Evidence for an essential arginine residue at the active site of ATP citrate lyase from rat liver.

Rat liver ATP citrate lyase was inactivated by 2, 3-butanedione and phenylglyoxal. Phenylglyoxal caused the most rapid and complete inactivation of enzyme activity in 4-(2-hydroxyethyl)-1-piperazine-ethanesulphonic acid buffer, pH 8. Inactivation by both butanedione and phenylglyoxal was concentration-dependent and followed pseudo- first-order kinetics. Phenylglyoxal also decreased autophosphorylation (catalytic phosphate) of ATP citrate lyase. Inactivation by phenylglyoxal and butanedione was due to the modification of enzyme arginine residues: the modified enzyme failed to bind to CoA-agarose. The V declined as a function of inactivation, but the Km values were unaltered. The substrates, CoASH and CoASH plus citrate, protected the enzyme significantly against inactivation, but ATP provided little protection. Inactivation with excess reagent modified about eight arginine residues per monomer of enzyme. Citrate, CoASH and ATP protected two to three arginine residues from modification by phenylglyoxal. Analysis of the data by statistical methods suggested that the inactivation was due to modification of one essential arginine residue per monomer of lyase, which was modified 1.5 times more rapidly than were the other arginine residues. Our results suggest that this essential arginine residue is at the CoASH binding site.     

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.     

Chemical modification of arginine residues of rat liver S-adenosylhomocysteinase

Rat liver S-adenosylhomocysteinase (EC 3.3.1.1) is inactivated by phenylglyoxal following pseudo-first order kinetics. The dependence of the apparent first order rate constant for inactivation on the phenylglyoxal concentration shows that the inactivation is second order in reagent. This fact together with the reversibility of inactivation upon removal of excess reagent and the lack of reaction at residues other than arginine as revealed by amino acid analysis and incorporation of phenylglyoxal into the protein indicate that the inactivation is due to the modification of arginine residue. The substrate adenosine largely but not completely protects the enzyme against inactivation. Although the modification of two arginine residues/subunit is required for complete inactivation, the relationship between loss of enzyme activity and the number of arginine residues modified, and the comparison of the numbers of phenylglyoxal incorporated into the enzyme in the presence and absence of adenosine indicate that one residue which reacts very rapidly with the reagent compared with the other is critical for activity. Although the phenylglyoxal treatment does not result in alteration of the molecular size of the enzyme or dissociation of the bound NAD+, the intrinsic protein fluorescence is largely lost upon modification. The equilibrium binding study shows that the modified enzyme apparently fails to bind adenosine.     

Chemical modification of a functional arginine residue of rat liver glycine methyltransferase

Rat liver glycine methyltransferase is inactivated irreversibly by phenylglyoxal in potassium phosphate buffer. The inactivation obeys pseudo-first-order kinetics, and the apparent first-order rate constant for inactivation is linearly related to the reagent concentration. A second-order rate constant of 10.54 +/- 0.44 M-1 min-1 is obtained at pH 8.2 and 25 degrees C. Amino acid analysis shows that only arginine is modified upon treatment with phenylglyoxal. Sodium acetate, a competitive inhibitor with respect to glycine, affords complete protection in the presence of S-adenosylmethionine. Acetate alone has no effect on the rate of inactivation. The value of the dissociation constant for acetate determined from the protection experiment is in good agreement with that obtained by kinetic analysis. Comparison of the amount of [14C]phenylglyoxal incorporated into the protein and the number of arginine residues modified in the presence and absence of protecting ligands indicates that modification of one arginine residue per enzyme subunit eliminates the enzyme activity, and this residue is identified as Arg-175 by peptide analysis. The arginine-modified glycine methyltransferase appears to bind S-adenosylmethionine as the native enzyme does, as seen from quenching of the protein fluorescence by S-adenosylmethionine. These results suggest the requirement of Arg-175 in binding the carboxyl group of the substrate glycine.     

A comparative study of essential arginine residues in Gramicidin S synthetase 2 and isoleucyl tRNA synthetase

In gramicidin S synthetase 2 (GS 2) from Bacillus brevis, L-proline, L-valine, L-ornithine, and L-leucine activations to aminoacyl adenylates are progressively inhibited by phenylglyoxal. The inactivation of GS 2 obeys pseudo-first-order kinetics. ATP completely prevents inactivation of GS 2 by phenylglyoxal, whereas amino acids only partially prevent it. In the presence of ATP, four arginine residues per mol of GS 2 are protected from modification by phenylglyoxal as determined by amino acid analysis and the incorporation of [7-14C]phenylgloxal into the enzyme protein, indicating that a single arginine residue is necessary for each amino acid activation. In isoleucyl tRNA synthetase from Escherichia coli, phenylglyoxal inhibits activation of L-isoleucine to isoleucyl adenylate. ATP completely prevents inactivation, although isoleucine only partially prevents it. One arginine residue of isoleucyl tRNA synthetase is protected by ATP from modification by phenylglyoxal, suggesting that a single arginine residue is essential for isoleucine activation. These results support the involvement of arginine residues in ATP binding with GS 2 or isoleucyl tRNA synthetase, and thus indicate that arginine residues of amino acid activating enzymes are essential for the formation of aminoacyl adenylates in both nonribosomal and ribosomal peptide biosynthesis.     

Arginine-specific modification of rabbit muscle phosphoglucose isomerase: Differences in the inactivation by phenylglyoxal and butanedione and in the protection by substrate analogs

Rabbit muscle phosphoglucose isomerase was modified with phenylglyoxal or 2,3-butanedione, the reaction with either reagent resulting in loss of enzymatic activity in a biphasic mode. At slightly alkaline pH butanedione was found to be approximately six times as effective as phenylglyoxal. The inactivation process could not be significantly reversed by removal of the modifier. Competitive inhibitors of the enzyme protected partially against loss of enzyme activity by either modification. The only kind of amino acid residue affected was arginine. However, more than one arginine residue per enzyme subunit was found to be susceptible to modification by the dicarbonyl reagents. From protection experiments it was concluded (i) that both modifiers react specifically with an arginine in the phosphoglucose isomerase active site and nonspecifically with one or more arginine residues elsewhere in the enzyme molecule, (ii) that modification at either loci causes loss of catalytic activity, and (iii) that butanedione has a higher preference for active site arginine than for arginine residues outside of the catalytic center whereas the opposite is true for phenylglyoxal.     

An essential residue at the active site of aspartate transcarbamylase.

Reaction of phenylglyoxal with aspartate transcarbamylase and its isolated catalytic subunit results in complete loss of enzymatic activity. This modification reaction is markedly influenced by pH and is partially reversible upon dialysis. Carbamyl phosphate or carbamyl phosphate with succinate partially protect the catalytic subunit and the native enzyme from inactivation by phenylglyoxal. In the native enzyme complete protection from inactivation is afforded by N-(phosphonacetyl)-L-aspartate. The decrease in enzymatic activity correlates with the modification of 6 arginine residues on each aspartate transcarbamylase molecule, i.e. 1 arginine per catalytic site. The data suggest that the essential arginine is involved in the binding of carbamyl phosphate to the enzyme. Reaction of the single thiol on the catalytic chain with 2-chloromercuri-4-nitrophenol does not prevent subsequent reaction with phenylglyoxal. If N-(phosphonacetyl)-L-aspartate is used to protect the active site we find that phenylglyoxal also causes the loss of activation of ATP and inhibition by CTP. The rate of loss of heterotropic effects is exactly the same for both nucleotides indicating that the two opposite regulatory effects originate at the same location on the enzyme, or are transmitted by the same mechanism between the subunits, or both.     

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 arginine residues in tryptophanase from Escherichia coli.

Tryptophanase from Escherichia coli B/1t7-A is inactivated by the arginine-specific reagent, phenylglyoxal, in potassium phosphate buffer at pH 7.8 AND 25 degrees. Apo- and holoenzyme are inactivated at the same rate, and inactivation of both is correlated with modification of 2 arginine residues/tryptophanase monomer. Substrate analogs having a carboxyl group protect the holoenzyme against both inactivation and arginine modification but have no effect on the inactivation or modification of the apoenzyme. Phenylglyoxal-modified apotryptophanase retains the capacity to bind the coenzyme, pyridoxal-P, but the spectrum of this reconstituted species differs from that of native holotryptophanase. Neither this reconstituted species nor the phenyglyoxal-modified holoenzyme shows the 500 nm absorption characteristic of the native enzyme when substrates are added. These results demonstrate a requirement for specific arginine residues for substrate binding and are discussed in the context of the known conformational and spectal forms of tryptophanase with regard to a possible role for arginine residues in formation of a catalytically effective enzyme-pyridoxal-P complex.     

Chemical modification studies on alkaline phosphatase from pearl oyster (Pinctada fucata): a substrate reaction course analysis and involvement of essential arginine and lysine residues at the active site

Alkaline phosphatases (ALP, EC 3.1.3.1) are ubiquitous enzymes found in most species. ALP from a pearl oyster, Pinctada fucata (PALP), is presumably involved in nacreous biomineralization processes. Here, chemical modification was used to investigate the involvement of basic residues in the catalytic activity of PALP. The Tsou's plot analysis indicated that the inactivation of PALP by 2,4,6-trinitrobenzenesulfonic acid (TNBS) and phenylglyoxal (PG) is dependent upon modification of one essential lysine and one essential arginine residue, respectively. Substrate reaction course analysis showed that the TNBS and PG inactivation of PALP followed pseudo-first-order kinetics and the second-order inactivation constants for the enzyme with or without substrate binding were determined. It was found that binding substrate slowed the PG inactivation whereas had little effect on TNBS inactivation. Protection experiments showed that substrates and competitive inhibitors provided significant protection against PG inactivation, and the modified enzyme lost its ability to bind the specific affinity column. However, the TNBS-induced inactivation could not be prevented in presence of substrates or competitive inhibitors, and the modified enzyme retained the ability to bind the affinity column. In a conclusion, an arginine residue involved in substrate binding and a lysine residue involved in catalysis were present at the active site of PALP. This study will facilitate to illustrate the role ALP plays in pearl formation and the mechanism involved.     

A functional arginine residue in the vacuolar H(+)-ATPase of higher plants.

The arginine-specific reagent phenylglyoxal inactivated the vacuolar H(+)-ATPase of red beet. Inactivation by phenylglyoxal followed pseudo-first-order kinetics and a double log plot of the t1/2 of inactivation versus phenylglyoxal concentration yielded a slope of 1.18. Neither inorganic anions nor DIDS protected from phenylglyoxal-mediated inactivation of the H(+)-ATPase. Indeed, Cl- stimulated the rate of phenylglyoxal-mediated H(+)-ATPase inactivation relative to SO4(2-). ATP, but not MgATP or ADP, protected from phenylglyoxal-mediated inactivation and inactivation resulted in a decrease in the Vmax of the H(+)-ATPase with little effect on the Km. Collectively, these results are consistent with phenylglyoxal-mediated inactivation of the vacuolar H(+)-ATPase resulting from modification of a single arginine residue in the catalytic nucleotide binding site of the vacuolar H(+)-ATPase. Stimulation of phenylglyoxal-mediated inactivation by Cl- indicates that exposure of the phenylglyoxal-sensitive functional arginine residue is enhanced in the presence of Cl-. The failure of MgATP to protect from phenylglyoxal inactivation suggests that ATP, rather than MgATP, binds directly to the catalytic site and that Mg2+ may act to promote catalysis subsequent to ATP binding.     

Essential arginine residues in the active sites of propionyl CoA carboxylase and beta-methylcrotonyl CoA carboxylase

At least one arginine residue is essential for substrate binding in or near the active sites of propionyl CoA carboxylase (PCC) and beta-methylcrotonyl CoA carboxylase (beta MCC) in cultured human fibroblasts. This conclusion is based on studies of enzyme inhibition by phenylglyoxal, a reagent which specifically modifies arginine residues. Human fibroblast PCC both in extracts and in a 20-fold purified preparation was nearly completely protected from phenylglyoxal inhibition following incubation with propionyl CoA or ATP. It appears that a phosphate group from either ATP or the CoA moiety of propionyl CoA reacts with the essential arginine residue(s). beta MCC which was similarly inhibited by phenylglyoxal was protected by beta-methylcrotonyl CoA and ATP. Thus phenylglyoxal may be used to label specific arginine residues within the active sites of previously sequenced carboxylases.     

L-serine binds to arginine-148 of the beta 2 subunit of Escherichia coli tryptophan synthase

Inactivation of the beta 2 subunit and of the alpha 2 beta 2 complex of tryptophan synthase of Escherichia coli by the arginine-specific dicarbonyl reagent phenylglyoxal results from modification of one arginyl residue per beta monomer. The substrate L-serine protects the holo beta 2 subunit and the holo alpha 2 beta 2 complex from both inactivation and arginine modification but has no effect on the inactivation or modification of the apo forms of the enzyme. This result and the finding that phenylglyoxal competes with L-serine in reactions catalyzed by both the holo beta 2 subunit and the holo alpha 2 beta 2 complex indicate that L-serine and phenylglyoxal both bind to the same essential arginyl residue in the holo beta 2 subunit. The apo beta 2 subunit is protected from phenylglyoxal inactivation much more effectively by phosphopyridoxyl-L-serine than by either pyridoxal phosphate or pyridoxine phosphate, both of which lack the L-serine moiety. The phenylglyoxal-modified apo beta 2 subunit binds pyridoxal phosphate and the alpha subunit but cannot bind L-serine or L-tryptophan. We conclude that the alpha-carboxyl group of L-serine and not the phosphate of pyridoxal phosphate binds to the essential arginyl residue in the beta 2 subunit. The specific arginyl residue in the beta 2 subunit which is protected by L-serine from modification by phenyl[2-14C]glyoxal has been identified as arginine-148 by isolating a labeled cyanogen bromide fragment (residues 135-149) and by digesting this fragment with pepsin to yield the labeled dipeptide arginine-methionine (residues 148-149). The primary sequence near arginine-148 contains three other basic residues (lysine-137, arginine-141, and arginine-150) which may facilitate anion binding and increase the reactivity of arginine-148. The conservation of the arginine residues 141, 148, and 150 in the sequences of tryptophan synthase from E. coli, Salmonella typhimurium, and yeast supports a functional role for these three residues in anion binding. The location and role of the active-site arginyl residues in the beta 2 subunit and in two other enzymes which contain pyridoxal phosphate, aspartate aminotransferase and glycogen phosphorylase, are compared.     

Evidence for an arginine residue at the substrate binding site of Escherichia coli adenylosuccinate synthetase as studied by chemical modification and site-directed mutagenesis

Chemical modification of adenylosuccinate synthetase from Escherichia coli with phenylglyoxal resulted in an inhibition of enzyme activity with a second-order rate constant of 13.6 M-1 min-1. The substrates, GTP or IMP, partially protected the enzyme against inactivation by the chemical modification. The other substrate, aspartate, had no such effect even at a high concentration. In the presence of both IMP and GTP during the modification, nearly complete protection of the enzyme against inactivation was observed. Stoichiometry studies with [7-14C]phenylglyoxal showed that only 1 reactive arginine residue was modified by the chemical reagent and that this arginine residue could be shielded by GTP and IMP. Sequence analysis of tryptic peptides indicated that Arg147 is the site of phenylglyoxal chemical modification. This arginine has been changed to leucine by site-directed mutagenesis. The mutant enzyme (R147L) showed increased Michaelis constants for IMP and GTP relative to the wild-type system, whereas the Km for aspartate exhibited a modest decrease as compared with the native enzyme. In addition, kcat of the R147L mutant decreased by a factor of 1.3 x 10(4). On the bases of these observations, it is suggested that Arg147 is critical for enzyme catalysis.     

Chemical modification of 3-HBA-6-hydroxylase by phenylglyoxal: kinetic and physicochemical studies on the modified enzyme.

The inactivation of 3-HBA-6-hydroxylase isolated from Micrococcus species by phenylglyoxal and protection offered by 3-HBA against inactivation indicate the presence of arginine residue at or near the substrate binding site. The loss of enzyme activity was time and concentration dependent and displayed pseudo-first order kinetics. A 'n' value of 0.9 was obtained thus suggesting the modification of a single arginine residue per active site which led to the loss of enzyme activity. The enzyme activity could be restored by extensive dialysis at neutral pH. Quenching of the intrinsic fluorescence and reduction in the ellipticity value at 280 nm in the near-UV CD spectrum of the enzyme was noticed after its treatment with phenylglyoxal. These observations probably imply distinct perturbations in the environment of adjacent aromatic amino acid residues such as tryptophan as a consequence of arginine modification.     

Chemical modification of the calmodulin-stimulated phosphatase, calcineurin, by phenylglyoxal

Chemical modification of calcineurin by phenylglyoxal was used to probe for the presence of arginine at, or in close proximity to, the catalytic site of this phosphatase. Phenylglyoxal inactivated calcineurin with a second-order rate constant of 1.5 M-1 min-1 at pH 7.5 and 30 degrees C. The inactivation reaction was extremely sensitive to Ca2+-induced conformational changes on calcineurin; removal of this metal ion from the reaction medium increased the rate of inactivation by almost 1 order of magnitude. Furthermore, significant protection of calcineurin by ADP was observed only in the presence of Ca2+, which suggests either that distinct sites are modified by phenylglyoxal in the absence and presence of Ca2+ or that the metal ion promotes binding of ADP to calcineurin. Inactivation of calcineurin by phenyl[2-14C]glyoxal resulted in the incorporation of more than 12 eq of the reagent. However, a kinetic analysis of the order of the inactivation reaction and complete protection of calcineurin by p-nitrophenyl phosphate suggest that only one of the modified residues is responsible for the loss of enzymatic activity. Protection of calcineurin by ADP was enhanced severalfold by calmodulin, which correlated well with a calmodulin-stimulated decrease in the Ki for this ligand. Protection of calcineurin from inactivation by phenylglyoxal was also observed in the presence of various other nucleotides; half-maximal protection by these poor substrates and competitive inhibitors was observed at concentrations near their respective inhibition constants. Thus, the results of this modification study indicate that at least 1 arginine residue is essential for the expression of catalytic activity of the calmodulin-regulated phosphatase.     

Functional arginine residues and carboxyl groups in the adenosine triphosphatase of the thermophilic bacterium PS-3

Treatment of purified ATPase of the thermophilic bacterium PS-3 with the arginine reagent phenylglyoxal or with Woodward's reagent K, gave complete inactivation of the enzyme. The inactivation rates followed apparent first-order kinetics. The apparent order of reaction with respect to inhibitor concentrations gave values near to 1 with both reagents, suggesting that inactivation was a consequence of modifying one arginine or carboxyl group per active site. ADP and ATP strongly protected the thermophilic ATPase against both reagents. GDP and IDP protected less, whilst CTP did not protect. Experiments in which the incorporation of [14C]phenylglyoxal into the enzyme was measured show that extrapolation of incorporation to 100% inactivation of the enzyme gives 8-9 mol [14C]phenylglyoxal per mol ATPase, whilst ADP or ATP prevent modification of about one arginine per mol.     

Specific arginine modification at the phosphatase site of muscle carbonic anhydrase

Mammalian carbonic anhydrase III has previously been shown to catalyze the hydrolysis of p-nitrophenyl phosphate in addition to possessing the conventional CO2 hydratase and p-nitrophenylacetate esterase activities. Modification of pig muscle carbonic anhydrase III with the arginine reagent phenylglyoxal yielded two clearly distinctive results. Reaction of the enzyme with phenylglyoxal at concentrations equivalent to those of the enzyme yielded stoichiometric inactivation titration of the enzyme's phosphatase activity, approaching 100% loss of activity with the simultaneous modification of one arginine residue, the latter based on a 1:1 reaction of phenylglyoxal with arginine. At this low ratio of phenylglyoxal to enzyme, neither the CO2 hydratase activity nor the acetate esterase activity was affected. When the modification was performed with a significant excess of phenylglyoxal, CO2 hydratase and acetate esterase activities were diminished as well. That loss of activity was accompanied by the incorporation of an additional half dozen phenylglyoxals and, presumably, the modification of an equal number of arginine residues. The data in their entirety are interpreted to show that the p-nitrophenylphosphatase activity is a unique property of carbonic anhydrase III and that excessive amounts of the arginine-modifying reagent lead to unspecific structural changes of the enzyme as a result of which all of its enzymatic activities are inactivated.     

Essential arginine residues in human liver arylsulfatase A.

Human liver arylsulfatase A was treated with arginine-specific reagents (diones), resulting in a loss of enzyme activitity with apparent first-order kinetics. Sulfite and borate—competitive inhibitors of the enzyme—provided complete protection from inactivation by phenylglyoxal. Sulfite and substrate each likewise protected against enzyme inactivation by 2,3-butanedione. A plot of pseudo-first-order rate constants of enzyme inactivation versus 2,3-butanedione concentrations suggests that an essential arginine residue is modified with a loss in function of the binding site or of the active site of the protein. Chemical analysis of the butanedione-treated sulfatase indicates that complete enzyme inactivation corresponds to a modification of only about 2 of the 20 arginine residues per enzyme subunit. Taken together, all of the results strongly suggest that arginine residues are essential for the activity of arylsulfatase A. An incidental discovery in this work is that borate ion is a competitive inhibitor of human arylsulfatase A with a K_i of 2.5 × 10^?4 M.     

Reaction of phenylglyoxal and (p-hydroxyphenyl) glyoxal with arginines and cysteines in the alpha subunit of tryptophan synthase

The alpha subunit of tryptophan synthase from Escherichia coli is inactivated by phenylglyoxal and by (p-hydroxyphenyl)glyoxal. The use of these chemical modification reagents to determine the role of arginyl residues in the alpha subunit of tryptophan synthase has been complicated by our finding that these reagents react with sulfhydryl groups of the alpha subunit, as well as with arginyl residues. Analyses of the data for incorporation of phenyl[2-14C]glyoxal, for inactivation, and for sulfhydryl modification in the presence and absence of indole-3-glycerol phosphate indicate that two sulfhydryl groups and one arginine are essential for the activity. Our finding that the substrate protects the single essential arginyl residue but not the two sulfhydryl groups is consistent with the observed kinetics of partial protection by substrate or by a substrate analogue, indole-3-propanol phosphate. In contrast to phenylglyoxal, (p-hydroxyphenyl)glyoxal modifies two to three sulhydryl groups that are not protected by indole-3-glycerol phosphate and modifies none of the arginyl residues that are modified by phenylglyoxal.