Allosteric behaviour of 1:5 hybrids of mutant subunits of Clostridium symbiosum glutamate dehydrogenase differing in their amino acid specificity.

Hybrid hexamers were made by refolding mixtures of two mutant forms of clostridial glutamate dehydrogenase. Mutant Cys320Ser (C320S) has a similar activity to the wild-type enzyme, but is unreactive with Ellman's reagent, 5,5'-dithiobis(2-nitrobenzoate) (DTNB). The triple mutant Lys89Leu/Ala163Gly/Ser380Ala (K89L/A163G/S380A), active with norleucine but not glutamate, is inactivated by DTNB, since the amino acid residue at position 320 is a cysteine residue. The chosen ratio favoured 1:5 hybrids of the triple mutant and C320S. The renatured mixture was treated with DTNB and separated on an NAD(+)-agarose column to which only C320S subunits bind tightly. Fractions were monitored for glutamate and norleucine activity and for releasable thionitrobenzoate to establish subunit stoichiometry. A fraction highly enriched in the 1:5 hybrid was identified. Homohexamers (C320S with 40 mM glutamate and 1 mM NAD(+) at pH 8.8, or K89L/A163G/S380A with 70 mM norleucine and 1 mM NAD(+) at pH 8.5) showed allosteric activation; succinate activated C320S approx. 50-fold (EC(50)=70 mM, h=2.4), and glutarate gave approx. 30-fold activation (EC(50)=35 mM, h=2.3). For the triple mutant, corresponding values were 80 mM and 2.2 for succinate, and 75 mM and 1.7 for glutarate, but maximal activation was only about 2-fold. In the 1:5 hybrid, with only one norleucine-active subunit per hexamer, responses to glutarate and succinate were still co-operative, and activation was more extensive than in the triple mutant homohexamer. A single norleucine-active subunit can thus respond co-operatively to a substrate analogue at the other five inactive sites. On the other hand, similar hyperbolic dependence on the norleucine concentration for the hybrid and the triple mutant homohexamer reflected the inability of C320S subunits to bind norleucine. With glutamate at pH 8.8, an h value of 3.6 was obtained for the 1:5 hybrid, in contrast with an h value of 5.2 for the C320S homohexamer. The "foreign" subunit evidently impedes inter-subunit communication to some extent.

Construction, separation and properties of hybrid hexamers of glutamate dehydrogenase in which five of the six subunits are contributed by the catalytically inert D165S.

In vitro subunit hybridization was used to explore the basis of putative allosteric behaviour in clostridial glutamate dehydrogenase. C320S and D165S mutant enzymes were chosen to construct the hybrid proteins. The C320S mutant protein is fully active and shows normal allosteric properties but lacks the reactive cysteine. D165S is capable of binding both glutamate and NAD(+) but is catalytically inactive. The mutant proteins were denatured separately in 4 M urea, mixed in a 5 : 1 (D165S/C320S) ratio and diluted into a refolding mixture composed of 2 mM NAD(+), 1 M fluoride and artificial chaperones (4 mM polyoxyethylene 10 lauryl ether and 1.6 mM beta-cyclodextrin). Under these conditions approximately 50% refolding was achieved for both mutant proteins separately. The renatured mixture was concentrated and separated from denatured proteins and the components of the refolding mixture by ultrafiltration and ion-exchange chromatography. Ellman's reagent, 5,5'-dithiobis (2-nitrobenzoic acid) (DTNB), which binds close to the NAD(+) binding site, thus abolishing coenzyme binding in the wild-type enzyme, also reacts with D165S but has no effect on C320S. Modification by DTNB was coupled with dye-ligand affinity chromatography on a Procion Red HE-3B column in order to separate the hybrid mixture into fractions of defined composition. An optimized procedure based on salt gradient elution was developed. DTNB-modified 5 : 1 hybrids, with only one subunit capable of binding coenzyme, showed classical Michaelis-Menten kinetics when the NAD(+) concentration was varied, whereas removal of the thionitrobenzoate moieties that blocked the other five coenzyme binding sites in the hexamer reinstated nonlinear behaviour, suggesting that 'nonlinear' behaviour of the native enzyme and the hybrid with six coenzyme binding sites depends on binding to multiple sites. When assayed at high pH with increasing glutamate concentration, the sample with only one active subunit showed reduced sigmoidicity in the dependence of reaction rate on glutamate concentration (h = 3.0) compared with native C320S with six active subunits (h = 5.2) suggesting that the interaction between the subunits was reduced but not abolished completely. Catalytically silent subunits can thus still contribute to cooperativity.

5,5'-Dithiobis-(2-nitrobenzoic acid) as a probe for a non-essential cysteine residue at the medium chain acyl-coenzyme A dehydrogenase binding site of the human 'electron transferring flavoprotein' (ETF).

Human 'electron transferring flavoprotein' (ETF) was inactivated by the thiol-specific reagent 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB). The kinetic profile showed the reaction followed pseudo-first-order kinetics during the initial phase of inactivation. Monitoring the release of 5-thio-2-nitrobenzoate (TNB) showed that modification of 1 cysteine residue was responsible for the loss of activity. The inactivation of ETF by DTNB could be reversed upon incubation with thiol-containing reagents. The loss of activity was prevented by the inclusion of medium chain acyl-CoA dehydrogenase (MCAD) and octanoyl-CoA. Cyanolysis of the DTNB modified-ETF with KCN led to the release of TNB accompanied presumably by the formation of the thio-cyano enzyme and with almost full recovery of activity. Conservation studies and the lack of 100% inactivation, however, suggested that this cysteine residue is not essential for the interaction with MCAD.

Specificity of coenzyme analogues and fragments in promoting or impeding the refolding of clostridial glutamate dehydrogenase.

NAD+ facilitates high-yield reactivation of clostridial glutamate dehydrogenase (GDH) after unfolding in urea. The specificity of this effect has been explored by using analogues and fragments of NAD+. The adenine portion, unlike the nicotinamide portion, is important for reactivation. Alteration in the nicotinamide portion, in acetylpyridine adenine dinucleotide, has little effect, whereas loss of the 6-NH2 substitution on the adenine ring, in 6-deamino NAD, diminishes the effectiveness of the nucleotide in promoting refolding. Also ADP-ribose, lacking nicotinamide, promotes reactivation whereas NMN-phosphoribose, lacking the adenine, does not. Of the smaller fragments, those containing an adenosine moiety, and especially those with one or more phosphate groups, impede the refolding ability of NAD+, and are able to bind to the folding intermediate though unable to facilitate refolding. These results are interpreted in terms of the known 3D structure for clostridial glutamate dehydrogenase. It is assumed that the refolding intermediate has a more or less fully formed NAD+-binding domain but a partially disordered substrate-binding domain and linking region. Binding of NAD+ or ADP-ribose appears to impose new structural constraints that result in completion of the correct folding of the second domain, allowing association of enzyme molecules to form the native hexamer.

Group specific antibodies against the putative AMP-binding domain signature SGTTGXPKG in peptide synthetases and related enzymes.

The superfamily of adenylate forming enzymes including peptide synthetases, acyl-CoA synthetases and insect luciferases is readily identified by the signature sequence SGTTGXPKG. This sequence including an invariant lysyl residue is located in a disordered loop region and was predicted to be of significant antigenicity. Antibodies were generated employing YTSGTTGRPKGC attached to bovine serum albumin and have been successfully used to identify respective enzymes and adenylate forming domains in multienzyme systems. These include the delta-(L-alpha-aminoadipyl)-L-cysteinyl-D-valine synthetases of Aspergillus nidulans and Acremonium chrysogenum, gramicidin S synthetase 1 and tyrocidine synthetase 1 from Bacillus brevis, acetyl-CoA synthetase from Alcaligenes eutrophus and a putative peptide synthetase from Metarhizium anisopliae. Weaker or no reactions are observed when the amino acid in position X in the protein is non-basic or hydrophobic, which is respectively the case for gramicidin S synthetase 1 and luciferase.

Intersubunit communication in hybrid hexamers of K89L/A163G/S380A and C320S mutants of glutamate dehydrogenase from Clostridium symbiosum.

The triple mutant K89L/A163G/S380A (inactive with glutamate but active with L-Nle and L-Met) and C320S (fully active with glutamate, entirely inactive with L-Nle and L-Met, and also lacking reactive cysteine) mutant of glutamate dehydrogenase (EC 1.4.1.2) of Clostridium symbiosum could be completely denatured by urea with the loss of structure and activity. The mutants denatured by urea could be reassociated to give stable hexamers with recovery of activity of approximately 67% by dilution in 0.1 M potassium phosphate buffer (pH 7.0) containing 2 mM NAD+. The native, urea-denatured, and renatured states of mutant enzymes were characterized by size exclusion chromatography on FPLC and native PAGE. Intersubunit hybrid hexamers containing five subunits of triple mutant and one subunit of C320S mutant were constructed by in vitro subunit hybridization followed by affinity chromatography. Kinetic analysis showed that a 5:1 hybrid hexamer, with only one C320S subunit able to bind NAD+ after DTNB modification, shows classical Michaelis-Menten kinetics with regard to NAD+. This contrasts with the apparent negative co-operativity shown by pure C320S hexamers and suggests that the interaction in NAD+ binding among subunits is eliminated in the hybrid. After removal of thionitrobenzoate, however, all of the subunits in the hybrid are able to bind NAD+. In this state the hybrid enzyme showed slight deviation from classical behavior with regard to NAD+, indicating reintroduction of some level of allosteric interaction. The hybrid hexamer also showed much reduced co-operativity with glutamate at pH 8.8, with a Hill coefficient of 3 for DTNB-treated hybrid (as compared to 5.2 for the pure C320S mutant) and 2.2 for the untreated hybrid. The fact that co-operativity in glutamate binding is not entirely eliminated correlates with evidence that the triple mutant subunits, though inactive toward glutamate, can nevertheless still bind this amino acid.

Alteration of the quaternary structure of glutamate dehydrogenase from Clostridium symbiosum by a single mutation distant from the subunit interfaces.

X-ray crystallographic studies have previously shown that glutamate dehydrogenase from Clostridium symbiosum is a homohexamer. Mutation of the active-site aspartate-165 to histidine causes an alteration in the structural properties of the enzyme. The mutant enzyme, D165H exists predominantly as a single species of lower molecular mass than the wild-type enzyme as indicated by gel filtration and sedimentation velocity analysis. The latter technique gives an S20,w value for D165H of (6.07 +/- 0.01)S which compares with (11.08 +/- 0.01)S for the wild-type, indicative of alteration of the homohexameric quaternary structure of the native enzyme to a dimeric form, a result confirmed by sedimentation equilibrium experiments. Further support for this is provided by chemical modification by Ellman's reagent of cysteine-144 in the mutant, a residue which is buried at the dimer-dimer interface in the wild-type enzyme and is normally inaccessible to modification. The results suggest a possible structural route for communication between the active sites and subunit interfaces which may be important for relaying signals between subunits in allosteric regulation of the enzyme.

Construction of a dimeric form of glutamate dehydrogenase from Clostridium symbiosum by site-directed mutagenesis.

By using site-directed mutagenesis, Phe-187, one of the amino-acid residues involved in hydrophobic interaction between the three identical dimers comprising the hexamer of Clostridium symbiosum glutamate dehydrogenase (GDH), has been replaced by an aspartic acid residue. Over-expression in Escherichia coli led to production of large amounts of a soluble protein which, though devoid of GDH activity, showed the expected subunit M(r) on SDS-PAGE, and cross-reacted with an anti-GDH antibody preparation in Western blots. The antibody was used to monitor purification of the inactive protein. F187D GDH showed altered mobility on non-denaturing electrophoresis, consistent with changed size and/or surface charge. Gel filtration on a calibrated column indicated an M(r) of 87000 +/- 3000. The mutant enzyme did not bind to the dye column routinely used in preparing wild-type GDH. Nevertheless suspicions of major misfolding were allayed by the results of chemical modification studies: as with wild-type GDH, NAD+ completely protected one-SH group against modification by DTNB, implying normal coenzyme binding. A significant difference, however, is that in the mutant enzyme both cysteine groups were modified by DTNB, rather than C320 only. The CD spectrum in the far-UV region indicated no major change in secondary structure in the mutant protein. The near-UV CD spectrum, however, was less intense and showed a pronounced Phe contribution, possibly reflecting the changed environment of Phe-199, which would be buried in the hexamer. Sedimentation velocity experiments gave corrected coefficients S20,W of 11.08 S and 5.29 S for the wild-type and mutant proteins. Sedimentation equilibrium gave weight average molar masses M(r,app) of 280000 +/- 5000 g/mol. consistent with the hexameric structure for the wild-type protein and 135000 +/- 3000 g/mol for F187D. The value for the mutant is intermediate between the values expected for a dimer (98000) and a trimer (147000). To investigate the basis of this, sedimentation equilibrium experiments were performed over a range of protein concentrations. M(r,app) showed a linear dependence on concentration and a value of 108 118 g/mol at infinite dilution. This indicates a rapid equilibrium between dimeric and hexameric forms of the mutant protein with an equilibrium constant of 0.13 l/g. An independent analysis of the radial absorption scans with Microcal Origin software indicated a threefold association constant of 0.11 l/g. Introduction of the F187D mutation thus appears to have been successful in producing a dimeric GDH species. Since this protein is inactive it is possible that activity requires subunit interaction around the 3-fold symmetry axis. On the other hand this mutation may disrupt the structure in a way that cannot be extrapolated to other dimers. This issue can only be resolved by making alternative dimeric mutants.

Identification of the reactive cysteine in clostridial glutamate dehydrogenase by site-directed mutagenesis and proof that this residue is not strictly essential.

Cys320 of clostridial glutamate dehydrogenase, a residue close to the coenzyme binding site, has been replaced by serine. The mutant enzyme was successfully overproduced and purified by using the normal protocol for the wild-type enzyme and also behaved indistinguishably from wild-type enzyme on native and SDS-PAGE. The specific activity was significantly enhanced in assays at both pH 7 (+90%) and pH 8 (+38%). Detailed initial-rate kinetics revealed that at pH 7 this increase was mainly attributable to a higher maximum rate, since the Km values for both substrates were marginally increased. In the mutant enzyme the inactivating reaction with DTNB that characterizes the wild-type enzyme is completely eliminated. This proves that inactivation of the wild-type enzyme is due to modification of Cys320, that nevertheless Cys320 is not strictly essential for catalytic activity and that the remaining cysteine residue at position 144 is inaccessible to DTNB. Provision of an engineered subunit with a correct native structure but with its DTNB titre decreased from 1 to 0 mol/mol now offers a valuable tool for counting subunits in hybrid oligomers.

Activity staining of halophilic enzymes: substitution of salt with a zwitterion in non-denaturing electrophoresis.

Several NAD(P)(+)-dependent dehydrogenases were partially purified from Halobacterium halobium. When salt (2M (NH4)2SO4) was replaced with glycine betaine (4M or 6M), the zwitterion stabilised activity less completely than the salt. Nevertheless most of the enzyme activity still remained after 90h, e.g. 70% for malate dehydrogenase. This level of stabilisation permitted non-denaturing gel electrophoresis in 4M betaine after dialysis to replace salt. Coomassie Blue staining showed good separation of the proteins, and activity staining, hitherto impossible for halophilic enzymes, readily identified the individual dehydrogenase bands. Transfer of activity-stained gels to Coomassie staining solution halted background formazan staining and showed up activity and other protein bands in contrasting colours.

Site and significance of chemically modifiable cysteine residues in glutamate dehydrogenase of Clostridium symbiosum and the use of protection studies to measure coenzyme binding.

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.

Is pyridoxal 5'-phosphate an affinity label for phosphate-binding sites in proteins?: The case of bovine glutamate dehydrogenase.

The effects of pyridoxal 5'-phosphate (PalP) on ox liver glutamate dehydrogenase (94% inactivation by 1.8 mM reagent at pH 7 and 25 degrees C) have been compared with those of three analogues, 5'-deoxypyridoxal (96% inactivation), pyridoxal 5'-sulphate (97%) and pyridoxal 5-methylsulphonate (94%), in order to establish whether PalP acts as an affinity label for this enzyme. Like PalP and unlike pyridoxal, which is a much less potent inactivator, none of the analogues has a free 5'-OH group to cyclize with the aldehyde function. The result with 5'-deoxypyridoxal shows that a negative charge, such as that of the phosphate group, is not required for efficient inactivation. With all four reagents, addition of an excess of cysteine or lysine led to 90-100% re-activation over 3-20 h. Dialysis also caused reactivation to a similar extent. A combination of 2.15 mM NADH, 1 mM GTP and 10 mM 2-oxoglutarate gave complete protection against PalP, but only partial protection against the analogues. 5'-Deoxypyridoxal still caused 20-25% inactivation in the presence of the protection mixture. Absorbance measurements after reduction with NaBH4 show the characteristic features of a reduced Schiff's base and allowed estimation of the extent of reaction. With all the reagents the protection mixture decreased incorporation by about 1 mol/mol, but levels of incorporation without protection varied from about 2 mol/mol for PalP up to about 5 mol/mol for 5'-deoxypyridoxal. The labelling at additional sites may explain the residual inactivation in the presence of potent protecting agents.

The glutamate dehydrogenase gene of Clostridium symbiosum. Cloning by polymerase chain reaction, sequence analysis and over-expression in Escherichia coli.

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.

Subunit assembly and active site location in the structure of glutamate dehydrogenase.

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.

A pH-dependent activation-inactivation equilibrium in glutamate dehydrogenase of Clostridium symbiosum.

1. On transferring Clostridium symbiosum glutamate dehydrogenase from pH 7 to assay mixtures at pH 8.8, reaction time courses showed a marked deceleration that was not attributable to the approach to equilibrium of the catalysed reaction. The rate became approximately constant after declining to 4-5% of the initial value. Enzyme, stored at pH 8.8 and assayed in the same mixture, gave an accelerating time course with the same final linear rate. The enzyme appears to be reversibly converted from a high-activity form at low pH to a low-activity form at high pH. 2. Re-activation at 31 degrees C upon dilution from pH 8.8 to pH 7 was followed by periodic assay of the diluted enzyme solution. At low ionic strength (5 mM-Tris/HCl), no re-activation occurred, but various salts promoted re-activation to a limiting rate, with full re-activation in 40 min. 3. Re-activation was very temperature-dependent and extremely slow at 4 degrees C, suggesting a large activation energy. 4. 2-Oxoglutarate, glutarate or succinate (10 mM) accelerated re-activation; L-glutamate and L-aspartate were much less effective. 5. The monocarboxylic amino acids alanine and norvaline appear to stabilize the inactive enzyme: 60 mM-alanine does not promote re-activation, and, as substrates at pH 8.8 for enzyme stored at pH 7, alanine and norvaline give progress curves showing rapid complete inactivation. 6. Mono- and di-nucleotides (AMP, ADP, ATP, NAD+, NADH, NADP+, CoA, acetyl-CoA) at low concentrations (10(-4)-10(-3) M) enhance re-activation at pH 7 and also retard inactivation at pH 8.8. 7. The re-activation rate is independent of enzyme concentration: ultracentrifuge experiments show no changes in molecular mass with or without substrates. 8. The activation-inactivation appears to be due to a slow pH-dependent conformational change that is sensitively responsive to the reactants and their analogues.

Kinetic studies of ox-liver glutamate dehydrogenase oxidative deamination of two glutamate analogues, L-threo-gamma-methylglutamate and L-alpha-amino-gamma-nitraminobutyrate, in the presence of the allosteric effector ADP.

Ox-liver glutamate dehydrogenase is known to utilise a wide range of amino acid substrates. Kinetic studies are presented here for L-threo-gamma-methylglutamate and L-alpha-amino-gamma-nitraminobutyrate in the presence of the allosteric effector ADP. The results presented are considered in the light of similar studies presented elsewhere in which the cofactor was systematically replaced by a variety of analogues. These amino acid analogues share the same pH optimum as glutamate, unlike the monocarboxylic amino acids including alanine and norvaline, and give linear double-reciprocal plots under the conditions used here. Studies with the alternative coenzymes have suggested an ordered addition of glutamate before coenzyme in the presence of ADP. The present results obtained under identical conditions support this conclusion.

The kinetic mechanism of ox liver glutamate dehydrogenase in the presence of the allosteric effector ADP. The oxidative deamination of L-glutamate.

In steady-state kinetic studies of ox liver glutamate dehydrogenase in 0.11 M-potassium phosphate buffer, pH7, at 25 degrees C, the concentration of ADP was varied from 0.5 to 1000 microM. Inhibition was observed except when the concentrations of both glutamate and coenzyme were high, when activation was seen. With NAD+ or NADP+ as coenzyme, 200 microM-ADP was sufficient to saturate the enzyme with respect to the major effect of this nucleotide. In the presence of 210 microM-ADP, widely varied concentrations of coenzyme give linear Lineweaver-Burk plots, in marked contrast with results obtained previously for kinetics without ADP. This has allowed evaluation for the reaction with NAD+, NADP+ and acetylpyridine-adenine dinucleotide (315 microM-ADP in the last case) of all four initial rate parameters, i.e. the phi coefficients in the equation: (Formula: see text) where A is coenzyme and B is glutamate. The relative constancy of phi B and of phi AB/phi A with the different coenzymes point to a compulsory-order mechanism with glutamate as the leading substrate. This conclusion, though unexpected, agrees well with various previous observations on the binding of oxidized coenzyme.

Butyryl-CoA dehydrogenase from Megasphaera elsdenii. Specificity of the catalytic reaction.

The absorption coefficient of butyryl-CoA dehydrogenase from Megasphaera elsdenii at 450 nm is determined as 14.4 mM-1 X cm-1 in the CoA-free form and 14.2 mM-1 X cm-1 in the CoA-liganded form (both yellow). The latter value is considerably higher than the earlier published estimate. Phenazine ethosulphate offers great advantages over phenazine methosulphate as a coupling dye in the catalytic assay despite giving lower Vmax. values (506 min-1 as compared with 1250 min-1 under the conditions used). The phenazine ethosulphate assay is used to establish a pH optimum of 8.05 for oxidation of 100 microM-butyryl-CoA. The rates of oxidation of a range of straight-chain, branched-chain and alicyclic acyl thioesters are used to provide the following information. Only straight-chain acyl groups containing 4-6 carbon atoms are easily accommodated by the postulated hydrophobic pocket of the enzyme. C-3-substituted acyl-CoA thioesters are not oxidized at a significant rate, suggesting that the C-3 pro-S-hydrogen atom of straight-chain substrates is partially exposed to the solvent. Acyl-CoA thioesters with substitutions at C-2 are oxidized, though at a lower rate than their straight-chain counterparts. This implies that the C-2 pro-S-hydrogen atom of straight-chain substrates is partially exposed to the solvent. Saturated alicyclic carboxylic acyl-CoA thioesters with 4-7 carbon atoms in the ring are oxidized, with maximal activity for the cyclohexane derivative. This implies that optimal oxidation requires a true trans orientation of the two departing hydrogen atoms. The strain imposed by bound unsaturated alicyclic acyl thioesters strikingly perturbs the flavin visible-absorption spectrum, with the exception of the cyclohex-2-ene derivative, which forms a complex with similar spectral properties to those of the crotonyl-CoA complex. In the thiol moiety of thioester substrates the amide bond of N-acetylcysteamine is essential for both binding and catalysis. The adenosine structure contributes substantially to strong binding, but is less important in determining the catalytic rate.

Beef liver glutamate dehydrogenase: effects of partial proteolysis with chymotrypsin.

1. After chymotryptic digestion of bovine glutamate dehydrogenase, the assay conditions determine whether activation or inhibition is observed. 2. The major fragments appear to remain physically associated. 3. Responses to both GTP and ADP are altered. Inhibition by GTP at pH 7 and 8 is almost abolished. 4. Out of various ligand combinations tested, GTP and NADH together provide the best protection against all the proteolytic effects.