Pyruvate phosphate dikinase (PPDK) catalyzes the interconversion of ATP, P(i), and pyruvate with AMP, PP(i), and phosphoenolpyruvate (PEP) in three partial reactions as follows: 1) E-His + ATP --> E-His-PP.AMP; 2) E-His-PP.AMP + P(i) --> E-His-P.AMP.PP(i); and 3) E-His-P + pyruvate --> E.PEP using His-455 as the carrier of the transferred phosphoryl groups. The crystal structure of the Clostridium symbiosum PPDK (in the unbound state) reveals a three-domain structure consisting of consecutive N-terminal, central His-455, and C-terminal domains. The N-terminal and central His-455 domains catalyze partial reactions 1 and 2, whereas the C-terminal and central His-455 domains catalyze partial reaction 3. Attempts to obtain a crystal structure of the enzyme with substrate ligands bound at the nucleotide binding domain have been unsuccessful. The object of the present study is to demonstrate Mg(II) activation of catalysis at the ATP/P(i) active site, to identify the residues at the ATP/P(i) active site that contribute to catalysis, and to identify roles for these residues based on their positions within the active site scaffold. First, Mg(II) activation studies of catalysis of E + ATP + P(i) --> E-P + AMP + PP(i) partial reaction were carried out using a truncation mutant (Tem533) in which the C-terminal domain is absent. The kinetics show that a minimum of 2 Mg(II) per active site is required for the reaction. The active site residues used for substrate/cofactor binding/activation were identified by site-directed mutagenesis. Lys-22, Arg-92, Asp-321, Glu-323, and Gln-335 mutants were found to be inactive; Arg-337, Glu-279, Asp-280, and Arg-135 mutants were partially active; and Thr-253 and Gln-240 mutants were almost fully active. The participation of the nucleotide ribose 2'-OH and alpha-P in enzyme binding is indicated by the loss of productive binding seen with substrate analogs modified at these positions. The ATP, P(i), and Mg(II) ions were docked into the PPDK N-terminal domain crevice, in an orientation consistent with substrate/cofactor binding modes observed for other members of the ATP-Grasp fold enzyme superfamily and consistent with the structure-function data. On the basis of this docking model, the ATP polyphosphate moiety is oriented/activated for pyrophosphoryl transfer through interaction with Lys-22 (gamma-P), Arg-92 (alpha-P), and the Gly-101 to Met-103 loop (gamma-P) as well as with the Mg(II) cofactors. The P(i) is oriented/activated for partial reaction 2 through interaction with Arg-337 and a Mg(II) cofactor. The Mg(II) ions are bound through interaction with Asp-321, Glu-323, and Gln-335 and substrate. Residues Glu-279, Asp-280, and Arg-135 are suggested to function in the closure of an active site loop, over the nucleotide ribose-binding site.

Component D (HgdAB) of 2-hydroxyglutaryl-CoA dehydratase from Clostridium symbiosum was purified to homogeneity. It is able to use component A from Acidaminococcus fermentans (HgdC) to initiate catalysis together with ATP, Mg2+ and a strong reducing agent such as Ti(III)citrate. Component D from C. symbiosum has a 6 x higher specific activity compared with that from A. fermentans and contains a second [4Fe-4S] cluster but the same amount of riboflavin 5'-phosphate (1.0 per heterodimeric enzyme, m = 100 kDa). M?ssbauer spectroscopy revealed symmetric cube-type structures of the two [4Fe-4S]2+ clusters. EPR spectroscopy showed the resistance of the clusters to reducing agents, but detected a sharp signal at g = 2. 004 probably due to a stabilized flavin semiquinone. Three genes from C. symbiosum coding for components D (hgdA and hgdB) and A (hgdC) were cloned and sequenced. Primer extension experiments indicated that the genes are transcribed in the order hgdCAB from an operon only half the size of that from A. fermentans. Sequence comparisons detected a close relationship to the dehydratase system from A. fermentans and HgdA from Fusobacterium nucleatum, as well as to putative proteins of unknown function from Archaeoglobus fulgidus. Lower, but significant, identities were found with putative enzymes from several methanogenic Archaea and Escherichia coli, as well as with the mechanistically related benzoyl-CoA reductases from the Proteobacteria Rhodopseudomonas palustris and Thauera aromatica.

The vancomycin resistance vanB2 gene cluster is disseminated worldwide and has been found in phylogenetically remote bacterial genera. The vanB2 operon is part of conjugative transposons Tn1549/Tn5382, but conjugative transposition of these elements has not been demonstrated. We have obtained transfer of a Tn1549-like element (referred to herein as "Tn1549-like") from Clostridium symbiosum MLG101 to Enterococcus faecium 64/3 and Enterococcus faecalis JH2-2 in the digestive tract of gnotobiotic mice and to E. faecium 64/3 in vitro. Retransfer of Tn1549-like from an E. faecium transconjugant also containing Tn916 to E. faecium BM77 was obtained in vitro, albeit at a very low frequency. Transfer efficiency was found to be both donor and recipient dependent. Pulsed-field gel electrophoresis analysis of total SmaI-digested DNA of 48 transconjugants indicated in 27 instances the acquisition of ca. 34 kb of DNA. Two transconjugants harbored two copies of the transposon. Sequencing of the flanking regions of Tn1549-like in 48 transconjugants revealed 29 integration events in 26 loci in the E. faecium genome, and two hot spots for insertion were identified. Integration of the transposon was associated with the acquisition of 5 (n = 18) or 6 (n = 7) bp of donor DNA or with 5-bp duplications of target DNA in the remaining transconjugants. These data demonstrate functionality of the Tn1549-like element and attest that the transfer of the vanB operon between enterococci and human commensal anaerobes occurs in the intestinal environment.

Glutamate dehydrogenase (GDH) of Clostridium symbiosum, like GDH from other species, is inactivated by pyridoxal 5'-phosphate (pyridoxal-P). This inactivation follows a similar pattern to that for beef liver GDH, in which a non-covalent GDH-pyridoxal-P complex reacts slowly to form a covalent complex in which pyridoxal-P is in a Schiff's-base linkage to lysine residues. [formula: see text] The equilibrium constant of this first-order reaction on the enzyme surface determines the final extent of inactivation observed [S. S. Chen and P. C. Engel (1975) Biochem. J. 147, 351-358]. For clostridial GDH, the maximal inactivation obtained was about 70%, reached after 10 min with 7 mM pyridoxal-P at pH 7. In keeping with the model, (a) inactivation became irreversible after reduction with NaBH4. (b) The NaBH4-reduced enzyme showed a new absorption peak at 325 nm. (c) Km values for NAD+ and glutamate were unaltered, although Vmax values were decreased by 70%. Kinetic analysis of the inactivation gave values of 0.81 +/- 0.34 min-1 for k3 and 3.61 +/- 0.95 mM for k2/k1. The linear plot of 1/(1-R) against 1/[pyridoxal-P], where R is the limiting residual activity reached in an inactivation reaction, gave a slightly higher value for k2/k1 of 4.8 +/- 0.47 mM and k4 of 0.16 +/- 0.01 min-1. NADH, NAD+, 2-oxoglutarate, glutarate and succinate separately gave partial protection against inactivation, the biggest effect being that of 40 mM succinate (68% activity compared with 33% in the control). Paired combinations of glutarate or 2-oxoglutarate and NAD+ gave slightly better protection than the separate components, but the most effective combination was 40 mM 2-oxoglutarate with 1 mM NADH (85% activity at equilibrium). 70% inactivated enzyme showed an incorporation of 0.7 mM pyridoxal-P/mol subunit, estimated spectrophotometrically after NaBH4 reduction, in keeping with the 1:1 stoichiometry for the inactivation. In a sample protected with 2-oxoglutarate and NADH, however, incorporation was 0.45 mol/mol, as against 0.15 mol/mol expected (85% active). Tryptic peptides of the enzyme, modified with and without protection, were purified by HPLC. Two major peaks containing phosphopyridoxyllysine were unique to the unprotected enzyme. These peaks yielded three peptide sequences clearly homologous to sequences of other GDH species. In each case, a gap at which no obvious phenylthiohydantoin-amino-acid was detected, matched a conserved lysine position. The gap was taken to indicate phosphopyridoxyllysine which had prevented tryptic cleavage.(ABSTRACT TRUNCATED AT 400 WORDS)

The gene encoding the NAD(+)-dependent glutamate dehydrogenase (GDH) of Clostridium symbiosum was cloned using the polymerase chain reaction (PCR) because it could not be recovered by standard techniques. The nucleotide sequence of the gdh gene was determined and it was overexpressed from the controllable tac promoter in Escherichia coli so that active clostridial GDH represented 20% of total cell protein. The recombinant plasmid complemented the nutritional lesion of an E. coli glutamate auxotroph. There was a marked difference between the nucleotide compositions of the coding region (G + C = 52%) and the flanking sequences (G + C = 30% and 37%). The structural gene encoded a polypeptide of 450 amino acid residues and relative molecular mass (M(r) 49,295 which corresponds to a single subunit of the hexameric enzyme. The DNA-derived amino acid sequence was consistent with a partial sequence from tryptic and cyanogen bromide peptides of the clostridial enzyme. The N-terminal amino acid sequence matched that of the purified protein, indicating that the initiating methionine is removed post-translationally, as in the natural host. The amino acid sequence is similar to those of other bacterial GDHs although it has a Gly-Xaa-Gly-Xaa-Xaa-Ala motif in the NAD(+)-binding domain, which is more typical of the NADP(+)-dependent enzymes. The sequence data now permit a detailed interpretation of the X-ray crystallographic structure of the enzyme and the cloning and expression of the clostridial gene will facilitate site-directed mutagenesis.

The three-dimensional crystal structure of the NAD(+)-linked glutamate dehydrogenase from Clostridium symbiosum has been solved to 1.96 A resolution by a combination of isomorphous replacement and molecular averaging and refined to a conventional crystallographic R factor of 0.227. Each subunit in this multimeric enzyme is organised into two domains separated by a deep cleft. One domain directs the self-assembly of the molecule into a hexameric oligomer with 32 symmetry. The other domain is structurally similar to the classical dinucleotide binding fold but with the direction of one of the strands reversed. Difference Fourier analysis on the binary complex of the enzyme with NAD+ shows that the dinucleotide is bound in an extended conformation with the nicotinamide moiety deep in the cleft between the two domains. Hydrogen bonds between the carboxyamide group of the nicotinamide ring and the side chains of T209 and N240, residues conserved in all hexameric GDH sequences, provide a positive selection for the syn conformer of this ring. This results in a molecular arrangement in which the A face of the nicotinamide ring is buried against the enzyme surface and the B face is exposed, adjacent to a striking cluster of conserved residues including K89, K113, and K125. Modeling studies, correlated with chemical modification data, have implicated this region as the glutamate/2-oxoglutarate binding site and provide an explanation at the molecular level for the B type stereospecificity of the hydride transfer of GDH during the catalytic cycle.

In this paper we report the amino acid sequence of pyruvate phosphate dikinase (PPDK) from Bacteroides symbiosus as determined from the nucleotide sequence of the PPDK gene. Comparison of the B. symbiosus PPDK amino acid sequence with that of the maize PPDK [Matsuoka, M., Ozeki, Y., Yamamoto, N., Hirano, H., Kamo-Murakami, Y., & Tanaka, Y. (1988) J. Biol. Chem. 263, 11080] revealed long stretches of homologous sequence (greater than 70% identity), which contributed to an overall sequence identity of 53%. The circular dichrosim spectra, hydropathy profiles, and calculated secondary structural elements of the two dikinases suggest that they may have very similar tertiary structures as well. A comparison made between the amino acid sequence of the maize and B. symbiosus dikinase with other known protein sequences revealed homology, concentrated in three stretches of sequences, to a mechanistically related enzyme, enzyme I of the Escherichia coli PEP: sugar phosphotransferase system [Saffen, D. W., Presper, K. A., Doering, T. L., Roseman, S. (1987) J. Biol. Chem. 262, 16241]. It is proposed that (i) these three stretches of sequence constitute the site for PEP binding and catalysis and a possible site for the regulation of enzymatic activity and (ii) the conserved sequences exist in a third mechanistically related enzyme, PEP synthase.

The amino acid sequence is reported for CNBr and tryptic peptide fragments of the NAD(+)-dependent glutamate dehydrogenase of Clostridium symbiosum. Together with the N-terminal sequence, these make up about 75% of the total sequence. The sequence shows extensive similarity with that of the NADP(+)-dependent glutamate dehydrogenase of Escherichia coli (52% identical residues out of the 332 compared) allowing confident placing of the peptide fragments within the overall sequence. This demonstrated sequence similarity with the E. coli enzyme, despite different coenzyme specificity, is much greater than the similarity (31% identities) between the GDH's of C. symbiosum and Peptostreptococcus asaccharolyticus, both NAD(+)-linked. The evolutionary implications are discussed. In the 'fingerprint' region of the nucleotide binding fold the sequence Gly X Gly X X Ala is found, rather than Gly X Gly X X Gly. The sequence found here has previously been associated with NADP+ specificity and its finding in a strictly NAD(+)-dependent enzyme requires closer examination of the function of this structural motif.

Glutaconyl-CoA decarboxylase (Gcd) couples the biotin-dependent decarboxylation of glutaconyl-CoA with the generation of an electrochemical Na(+) gradient. Sequencing of the genes encoding all subunits of the Clostridium symbiosum decarboxylase membrane complex revealed that it comprises two distinct biotin carrier subunits, GcdC(1) and GcdC(2), which differ in the length of a central alanine- and proline-rich linker domain. Co-crystallization of the decarboxylase subunit GcdA with the substrate glutaconyl-CoA, the product crotonyl-CoA, and the substrate analogue glutaryl-CoA, respectively, resulted in a high resolution model for substrate binding and catalysis revealing remarkable structural changes upon substrate binding. Unlike the GcdA structure from Acidaminococcus fermentans, these data suggest that in intact Gcd complexes, GcdA is associated as a tetramer crisscrossed by a network of solvent-filled tunnels.

A novel strictly anaerobic, vancomycin-resistant, Gram-positive coccus (strain CCRI-16,110(T)) was isolated from a human faecal specimen. This strain was characterized using morphological, biochemical and molecular taxonomic methods. The organism was unable to hydrolyse aesculin and failed to produce acid from cellobiose, d-lactose and alpha-raffinose. Acetic acid was the sole product of glucose fermentation by the organism. On the basis of 16S rRNA and tuf gene sequence comparison, strain CCRI-16,110(T) was most closely related to species of the genus Ruminococcus and formed a hitherto unknown sublineage within the Clostridium coccoides rRNA cluster of organisms (cluster XIVa). Based on phenotypic and phylogenetic evidence, a novel species, Ruminococcus gauvreauii sp. nov., is proposed. The type strain is CCRI-16,110(T) (=NML 060141(T) =CCUG 54,292(T) =JCM 14987(T)).

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.

The hyperthermophile Pyrococcus furiosus is one of the most thermostable organisms known, with an optimum growth temperature of 100 degrees C. The proteins from this organism display extreme thermostability. We have undertaken the structure determination of glutamate dehydrogenase from P. furiosus in order to gain further insights into the relationship between molecular structure and thermal stability. The structure of P. furiosus glutamate dehydrogenase, a homohexameric enzyme, has been determined at 2.2 A resolution and compared with the structure of glutamate dehydrogenase from the mesophile Clostridium symbiosum. Comparison of the structures of these two enzymes has revealed one major difference: the structure of the hyperthermophilic enzyme contains a striking series of ion-pair networks on the surface of the protein subunits and buried at both interdomain and intersubunit interfaces. We propose that the formation of such extended networks may represent a major stabilizing feature associated with the adaptation of enzymes to extreme temperatures.

We have solved the structure of the binary complex of the glutamate dehydrogenase from Clostridium symbiosum with glutamate to 1.9 A resolution. In this complex, the glutamate side-chain lies in a pocket on the enzyme surface and a key determinant of the enzymic specificity is an interaction of the substrate gamma-carboxyl group with the amino group of Lys89. In the apo-enzyme, Lys113 from the catalytic domain forms an important hydrogen bond to Asn373, in the NAD(+)-binding domain. On glutamate binding, the side-chain of this lysine undergoes a significant movement in order to optimize its hydrogen bonding to the alpha-carboxyl group of the substrate. Despite this shift, the interaction between Lys113 and Asn373 is maintained by a large-scale conformational change that closes the cleft between the two domains. Modelling studies indicate that in this "closed" conformation the C-4 of the nicotinamide ring and the alpha-carbon atom of the amino acid substrate are poised for efficient hydride transfer. Examination of the structure has led to a proposal for the catalytic activity of the enzyme, which involves Asp165 as a general base, and an enzyme-bound water molecule, hydrogen-bonded to an uncharged lysine residue, Lys125, as an attacking nucleophile in the reaction.

Protein chemical studies of NAD(+)-dependent glutamate dehydrogenase (GDH; EC 1.4.1.2) from Clostridium symbiosum indicate only two cysteine residues/subunit, in good agreement with the gene sequence. Experiments with various thiol-modifying reagents reveal that in native clostridial GDH only one of these two cysteines is accessible for reaction. This residue does not react with iodoacetate, iodoacetamide, N-ethylmaleimide or N-phenylmaleimide, but reaction with either p-chloromercuribenzene sulphonate or 5,5'-dithiobis(2-nitrobenzoic acid) causes complete inactivation, preventable by NAD+ or NADH but not by glutamate or 2-oxoglutarate. Protection studies with combinations of substrates show that glutamate enhances protection by NADH, whereas 2-oxoglutarate diminishes it. These studies were also used to determine a dissociation constant (0.69 mM) for the enzyme-NAD+ complex. Similar data for NADH indicated mildly cooperative binding with a Hill coefficient of 1.32. The significance of these results is discussed in the light of the high-resolution crystallographic structure for clostridial GDH and in relation to information for GDH from other sources.

Proteolysis of Clostridium symbiosum pyruvate phosphate dikinase (PPDK) in its free or phosphorylated state with subtilisin Carlsberg followed two different cleavage pathways. The major pathway involved initial cleavage of the holoenzyme (93 kDa) into a stable 25-kDa N-terminal fragment and transiently stable 67-kDa C-terminal fragment. The 67-kDa fragment was cleaved to generate a stable 35-kDa fragment and an unstable 30-kDa fragment (containing the catalytic histidine). Proteolytic cleavage via the minor pathway divided the holoenzyme into an unstable 37-kDa N-terminal piece (which was further cleaved to the stable 25-kDa fragment produced in the major pathway) and a transiently stable 55-kDa C-terminal fragment. The 55-kDa fragment was then cleaved to produce the stable 35-kDa fragment produced by the major pathway. The cleavage pattern of PPDK complexed with the ATP analog adenyl imidodiphosphate was identical to that of the free enzyme, only the rate of cleavage as slower. In contrast, proteolysis of the phosphorylenzyme-oxalate complex generated the 55-kDa fragment indicating that oxalate binding induces a change in protein conformation. Treatment of PPDK with [1-14C]bromopyruvate followed by proteolysis revealed selective radiolabeling of the stable 35-kDa fragment while similar experiments with [14C]2',3'-dialdehyde adenosine 5'-monophosphate resulted in selective radiolabeling of the stable 25-kDa fragment. These results were interpreted to suggest that PPDK contains several structural domains and that the catalytic histidine, the pyruvate binding site, and the ATP binding site may be located on different domains.

A putative catalytic aspartyl residue, Asp-165, in the active site of clostridial glutamate dehydrogenase has been replaced with serine by site-directed mutagenesis. The mutant enzyme is efficiently overexpressed in Escherichia coli as a soluble protein and can be successfully purified by the dye-ligand chromatographic procedure normally employed for the wild-type enzyme. By several criteria, including circular dichroism spectrum, sulphydryl reactivity with Ellman's reagent, crystallization and mobility in non-denaturing electrophoresis, the enzyme appears to be correctly folded. NAD+ protects the D165S mutant against modification by Ellman's reagent, suggesting unimpaired binding of coenzyme. In standard assays the specific activity is decreased 10(3)-fold in the reductive amination reaction and 10(5)-fold for oxidative deamination. Kinetic studies show that apparent Km values for NADH and 2-oxoglutarate are almost unchanged. The large reduction in the reaction rate coincides with a weakening of the affinity for ammonium ion (Km > 300 mM, compared with 60 mM for the wild-type). The data are entirely consistent with the direct involvement of D165 in catalysis rather than in the binding of coenzyme or 2-oxoglutarate.

Pyruvate phosphate dikinase (PPDK) catalyzes the interconversion of adenosine 5'-triphosphate (ATP), orthophosphate (Pi), and pyruvate with adenosine 5'-monophosphate (AMP), pyrophosphate (PPi), and phosphoenolpyruvate (PEP). The reaction takes place according to the following steps: (1) E+ATP+P(i)<-->E-PP.AMP.P(i), (2) E-PP.AMP.P(i)<-->E-P+AMP+PP(i), and (3) E-P+pyruvate<-->E+PEP, where E represents free enzyme; E-PP, pyrophosphorylenzyme; and E-P, phosphorylenzyme. Steps 1 and 2 comprise the nucleotide partial reaction, and step 3 comprises the pyruvate partial reaction. The present studies were carried out to locate amino acid residues within the primary structure of Clostridium symbiosum PPDK participating in the catalysis of the pyruvate partial reaction. The enzyme was treated with the affinity label [1-14C]bromopyruvate, reduced with NaBH4, proteolyzed with trypsin, and chromatographed on an HPLC column. The radiolabeled tryptic peptide isolate was sequenced to reveal Cys 831 as the site of alkylation. Using PCR techniques Cys 831 was replaced by Ala, and the C831A PPDK mutant formed was then subjected to kinetic analysis. Rapid quench studies of single turnover reactions on the enzyme showed that the mutant is as efficient as wild-type PPDK in catalyzing the nucleotide partial reaction while it is unable to catalyze the pyruvate partial reaction. These results were interpreted as evidence for a role of Cys 831 in pyruvate/PEP binding and/or catalysis.

Pyruvate phosphate dikinase contains a pivotal histidyl residue which functions to mediate the transfer of phosphoryl moieties during the reaction catalyzed by the enzyme. The tryptic peptide which contains this essential histidyl residue has been isolated by a two-step procedure originally developed by Wang and co-workers [Wang, T., Jurasek, L., & Bridger, W. A. (1972) Biochemistry 11, 2067]. This peptide has been sequenced by the manual dansyl-Edman procedure and is shown to be NH2-Gly-Gly-Met-Thr-Ser-His-Ala-Ala-Val-Val-Ala-Arg-CO2H. There is no readily interpretable homology between this peptide and other phosphorylated histidyl peptides previously isolated from other enzymes. By use of Chou & Fasman [Chou, P. Y., & Fasman, G. D. (1974) Biochemistry 13, 222], it is predicted that the sequence contains an alpha helix from the methionine residue through to the carboxyl terminal arginine residue.

Pyruvate phosphate dikinase (PPDK) catalyzes the interconversion of ATP, Pi, and pyruvate with AMP, PPi, and PEP in three partial reactions: (1) E + ATP --> E.ATP --> E-PP.AMP, (2) E-PP.AMP + Pi --> E-PP.AMP.Pi --> E-P.AMP.PPi, and (3) E-P + pyruvate --> E-P.pyruvate --> E.PEP. The Clostridium symbiosum PPDK structure consists of N-terminal, central, and C-terminal domains. The N-terminal and central domains catalyze partial reactions 1 and 2 whereas the C-terminal and central domains catalyze partial reaction 3. The goal of the present work is to determine where on the N-terminal domain catalysis of partial reactions 1 and 2 occurs and, in particular, where the Pi binding site is located. Computer modeling studies implicated Arg337 as a key residue for Pi binding. This role was tested by site-directed mutagenesis. The R337A PPDK was shown to be impaired in catalysis of the forward (kcat 300-fold lower) and reverse (kcat 30-fold lower) full reactions. Time courses for the single turnover reactions were measured to show that catalysis of partial reaction 1 is 5-fold slower in the mutant, catalysis of the second partial reaction is 140-fold slower in the mutant, and catalysis of the third partial reaction is unaffected. With the exception of the mutation site, the crystal structure of the R337A PPDK closely resembles the structure of the wild-type protein. Thus, the altered kinetic properties observed for this mutant are attributed solely to the elimination of the interaction between substrate and the guanidinium group of the Arg337 side chain. On the basis of these findings we propose that the Pi binding site is located within the crevice of the PPDK N-terminal domain, at a site that is flanked by the ATP beta-P and the Mg2+ cofactor.

Comparisons of the structures of glutamate dehydrogenase (GluDH) and leucine dehydrogenase (LeuDH) have suggested that two substitutions, deep within the amino acid binding pockets of these homologous enzymes, from hydrophilic residues to hydrophobic ones are critical components of their differential substrate specificity. When one of these residues, K89, which hydrogen-bonds to the gamma-carboxyl group of the substrate l-glutamate in GluDH, was altered by site-directed mutagenesis to a leucine residue, the mutant enzyme showed increased substrate activity for methionine and norleucine but negligible activity with either glutamate or leucine. In order to understand the molecular basis of this shift in specificity we have determined the crystal structure of the K89L mutant of GluDH from Clostridium symbiosum. Analysis of the structure suggests that further subtle differences in the binding pocket prevent the mutant from using a branched hydrophobic substrate but permit the straight-chain amino acids to be used as substrates. The three-dimensional crystal structure of the GluDH from C. symbiosum has been previously determined in two distinct forms in the presence and absence of its substrate glutamate. A comparison of these two structures has revealed that the enzyme can adopt different conformations by flexing about the cleft between its two domains, providing a motion which is critical for orienting the partners involved in the hydride transfer reaction. It has previously been proposed that this conformational change is triggered by substrate binding. However, analysis of the K89L mutant shows that it adopts an almost identical conformation with that of the wild-type enzyme in the presence of substrate. Comparison of the mutant structure with both the wild-type open and closed forms has enabled us to separate conformational changes associated with substrate binding and domain motion and suggests that the domain closure may well be a property of the wild-type enzyme even in the absence of substrate.

The subunit of the enzyme glutamate dehydrogenase comprises two domains separated by a cleft harboring the active site. One domain is responsible for dinucleotide binding and the other carries the majority of residues which bind the substrate. During the catalytic cycle a large movement between the two domains occurs, closing the cleft and bringing the C4 of the nicotinamide ring and the Calpha of the substrate into the correct positioning for hydride transfer. In the active site, two residues, K89 and S380, make interactions with the gamma-carboxyl group of the glutamate substrate. In leucine dehydrogenase, an enzyme belonging to the same superfamily, the equivalent residues are L40 and V294, which create a more hydrophobic specificity pocket and provide an explanation for their differential substrate specificity. In an attempt to change the substrate specificity of glutamate dehydrogenase toward that of leucine dehydrogenase, a double mutant, K89L,S380V, of glutamate dehydrogenase has been constructed. Far from having a high specificity for leucine, this mutant appears to be devoid of any catalytic activity over a wide range of substrates tested. Determination of the three-dimensional structure of the mutant enzyme has shown that the loss of function is related to a disordering of residues linking the enzyme's two domains, probably arising from a steric clash between the valine side chain, introduced at position 380 in the mutant, and a conserved threonine residue, T193. In leucine dehydrogenase the steric clash between the equivalent valine and threonine side chains (V294, T134) does not occur owing to shifts of the main chain to which these side chains are attached. Thus, the differential substrate specificity seen in the amino acid dehydrogenase superfamily arises from both the introduction of simple point mutations and the fine tuning of the active site pocket defined by small but significant main chain rearrangements.