Structures of glyceraldehyde 3-phosphate dehydrogenase in Neisseria gonorrhoeae and Chlamydia trachomatis.

Neisseria gonorrhoeae (Ng) and Chlamydia trachomatis (Ct) are the most commonly reported sexually transmitted bacteria worldwide and usually present as co-infections. Increasing resistance of Ng to currently recommended dual therapy of azithromycin and ceftriaxone presents therapeutic challenges for syndromic management of Ng-Ct co-infections. Development of a safe, effective, and inexpensive dual therapy for Ng-Ct co-infections is an effective strategy for the global control and prevention of these two most prevalent bacterial sexually transmitted infections. Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) is a validated drug target with two approved drugs for indications other than antibacterials. Nonetheless, any new drugs targeting GAPDH in Ng and Ct must be specific inhibitors of bacterial GAPDH that do not inhibit human GAPDH, and structural information of Ng and Ct GAPDH will aid in finding such selective inhibitors. Here, we report the X-ray crystal structures of Ng and Ct GAPDH. Analysis of the structures demonstrates significant differences in amino acid residues in the active sites of human GAPDH from those of the two bacterial enzymes suggesting design of compounds to selectively inhibit Ng and Ct is possible. We also describe an efficient in vitro assay of recombinant GAPDH enzyme activity amenable to high-throughput drug screening to aid in identifying inhibitory compounds and begin to address selectivity.

Development of a non-denaturing 2D gel electrophoresis protocol for screening in vivo uranium-protein targets in Procambarus clarkii with laser ablation ICP MS followed by protein identification by HPLC-Orbitrap MS.

Limited knowledge about in vivo non-covalent uranium (U)-protein complexes is largely due to the lack of appropriate analytical methodology. Here, a method for screening and identifying the molecular targets of U was developed. The approach was based on non-denaturing 1D and 2D gel electrophoresis (ND-PAGE and ND-2D-PAGE (using ND-IEF as first dimension previously described)) in conjunction with laser ablation inductively coupled plasma mass spectrometry (LA-ICP MS) for the detection of U-containing proteins. The proteins were then identified by µbore HPLC-Orbitrap MS/MS. The method was applied to the analysis of cytosol of hepatopancreas (HP) of a model U-bioaccumulating organism (Procambarus clarkii). The imaging of uranium in 2D gels revealed the presence of 11 U-containing protein spots. Six protein candidates (i.e. ferritin, glyceraldehyde-3-phosphate dehydrogenase, triosephosphate isomerase, cytosolic manganese superoxide dismutase (Mn-SOD), glutathione S transferase D1 and H3 histone family protein) were then identified by matching with the data base of crustacea Decapoda species (e.g. crayfish). Among them, ferritin was the most important one. This strategy is expected to provide an insight into U toxicology and metabolism.

Crystal structures of rice (Oryza sativa) glyceraldehyde-3-phosphate dehydrogenase complexes with NAD and sulfate suggest involvement of Phe37 in NAD binding for catalysis.

Cytosolic Oryza sativa glyceraldehyde-3-phosphate dehydrogenase (OsGAPDH), the enzyme involved in the ubiquitous glycolysis, catalyzes the oxidative phosphorylation of glyceraldehyde-3-phosphate to 1,3-biphosphoglycerate (BPG) using nicotinamide adenine dinucleotide (NAD) as an electron acceptor. We report crystal structures of OsGAPDH in three conditions of NAD-free, NAD-bound and sulfate-soaked forms to discuss the molecular determinants for coenzyme specificity. The structure of OsGAPDH showed a homotetramer form with each monomer comprising three domains-NAD-binding, catalytic and S-loop domains. NAD binds to each OsGAPDH subunits with some residues forming positively charged grooves that attract sulfate anions, as a simulation of phosphate groups in the product BPG. Phe37 not only forms a bottleneck to improve NAD-binding but also combines with Pro193 and Asp35 as key conserved residues for NAD-specificity in OsGAPDH. The binding of NAD alters the side-chain conformation of Phe37 with a 90° rotation related to the adenine moiety of NAD, concomitant with clamping the active site about 0.6 Å from the "open" to "closed" form, producing an increased affinity specific for NAD. Phe37 exists only in higher organisms, whereas it is replaced by other residues (Thr or Leu) with smaller side chains in lower organisms, which makes a greater distance between Leu34 and NAD of E. coli GAPDH than that between Phe37 and NAD of OsGAPDH. We demonstrated that Phe37 plays a crucial role in stabilizing NAD binding or intermediating of apo-holo transition, resulting in a greater NAD-dependent catalytic efficiency using site-directed mutagenesis. Phe37 might be introduced by evolution generating a catalytic advantage in cytosolic GAPDH.

Oxidative stress triggers thiol oxidation in the glyceraldehyde-3-phosphate dehydrogenase of Staphylococcus aureus.

The high-resolution two-dimensional protein gel electrophoresis technique combined with matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF MS) was used to analyse the oxidative stress response in Staphylococcus aureus COL. Exponentially growing cells were supplemented with 100 mM H2O2 leading to a growth arrest lasting 30 min. The comparison of the two-dimensional pattern of cytoplasmic protein extracts of stressed and unstressed cells revealed only a few changes in the protein synthesis profile. However, the isoelectric points of Gap (glyceraldehyde-3-phosphate dehydrogenase), AhpC (alkylhydroperoxide reductase) and MvaS (HMG-CoA-synthase) changed strikingly. For analysis of the modification of Gap, tandem hybrid mass spectrometry (Q-Star) was used. The observed pI shift resulted from the oxidation to sulphonic acid of cysteine 151, which is crucial for catalytic activity. A drop in ATP and a complete inactivation of Gap was accompanied by the growth arrest. About 30 min after the addition of H2O2, the damaged Gap was still present, but a new protein spot at the original location became visible, representing the newly synthesized enzyme that is active again. This is accompanied by the restoration of Gap enzyme activity, ATP levels and recovery of growth. There is a strong correlation between growth, ATP level and Gap activity under oxidative stress conditions, indicating that the H2O2-triggered Gap inactivation might be one reason for growth arrest under these conditions. Our data indicate that the damaged Gap protein was not repaired.

In vitro effect of metal ions on the activity of two amphibian glyceraldehyde-3-phosphate dehydrogenases: potential metal binding sites.

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH, EC 1.2.1.12) was purified from two amphibian species, Xenopus laevis and Pleurodeles waltl. Comparative studies revealed that the two proteins differ by their subunit molecular masses, pI values and V8 digested peptide maps. The effect of zinc, cadmium and copper ions on GAPDH enzymatic activity has been examined in vitro. A time, metal concentration and metal type dependent inhibition was observed for both enzymes. X. laevis and P. waltl GAPDHs exhibit a much greater sensitivity to copper than to cadmium or zinc ions. Different half-lives and differential sensitivity to various metals was observed between the two enzymes with P. waltl GAPDH being remarkably tolerant to cadmium ions compared to the X. laevis enzyme. In order to understand the differential sensitivity of the two enzymes to metals, we produced 3D models of both X. laevis and P. waltl GAPDH structures based upon known 3D structures of GAPDHs from other species. This necessitated, in a first step, to clone a 900 bp cDNA fragment encoding the nearly full-length P. waltl GAPDH. Spatial motif searches on the homology models indicated potential metal binding sites involving cysteine and histidine residues outside the catalytic sites, existing only in either the X. laevis or the P. waltl GAPDH sequences.

Structures of D-glyceraldehyde-3-phosphate dehydrogenase complexed with coenzyme analogues.

Crystal structures of GAPDH from Palinurus versicolor complexed with two coenzyme analogues, SNAD(+) and ADP-ribose, were determined by molecular replacement and refined at medium resolution to acceptable crystallographic factors and reasonable stereochemistry. ADP-ribose in the ADP-ribose-GAPDH complex adopts a rather extended conformation. The interactions between ADP-ribose and GAPDH are extensive and in a fashion dissimilar to the coenzyme NAD(+). This accounts for the strong inhibiting ability of ADP-ribose. The conformational changes induced by ADP-ribose binding are quite different to those induced by NAD(+) binding. This presumably explains the non-cooperative behaviour of the ADP-ribose binding. Unexpectedly, the SNAD(+)-GAPDH complex reveals pairwise asymmetry. The asymmetry is significant, including the SNAD(+) molecule, active-site structure and domain motion induced by the coenzyme analogue. In the yellow or red subunits [nomenclature of subunits is as in Buehner et al. (1974). J. Mol. Biol. 90, 25-49], SNAD(+) binds similarly, as does NAD(+) in holo-GAPDH. While, in the green or blue subunit, the SNAD(+) binds in a non-productive manner, resulting in a disordered thionicotinamide ring and rearranged active-site residues. The conformation seen in the yellow and red subunits of SNAD(+)-GAPDH is likely to represent the functional state of the enzyme complex in solution and thus accounts for the substrate activity of SNAD(+). A novel type of domain motion is observed for the binding of the coenzyme analogues to GAPDH. The possible conformational transitions involved in the coenzyme binding and the important role of the nicotinamide group are discussed.

A phosphate-stimulated NAD(P)+-dependent glyceraldehyde-3-phosphate dehydrogenase in Bacillus cereus.

Glyceraldehyde-3-phosphate dehydrogenase (GAPDH), a key enzyme of central carbon metabolism, was studied in a Bacillus cereus strain isolated from the phosphate layer from Morocco. Enzymatic assays with cell extracts demonstrated that when grown on Luria-Bertani (LB) medium, B. cereus contains a major NAD+-dependent GAPDH activity and only traces of NADP+-dependent activity, but in cells grown on Pi-supplemented LB medium a strong increase of the NADP+-dependent activity, that became predominant, occurs concurrently with a GAPDH protein increase. Our results show that B. cereus possesses two GAPDH activities, namely NAD+- and NADP+-dependent, catalyzed by two enzymes with distinct coenzyme specificity and different phosphate regulation patterns. The finding of a phosphate-stimulated NADP+-dependent GAPDH in B. cereus indicates that this bacterium can modulate its primary carbon metabolism according to phosphate availability.

Functional maps of the junctions between interglobular contacts and active sites in glycolytic enzymes -- a comparative analysis of the biochemical and structural data.

BACKGROUND: Oligomers and separate subunits of the glycolytic enzymes often have different catalytic properties. However, spectral data show an apparent lack of significant conformational changes during oligomerization. Since the conformation of an enzyme determines its catalytic properties, the structural mechanism(s) influencing the activity is of considerable interest. MATERIAL/METHODS: Analysis of the spatial structures of the junctions between interglobular contacts and binding sites may give a clue to the mechanism(s) of the activation. In this work, the problem was studied using available structural and biochemical data for the oligomeric enzymes of glycolysis. RESULTS: Computational analysis of the structures of the junctions has identified three structurally distinct types of junctions: 1. interglobular binding site (2 of 8 enzymes); 2. domain-domain stabilization (5 of 8); and 3. 'sequence overlap' or a local conformational change (all enzymes). Thus the catalytic activity may be influenced through the shifts of the modules of protein structure (types 1, 2) and/or due to a slight change in the local structure (type 3). The more common junctions of types 2 and 3 are well conserved among eukaryotic enzymes, which suggests their biological importance. CONCLUSIONS: The results suggest that a profound and a complex change in conformation in subunits of an oligomeric enzyme may not be necessary for a significant change in the catalytic properties. The analysis maps the residues important for the junctions and thus for the link between the catalytic activity and the oligomeric state of the enzymes.

Structural analysis of glyceraldehyde 3-phosphate dehydrogenase from Escherichia coli: direct evidence of substrate binding and cofactor-induced conformational changes.

The crystal structures of gyceraldehyde 3-phosphate dehydrogenase (GAPDH) from Escherichia coli have been determined in three different enzymatic states, NAD(+)-free, NAD(+)-bound, and hemiacetal intermediate. The NAD(+)-free structure reported here has been determined from monoclinic and tetragonal crystal forms. The conformational changes in GAPDH induced by cofactor binding are limited to the residues that bind the adenine moiety of NAD(+). Glyceraldehyde 3-phosphate (GAP), the substrate of GAPDH, binds to the enzyme with its C3 phosphate in a hydrophilic pocket, called the "new P(i)" site, which is different from the originally proposed binding site for inorganic phosphate. This observed location of the C3 phosphate is consistent with the flip-flop model proposed for the enzyme mechanism [Skarzynski, T., Moody, P. C., and Wonacott, A. J. (1987) J. Mol. Biol. 193, 171-187]. Via incorporation of the new P(i) site in this model, it is now proposed that the C3 phosphate of GAP initially binds at the new P(i) site and then flips to the P(s) site before hydride transfer. A superposition of NAD(+)-bound and hemiacetal intermediate structures reveals an interaction between the hydroxyl oxygen at the hemiacetal C1 of GAP and the nicotinamide ring. This finding suggests that the cofactor NAD(+) may stabilize the transition state oxyanion of the hemiacetal intermediate in support of the flip-flop model for GAP binding.

Structure of apo-glyceraldehyde-3-phosphate dehydrogenase from Palinurus versicolor.

d-Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) shows cooperative properties for binding coenzymes. The structure of apo-GAPDH from Palinurus versicolor has been solved at 2.0 A resolution by X-ray crystallography. The final model gives a crystallographic R factor of 0.178 in the resolution range 8 to 2 A. The structural comparison with holo-GAPDH from the same species reveals a conformational change induced by coenzyme binding similar to that observed in Bacillus stearothermophilus GAPDH but to a lesser extent. The differences in magnitude during the apo-holo transition between these two enzymes were analyzed with respect to the change of the amino acid composition in the coenzyme binding pocket. In the crystalline state of apo-GAPDH, the overall structures of the subunits are similar to each other; however, significant differences in temperature factors and minor differences in domain rotation upon coenzyme binding were observed for different subunits. These structural features are discussed in relation to the environmental asymmetry of crystallographically independent subunits.

Activating oligomerization as intermediate level of signal transduction: analysis of protein-protein contacts and active sites in several glycolytic enzymes.

A number of enzymes have inactive monomeric and active oligomeric forms. This suggests presence of definite interglobular contact -active site interaction in the enzymes. Although the phenomenon is widely studied in vitro as part of folding process the biological roles of the phenomenon, termed here as "activating oligomerization" are not clearly understood. In this work a procedure for analysis of protein-protein interactions was elaborated. Using spatial structures of several glycolytic enzymes potential role of kinase phosphorylation in regulation of oligomerization of the proteins as well as association of domains in a two-domain protein was assessed. In the enzymes 15-75% of kinase sites (mainly protein kinase C and casein kinase 2 sites) are placed in interglobular contact region(s). Upon being phosphorylated these sites may prevent oligomer formation. In structures of all the enzymes definite evidences of connection between active site and interglobular contact were found. Two structural mechanisms of interglobular contact influence on the active site were proposed. In addition to known mechanism of oligomerization initiated by allosteric metabolites the influence may be also exerted through functional sequence overlap and/or interdomain contact stabilization mechanisms. Implications for regulation of enzyme cellular function(s), signal transduction and metabolic analysis are considered. It is concluded that activating oligomerization may represent an intermediate level of enzyme cellular regulation.

Structure of active site carboxymethylated D-glyceraldehyde-3-phosphate dehydrogenase from Palinurus versicolor.

The structure of active site carboxymethylated D-glyceraldehyde-3-phosphate dehydrogenase from Palinurus versicolor was determined in the presence of coenzyme NAD+ at 1.88 A resolution with a final R-factor of 0.175. The structure refinement was carried out on the basis of the structure of holo-GAPDH at 2.0 A resolution using the program XPLOR. The carboxymethyl group connected to Cys149 is stabilized by a hydrogen bond between its OZ1 and Cys149N, and charge interaction between the carboxyl group and the nicotinamide moiety. The modification of Cys149 induced conformational changes in the active site, in particular, the site of sulphate ion 501 (the proposed attacking inorganic phosphate ion in catalysis), and segment 208-218 nearby. Extensive hydrogen-bonding interactions occur in the active site, which contribute to the higher stability of the modified enzyme. The modification of the active site did not affect the conformation of GAPDH elsewhere, including the subunit interfaces. The structures of the green and red subunits in the asymmetric unit are nearly identical, suggesting that the half-site reactivity of this enzyme is from ligand-induced rather than pre-existing asymmetry. It is proposed that the carboxymethyl group takes the place of the acyl group of the reaction intermediate, and the catalytic mechanism of this enzyme is discussed in the light of a comparison of the structures of the native and the carboxymethylated GAPDH.

Structure of holo-glyceraldehyde-3-phosphate dehydrogenase from Palinurus versicolor refined at 2 A resolution.

The crystal structure of holo-glyceraldehyde-3-phosphate dehydrogenase from Palinurus versicolor, South China sea lobster, was determined and refined at 2 A resolution to an R factor of 17.1% and reasonable stereochemistry. The structure refinement has not altered the overall structure of GAPDH from this lobster species. However, some local changes in conformation and the inclusion of ordered solvent model have resulted in a substantial improvement in the accuracy of the structure. Structure analysis reveals that the two subunits including NAD+ in the asymmetric unit are remarkably similar. The thermal differences between the two subunits found in some regions of the NAD+-binding domain may originate from different crystallographic environments rather than from an inherent molecular asymmetry. In this structure, the side chain of Arg194 does not point toward the active site but forms an ion pair with Asp293 from a neighboring subunit. Structural comparisons with other GAPDH's of known structure reveal that obvious contrast exists between mesophilic and thermophilic GAPDH mainly in the catalytic domain with significant conformational differences in the S-loop, beta7-strand and loop 120-125; the P-axis interface is more conserved than the R- and Q-axis interfaces and the catalytic domain is more conserved than the NAD+-binding domain. Some possible factors affecting the thermostability of this enzyme are tentatively analyzed by comparison with the highly refined structures of thermophilic enzymes.

Purification and partial characterization of glyceraldehyde-phosphate dehydrogenase from electric organ of Electrophorus electricus (L.).

The glyceraldehyde-phosphate dehydrogenase (GAPDH, EC 1.2.1.12) was purified to homogeneity from electric organ of Electrophorus electricus (L.) by a hydrophobic chromatography method on deacetylcolchicine-Sepharose. The purification resulted in a 162 fold increase in specific activity of the GAPDH and final yield was approximately 37%. The purified enzyme showed a single band in SDS-PAGE, with an apparent molecular mass of 36 kDa. The purity of the colchicine-Sepharose isolated material was analysed by isoelectrophocusing and immunoblotting using a heterologous rabbit serum anti-GAPDH. Sequence analysis of the 40-N-terminal amino acids, determined by Edman degradation, revealed its identity to other GAPDHs proteins being the largest number of identical amino acids to lobster (92.5%), rabbit muscle (85%) and human liver (80%) GAPDH.

Effector-induced dissociation of glyceraldehyde-3-phosphate dehydrogenase discriminated by urea solvation.

The dissociation of glyceraldehyde-3-phosphate dehydrogenase (GAPD) from pig muscle in water solutions (0.1 M phosphate, pH 7) at increased urea concentrations was studied by means of frontal-gel chromatography, intrinsic (TRP) fluorescence, differential absorption spectroscopy and selective chemical modification at TRP0193. The results are in agreement with a consecutive two-step model of dissociation of the tetramer and the dimer (C*T = 0.42 M urea < C*D = 1.39 M urea). The binding effector(s) destabilizes the oligomeric structures (delta GT changes from -1.00 to -0.54 kcal/mol; delta GD from -2.30 to -1.22 kcal/mol). The introduction of the bulky Koshland-reagent group to TRP-193 at the subunit-subunit interface leads to a decrease of the stability with delta delta G approximate to 1 kcal/mol, owing to TRP-193...TYR-39...TYR-92 cluster destruction. By using lobster GAPD atomic coordinates (PDB file 1GPD) and pig muscle GAPD amino-acid sequence, a tentative molecular model was constructed and the subunit contacts in terms of the Lee-Richard static accessibilities were described. A detailed analysis of the dissociation as a transfer of the buried residues from the molecular interface to the urea solutions was performed.

Structural basis for the extreme thermostability of D-glyceraldehyde-3-phosphate dehydrogenase from Thermotoga maritima: analysis based on homology modelling.

D-Glyceraldehyde-3-phosphate dehydrogenase (GAPDH) from a hyperthermophilic eubacterium, Thermotoga maritima, is remarkably heat stable (Tm = 109 degrees C). In this work, we have applied homology modelling to predict the 3-D structure of Th.maritima GAPDH to reveal the structural basis of thermostability. Three known GAPDH structures were used as reference proteins. First, the rough model of one subunit was constructed using the identified structurally conserved and variable regions of the reference proteins. The holoenzyme was assembled from four subunits and the NAD molecules. The structure was refined by energy minimization and molecular dynamics simulated annealing. No errors were detected in the refined model using the 3-D profile method. The model was compared with the structure of Bacillus stearothermophilus GAPDH to identify structural details underlying the increased thermostability. In all, 12 extra ion pairs per subunit were found at the protein surface. This seems to be the most important factor responsible for thermostability. Differences in the non-specific interactions, including hydration effects, were also found. Minor changes were detected in the secondary structure. The model predicts that a slight increase in alpha-helical propensities and helix-dipole interactions also contribute to increased stability, but to a lesser degree.

Mechanism of light modulation: identification of potential redox-sensitive cysteines distal to catalytic site in light-activated chloroplast enzymes.

Light-dependent reduction of target disulfides on certain chloroplast enzymes results in a change in activity. We have modeled the tertiary structure of four of these enzymes, namely NADP-linked glyceraldehyde-3-P dehydrogenase, NADP-linked malate dehydrogenase, sedoheptulose bisphosphatase, and fructose bisphosphatase. Models are based on x-ray crystal structures from non-plant species. Each of these enzymes consists of two domains connected by a hinge. Modeling suggests that oxidation of two crucial cysteines to cystine would restrict motion around the hinge in the two dehydrogenases and influence the conformation of the active site. The cysteine residues in the two phosphatases are located in a region known to be sensitive to allosteric modifiers and to be involved in mediating structural changes in mammalian and microbial fructose bisphosphatases. Apparently, the same region is involved in covalent modification of phosphatase activity in the chloroplast.

Non-phosphorylating GAPDH of higher plants is a member of the aldehyde dehydrogenase superfamily with no sequence homology to phosphorylating GAPDH.

Non-phosphorylating glyceraldehyde 3-phosphate dehydrogenase (GAPDH, NADP-specific, EC 1.2.1.9) operates in the cytosol of autotrophic eukaryotes where it generates NADPH for biosynthetic processes from photosynthetic glyceraldehyde 3-phosphate exported from the chloroplast by the phosphate translocator. Here we report the first cloning and characterization of cDNAs encoding complete polypeptide chains of nonphosphorylating GAPDH from pea and maize by using oligonucleotide probes derived from amino acid sequences determined for the purified enzyme. Unexpectedly, nonphosphorylating GAPDH cannot be aligned with the well-known sequences of phosphorylating GAPDH, but shares about 30% amino acid identity with various specialized and non-specialized aldehyde dehydrogenases (ALDHs) of eubacteria and eukaryotes. A phylogenetic analysis of this ALDH superfamily reveals a complex evolutionary pattern with numerous major branches carrying genes from eubacteria, eukaryotes, or both, encoding enzymes that are specific or non-specific for particular aldehyde substrates. This topology suggests a concomitant emergence of multiple substrate specificities from non-specialized ALDH during an early evolutionary phase of intense metabolic diversification. Although unrelated at the sequence level, non-phosphorylating aldehyde dehydrogenases and phosphorylating GAPDH resemble one another with respect to catalytic hydride transfer and covalent thiol ester formation. Whether or not this reflects an ancestral relationship can only be decided when crystallographic data for ALDH enzymes have become available.

Functional significance of protein conformational isomerisation in the glyceraldehyde-3-phosphate dehydrogenase-catalysed reaction.

The tetrameric mung bean glyceraldehyde-3-phosphate dehydrogenase is found to bind approximately four moles substrate, glyceraldehyde-3-phosphate, per mole enzyme with Kdiss equal to or less than 9.6 microM at pH 7.3, showing a slight positive cooperativity. Addition of excess substrate to a solution of the enzyme and excess NAD+ leads to a "burst" of NADH formation followed by a slow linear increase (monitored spectrophotometrically). Amount of NADH formed in the burst phase is pH-dependent and is equal to 3.6 moles per mole enzyme at pH 8.6 and above. Presuming four equivalent and independent sites per enzyme molecule (i.e. D2-symmetry), consistent values were obtained for the equilibrium constant of the oxidation-reduction step at different pH and most substrate concentrations. At lower pH (7.3) and high [NAD+]/[substrate] ratios, favouring the C2- symmetry conformation of the enzyme, the magnitude of the burst phase was negligibly small; practically no oxidation reduction reaction took place. Combining these with earlier results on the group transfer step, it is suggested that the oxidation-reduction and group transfer steps of the reaction catalysed by this enzyme require the D2 and C2 symmetry conformations of the enzyme, respectively.

Inactivation of glyceraldehyde-3-phosphate dehydrogenase with SH-reagents and its relationship to the protein quaternary structure.

Inactivation of mung bean glyceraldehyde-3-phosphate dehydrogenase (GPDH) with excess iodoacetate or N-ethylmaleimide exhibits pseudo-first order kinetics at pH 7.3 and 8.6 in the absence and presence of NAD+, suggesting that all the reactive SH groups (four per tetrameric GPDH molecule) have equivalent reactivity towards these reagents. This is similar to the D2-symmetry conformation proposed on the basis of thermal inactivation data [Malhotra and Srinivasan, Arch. Biochem. Biophys. 236, 775-781 (1985)]. With p-chloromercury benzoate (p-CMB), the inactivation of GPDH is very fast and its kinetics can be monitored at low reagent concentration only. Keeping a high molar p-CMB: enzyme ratio (= 47), the kinetics were found to be biphasic, with half of the activity being lost in a fast and the remaining in a slow phase, characteristic of C2-symmetry conformation and half site reactivity. The p-CMB inactivation could be largely reversed on the addition of excess cysteine. A comparison of these data with literature reports on this and other GPDHs reveals that all reagents having large non-polar moieties exhibit half site reactivity with this enzyme.