The NADH dehydrogenase of the respiratory chain of Escherichia coli. II. Kinetics of the purified enzyme and the effects of antibodies elicited against it on membrane-bound and free enzyme.

The purified respiratory chain NADH dehydrogenase of Escherichia coli oxidizes NADH with either dichlorophenolindophenol (DCIP). ferricyanide, or menadione as electron acceptors, with values for NADH are similar with the three electron acceptors (approximately 50 muM). The purified enzyme contains no flavin and has an absolute requirement for FAD, with Km values around 4 muM. The pH optimum of the enzyme appears to be between 6.5 and 7; the optimum is difficult to establish because of nonenzymatic reduction of DCIP at the lower pH values. Potassium cyanide stimulates the DCIP reductase activity about 2-fold, but has no effect on ferricyanide reductase. The enzyme exhibits hyperbolic kinetics with respect to NADH concentration in both the ferricyanide and DCIP reductase assays, but cooperatively is seen in the menadione reductase reaction. NAD+ is an effective competitive inhibitor of the reaction (Ki congruent to 20 muM); in the presence of NAD+, the NADH saturation curve becomes cooperative, even in the DCIP reductase assay. Many adenine containing nucleotides are competitive inhibitors of the enzyme. The apparent Ki values for these nucleotides as inhibitors of the purified enzyme, the membrane-bound NADH dehydrogenase, and the NADH oxidase are equivalent. An examination of inhibitory effects of a series of adenine nucleotides suggests that the inhibitors act as analogues of NAD+, which is the true physiological inhibitor. The results suggest that the enzyme in situ is always partially inhibited by the levels of NAD- in the E coli cell, and thus behaves in a cooperative fashion to changes in the NAD+/NADH ratio. An antibody has been elicited against the purified NADH dehydrogenase. Immunodiffusion and crossed immunoelectrophoresis show that the antibody is directed principally against the NADH dehydrogenase, with some activity against minor contaminants in the purified preparation. The antibody inhibits NADH dehydrogenase activity 50% at saturating levels. When this antibody preparation is used to examine solubilized membrane preparations, two major immunoprecipitates are found. A parallel inhibition of the membrane-bound NADH dehydrogenase and NADH oxidase activities is seen, supporting the hypothesis that the purified enzyme is indeed a component of the respiratory chain-dependent NADH oxidase pathway.     

Investigation of the relation of the pH-dependent dissociation of malate dehydrogenase to modification of the enzyme by N-ethylmaleimide.

The pH-dependent dissociation of porcine heart mitochondrial malate dehydrogenase (L-malate:NAD+ oxidoreductase, EC 1.1.1.37) has been further characterized using the technique of sedimentation velocity ultracentrifugation. The increased rate and specificity of the inactivation of mitochondrial malate dehydrogenase by the sulfhydryl reagent N-ethylmaleimide has been correlated with the pH-dependent dissociation of the enzyme. Data obtained using NAD+ and its component parts to reassociate the enzyme and also to protect the enzyme from inactivation by N-ethylmaleimide suggest that the sulfhydryl residues being modified by N-ethylmaleimide are inaccessible when the enzyme is in its dimeric form. A dissociation curve for the pH-dependent dissociation suggests that a limited number of residues are being protonated concomitant with dissociation of the enzyme. An apparent pKa of 5.3 has been determined for this phenomenon. Studies using enzyme modified by the sulfhydryl reagent N-ethylmaleimide indicate that selective modification of essential sulfhydryl residues alters the proper binding of NADH.     

Inactivation of Escherichia coli L-threonine dehydrogenase by 2,3-butanedione. Evidence for a catalytically essential arginine residue

Incubation of homogeneous preparations of L-threonine dehydrogenase from Escherichia coli with 2,3-butanedione, 2,3-pentanedione, phenylglyoxal, or 1,2-cyclohexanedione causes a time- and concentration-dependent loss of enzymatic activity; plots of log percent activity remaining versus time are linear to greater than 90% inactivation, indicative of pseudo-first order inactivation kinetics. The reaction order with respect to the concentration of modifying reagent is approximately 1.0 in each case suggesting that the loss of catalytic activity is due to one molecule of modifier reacting with each active unit of enzyme. Controls establish that this inactivation is not due to modifier-induced dissociation or photoinduced nonspecific alteration of the dehydrogenase. Essentially the same Km but decreased Vmax values are obtained when partially inactivated enzyme is compared with native. NADH (25 mM) and NAD+ (70 mM) give full protection against inactivation whereas much higher concentrations (i.e. 150 mM) of L-threonine or L-threonine amide provide a maximum of 80-85% protection. Amino acid analyses coupled with quantitative sulfhydryl group determinations show that enzyme inactivated 95% by 2,3-butanedione loses 7.5 arginine residues (out of 16 total)/enzyme subunit with no significant change in other amino acid residues. In contrast, only 2.4 arginine residues/subunit are modified in the presence of 80 mM NAD+. Analysis of the course of modification and inactivation by the statistical method of Tsou (Tsou, C.-L. (1962) Sci. Sin. 11, 1535-1558) demonstrates that inactivation of threonine dehydrogenase correlates with the loss of 1 "essential" arginine residue/subunit which quite likely is located in the NAD+/NADH binding site.     

Purification and partial characterization of a methylglyoxal reductase from goat liver

An enzyme which catalyzes the reduction of methylglyoxal to lactaldehyde has been isolated and purified from goat liver to apparent homogeneity. NADH was found to be a better substrate than NADPH for methylglyoxal reduction. Stoichiometrically equivalent amounts of lactaldehyde and NAD are formed from methylglyoxal and NADH. Enzyme activity was located only in the soluble supernatant fractions of liver cells. Of the various carbonyl compounds tested, methylglyoxal was found to be the best substrate. The pH optimum of the enzyme was found to be 6.5, and Km for methylglyoxal was 0.4 mM. The molecular weight of the enzyme was found to be 89000 by gel filtration on a Sephadex G-200 column. Electrophoresis on sodium dodecyl sulfate-polyacrylamide gel revealed that the enzyme is composed of two subunits. The enzyme is highly sensitive to sulfhydryl group reagents. The inactivation by p-chloromercuribenzoate could be substantially protected by methylglyoxal in combination with NADH, indicating a possible involvement of one or more sulfhydryl group(s) at the active site of the enzyme.     

Nonpolar interactions in the modification of an essential sulfhydryl of sorbitol dehydrogenase by N-alkylmaleimides

A series of N-alkylmaleimides varying in chainlength from N-methyl- to N-octylmaleimide inclusive was shown to effectively inactivate sheep liver sorbitol dehydrogenase at pH 7.5 and 25 degrees C. The apparent second-order rate constants for inactivation increased with increasing chainlength of the N-alkylmaleimide used. Positive chainlength effects were also indicated by the Kd values for the N-ethyl and N-heptyl derivatives obtained from studies of the saturation kinetics observed for inactivation of the enzyme at high concentrations of these maleimides. The complete inactivation of sorbitol dehydrogenase was demonstrated to occur through the selective covalent modification of one cysteine residue per subunit of enzyme. The stoichiometry of enzyme inactivation was supported on the one hand by fluorescence titration with fluorescein mercuric acetate of the native and the inactivated enzyme, and, on the other hand, by the simultaneous inactivation of the enzyme with selective modification of one sulfhydryl per subunit by N-[p-(2-benzoxazolyl)phenyl]maleimide. Protection of the enzyme from N-alkylmaleimide inactivation was observed with the binding of NADH, whereas both NAD and sorbitol were ineffective as protecting ligands. Diazotized 3-aminopyridine adenine dinucleotide, in contrast to previous studies of this reagent with yeast alcohol dehydrogenase and rabbit muscle glycerophosphate dehydrogenase, did not function as a site-labeling reagent for sorbitol dehydrogenase.     

A cysteine residue (cysteine-116) in the histidinol binding site of histidinol dehydrogenase

Salmonella typhimurium L-histidinol dehydrogenase (EC 1.1.1.23), a four-electron dehydrogenase, was inactivated by an active-site-directed modification reagent, 7-chloro-4-nitro-2,1,3-benzoxadiazole (NBD-Cl). The inactivation followed pseudo-first-order kinetics and was prevented by low concentrations of the substrate L-histidinol or by the competitive inhibitors histamine and imidazole. The observed rate saturation kinetics for inactivation suggest that NBD-Cl binds to the enzyme noncovalently before covalent inactivation occurs. The UV spectrum of the inactivated enzyme showed a peak at 420 nm, indicative of sulfhydryl modification. Stoichiometry experiments indicated that full inactivation was correlated with modification of 1.5 sulfhydryl groups per subunit of enzyme. By use of a substrate protection scheme, it was shown that 0.5 sulfhydryl per enzyme subunit was neither protected against NBD-Cl modification by L-histidinol nor essential for activity. Modification of the additional 1.0 sulfhydryl caused complete loss of enzyme activity and was prevented by L-histidinol. Pepsin digestion of NBD-modified enzyme was used to prepare labeled peptides under conditions that prevented migration of the NBD group. HPLC purification of the peptides was monitored at 420 nm, which is highly selective for NBD-labeled cysteine residues. By amino acid sequencing of the major peptides, it was shown that the reagent modified primarily Cys-116 and Cys-377 and that the presence of L-histidinol gave significant protection of Cys-116. The presence of a cysteine residue in the histidinol binding site is consistent with models in which formation and subsequent oxidation of a thiohemiacetal occurs as an intermediate step in the overall reaction.     

Uridine Prevents Fenofibrate-Induced Fatty Liver

Uridine, a pyrimidine nucleoside, can modulate liver lipid metabolism although its specific acting targets have not been identified. Using mice with fenofibrate-induced fatty liver as a model system, the effects of uridine on liver lipid metabolism are examined. At a daily dosage of 400 mg/kg, fenofibrate treatment causes reduction of liver NAD⁺/NADH ratio, induces hyper-acetylation of peroxisomal bifunctional enzyme (ECHD) and acyl-CoA oxidase 1 (ACOX1), and induces excessive accumulation of long chain fatty acids (LCFA) and very long chain fatty acids (VLCFA). Uridine co-administration at a daily dosage of 400 mg/kg raises NAD⁺/NADH ratio, inhibits fenofibrate-induced hyper-acetylation of ECHD, ACOX1, and reduces accumulation of LCFA and VLCFA. Our data indicates a therapeutic potential for uridine co-administration to prevent fenofibrate-induced fatty liver.     

Modification of mouse testicular lactate dehydrogenase by pyridoxal 5''-phosphate.

1. Mouse C4 lactate dehydrogenase treated in the dark with pyridoxal 5'-phosphate at pH8.7 and 25 degrees C loses activity gradually; 1mM-pyridoxal 5'-phosphate causes 83% inactivation, and higher concentrations of the reagent cause no further loss of activity. 2. The final extent of inactivation is very pH-dependent, greater inactivation occurring at the high pH values. 3. Inactivation may be fully reversed by addition of cysteine, or made permanent by reducing the enzyme with NaBH4. 4. The absorption spectrum of inactivated reduced enzyme indicates modification of lysine residues. Inactivation by 80% corresponds to modification of at least 1.8 mol of lysine/mol of enzyme subunit. 5. There is no loss of free thiol groups after inactivation with pyridoxal 5'-phosphate and reduction of the enzyme. 6. NAD+ or NADH gives complete protection against inactivation. protection studies with coenzyme fragments indicate that the AMP moiety is largely responsible for the protective effect. Lactate (10 mM) gives no protection in the absence of added nucleotides, but greatly enhances the protection given by ADP-ribose (1 mM). Thus ADP-ribose is able to trigger the binding of lactate. 7. Pyridoxal 5'-phosphate also acts as a non-covalent inhibitor of mouse C4 lactate dehydrogenase. The inhibition is non-competitive with respect to both NAD+ and lactate. 8. Km values for the enzyme at pH 8.0 and 25 degrees C, with the non-varied substrate saturating, are 0.3 mM-lactate and 5 microM-NAD+. 9. These results are discussed and compared with pyridoxal 5'-phosphate modification of other lactate dehydrogenase isoenzymes and related dehydrogenases.     

Half-site reactivity of an essential thiol group of D-beta-hydroxybutyrate dehydrogenase

D-beta-Hydroxybutyrate dehydrogenase is a lipid-requiring enzyme, which is a tetramer both in the mitochondrial inner membrane and as the purified enzyme reconstituted with phospholipid. For the active enzyme-phospholipid complex in the absence of ligands, we previously found that reaction with N-ethylmaleimide (at 5 mol/mol of enzyme subunit) resulted in progressive loss of enzymic activity with an inactivation stoichiometry of 1 equiv of sulfhydryl derivatized per mole of enzyme and a maximum derivatization of 2 equiv [Latruffe, N., Brenner, S. C., & Fleischer, S. (1980) Biochemistry 19, 5285-5290]. We now find, in the presence of nucleotide or substrate, that the rate of inactivation is significantly reduced, which indicates that these ligands afford protection of the essential sulfhydryl. Further, in the presence of ligands, the inactivation stoichiometry is 0.5, consistent with half-of-the-site reactivity of the essential sulfhydryl. Thus, at a low ratio of N-ethylmaleimide to enzyme, nucleotide or substrate affords essentially complete protection of the nonessential sulfhydryl from derivatization. The binding characteristics of NADH to both the native and N-ethylmaleimide-derivatized enzyme have been compared by fluorescence spectroscopy. Quenching of intrinsic tryptophan fluorescence of the protein shows that the enzyme, derivatized with N-ethylmaleimide either in the absence or in the presence of NAD+, binds NADH but with a reduced Kd (approximately 50 microM as compared with approximately 20 microM for native enzyme). However, a critical change has occurred in that resonance energy transfer from protein to bound NADH, observed in the native enzyme, is abolished in the N-ethylmaleimide-derivatized enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Effects of nicotinamide coenzymes on the stability of enzyme activities and proteins in niacin-deficient quail tissues against trypsin treatment

The stability of liver and muscle enzymes and proteins in niacin-deficient quail towards trypsin treatment in the presence and absence of coenzymes, NAD or NADP, was characterized. The protection of liver dehydrogenases by coenzymes was low when they are subjected to trypsin digestion for 60 min. In contrast, in the muscle there was substantial protection against trypsin inactivation of glyceraldehyde-3-phosphate dehydrogenase by NAD and of 6-phosphogluconate dehydrogenase by NADP. Among all enzymes tested, glyceraldehyde-3-phosphate dehydrogenase showed the greatest protection against trypsin inactivation by NAD. SDS-polyacrylamide gel electrophoresis demonstrated that muscle proteins from the niacin-deficient group were more substantially protected compared to control and pair-fed groups when liver and muscle extracts were spiked with NAD and subjected to trypsin digestion. Overall results suggest that niacin deficiency exerted specific destabilizing effects on the stability of enzymes and proteins in muscle.     

The sulfhydryl content of L-threonine dehydrogenase from Escherichia coli K-12: relation to catalytic activity and Mn2+ activation

When oxidized to cysteic acid by performic acid or converted to carboxymethylcysteine by alkylation of the reduced enzyme with iodoacetate, a total of six half-cystine residues/subunit are found in L-threonine dehydrogenase (L-threonine: NAD+ oxidoreductase, EC 1.1.1.103; L-threonine + NAD(+)----2-amino-3-oxobutyrate + NADH) from Escherichia coli K-12. Of this total, two exist in disulfide linkage, whereas four are titratable under denaturing conditions by dithiodipyridine, 5,5'-dithiobis(2-nitrobenzoic acid), or p-mercuribenzoate. The kinetics of enzyme inactivation and of modification by the latter two reagents indicate that threonine dehydrogenase has no free thiols that selectively react with bulky compounds. While incubation of the enzyme with a large excess of iodoacetamide causes less than 10% loss of activity, the native dehydrogenase is uniquely reactive with and completely inactivated by iodoacetate. The rate of carboxymethylation by iodoacetate of one -SH group/subunit is identical with the rate of inactivation and the carboxymethylated enzyme is no longer able to bind Mn2+. NADH (0.5 mM) provides 40% protection against this inactivation; 60 to 70% protection is seen in the presence of saturating levels of NADH plus L-threonine. Such results coupled with an analysis of the kinetics of inactivation caused by iodoacetate are interpreted as indicating the inhibitor first forms a reversible complex with a positively charged moiety in or near the microenvironment of a reactive -SH group in the enzyme before irreversible alkylation occurs. Specific alkylation of one -SH group/enzyme subunit apparently causes protein conformational changes that entail a loss of catalytic activity and the ability to bind Mn2+.     

The role of the essential sulfhydryl group in assimilatory NADH: nitrate reductase of Chlorella

Incubation of the complex metalloflavoprotein, assimilatory nitrate reductase with N-ethylmaleimide, or a spin-labeled analog, 4-maleimido-2,2,6,6-tetramethylpiperidinooxyl, resulted in a time-dependent inactivation of NADH:nitrate reductase and NADH: cytochrome-c reductase activity with no effect on reduced methyl viologen:nitrate reductase activity. Inactivation of the enzyme, which could be prevented by incubation in the presence of NADH, was achieved following modification of a single sulfhydryl group determined from [3H]N-ethylmaleimide incorporation and quantitation of the EPR spectrum of the spin-labeled enzyme. Sulfhydryl group modification precluded reduction of the enzyme by NADH and NAD+ binding. The EPR spectrum of the spin-labeled enzyme revealed the presence of a single species with the nitroxide retaining substantial motional freedom. Cleavage of the spin-labeled enzyme using corn-inactivating protease and separation into its flavin and molybdenum/heme domains followed by EPR spectroscopy revealed the modified sulfhydryl group to be associated with the latter fragment suggesting a close interaction of these domains in the region of the nucleotide-binding site.     

Glyoxylic acid prevents NAD+ and NADH depletion in K562 cells cultured at limiting dilution

K562 erythroleukemic cells cultured at low population density in the absence of serum die within 12-24 hours, unless 0.1 mM glyoxylic acid is added to the culture medium. Earlier events, preceding cell death and occurring within 2 hours culture, are: a) a marked drop of both the NAD+/NADH ratio and the NAD+ concentration, which is prevented by 10mM benzamide, b) an increased biosynthesis of NAD+, leading to extensive depletion of cellular ATP. In the presence of 0.1 mM glyoxylic acid the NAD+/NADH ratio as well as their absolute concentrations remain unchanged, while NAD+ biosynthesis is absent. A NAD+/NADH glycohydrolase activity is present in the cell extract, inhibited by 10 mM benzamide and with a higher affinity for NADH than for NAD+. Preservation of a high NAD+/NADH ratio by glyoxylic acid apparently prevents enzyme activity and the related loss of pyridine nucleotides.     

Effect of ligands on the reactivity of essential sulfhydryls in brain hexokinase. Possible interaction between substrate binding sites.

Inactivation of bovine brain mitochondrial hexokinase by 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB), a sulfhydryl specific reagent, has been investigated. The study shows that the inactivation of the enzyme by DTNB proceeds by way of prior binding of the reagent to the enzyme and involves the reaction of 1 mol of DTNB with a mol of enzyme. At stoichiometric levels of DTNB, the inactivation of the enzyme is accompanied by the formation of a disulfide bond. But it is not clear whether the disulfide bond or the mixed disulfide intermediate formed prior to it causes inactivation. On the basis of considerable protection afforded by glucose against this inactivation it is tentatively concluded that the sulfhydryl residues involved in this inactivation are at the glucose binding site of the enzyme, although other possibilities are not ruled out. An analysis of effects of various substrates and inhibitors on the kinetics of inactivation and sulfhydryl modification by DTNB has led to the proposal that the binding of substrates to the enzyme is interdependent and that glucose and glucose 6-phosphate produce slow conformational changes in the enzyme. Protective effects by ligands have been employed to calculate their dissociation constant with respect to the enzyme. The data also indicate that glucose 6-phosphate and inorganic phosphate share the same locus on the enzyme as the gamma phosphate of ATP and that nucleotides ATP and ADP bind to the enzyme in the absence of Mg2+.     

Chemical modification of 3 alpha,20 beta-hydroxysteroid dehydrogenase with diethyl pyrocarbonate. Evidence for an essential, highly reactive, lysyl residue

Diethyl pyrocarbonate inactivated the tetrameric 3 alpha,20 beta-hydroxysteroid dehydrogenase with second-order rate constants of 1.63 M-1 s-1 at pH 6 and 25 degrees C or 190 M-1 s-1 at pH 9.4 and 25 degrees C. The activity was slowly and partially restored by incubation with hydroxylamine (81% reactivation after 28 h with 0.1 M hydroxylamine, pH 9, 25 degrees C). NADH protected the enzyme against inactivation with a Kd (10 microM) very close to the Km (7 microM) for the coenzyme. The ultraviolet difference spectrum of inactivated vs. native enzyme indicated that a single histidyl residue per enzyme subunit was modified by diethyl pyrocarbonate, with a second-order rate constant of 1.8 M-1 s-1 at pH 6 and 25 degrees C. The histidyl residue, however, was not essential for activity because in the presence of NADH it was modified without enzyme inactivation and modification of inactivated enzyme was rapidly reversed by hydroxylamine without concomitant reactivation. Progesterone, in the presence of NAD+, protected the histidyl residue against modification, and this suggests that the residue is located in or near the steroid binding site of the enzyme. Diethyl pyrocarbonate also modified, with unusually high reaction rate, one lysyl residue per enzyme subunit, as demonstrated by dinitrophenylation experiments carried out on the treated enzyme. The correlation between inactivation and modification of lysyl residues at different pHs and the protection by NADH against both inactivation and modification of lysyl residues indicate that this residue is essential for activity and is located in or near the NADH binding site of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

Conformational features of bovine heart mitochondrial transhydrogenase

Both purified and functionally reconstituted bovine heart mitochondrial transhydrogenase were treated with various sulfhydryl modification reagents in the presence of substrates. In all cases, NAD+ and NADH had no effect on the rate of inactivation. NADP+ protected transhydrogenase from inactivation by 5,5'-dithiobis(2-nitrobenzoic acid) (DTNB) in both systems, while NADPH slightly protected the reconstituted enzyme but stimulated inactivation in the purified enzyme. The rate of N-ethylmaleimide (NEM) inactivation was enhanced by NADPH in both systems. The copper-(o-phenanthroline)2 complex [Cu(OP)2] inhibited the purified enzyme, and this inhibition was substantially prevented by NADP+. Transhydrogenase was shown to undergo conformational changes upon binding of NADP+ or NADPH. Sulfhydryl quantitation with DTNB indicated the presence of two sulfhydryl groups exposed to the external medium in the native conformation of the soluble purified enzyme or after reconstitution into phosphatidylcholine liposomes. In the presence of NADP+, one sulfhydryl group was quantitated in the nondenatured soluble enzyme, while none was found in the reconstituted enzyme, suggesting that the reactive sulfhydryl groups were less accessible in the NADP+-enzyme complex. In the presence of NADPH, however, four sulfhydryl groups were found to be exposed to DTNB in both the soluble and reconstituted enzymes. NEM selectively reacted with only one sulfhydryl group of the purified enzyme in the absence of substrates, but the presence of NADPH stimulated the NEM-dependent inactivation of the enzyme and resulted in the modification of three additional sulfhydryl groups. The sulfhydryl group not modified by NEM in the absence of substrates is not sterically hindered in the native enzyme as it can still be quantitated by DTNB or modified by iodoacetamide.(ABSTRACT TRUNCATED AT 250 WORDS)     

The reactions of Escherichia coli citrate synthase with the sulfhydryl reagents 5,5'-dithiobis-(2-nitrobenzoic acid) and 4,4'-dithiodipyridine.

Citrate synthase of Escherichia coli reacts rapidly with 1 equivalent of Ellman's reagent, 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB), per subunit, losing completely its sensitivity to the allosteric inhibitor, NADH. When the enzyme is treated instead with 4,4'-dithiodipyridine (4,4'-PDS), all activity is lost. Certain evidence in this paper is consistent with the belief that the sulfhydryl group modified by DTNB, and that whose modification by 4,4'-PDS inactivates the enzyme, are the same. (i) Both reagents abolish NADH fluorescence enhancement by the enzyme. (ii) Saturating levels of NADH and some other adenylic acid derivatives inhibit the reactions with both reagents. (iii) When the enzyme is modified with one equivalent of DTNB or 4,4'-PDS, subsequent reactivity toward the other reagent is greatly decreased. (iv) Following modifications, the DTNB and 4,4'-PDS derivatives spontaneously lose thionitrobenzoate (TNB) or pyridine-4-thione (PT), respectively, in reactions which are thought to involve displacement of TNB or PT by a second enzyme sulfhydryl group, so that an enzyme disulfide is introduced. The introduction of the disulfide bond, if this is what occurs, does not lead to cross-linking of citrate synthase polypeptide chains, as judged by sodium dodecyl sulfate polyacrylamide gel electrophoresis under nonreducing conditions. Certain evidence has also been found, however, that the sites of modification by DTNB and 4,4'-PDS are not the same. (i) DTNB modification desensitizes to NADH but does not inactivate, while 4,4'-PDS inactivates at least 99.9%. (ii) The presumed disulfide from elimination of TNB is also active, while that from PT modification is no more active than the original 4,4'-PDS modified product. (iii) Prior modification of the enzyme with DTNB affords no protection against later inactivation by 4,4'-PDS. The studies therefore indicate a close relationship between the DTNB desensitization and 4,4'-PDS inactivation, but they are unable to identify it exactly. Other properties of the DTNB reaction are also described, and a hypothesis is offered to explain quantitatively the finding that desensitization lags behind modification during the modification of citrate synthase by DTNB.     

Uridine diphosphate D-glucose dehydrogenase of Aerobacter aerogenes

Uridine diphosphate d-glucose dehydrogenase (EC 1.1.1.22) from Aerobacter aerogenes has been partially purified and its properties have been investigated. The molecular weight of the enzyme is between 70,000 and 100,000. Uridine diphosphate d-glucose is a substrate; the diphosphoglucose derivatives of adenosine, cytidine, guanosine, and thymidine are not substrates. Nicotinamide adenine dinucleotide (NAD), but not nicotinamide adenine dinucleotide phosphate, is active as hydrogen acceptor. The pH optimum is between 9.4 and 9.7; the K(m) is 0.6 mm for uridine diphosphate d-glucose and 0.06 mm for NAD. Inhibition of the enzyme by uridine diphosphate d-xylose is noncooperative and of mixed type; the K(i) is 0.08 mm. Thus, uridine diphosphate d-glucose dehydrogenase from A. aerogenes differs from the enzyme from mammalian liver, higher plants, and Cryptococcus laurentii, in which uridine diphosphate d-xylose functions as a cooperative, allosteric feedback inhibitor.     

The essential active-site lysines of clostridial glutamate dehydrogenase. A study with pyridoxal-5'-phosphate.

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)     

Purification and properties of the glutathione reductase of Chromatium vinosum.

The Chromatium vinosum glutathione reductase [NAD(P)H: glutathione disulfide oxidoreductase, EC 1.6.4.2] was purified to apparent homogeneity. The enzyme was found to require reduced nicotinamide adenine dinucleotide (NADH) as a reductant and to be specific for oxidized glutathione (GSSG). The polypeptide molecular weight in sodium dodecyl sulfate was found to be 52,000. Incubation of enzyme with NADH in the absence of GSSG resulted in a significant loss in activity. The enzyme was stimulated by phosphate and sulfate ion, but was inhibited by chloride ion, heavy metals, and sulfhydryl reagents. Adenylate nucleotides were inhibitory, and the data suggested that they were acting as competitive inhibitors of flavin adenine dinucleotide (FAD). The Km values of 7 X 10-3 for GSSG and 6 X 10-5 M for NADH were the highest reported of any previously investigated glutathione reductase. The order of addition of components markedly affected the response of the enzyme to FAD. A requirement for FAD (Km 5.2 X 10-7 M) was seen if the enzyme was incubated with NADH prior to GSSG addition, whereas no FAD was required if the order was reversed.