wild-type PPDK (kcat = 36 s-1, AMPK(m) = 7 microM, PP(i)K(m) = 70 microM, PEPK(m) = 27 microM) to those of R337L PPDK (kcat = 2 s-1, AMPK(m) = 85 microM, PP(i)K(m) = 3700 microM, PEPK(m) = 6 microM) and G254I PPDK (kcat = 0.1 s-1, AMPK(m) = 1300 microM, PP(i)K(m) = 1200 microM, PEPK(m) = 12 microM) indicated impaired catalysis of the nucleotide partial reaction (E.ATP.P(i) --> E-PP.AMP.P(i) --> E-P.AMP.PP(i) in these mutants. The single turnover reactions of [32P]PEP to [32P]E-P.pyruvate catalyzed by the PPDK mutants were shown to be comparable to those of wild-type PPDK. In contrast, the formation of [32P]E-PP/[32P]E-P in single turnover reactions of [beta-32P]ATP/P(i) was significantly inhibited. Finally, the location of the adenosine 5'-diphosphate binding site within the nucleotide binding domain of D-alanine-D-alanine ligase, a structural homologue of the PPDK N-terminal domain [Herzberg, O. (1996) Proc. Natl. Acad. Sci. U.S.A. 93, 2652-2657] indicates, by analogy, the location of the nucleotide binding site in PPDK. Residues G254, R337, and E323 as well as the site of photoaffinity labeling are located within this region.

Evolution of structure and substrate specificity in D-alanine:D-alanine ligases and related enzymes

The D-alanine:D-alanine-ligase-related enzymes can have three preferential substrate specificities. Usually, these enzymes synthesize D-alanyl-D-alanine. In vancomycin-resistant Gram-positive bacteria, structurally related enzymes synthesize D-alanyl-D-lactate or d-alanyl-d-serine. The sequence of internal fragments of eight structural d-alanine:d-alanine ligase genes from enterococci has been determined. Alignment of the deduced amino acid sequences with those of other related enzymes from Gram-negative and Gram-positive bacteria revealed the presence of four distinct sequence patterns in the putative substrate-binding sites, each correlating with specificity to a particular substrate (D-alanine:D-lactate ligases exhibited two patterns). Phylogenetic analysis showed different clusters. The enterococcal subtree was largely superimposable on that derived from 16S rRNA sequences. In lactic acid bacteria, structural divergence due to differences in substrate specificity was observed. Glycopeptide resistance proteins VanA and VanB, the VanC-type ligases, and DdlA and DdlB from enteric bacteria and Haemophilus influenzae constituted separate clusters.

Structural classification of proteins: new superfamilies

The structural classification of proteins reveals that it is already more likely to find that a new protein structure has similarity to another structure than to find that it has a new fold. Reviewed here are those new superfamilies that include proteins of general interest: Sonic hedgehog, macrophage migration inhibitory factor, nuclear transport factor-2, double stranded RNA binding domain, GroES, the proteasome, new ATP-hydrolyzing ligases and flavoproteins.

Swiveling-domain mechanism for enzymatic phosphotransfer between remote reaction sites

The crystal structure of pyruvate phosphate dikinase, a histidyl multiphosphotransfer enzyme that synthesizes adenosine triphosphate, reveals a three-domain molecule in which the phosphohistidine domain is flanked by the nucleotide and the phosphoenolpyruvate/pyruvate domains, with the two substrate binding sites approximately 45 angstroms apart. The modes of substrate binding have been deduced by analogy to D-Ala-D-Ala ligase and to pyruvate kinase. Coupling between the two remote active sites is facilitated by two conformational states of the phosphohistidine domain. While the crystal structure represents the state of interaction with the nucleotide, the second state is achieved by swiveling around two flexible peptide linkers. This dramatic conformational transition brings the phosphocarrier residue in close proximity to phosphoenolpyruvate/pyruvate. The swiveling-domain paradigm provides an effective mechanism for communication in complex multidomain/multiactive site proteins.

Cure for a crisis?

The first look at the three-dimensional structure of an essential penicillin binding protein from a human pathogen, and its complex with a beta-lactam antibiotic provides hope for the future design of improved antibiotics.

Biotin carboxylase comes into the fold

Extensive three-dimensional structural resemblances between biotin carboxylase and the ADP-forming peptide synthetases, represented by glutathione synthetase and D-Ala:D-Ala ligase, reveal a previously unsuspected evolutionary relationship between two major families of ADP-forming ligases.

Synthesis and evaluation of inhibitors of bacterial D-alanine:D-alanine ligases

BACKGROUND

D-Alanine:D-alanine ligase is essential for bacterial cell wall synthesis, assembling one of the subunits used for peptidoglycan crosslinking. The resulting aminoacyl-D-Ala-D-Ala strand is the Achilles' heel of vancomycin-susceptible bacteria; binding of vancomycin to this sequence interferes with crosslinking and blocks cell-wall synthesis. A mutant enzyme (VanA) from vancomycin-resistant Enterococcus faecium has been found to incorporate alpha-hydroxy acids at the terminal site instead of D-Ala; the resulting depsipeptides do not bind vancomycin, yet function in the crosslinking reaction. To investigate the binding specificity of these ligases, we examined their inhibition by a series of substrate analogs.

RESULTS

Phosphinate and phosphonate dipeptide analogs (which, after phosphorylation by the enzyme, mimic intermediates in the ligation reaction) were prepared and evaluated as reversible inhibitors of the wild-type ligases DdlA and DdlB from Escherichia coli and of the mutant enzyme VanA. Ki values were calculated for the first stage of inhibitor binding according to a mechanism in which inhibitor competes with D-Ala for both substrate binding sites. DdlA is potently inhibited by phosphinates but not by phosphonates, while DdlB and VanA show little discrimination; both series of compounds inhibit DdlB strongly and VanA weakly.

CONCLUSIONS

VanA has greatly reduced affinity for all the ligands studied. The relative affinities of the inhibitors in the reversible binding step are not, however, consistent with the substrate specificities of the enzymes. We propose a mechanism in which proton transfer from the attacking nucleophile to the departing phosphate occurs directly, without intervention of the enzyme.

Bacterial resistance to vancomycin: five genes and one missing hydrogen bond tell the story

A plasmid-borne transposon encodes enzymes and regulator proteins that confer resistance of enterococcal bacteria to the antibiotic vancomycin. Purification and characterization of individual proteins encoded by this operon has helped to elucidate the molecular basis of vancomycin resistance. This new understanding provides opportunities for intervention to reverse resistance.

Phosphinate analogs of D-, D-dipeptides: slow-binding inhibition and proteolysis protection of VanX, a D-, D-dipeptidase required for vancomycin resistance in Enterococcus faecium

VanX is a D-Ala-D-Ala dipeptidase that is essential for vancomycin resistance in Enterococcus faecium. Contrary to most proteases and peptidases, it prefers to hydrolyze the amino substrate but not the related kinetically and thermodynamically more favorable ester substrate D-Ala-D-lactate. The enzymatic activity of VanX was previously found to be inhibited by the phosphinate analogs of the proposed tetrahedral intermediate for hydrolysis of D-Ala-D-Ala. Here we report that such phosphinates are slow-binding inhibitors. D-3-[(1-Aminoethyl)phosphinyl]-D-2-methylpropionic acid I showed a time-dependent onset of inhibition of VanX and a time-dependent return to uninhibited steady-state rates upon dilution of the enzyme/inhibitor mixture. The initial inhibition constant Ki after immediate addition of VanX to phosphinate I to form the E-I complex is 1.5 microM but is then lowered by a relatively slow isomerization step to a second complex, E-I*, with a final K*i of 0.47 microM. This slow-binding inhibition reflects a Km/K*i ratio of 2900:1. The rate constant for the slow dissociation of complex E-I* is 0.24 min-1. A phosphinate analog with an ethyl group replacing what would be the side chain of the second D-alanyl residue in the normal tetrahedral adduct gives a K*i value of 90 nM. Partial proteolysis of VanX reveals two protease-sensitive loop regions that are protected by the intermediate analog phosphinate, indicating that they may be part of the VanX active site.

Update on computer-aided drug design

Recent advances in computational methods for drug design include developments in quantitative structure-activity relationship approaches as well as novel structure-based strategies. Many new protein structures of pharmaceutical interest have been solved, a number of which contain a bound inhibitor. Continued progress has been reported in algorithms for de novo design, ligand docking, and scoring of protein-ligand binding energy. Meanwhile, several drugs that were designed by intensive use of computational methods are advancing through clinical trials.

Substrate binding and carboxylation by dethiobiotin synthetase--a kinetic and X-ray study

BACKGROUND

The vitamin biotin is a ubiquitous prosthetic group of carboxylase and transcarboxylase enzymes. Biotin biosynthesis occurs by similar pathways in microorganisms and plants. The penultimate step in biotin biosynthesis, catalyzed by dethiobiotin synthetase (DTBS), involves a unique ATP-dependent N-carboxylation, resulting in formation of the ureido ring function of dethiobiotin. The first two steps of dethiobiotin formation, which is a complex, multistep enzymatic reaction, have been elucidated by a combination of X-ray crystallography and kinetic methods.

RESULTS

The first step in catalysis by DTBS is the formation of an enzyme-substrate complex and the second is the enzymatic carboxylation of the bound substrate. Both steps are Mg2+ dependent. The kinetic constants in the presence and absence of Mg2+ have been measured and a set of X-ray structures determined at different stages of the reaction. The conformational changes in the active site of the enzyme, induced by Mg2+, substrate binding and substrate carboxylation, have been monitored crystallographically and are discussed. Sulfate ions bound to DTBS may mimic the behaviour of the alpha- and gamma-phosphates of ATP in Mg2+ binding and in the subsequent steps of the reaction.

CONCLUSIONS

Mg2+ is an essential cation for both substrate binding and carbamate formation by DTBS, when sulfate is present. The conformational changes induced at the active site in the DTBS-substrate complex, when Mg2+ is present, are small yet highly significant and serve to optimize the interactions between substrate and enzyme. DTBS is active as a homodimer and the substrate-binding site straddles both monomers in the dimer. The carboxylation site is unambiguously identified as the N-7 amino group of the substrate, rather than the N-8 amino group, as previously suggested. The elongated nucleotide-binding loop (the P loop) binds both ATP and substrate in a manner which suggests that this feature may be of wider importance.

Glutathionylspermidine metabolism in Escherichia coli. Purification, cloning, overproduction, and characterization of a bifunctional glutathionylspermidine synthetase/amidase

Glutathionylspermidine (GSP) synthetases of Trypanosomatidae and Escherichia coli couple hydrolysis of ATP (to ADP and Pi) with formation of an amide bond between spermidine (N-(3-aminopropyl)-1,4-diaminobutane) and the glycine carboxylate of glutathione (gamma-Glu-Cys-Gly). In the pathogenic trypanosomatids, this reaction is the penultimate step in the biosynthesis of the antioxidant metabolite, trypanothione (N1,N8-bis-(glutathionyl)spermidine), and is a target for drug design. In this study, GSP synthetase was purified to near homogeneity from E. coli B, the gene encoding it was isolated and sequenced, the enzyme was overexpressed and purified in quantity, and the recombinant enzyme was characterized. The 70-kDa protein was found to have an unexpected second catalytic activity, glutathionylspermidine amide bond hydrolysis. Thus, the bifunctional GSP synthetase/amidase catalyzes opposing amide bond-forming and -cleaving reactions, with net hydrolysis of ATP. The synthetase activity is selectively abrogated by proteolytic cleavage 81 residues from the C terminus, suggesting that the two activities reside in distinct domains (N-terminal amidase and C-terminal synthetase). Proteolysis at this site is facile in the absence of substrates, but is inhibited in the presence of ATP, glutathione, and Mg2+. A series of analogs was used to probe the spermidine-binding site of the synthetase activity. The activity of diaminopropane as a substrate, inactivity of the C4-C8 diaminoalkanes, and greater loss of specificity for analogs modified in the 3-aminopropyl moiety than for those modified in the 4-aminobutyl moiety indicate that the enzyme recognizes predominantly the diaminopropane portion of spermidine and corroborate N-1 (the aminopropyl N) as the site of glutathione linkage (Tabor, H. and Tabor, C. W. (1975) J. Biol. Chem. 250, 2648-2654). Trends in Km and kcat for a set of difluorosubstituted spermidine derivatives suggest that the enzyme may bind the minor, deprotonated form of the amine nucleophile.

A common fold for peptide synthetases cleaving ATP to ADP: glutathione synthetase and D-alanine:d-alanine ligase of Escherichia coli

Examination of x-ray crystallographic structures shows the tertiary structure of D-alanine:D-alanine ligase (EC 6.3.2.4). a bacterial cell wall synthesizing enzyme, is similar to that of glutathione synthetase (EC 6.32.3) despite low sequence homology. Both Escherichia coli enzymes, which convert ATP to ADP during ligation to produce peptide products, are made of three domains, each folded around a 4-to 6-stranded beta-sheet core. Sandwiched between the beta-sheets of the C-terminal and central domains of each enzyme is a nonclassical ATP-binding site that contains a common set of spatially equivalent amino acids. In each enzyme, two loops are proposed to exhibit a required flexibility that allows entry of ATP and substrates, provides protection of the acylphosphate intermediate and tetrahedral adduct from hydrolysis during catalysis, and then permits release of products.