Essential arginyl residues in fructose-1,6-bisphosphatase.

Modification of pig kidney fructose-1,6-bisphosphatase with 2,3-butanedione in borate buffer (pH 7.8) leads to the loss of the activation of the enzyme by monovalent cations, as well as to the loss of allosteric adenosine 5'-monophosphate (AMP) inhibition. In agreement with the results obtained for the butanedione modification of arginyl residues in other enzymes, the effects of modification can be reversed upon removal of excess butanedione and borate. Significant protection to the loss of K+ activation was afforded by the presence of the substrate fructose 1,6-bisphosphate, whereas AMP preferentially protected against the loss of AMP inhibition. The combination of both fructose 1,6-bisphosphate and AMP fully protected against the changes in enzyme properties on butanedione treatment. Under the latter conditions, one arginyl residue per mole of enzyme subunit was modified, whereas three arginyl residues were modified by butanedione under conditions leading to the loss of both potassium activation and AMP inhibition. Thus, the modification of two arginyl residues per subunit would appear to be responsible for the change in enzyme properties. The present results, as well as those of a previous report on the subject (Marcus, F. (1975), Biochemistry 14, 3916-3921) support the conclusion that one arginyl residue per subunit is essential for monovalent cation activation, and another arginyl residue is essential for AMP inhibition. A likely role of the latter residue could be its involvement in the binding of the phosphate group of AMP.     

Comparative titration of arginyl residues in purified D-β-hydroxybutyrate apodehydrogenase and in the reconstituted phospholipid-enzyme complex

In order to titrate and understand the role of arginyl residues of D-β-hydroxybutyrate dehydrogenase, arginyl specific reagents: butanedione, 1,2-cyclohexanedione and phenylglyoxal were incubated with three different forms of the enzyme; native enzyme (inner mitochondrial membrane bound), purified apoenzyme (phospholipid -free) and phospholipid-enzyme complex (reconstituted active form).After complete inactivation of the enzyme by [¹⁴C]-phenylglyoxal, the number of modified arginyl residues was different: one with the lipid-free apoenzyme and three with the phospholipid-enzyme complex, suggesting a conformational change of the enzyme triggered by the presence of phospholipids.After exhaustive chemical modification either of the apoenzyme or of the phospholipid-enzyme complex with [¹⁴C]-phenylglyoxal, four arginyl residues were titrated indicating that these residues are located in the hydrophilic part of the enzyme, not interacting with phospholipids.Reconstituted enzyme inactivated by butanedione could no longer bind a pseudosubstrate (succinate) which indicates that an arginyl residue is involved in the enzyme-substrate complex formation.The values of second order rate constants of D-β-hydroxybutyrate dehydrogenase inactivation by butanedione and 1,2-cyclohexanedione were unchanged with the three enzyme forms, suggesting that phospholipids are not involved in the substrate binding mechanism.     

Role of arginyl residues in yeast hexokinase PII.

Yeast hexokinase PII is rapidly inactivated (assayed at pH 8.0) by either butanedione in borate buffer or phenylglyoxal, reagents which are highly selective for the modification of arginyl residues. MgATP alone offers no protection against inactivation, consistent with low affinity of hexokinase for this nucleotide in the absence of sugar. Glucose provides slight protection against inactivation, while the combined presence of glucose and MgATP gives significant protection, suggesting that modified arginyl residues may lie at the active site, possibly serving to bind the anionic polyphosphate of the nucleotide in the ternary enzyme:sugar:nucleotide complex. Extrapolation to complete inactivation suggests that inactivation by butanedione correlates with the modification of 4.2 arginyl residues per subunit, and complete protection against inactivation by the combined presence of glucose and MgATP correlates with the protection of 2 to 3 arginyl residues per subunit. When the modified enzyme is assayed at pH 6.5, significant activity remains. However, modification by butanedione in borate buffer abolishes the burst-type slow transient process, observed when the enzyme is assayed at pH 6.5, to such an extent that after extensive modification the kinetic assays are characterized by a lag-type slow transient process. But even after extensive modification, hexokinase PII still demonstrates negative cooperativity with MgATP and is still strongly activated by citrate when assayed at pH 6.5.     

Essential arginine residues in D-glyceraldehyde-3-phosphate dehydrogenase.

Two arginyl residues per subunit of yeast D-glyceraldehyde-3-phoshphate dehydrogenase were modified by treatment with butanedione without significant changes in the compostion of other amino acid residues. The modified enzyme displays no dehydrogenase activity. It retains the capacity for interacting with the coenzyme NAD, but binds it less firmly than does the native enzyme. The molar absorbance of the enzyme-NAD complex is markedly reduced and the reactivity of the active-center SH groups is changed in the modified enzyme. The native and modified enzymes show identical fluorescence spectra, absorbance and CD spectra.     

Arginyl residues involvement in the microtubule assembly

Modification of pig brain tubulin with 2,3-butanedione, an arginine-specific reagent, resulted in a decrease of its microtubule formation capacity, with apparent first-order kinetics. However, microtubules already assembled were not affected by the reagent. The relation between the polymerization inhibition rate constant and the butanedione concentration followed a saturation curve whereas the colchicine binding activity remained unchanged over that concentration range. GTP partially prevented the decrease of tubulin polymerization induced by the butanedione treatment. This protective effect of GTP was increased by glycerol. The butanedione inhibition of tubulin polymerization appears to be related to the modification of no more than three arginyl residues. These data suggest that at least one of the arginyl residues plays an essential role in tubulin polymerization, probably through its interaction with the negatively charged phosphate moiety of the nucleotide.     

Evidence for an essential role for arginyl residues for yeast phosphoglycerate kinase.

Reaction of yeast phosphoglycerate kinase with either butanedione or cyclohexanedione can result in modification of up to all 13 arginyl residues with total loss of activity; however, extrapolation to zero activity for partially modified preparations indicates that up to 7 arginyls are essential. Whereas 20 mm 3-phosphoglycerate affords partial protection of activity toward both reagents, 20 mm MgATP affords complete protection of activity and protects 2 arginyls against modification by butanedione and 1 arginyl against modification by cyclohexanedione. With butanedione the modification could be reversed with total recovery of activity, suggesting that only arginyl groups were modified, which is consistent with the amino acid analysis of the modified protein. Only at high cyclohexanedione concentrations or long reaction times was a yellow product obtained that showed loss of lysyl residues. Circular dichroism spectra show that even when all the arginyls are modified by butanedione or up to 10 modified by cyclohexanedione there is no change observed in the far or near ultraviolet, indicating that there is no detectable conformational change concomitant with modification, which is confirmed by hydrodynamic studies. It is concluded that at least one, possibly two, arginyls of yeast phosphoglycerate kinase are essential for its action on ATP.     

The role of arginine residues in the function of D-glyceraldehyde-3-phosphate dehydrogenase.

Inactivation of apo-glyceraldehyde-3-phosphate dehydrogenase from rat skeletal muscle in the presence of butanedione is the result of modification of one arginyl residue per subunit of the tetrameric enzyme molecule. The loss of activity follows pseudo-first-order kinetics. NAD+ increases the apparent first-order rate constant of inactivation. The effect of NAD+ on the enzyme inactivation is cooperative (Hill coefficient = 2.3--3.2). Glyceraldehyde 3-phosphate protected the holoenzyme against inactivation, decreasing the rate constant of the reaction. At saturating concentrations of substrate the protection was complete. The Hill plot demonstrates that the effect is cooperative. This suggests that subunit interactions in the tetrameric holoenzyme molecule may affect the reactivity of the essential arginyl residues. In contrast, glyceraldehyde 3-phosphate had no effect on the rate of inactivation of the apoenzyme in the presence of butanedione. 100 mM inorganic phosphate protected both the apoenzyme and holoenzyme against inactivation. The involvement of the microenvironment of the arginyl residues in the functionally important conformational changes of the enzyme is discussed.     

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.     

An essential arginyl residue at the nucleotide binding site of creatine kinase.

Treatment of rabbit muscle creatine kinase (EC 2.4.3.2) with either butanedione in borate buffer or phenylglyoxal in Veronal buffer decreases enzymatic activity correlating with the modification of a single arginyl residue per subunit of the dimeric enzyme. Very little activity is lost when modification is performed in the presence of MgATP or MgADP. Nucleotide binding to the modified enzyme is virtually abolished as determined by ultraviolet difference spectroscopy. The data suggest that an arginyl residue plays an essential role in the enzymatic mechanism of creatine kinase, probably as a recognition site for the negatively charged oligophosphate moiety of the nucleotide.     

Functional consequences of modifying highly reactive arginyl residues of fructose 1,6-bisphosphatase. Loss of monovalent cation activation.

Modification of pig kidney fructose 1,6-bisphosphatase with 2,3-butanedione (in the presence of AMP) results in the loss of activation of the enzyme by monovalent cations. Under these conditions about 8 arginyl residues per mole of enzyme were modified. No other residues were modified. No loss of monovalent cation activation occurs when modification with 2,3-butanedione is carried out in the presence of AMP plus the substrate fructose 1,6-bisphosphate and 3.2 less arginyl residues were modified. Since fructose 1,6-bisphosphatase contains 4 subunits, it is suggested that one arginyl residue per subunit plays an essential role in monovalent cation activation of the enzyme. Studies on sulfhydryl group reactivity toward 5,5'-dithiobis(2-nitrobenzoic acid) explain the protection exerted by fructose 1,6-bisphosphate against the loss of monovalent cation activation in terms of an enzyme conformational change induced by substrate, which makes unreactive the essential arginyl residue. The results of the present paper, as well as previous evidence, are discussed in terms of the mechanism of monovalent cation activation of fructose 1,6-biphosphatase.     

Essential arginyl residues in yeast enolase.

Yeast enolase is rapidly inactivated by butanedione in borate buffer, complete inactivation correlating with the modification of 1. 8 arginyl residues per subunit. Protection against inactivation is provided by either an equilibrium mixture of substrates or inorganic phosphate, a competitive inhibitor of the enzyme. Complete protection by substrates correlates with the shielding of 1. 3 arginyl residues per subunit, while phosphate protects 1. 0 arginyl residue per subunit from modification.     

The role of arginyl residues in porphyrin binding to ferrochelatase

The role of cationic amino acid residues in the binding of porphyrin substrates by purified bovine ferrochelatase (protoheme ferro-lyase, EC 4.99.1.1) have been examined via chemical modification with camphorquinone-10-sulfonic acid, phenylglyoxal, butanedione, and trinitrobenzene sulfonate. The data obtained show that modification of arginyl, but not lysyl, residues results in the rapid inactivation of ferrochelatase. The 2,4-disulfonate deuteroporphyrin, which is a competitive inhibitor of mammalian ferrochelatase, protects the enzyme against inactivation. Ferrous iron has no protective effect. Reaction with radiolabeled phenylglyoxal shows that modification of 1 arginyl residue causes maximum inhibition of enzyme activity. The inactivation does not follow simple pseudo-first order reaction kinetics, but is distinctly biphasic in nature. Comparison of the enzyme kinetics for modified versus unmodified enzyme show that modification with camphorquinone-10-sulfonic acid has no effect on the Km for iron but does alter the Km for porphyrin.     

Identification of essential arginyl residues in cytoplasmic malate dehydrogenase with butanedione.

The inactivation of cytoplasmic malate dehydrogenase (L-malate: NAD+ oxidoreductase, EC 1.1.1.37) from porcine heart and the specific modification of arginyl residues have been found to occur when the enzyme is inhibited with the reagent butanedione in sodium borate buffer. The inactivation of the enzyme was found to follow pseudo-first order kinetics. This loss of enzymatic activity was concomitant with the modification of 4 arginyl residues per molecule of enzyme. All 4 residues could be made inaccessible to modification when a malate dehydrogenase-NADH-hydroxymalonate ternary complex was formed. Only 2 of the residues were protected by NADH alone and appear to be essential. Studies of the butanedione inactivation in sodium phosphate buffer and of reactivation of enzymatic activity, upon the removal of excess butanedione and borate, support the role of borate ion stabilization in the inactivation mechanism previously reported by Riordan (Riordan, J.F. (1970) Fed. Proc. 29, Abstr. 462; Riordan, J.F. (1973) Biochemistry 12, 3915-3923). Protection from inactivation was also provided by the competitive inhibitor AMP, while nicotinamide exhibited no effect. Such results suggest that the AMP moiety of the NADH molecule is of major importance in the ability of NADH to protect the enzyme. When fluorescence titrations were used to monitor the ability of cytoplasmic malate dehydrogenase to form a binary complex with NADH and to form a ternary complex with NADH and hydroxymalonate, only the formation of ternary complex seemed to be effected by arginine modification.     

Oxidation of NADPH by submitochondrial particles from beef heart in complete absence of transhydrogenase activity from NADPH to NAD.

Treatment of submitochondrial particles (ETP) with trypsin at 0 degrees destroyed NADPH leads to NAD (or 3-acetylpyridine adenine dinucleotide, AcPyAD) transhydrogenase activity. NADH oxidase activity was unaffected; NADPH oxidase and NADH leads to AcPyAD transhydrogenase activities were diminished by less than 10%. When ETP was incubated with trypsin at 30 degrees, NADPH leads to NAD transhydrogenase activity was rapidly lost, NADPH oxidase activity was slowly destroyed, but NADH oxidase activity remained intact. The reduction pattern by NADPH, NADPH + NAD, and NADH of chromophores absorbing at 475 minus 510 nm (flavin and iron-sulfur centers) in complex I (NADH-ubiquinone reductase) or ETP treated with trypsin at 0 degrees also indicated specific destruction of transhydrogenase activity. The sensitivity of the NADPH leads to NAD transhydrogenase reaction to trypsin suggested the involvement of susceptible arginyl residues in the enzyme. Arginyl residues are considered to be positively charged binding sites for anionic substrates and ligands in many enzymes. Treatment of ETP with the specific arginine-binding reagent, butanedione, inhibited transhydrogenation from NADPH leads to NAD (or AcPyAD). It had no effect on NADH oxidation, and inhibited NADPH oxidation and NADH leads to AcPyAD transhydrogenation by only 10 to 15% even after 30 to 60 min incubation of ETP with butanedione. The inhibition of NADPH leads to NAD transhydrogenation was diminished considerably when butanedione was added to ETP in the presence of NAD or NADP. When both NAD and NADP were present, the butanedione effect was completely abolished, thus suggesting the possible presence of arginyl residues at the nucleotide binding site of the NADPH leads to NAD transhydrogenase enzyme. Under conditions that transhydrogenation from NADPH to NAD was completely inhibited by trypsin or butanedione, NADPH oxidation rate was larger than or equal to 220 nmol min-1 mg-1 ETP protein at pH 6.0 and 30 degrees. The above results establish that in the respiratory chain of beef-heart mitochondria NADH oxidation, NADPH oxidation, and NADPH leads to NAD transhydrogenation are independent reactions.     

Modification of ferredoxin-NADP+ reductase from the alga Bumilleriopsis with butanedione and dansyl chloride

Modification of ferredoxin-NADP⁺ reductase from the alga Bumilleriopsis with butanedione (diacetyl) and dansyl chloride results in loss of enzymatic activity. Under pseudo-first order conditions the rate of inactivation by butanedione is directly proportional to the concentration of the modifying reagent with a slope of unity. The protective effect of pyridine nucleotides, as well as their analogs against inactivation by butanedione indicates involvement of arginine in the binding of pyridine nucleotides at the active site. Inactivation by dansyl chloride suggests that a further amino acid is involved, possibly lysine. Amino acid analyses of the butanedione-treated reductase show that the degree of inactivation correlates well with the decrease in arginine. Furthermore, two arginine residues are modified concomitant with complete inactivation of the enzyme, although this does not imply that both residues participate necessarily in the binding of pyridine nucleotides. Fingerprint analysis of the carboxymethylated, trypsin-digested enzyme indicates loss of one arginine-containing peptide when the protein had been modified by butanedione. There was no change in cysteine-containing peptides.     

Modification of arginine residues in pyruvate kinase (author's transl)

Pyruvate kinase from pig heart is inactivated by the specific arginyl reagent phenylglyoxal. The loss of activity is caused by the reaction of a single molecule of phenylglyoxal per subunit of enzyme. During inactivation 3 - 6 arginyl residues are modified dependent on the concentration of phenylglyoxal used for modification. The solubility of the protein is reduced by the modification. ATP or phosphoenolpyruvate protect against inactivation. A single arginine is less subject to chemical modification in their presence. Therefore we assume that an arginine is essential at the substrate binding site. The activating ion K does not affectinactivation, where as Mg2 diminishes inactivation. Pyruvate kinase from rabbit muscle is modified by phenylglyoxal in a similar manner.     

Implication of arginyl residues in mRNA binding to ribosomes

Modification of Escherichia coli robosomes with phenylglyoxal and butanedione, protein reagents specific for arginyl residues, inactivates polypeptide polymerization, assayed as poly(U)-dependent polyphenylalanine synthesis, and the binding of poly(U). Inactivation is produced by modification of the 30-S subunit. Both the RNA and the protein moieties of 30-S subunits are modified by phenylglyoxal, and modification of either of them is accompanied by inactivation of polypeptide synthesis. Modification of only the split proteins released from 30-S subunits by prolonged dialysis against a low-ionic-strength buffer, which contain mainly protein S1, produces inhibition of poly(U) binding and inactivation of polypeptide synthesis. Amino acid analysis of the modified split proteins showed a significant modifications of arginyl residues. These results indicate that the arginyl residues of a few 30-S proteins might be important in the interaction between mRNA and the 30-S subunit, which agrees with the general role assigned to the arginyl residues of proteins as the positively charged recognition site for anionic ligands.     

Inactivation of ATP-dependent deoxyribonuclease of Micrococcus luteus by 2,3-butanedione

ATP-dependent deoxyribonuclease from Micrococcus luteus was purified to near homogeneity by a procedure involving gentle cell lysis, ammonium sulfate fractionation, TEAE-cellulose chromatography, Sephadex G-150 gel filtration and DNA-cellulose chromatography. Treatment of the enzyme with 2,3-butanedione, which binds specifically to arginyl residues, caused rapid loss of enzyme activities and the effect was enhanced by borate ion. The reaction obeyed first order kinetics with respect to the butanedione concentration, indicating that at least one functional arginyl residue is involved in the inactivation reaction. The enzyme was protected from inactivation by the presence of a low concentration of ATP, but not of ADP, AMP or adenosine. These results indicate that ATP-dependent deoxyribonuclease of Micrococcus luteus has functional arginyl residue(s) at an ATP-binding site.     

Arginine residues involved in binding of tetrahydrofolate to sheep liver serine hydroxymethyltransferase.

The arginine residue(s) necessary for tetrahydrofolate binding to sheep liver serine hydroxymethyltransferase were located by phenylglyoxal modification. The incorporation of [7-14C]phenylglyoxal indicated that 2 arginine residues were modified per subunit of the enzyme and the modification of these residues was prevented by tetrahydrofolate. In order to locate the sites of phenylglyoxal modification, the enzyme was reacted in the presence and absence of tetrahydrofolate using unlabeled and radioactive phenylglyoxal, respectively. The labeled phenylglyoxal-treated enzyme was digested with trypsin, and the radiolabeled peptides were purified by high-performance liquid chromatography on reversed-phase columns. Sequencing the tryptic peptides indicated that Arg-269 and Arg-462 were the sites of phenylglyoxal modification. Neither a spectrally discernible 495-nm intermediate (characteristic of the native enzyme when substrates are added) nor its enhancement by the addition of tetrahydrofolate, was observed with the phenylglyoxal-modified enzyme. There was no enhancement of the rate of the exchange of the alpha-proton of glycine upon addition of tetrahydrofolate to the modified enzyme as was observed with the native enzyme. These results demonstrate the requirement of specific arginine residues for the interaction of tetrahydrofolate with sheep liver serine hydroxymethyltransferase.     

Further definition of the substrate specificity of the alpha-herpesvirus protein kinase and comparison with protein kinases A and C

The pseudorabies virus protein kinase prefers model substrates containing arginyl residues on the amino-terminal side of a target seryl or threonyl residue. We have defined this substrate specificity more precisely in experiments using a new series of synthetic model peptides. When the number of arginyl residues was varied from two to four in substrates of the type RnASVA it was found that peptides with four arginyl residues constituted the best substrates, although the most marked decrease in Km was seen on increasing the number of arginyl residues from two to three. The effect of varying the number of 'spacer' alanyl residues from zero to three was investigated in peptides of the type R4AmSVA, and the peptide with one alanyl residue was found to be the best substrate, making R4X the optimal amino-terminal environment for this enzyme. A similar substrate specificity was observed with the herpes simplex type 1 protein kinase. Protein kinase C was found to have a quite similar substrate preference to the viral enzyme as far as the number and position of the amino-terminal basic residues was concerned; but, unlike the viral protein kinase, it also requires carboxy-terminal basic residues in optimal peptide substrates, and can tolerate the substitution of lysyl for arginyl residues. The cyclic AMP-dependent protein kinase, like the viral enzyme, had favourable kinetic constants for this series of peptides, but differed from the latter in being able to catalyze the phosphorylation of the peptides with two to four arginyl residues with similar efficiency. Studies with the protein, clupeine Y1, as substrate indicated that the pseudorabies virus protein kinase can tolerate arginyl residues on the carboxyl-terminal side of its target residue when there are suitable amino-terminal arginyl determinants. In this respect the virus protein kinase resembled protein kinase C but differed from the cyclic AMP-dependent protein kinase which cannot tolerate such carboxyl-terminal basic residues. The relationship of substrate specificity with model peptides to the ability of the pseudorabies virus protein kinase to phosphorylate proteins in vitro and in vivo is discussed.