Coenzyme B12-dependent diol dehydrase: Chemical modification with 2,3-butanedione and phenylglyoxal

The apoenzyme of diol dehydrase was inactivated by two arginine-specific reagents, 2,3-butanedione and phenylglyoxal, in borate buffer. In both cases, the inactivation followed pseudo-first-order kinetics. Kinetic data show that the incorporation of a single reagent molecule per active site of the enzyme is necessary for the complete inactivation. The modification with 2,3-butanedione was reversed by dilution of the reagent and borate concentrations (65% activity recovered). 1,2-Propanediol (substrate) partially protected the enzyme against inactivation. The holoenzyme was almost insensitive to 2,3-butanedione and phenylglyoxal, indicating that the essential arginine residue is prevented from the attack of these reagents either by direct blockage with the bound coenzyme or by an indirect conformational change caused by coenzyme binding. The inactivation of diol dehydrase by 2,3-butanedione did not result in dissociation of the enzyme into subunits. From these results, we concluded that the essential arginine residue is located at or in close proximity to the active site of diol dehydrase.     

Inactivation of purine nucleoside phosphorylase by modification of arginine residues.

Treatment of purine nucleoside phosphorylase (EC 2.4.2.1), from either calf spleen or human erythrocytes, with 2,3-butanedione in borate buffer or with phenylglyoxal in Tris buffer markedly decreased the enzyme activity. At pH 8.0 in 60 min, 95% of the catalytic activity was destroyed upon treatment with 33 mM phenylglyoxal and 62% of the activity was lost with 33 mm 2,3-butanedione. Inorganic phosphate, ribose-1-phosphate, arsenate, and inosine when added prior to chemical modification all afforded protection from inactivation. No apparent decrease in enzyme catalytic activity was observed upon treatment with maleic anhydride, a lysine-specific reagent. Inactivation of electrophoretically homogeneous calf-spleen purine nucleoside phosphorylase by butanedione was accompanied by loss of arginine residues and of no other amino acid residues. A statistical analysis of the inactivation data vis-à-vis the fraction of arginines modified suggested that one essential arginine residue was being modified.     

Essential Arginyl Residues in the Plasma Membrane H-ATPase from Vigna radiata L. (Mung Bean) Roots

Proton-translocating ATPase (H⁺-ATPase) was purified from mung bean (Vigna radiata L.) roots. Treatment of this enzyme with the arginine-specific reagent 2,3-butanedione in the presence of borate at 37°C (pH 7.0), caused a marked decrease in its activity. Under this condition, half-maximal inhibition was brought about by 20 millimolar 2,3-butanedione at 12 minutes. MgATP and MgADP, the physiological substrate and competitive inhibitor of the ATPase, respectively, provided partial protection against inactivation. Loss of activity followed pseudo-first order kinetics with respect to 2,3-butanedione concentration, and double log plots of pseudo-first order rate constants versus reagent concentration gave a curve with a slope of 0.984. Thus, inactivation may possibly result from reaction of one arginine residue at each active site of the enzyme. The results obtained from the present study indicate that at least one arginyl residue performs an essential function in the plasma membrane H⁺-ATPase, probably at the catalytic site.     

Evidence of essential arginyl residues in rabbit muscle pyruvate kinase.

Rabbit muscle pyruvate kinase is inactivated by 2,3-butanedione in borate buffer. The inactivation follows pseudo-first-order kinetics with a calculated second-order rate constant of 4.6 m^?1 min^?1. The modification can be reversed with almost total recovery of activity by elimination of the butanedione and borate buffer, suggesting that only arginyl groups are modified; this result agrees with the loss of arginine detected by amino acid analysis of the modified enzyme. Using the kinetic data, it was estimated that the reaction of a single butanedione molecule per subunit of the enzyme is enough to completely inactivate the protein. The inactivation is partially prevented by phosphoenolpyruvate in the presence of K⁺ and Mg²⁺, but not by the competitive inhibitors lactate and bicarbonate. These findings point to an essential arginyl residue being located near the phosphate binding site of phosphoenolpyruvate.     

Involvement of an essential arginyl residue in the coupling activity of Rhodospirillum rubrum chromatophores.

The arginine reagents phenylglyoxal and 2,3-butanedione in borate buffer completely inhibited photophosphorylation and Mg-ATPase of Rhodospirillum rubrum chromatophores. The inactivation rates followed apparent first order kinetics. Oxidative phospho-rylation and the light-dependent ATP-P_i exchange reactions ofR. rubrum chromatophores and the Ca-ATPase activity of the soluble coupling factor were similarly inhibited by 2,3-butanedione in borate buffer. The apparent order of reaction with respect to inhibitor concentrations for all these reactions gave values of near 1 suggesting that inactivation was the consequence of modifying one arginine per active site. ATP synthesis and hydrolysis by R. rubrum chromatophores were strongly protected against inactivation by ADP and ATP, respectively, and by other nucleotides that are substrates of the reactions but not by the products. Similarly, the Ca-ATPase of the soluble coupling factor was protected by ATP but not by ADP. Inactivation of chromatophores reactions by butanedione in borate buffer was more rapid in the light than in the dark. The results suggest that the catalytic sites for ATP synthesis and hydrolysis on the chromatophore coupling factor are different and both contain an essential arginine.     

Detection of essential arginine in bacterial peptidyl dipeptidase-4: arginine is not the anion binding site

Peptidyl dipeptidase-4 from Pseudomonas maltophilia was modified with the arginine reagents p-hydroxyphenylglyoxal and 2,3-butanedione. The enzyme was inactivated in a pseudo-first-order manner by p-hydroxyphenylglyoxal with a half-time of 72 min. Inactivation by 2,3-butanedione was biphasic with a rapid phase followed by a slower inactivation to less than 10% activity within 24h. The competitive inhibitor thiorphan protected against inactivation by phydroxyphenylglyoxal and by 2,3-butanedione also but to a lesser degree. Inhibitory anions chloride and phosphate did not protect against inactivation by either reagent. These data support the conclusion that an active site arginine is essential for substrate hydrolysis. Furthermore, arginine is not the binding site for the inhibitors chloride and phosphate.     

Presence of one essential arginine that specifically binds the 2′-phosphate of NADPH on each of the ketoacyl reductase and enoyl reductase active sites of fatty acid synthetase

Two arginine modifying reagents, phenylglyoxal and 2,3-butanedione, inactivated fatty acid synthetase from goose uropygial gland. This inactivation could be partially prevented by NADP, 2′-AMP, and 2′,5′-ADP, whereas acetyl-CoA and/or malonyl-CoA provided very little protection. Ketoacyl reductase and enoyl reductase activities of fatty acid synthetase showed similar inactivation by phenylglyoxal and butanedione and protection by only NADP and its 2′-phosphate-containing analogs. Furthermore, 2′-AMP was found to be a competitive inhibitor of overall fatty acid synthetase, ketoacyl reductase, and enoyl reductase with apparent K_i values of 1.4, 0.2, and 14 mm, respectively. These results suggest that binding of NADPH to fatty acid synthetase involves specific interaction of the 2′-phosphate with the guanidino group of arginine residues at the active site of the two reductases. Quantitation of the number of arginine residues modified revealed that 4 out of 106 arginine residues per subunit of the synthetase showed high reactivity toward phenylglyoxal. Scatchard analysis showed that two rapidly reacting arginine residues had no effect on the catalytic activity, while modification of two additional arginine residues resulted in complete loss of enzyme activity. Under these conditions, of the seven partial reactions of fatty acid synthetase, only the ketoacyl reductase and enoyl reductase activities were inhibited by phenylglyoxal. The differential reversal of inhibition of the two reductases and the overall activity of fatty acid synthetase, resulting from dialysis of the modified enzyme, suggested that both ketoacyl reductase sites and enoyl reductase sites are required for the full expression of fatty acid synthetase activity. The results of the present chemical modification studies are consistent with the hypothesis that each subunit of fatty acid synthetase contains one ketoacyl reductase and one enoyl reductase and suggest that one essential arginine is present at each of these active sites.     

Essential arginyl residues in the H+-translocating ATPase of plasma membrane from the yeast Schizosaccharomyces pombe

The H+-translocating adenosine-5'-triphosphatase (ATPase) purified from the yeast Schizosaccharomyces pombe is inactivated upon incubation with the arginine modifier 2,3-butanedione. The inactivation of the enzyme is maximal at pH values above 8.5. The modified enzyme is reactivated when incubated in the absence of borate after removal of 2,3-butanedione. The extent of inactivation is half maximal at 10 mM 2,3-butanedione for an incubation of 30 min at 30 degrees C at pH 7.0. Under the same conditions, the time-dependence of inactivation is biphasic in a semi-logarithmic plot with half-lives of 10.9 min and 65.9 min. Incubation with 2,3-butanedione lowering markedly the maximal rate of ATPase activity does not modify the Km for MgATP. These data suggest that two classes of arginyl residues play essential role in the plasma membrane ATPase activity. Magnesium adenosine 5'-triphosphate (MgATP) and magnesium adenosine 5'-diphosphate (MgADP), the specific substrate and product, protect partially against enzyme inactivation by 2,3-butanedione. Free ATP or MgGTP which are not enzyme substrates do not protect. Free magnesium, another effector of enzyme activity, exhibits partial protection at magnesium concentrations up to 0.5 mM, while increased inactivation is observed at higher Mg2+ concentrations. These protections indicate either the existence of at least one reactive arginyl in the substrate binding site or a general change of enzyme conformation induced by MgATP, MgADP or free magnesium.     

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.     

Presence of an essential arginyl residue in D-β-hydroxybutyrate dehydrogenase from mitochondrial inner membrane

D-β-hydroxybutyrate dehydrogenase, a lipid requiring enzyme, is rapidly and completely inactivated by phenylglyoxal, 2,3-butanedione and 1,2-cyclohexanedione. Inactivation, which occurs at the millimolar range, depends on the nature of buffer, borate ions are required to get enzyme inactivation by 2,3-butanedione. Most of the inactivation follows a pseudo first order kinetics, the stoichiometry being of one to one. Presence of NAD⁺ or methylmalonate (a substrate-like compound) prior addition of inhibitor does not affect inactivation, while methylmalonate in presence of NAD⁺ strongly protects against inactivation. Chemical modification of the enzyme does not affect K_D of NAD while K_M of β-hydroxybutyrate and Ki of methylmalonate (protecting agent) increase. In view of the high specificity of these inhibitors for arginyl residues of proteins, these results are in favour of the presence of at least one arginyl residue essential for enzyme activity and located in, or near the substrate binding site.     

A functional arginine residue in NADPH-dependent aldehyde reductase from pig kidney.

Pig kidney aldehyde reductase is inactivated by 2,3-butanedione, phenylglyoxal, methylglyoxal, and 1,2-cyclohexanedione. 2,3-Butanedione caused the most rapid loss in enzyme activity, the rate of loss being proportional to the concentration of 2,3-butanedione. Neither D-glyceraldehyde nor pyridine 3-aldehyde, both substrates for this broadly specific enzyme, protected the enzyme from inactivation but 1 mM NADPH or NADP completely prevented the loss of activity by 2,3-butanedione suggesting the involvement of arginine in the binding of cofactor. Nicotinamide mononucleotide (NMN) (reduced form) offered no protection to inactivation whereas ADP-ribose phosphate gave complete protection indicating that it is the latter portion of NADPH which interacts with the essential arginine. Both NMN and ADP-ribose phosphate are competitive inhibitors of aldehyde reductase with respect to NADPH. Butanedione-modified aldehyde reductase could still bind to a blue dextran-Sepharose 4B column suggesting that the modified arginine did not bind NADPH. This was confirmed by fluorescence spectra which showed that chemically modified aldehyde reductase caused the same blue shift of NADPH fluorescence as did native aldehyde reductase. Of additional interest was the quenching of NADPH fluorescence by aldehyde reductase which, with one exception, is in contrast to the fluorescence behavior of all other oxidoreductases.     

The nature of functional groups in the active center of antitumor glutamin-(asparagin-)ase

The effect of two reagents on glutamin (asparagin) ase from Pseudomonas aurantiaca-548 has been studied. 2,3-butanedione which modified arginine residues was ineffective for the inactivation of the enzyme. The enzyme was completely inactivated in the presence of N-ethyl-5-phenylisoxazolium-3'-sulfonate (Woodward's reagent K). The effects of pH, reagent concentration, competitive inhibitors and their analogues on the rate or degree of enzyme inactivation were studied. The experimental results suggest that the carboxyl groups localized at the active site of glutamin (asparagin) ase are probably essential for the substrate binding.     

Essential arginine residues in the nitrate uptake system from corn seedling roots

Three dicarbonyl reagents were used to demonstrate the presence of an essential arginine residue in the NO₃⁻ uptake system from corn seedling roots (Zea mays L., Golden Cross Bantam). Incubation of corn seedlings with 2,3-butanedione (0.125-1.0 millimolar) and 1,2-cyclohexanedione (0.5-4.0 millimolar) in the presence of borate or with phenylglyoxal (0.25-2.0 millimolar) at pH 7.0 and 30°C resulted in a time-dependent loss of NO₃⁻ uptake following pseudo-first-order kinetics. Second-order rate constants obtained from slopes of linear plots of pseudo-first-order rate constants versus reagent concentrations were 1.67 × 10⁻², 0.68 × 10⁻², and 1.00 × 10⁻² millimolar per minute for 2,3-butanedione, 1,2-cyclohexanedione, and phenylglyoxal, respectively, indicating the faster rate of inactivation with 2,3-butanedione at equimolar concentration. Double log plots of pseudo-first-order rate constants versus reagent concentrations yielded slope values of 1.031 (2,3-butanedione), 1.004 (1,2-cyclohexanedione), and 1.067 (phenylglyoxal), respectively, suggesting the modification of a single arginine residue. The effectiveness of the dicarbonyl reagents appeared to increase with increasing medium pH from 5.5 to 8.0. Unaltered K_m and decreased V_max in the presence of reagents indicate the inactivation of the modified carriers with unaltered properties. The results thus obtained indicate that the NO₃⁻ transport system possesses at least one essential arginine residue.     

Characterization of essential arginyl residues in sheep kidney (Na+ + K+) -ATPase.

Treatment of highly purified sheep kidney medulla (Na⁺ + K⁺)-ATPase with 2,3-butanedione results in a rapid inactivation of the enzyme. Contrary to a previous report using rabbit kidney enzyme (DePont et al., Biochim. Biophys. Acta (1977) 482, 213), the inactivation is biphasic under a variety of experimental conditions, with a rapid, initial inactivation which is followed by a slower loss of activity. The second, slower phase of the inhibition obeys pseudo-first order kinetics, with a second order rate constant for inhibition of 20 min^?1M^?1. ATP and ADP provide no protection in the initial phase of the inhibition, but protect the enzyme completely from the second phase of the inhibition. AMP, while less effective than ATP and ADP, provides a partial protection of the enzyme activity from inhibition by 2,3-butanedione. Inorganic phosphate provides partial protection in both phases of the inactivation. Adenosine alone is without effect, but adenosine plus inorganic phosphate provides a greater protection than phosphate alone. The results indicate that either (1) two or more active site residues or (2) a single arginine, experiencing different reactivities in two different active site conformations, are essential to (Na⁺ + K⁺)-ATPase activity.     

Selective chemical modification of Escherichia coli elongation factor G: butanedione modification of an arginine essential for nucleotide binding.

Treatment of Escherichia coli elongation factor G with the arginine reagent, 2,3-butanedione, leads to the inactivation of the enzyme when performed in sodium borate buffers. The inhibition follows pseudo-first-order kinetics until 95% of the activity has been lost and further incubation results in complete inhibiton. Removal of the borate by exhaustive dialysis results in the restoration of approximately 85% of the original activity. The pH dependence of the reaction suggests that the ionization of a group in the protein with a pKa of approximately 8.8 facilitates the reaction with butanedione. A reaction order of 1.01 +/- 0.13 was calculated for the inhibition reaction, indicating that the incorporation of one butanedione per elongation factor G results in the inactivation of the enzyme. The kinetics of inhibition in the presence of GTP indicate that the elongation factor G-GTP complex is refractory to butanedione inhibiton. Elongation factor G which has been partially inactivated by butanedione has the same apparent Km for GTP as does the native enzyme. These results indicate that elongation factor G contains only one essential arginine residue which is reactive with butanedione and that this residue is located at its nucleotide binding site.     

Evidence for an essential arginine residue at the active site of Escherichia coli acetate kinase

Escherichia coli acetate kinase (ATP: acetate phosphotransferase, EC 2.7.2.1.) was inactivated in the presence of either 2,3-butanedione in borate buffer or phenylglyoxal in triethanolamine buffer. When incubated with 9.4 mM phenylglyoxal or 5.1 mM butanedione, the enzyme lost its activity with an apparent rate constant of inactivation of 0.079 min-1, respectively. The loss of enzymatic activity was concomitant with the loss of an arginine residue per active site. Phosphorylated substrates of acetate kinase, ATP, ADP and acetylphosphate as well as AMP markedly decreased the rate of inactivation by both phenylglyoxal and butanedione. Acetate neither provided any protection nor affected the protection rendered by the adenine nucleotides. However, it interfered with the protection afforded by acetylphosphate. These data suggest that an arginine residue is located at the active site of acetate kinase and is essential for its catalytic activity, probably as a binding site for the negatively charged phosphate group of the substrates.     

On the probable involvement of arginine residues in the bile-salt-binding site of human pancreatic carboxylic ester hydrolase

Modification of arginine residues with 2,3-butanedione inhibits the carboxylic-ester hydrolase activity on soluble and emulsified substrates when assayed with bile salts. The alpha-dicarbonyl reagent modifies seven of the nineteen arginine residues present per enzyme molecule. Nevertheless the inactivation with butanedione is greatly diminished when the protein is in the presence of negatively charged micellar bile salt. In these conditions we observe the protection of one arginine residue by sodium taurodeoxycholate and of two arginine residues by sodium cholate. This suggests that the carboxylic-ester hydrolase from human pancreatic juice contains at least two arginine residues essential for the activation by bile salts. All our data confirm the presence of two bile-salt-binding sites on the enzyme in which one arginine per site is involved and plays the general role of an anionic binding site. This study provides evidence that arginine residues may play an essential role in the interaction between bile salts and protein.     

Binding of the Human “Electron Transferring Flavoprotein” (ETF) to the Medium Chain Acyl-CoA Dehydrogenase (MCAD) Involves an Arginine and Histidine Residue

The interaction between the “electron transferring flavoprotein” (ETF) and medium chain acyl-CoA dehydrogenase (MCAD) enables successful flavin to flavin electron transfer, crucial for the β-oxidation of fatty acids. The exact biochemical determinants for ETF binding to MCAD are unknown. Here we show that binding of human ETF, to MCAD, was inhibited by 2,3-butanedione and diethylpyrocarbonate (DEPC) and reversed by incubation with free arginine and hydroxylamine respectively. Spectral analyses of native ETF vs modified ETF suggested that flavin binding was not affected and that the loss of ETF activity with MCAD involved modification of one ETF arginine residue and one ETF histidine residue respectively. MCAD and octanoyl-CoA protected ETF against inactivation by both 2,3-butanedione and DEPC indicating that the arginine and histidine residues are present in or around the MCAD binding site. Comparison of exposed arginine and histidine residues among different ETF species, however, indicates that arginine residues are highly conserved but that histidine residues are not. These results lead us to conclude that this single arginine residue is essential for the binding of ETF to MCAD, but that the single histidine residue, although involved, is not.     

Evidence for involvement of arginyl residue at the catalytic site of penicillin acylase from Escherichia coli

Incubation of penicillin acylase from Escherichia coli with phenylglyoxal or 2,3-butanedione results in enzyme inactivation. Both benzylpenicillin and phenylacetate protect the enzyme against the inactivation, indicating the presence of arginine at or near the catalytic site. The reactions follow pseudofirst order kinetics and the inactivation kinetics indicate the presence of a single essential arginine moiety.     

Pigeon liver malic enzyme: Involvement of an arginyl residue at the binding site for malate and its analogs

Treatment of malic enzyme with arginine-specific reagents phenylglyoxal or 2,3-butanedione results in pseudo-first-order loss of oxidative decarboxylase activity. Inactivation by phenylglyoxal is completely prevented by saturating concentrations of NADP⁺, Mn²⁺, and substrate analog hydroxymalonate. Double log plots of pseudo-first-order rate constant versus concentration yield straight lines with identical slopes of unity for both reagents, suggesting that reaction of one molecule of reagent per active site is associated with activity loss. In parallel experiments, complete inactivation is accompanied by the incorporation of four [¹⁴C]phenylglyoxal molecules, and the loss of two arginyl residues per enzyme subunit, as determined by the colorimetric method of Yamasaki et al (R. B. Yamasaki, D. A. Shimer, and R. E. Feeney (1981) Anal. Biochem., 14, 220–226). These results confirm a 2:1 ratio for the reaction between phenylglyoxal and arginine (K. Takahashi (1968) J. Biol. Chem., 243, 6171–6179) and yield a stoichiometry of two arginine residues reacted per subunit for complete inactivation, of which one is essential for enzyme activity as determined by the statistical method of Tsou (C. L. Tsou (1962) Acta Biochim. Biophys. Sinica, 2, 203–211) and the Ray and Koshland analysis (W. J. Ray and D. E. Koshland (1961) J. Biol. Chem., 236, 1973–1979). Amino acid analysis of butanedione-modified enzyme also shows loss of arginyl residues, without significant decrease in other amino acids. Modification by phenylglyoxal does not significantly affect the affinity of this enzyme for NADPH. Binding of l-malate and its dicarboxylic acid analogs oxalate and tartronate is abolished upon modification, as is binding of the monocarboxylic acid α-hydroxybutyrate. The latter result indicates binding of the C-1 carboxyl group of the substrate to an arginyl residue on the enzyme.