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.     

Labeling of specific lysine residues at the active site of glutamine synthetase

Glutamine synthetase (Escherichia coli) was incubated with three different reagents that react with lysine residues, viz. pyridoxal phosphate, 5'-p-fluorosulfonylbenzoyladenosine, and thiourea dioxide. The latter reagent reacts with the epsilon-nitrogen of lysine to produce homoarginine as shown by amino acid analysis, nmr, and mass spectral analysis of the products. A variety of differential labeling experiments were conducted with the above three reagents to label specific lysine residues. Thus pyridoxal phosphate was found to modify 2 lysine residues leading to an alteration of catalytic activity. At least 1 lysine residue has been reported previously to be modified by pyridoxal phosphate at the active site of glutamine synthetase (Whitley, E. J., and Ginsburg, A. (1978) J. Biol. Chem. 253, 7017-7025). By varying the pH and buffer, one or both residues could be modified. One of these lysine residues was associated with approximately 81% loss in activity after modification while modification of the second lysine residue led to complete inactivation of the enzyme. This second lysine was found to be the residue which reacted specifically with the ATP affinity label 5'-p-fluorosulfonylbenzoyladenosine. Lys-47 has been previously identified as the residue that reacts with this reagent (Pinkofsky, H. B., Ginsburg, A., Reardon, I., Heinrikson, R. L. (1984) J. Biol. Chem. 259, 9616-9622; Foster, W. B., Griffith, M. J., and Kingdon, H. S. (1981) J. Biol. Chem. 256, 882-886). Thiourea dioxide inactivated glutamine synthetase with total loss of activity and concomitant modification of a single lysine residue. The modified amino acid was identified as homoarginine by amino acid analysis. The lysine residue modified by thiourea dioxide was established by differential labeling experiments to be the same residue associated with the 81% partial loss of activity upon pyridoxal phosphate inactivation. Inactivation with either thiourea dioxide or pyridoxal phosphate did not affect ATP binding but glutamate binding was weakened. The glutamate site was implicated as the site of thiourea dioxide modification based on protection against inactivation by saturating levels of glutamate. Glutamate also protected against pyridoxal phosphate labeling of the lysine consistent with this residue being the common site of reaction with thiourea dioxide and pyridoxal phosphate.     

Primary structure and properties of an inactive mutant aspartate transcarbamoylase.

A mutant form of Escherichia coli aspartate transcarbamoylase (ATCase) which lacks catalytic activity has been purified and characterized (Wall, K.A., Flatgaard, J.E., Gibbons, I., and Schachman, H.K. (1979) J. Biol. Chem 254, 11910-11916). Peptide mapping of the mutant and wild type catalytic chains followed by the determination of the amino acid sequence of the one altered peptide in the mutant indicated that a glycyl residue was replaced by aspartic acid. This substitution is located at position 125 in the tentative sequence kindly provided by W. Konigsberg (personal communication). The mutant protein has an overall secondary structure similar to that of the wild type as indicated by circular dichroism spectroscopy. However, marked changes in the reactivity of several amino acid residues were demonstrated. Lysyl residue 84 which in the wild type subunits reacts specifically with pyridoxal 5'-phosphate is only slightly reactive in the mutant even though the peptide containing that residue was not altered in amino acid composition. Another residue, cysteinyl 46, which is thought to be in the active site, is much more reactive toward p-hydroxymercuribenzoate in the mutant subunit than in the wild type protein. Finally, tyrosyl residue 213, which according to recent crystallographic studies is not near the active site and which exhibits an unusually low pK (9.1) in the wild type catalytic subunits, appears to have its pK shifted to 10.5 or higher as a result of the mutation. The evidence indicates that the substitution of an aspartyl for a glycyl residue at a region of the amino acid sequence remote from those residues in the active site causes sufficient modification of the tertiary structure to cause the loss of enzyme activity and to affect the reactivity of other residues in the protein. Moreover, the quaternary structure of the intact enzyme is altered as well since the subunit interactions are greatly weakened.     

Influence of phosphate ligands in abolishing the conformational difference between ribonuclease A and its acid-denatured derivative.

The initial structural alteration of RNAase A due to acid denaturation (0.5 N HCl, 30 degrees C) that accompanies deamidation (without altering enzymic activity) has been dectected by spectrophotometric titration, fluorescence and ORD/CD measurements. It is shown that acid treated RNAase A has an altered conformation at neutral pH, 25 degrees C. This is characterized by the increased accessibility of buried tyrosine residue(s) towards the solvent. The most altered conformation of RNAase A is found in the 10 h acid-treated derivative. This has about 1.5 additional exposed tyrosine residues and a lesser amount of secondary structure than RNAase A. All three methods (titration, fluorescence and CD) established that the structural transition of RNAase A is biphasic. The first phase occurs within 1 h and the resulting subtle conformational change is constant up to 7 h. Following this, after the release of 0.55 mol of ammonia, the major conformational change begins. The altered conformation of the acid-denatured RNAase A could be reversed completely to the native state through a conformational change induced by substrate analogs like 2'- or 3'-CMP. Thus the monodeamidated derivative isolated from the acid-denatured RNAase A by phosphate is very similar to RNAase A in over-all conformation. The results suggest the possibility of flexibility in the RNAase A molecule that does not affect its catalytic activity, as probed through the tyrosine residues.     

Efrapeptin prevents modification by phenylglyoxal of an essential arginyl residue in mitochondrial adenosine triphosphatase.

Studies of phenylglyoxal incorporation by beef-heart mitochondrial ATPase reveal one fast-reacting arginyl residue/enzyme molecule. Modification of this group proceeds at a rate which parallels the loss of enzymatic activity. Efrapeptin protects the arginyl residue from reaction with phenylglyoxal. The data suggest that efrapeptin binds at the catalytic site and blocks accessibility of an essential arginine at the adenine nucleotide binding site. The detection of a single, fast-reacting, essential arginine on an enzyme with multiple copies of the catalytic subunit, provides further evidence in support of the alternating site mechanism for ATP synthesis proposed by Kayalar et al. (Kayalar, C., Rosing, J., and Boyer, P.D. (1977) J.Biol. Chem. 252, 2486--2491).     

A new arylating agent, 2-carboxy-4,6-dinitrochlorobenzene. Reaction with model compounds and bovine pancreatic ribonuclease.

The reagent 2-carboxy-4,6-dinitrochlorobenzene (CDNCB) reacts with the imino, amino and sulfhydryl groups of model compounds. At pH 8.2, sulfhydryl groups react much faster than do amines. N alpha-Acetylhistidine, N alpha-acetyltyrosine and N alpha-acetyltryptophan do not react. Poly(L-Lysine) and poly(DL-lysine) react about 50 times as fast as does N alpha-acetyllysine. A dichloroanalog, 6-carboxy-2,4-dinitro-1,3-dichlorobenzene, shows stepwise reactivity with amines. With bovine pancreatic ribonuclease, which contains no sulfhydryl, CDNCB reacts preferentially with the epsilon-amino of Lys-41 at 450 times the rate with the epsilon-amino of N alpha-acetyllysine. The preferential reactivity at Lys-41 is discussed in relation to the pK of Ly-41, the cationic character of the active site cleft, and the mechanism of RNAase action on substrates.     

Arginine residues are critical for the heparin-cofactor activity of antithrombin III.

A dilution/quench technique was used to monitor the time course of chemical modification on the heparin-cofactor (a) and progressive thrombin-inhibitory (b) activities of human antithrombin III. Treatment of antithrombin III (AT III) with 2,4,6-trinitrobenzenesulphonate at pH 8.3 and 25 degrees C leads to the loss of (a) at 60-fold more rapid rate than the loss of (b). This is consistent with previous reports [Rosenberg & Damus (1973) J. Biol. Chem. 248, 6490-6505; Pecon & Blackburn (1984) J. Biol. Chem. 259, 935-938] that lysine residues are involved in the binding of heparin to AT III, but not in thrombin binding. Treatment of AT III with phenylglyoxal at pH 8.3 and 25 degrees C again leads to a more rapid loss of (a) than of (b), with the loss of the former proceeding at a 4-fold faster rate. The presence of heparin during modification with phenylglyoxal significantly decreases the rate of loss of (a). Full loss of (a) correlates with the modification of seven arginine residues per inhibitor molecule, whereas loss of (b) does not commence until approximately four arginine residues are modified and is complete upon the modification of approximately eleven arginine residues per inhibitor molecule. This suggests that (the) arginine residue(s) in AT III are involved in the binding of heparin in addition to the known role of Arg-393 at the thrombin-recognition site [Rosenberg & Damus (1973) J. Biol. Chem. 248, 6490-6505; Jörnvall, Fish & Björk (1979) FEBS Lett. 106, 358-362].     

The states of tyrosyl and tryptophyl residues in a protein proteinase inhibitor (Streptomyces subtilisin inhibitor

The states of tyrosyl and tryptophyl residues of a dimeric protein proteinase inhibitor, Streptomyces subtilisin inhibitor (Sato, S & Murao, S. (1973), Agric. Biol. Chem. 37, 1067) were studies by solvent perturbation difference spectroscopy with methanol, ethylene glycol, polyethylene glycol, and deuterium oxide as perturbants, and by spectrophotometric titration at alkaline pH. It appeared that all three tyrosyl residues per monomer of the inhibitor were exposed on the surface of the molecule, and their apparent pK values were estimated separately to be 9.58, 11.10, and 12.42. The single tryptophyl residue per monomer of the inhibitor appeared to be partially buried in the protein molecule.     

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.     

Involvement of basic amino acids in the activity of a nucleic acid helix-destabilizing protein

Under conditions of low ionic strength, ribonuclease A, which binds more tightly to single- than to double-stranded DNA, lowers the melting temperature of DNA helices (Jensen and von Hippel (1976) J. Biol. Chem. 251, 7198-7214). The effects of chemical modification of lysine and arginine residues on the helix-destabilizing properties of this protein have been examined. Removal of the positive charge on the lysine epsilon-amino group, either by maleylation or acetylation, destroys the ability of RNAase A to lower the Tm of poly[d(A-T)]. However, reductive alkylation of these residues, which has not effect on charge, yields derivatives which lower the Tm by only about one-half that seen with unmodified controls. Phenylglyoxalation of arginines can largely remove the Tm-depressing activity of RNAase A. RNAase S, which is produced by cleavage of RNAase A between amino acids 20 and 21, possesses DNA helix-destabilizing activity comparable to that of the parent protein, whereas S-protein (residues 21-124) increases poly[d(A-T)] Tm and S-peptide (1-20) has no effect on Tm. These results suggest that specific location of several basic amino acids situated on the surface of RNAase A is largely responsible for this protein's DNA melting activity.     

Role of cysteine residues in ribonuclease H from Escherichia coli. Site-directed mutagenesis and chemical modification.

The role of the three cysteine residues at positions 13, 63 and 133 in Escherichia coli RNAase H, an enzyme that is sensitive to N-ethylmaleimide [Berkower, Leis & Hurwitz (1973) J. Biol. Chem. 248, 5914-5921], was examined by using both site-directed mutagenesis and chemical modification. Novel aspects that were found are as follows. First, none of the cysteine residues is required for activity. Secondly, chemical modification of either Cys-13 or Cys-133 with thiol-blocking reagents inactivates the enzyme, but that of Cys-63 does not. Thus the sensitivity of E. coli RNAase H to N-ethylmaleimide arises not from blocking of the thiol group but from steric hindrance by the modifying group incorporated at either Cys-13 or Cys-133.     

On the reaction of papain and succinylpapin with diazo-1-H-tetrazole.

1. The reaction of papain and succinylpapain with diazo-1-H-tetrazole was investigated under different conditions. The extent of modification of the amino acids histidine, tyrosine, tryptophan and lysine was determined spectrophotometrically and/or by amino acid analysis. 2. Only one of the two histidine residues present in the enzyme reacts with diazo-1-H-tetrazole forming a monoazo derivative. The pH dependence of the coupling reaction reveals a normal pK of this reactive histidine. There are several arguments suggesting that this may be histidine 159 near the essential SH-group of papain. 3. All five tryptophan residues of the protein react with the diazonium ion below pH 7 forming a monoazo derivative with an absorption maximum at 370 nm, above pH 7 only four residues couple with diazo-1-H-tetrazole. The reaction of one tryptophan and one histidine are correlated as can be concluded from the pH dependence of the coupling rate of both amino acids and the parallel impairment of the catalytic acitivity. 4. 10-11 tyrosine residues out of 19 react with diazo-1-H-tetrazole to give bisazo compounds. 5 residues involved in hydrogen bridges form monoazo compounds. Only 12 tyrosines can be acylated by acetylimidazole. A relationship between the extent of modification of tyrosine and the activity of the enzyme could not be found.     

Isolation and functional properties of an arginine-selective endoprotease from rat intestinal mucosa. A putative prosomatostatin convertase.

The endoproteolytic activity previously detected in rat intestinal mucosal extracts (Beinfeld M., Bourdais, J., Kuks, P., Morel, A., and Cohen, P. (1989) J. Biol. Chem. 264, 4460-4465), was purified to homogeneity as a 65-kDa molecular species. This putative proprotein-processing enzyme cleaves the peptide bond on the carboxyl side of a single arginine residue in hepta-[Leu62-Gln-Arg-Ser-Ala-Asn-Ser68] or trideca-[Asp56-Glu-Met-Arg-Leu-Glu-Leu-Gln-Arg-Ser-Ala-Asn-+ ++Ser68] peptides, reproducing the prosomatostatin sequence around Arg64, the locus for endoproteolytic release of either somatostatin-28 or its NH2-terminal fragment, somatostatin-28-(1-12), from their common precursor. This enzyme exhibits a strict selectivity for arginyl residues, as demonstrated with related substrates, and did not cleave at lysyl residues. Moreover, only arginyl residues belonging to peptides of the prosomatostatin family were cleaved, since no hydrolysis of peptides from other prohormones was detected. In addition, the arginine residue situated at position -5 on the NH2-terminal side of Arg64 not only did not function as a cleavage locus, but had no effect on the overall cleavage kinetics of the prosomatostatin-(56-68) peptide substrate. This enzyme also cleaved, but with much less efficiency, the peptide bond on the carboxyl side of an arginine in peptides containing either an Arg-Lys or a Lys-Arg doublet corresponding to prohormone cleavage sites. This enzyme was insensitive to divalent cation chelators, was completely inhibited by aprotinin and leupeptin, and was somewhat inhibited by other serine-protease inhibitors. It is concluded that this endoprotease is a serine protease and could be involved in prohormone or proprotein post-translational processing at single arginine cleavage sites.     

Substitution of an arginyl residue for the active site lysyl residue (Lys258) of aspartate aminotransferase

The active site lysyl residue (Lys258) of E. coli aspartate amino transferase was substituted for an arginyl residue by oligonucleotide-directed, site-specific mutagenesis. The mutant enzyme was obviously unable to form an aldimine bond with pyridoxal 5'-phosphate but firmly bound the coenzyme. The finding that the mutation did not lead to entire loss in the enzymic activity suggests that Lys258 may not be essential but auxiliary for enzymic catalysis. It is also conceived that the positive charge provided by Arg258 may contribute to the enzymic catalysis.     

Identification of amino acid residues modified by pyridoxal 5'-phosphate in Escherichia coli glutamine synthetase

Chemical modification studies with pyridoxal 5'-phosphate have indicated that lysine(s) appear to be at or near the active site of Escherichia coli glutamine synthetase (Colanduoni, J., and Villafranca, J. J. (1985) J. Biol. Chem. 260, 15042-15050; Whitley, E. J., Jr., and Ginsburg, A. (1978) J. Biol. Chem. 253, 7017-7025). Enzyme samples were prepared that contained approximately 1, approximately 2, and approximately 3 pyridoxamine 5'-phosphate residues/50,000-Da monomer; the activity of each sample was 100, 25, and 14% of the activity of unmodified enzyme, respectively. Cyanogen bromide cleavage of each enzyme sample was performed, the peptides were separated by high performance liquid chromatography, and the peptides containing pyridoxamine 5'-phosphate were identified by their absorbance at 320 nm. These isolated peptides were analyzed for amino acid composition and sequenced. The N terminus of the protein (a serine residue) was modified by pyridoxal 5'-phosphate at a stoichiometry of approximately 1/50,000 Da and this modified enzyme had full catalytic activity. Beyond a stoichiometry of approximately 1, lysines 383 and 352 reacted with pyridoxal 5'-phosphate and each modification results in a partial loss of activity. When various combinations of substrates and substrate analogs (ADP/Pi or L-methionine-SR-sulfoximine phosphate/ADP) were used to protect the enzyme from modification, Lys-352 was protected from modification indicating that this residue is at the active site. Under all experimental conditions employed, Lys-47, which reacts with the ATP analog 5'-p-fluorosulfonylbenzoyl-adenosine does not react with pyridoxal 5'-phosphate.     

Importance of arginine residues in the determination of the biological activity of human corticosteroid-binding globulin

The binding activity of human corticosteroid-binding globulin (CBG) is pH dependent and governed in alkaline pH ranges by the pK of arginine. No essential arginine residues is located in the binding site. The loss of biological activity is rapid and complete as soon as one arginine residue is modified by phenylglyoxal. There is also a transconformation of the CBG molecule. Therefore the surprising stability of CBG up to pH 11.5 may be explained by a large dependence of the CBG tertiary structure on the integrity of one arginine residue : as long as the ionized state of this single residue is not changed (pH less than pK of the guanidyl group) the tertiary structure of the biologically active CBG is maintained in alkaline pH ranges.     

Inactivation of D-(-)-beta-hydroxybutyrate dehydrogenase by modifiers of carboxyl and histidyl groups

Data presented in this paper suggest that D-(-)-beta-hydroxybutyrate dehydrogenase (BDH) purified from bovine heart mitochondria contains an essential carboxyl group and an essential histidyl residue at or near the active site. Lactate and malate dehydrogenases, which catalyze reactions analogous to that catalyzed by BDH, also contain an aspartyl and a histidyl residue at the active site [Birktoft, J.J., & Banaszak, L.J. (1983) J. Biol. Chem. 258, 472-482]. In addition, all three enzymes contain an essential arginyl residue, apparently concerned with electrostatic interaction with their respective carboxylic acid substrates, and promote ternary adduct formation involving the enzyme, NAD, and sulfite.     

The amino acid sequence of ribonuclease U2 from Ustilago sphaerogena.

1. RNAase (ribonuclease) U2, a purine-specific RNAase, was reduced, aminoethylated and hydrolysed with trypsin, chymotrypsin and thermolysin. On the basis of the analyses of the resulting peptides, the complete amino acid sequence of RNAase U2 was determined, 2. When the sequence was compared with the amino acid sequence of RNAase T1 (EC 3.1.4.8), the following regions were found to be similar in the two enzymes; Tyr-Pro-His-Gln-Tyr (38-42) in RNAase U2 and Tyr-Pro-His-Lys-Tyr (38-42) in RNAase T1, Glu-Phe-Pro-Leu-Val (61-65) in RNAase U2 and Glu-Trp-Pro-Ile-Leu (58-62) in RNAase T1, Asp-Arg-Val-Ile-Tyr-Gln (83-88) in RNAase U2 and Asp-Arg-Val-Phe-Asn (76-81) in RNAase T1 and Val-Thr-His-Thr-Gly-Ala (98-103) in RNAase U2 and Ile-Thr-His-Thr-Gly-Ala (90-95) in RNAase T1. All of the amino acid residues, histidine-40, glutamate-58, arginine-77 and histidine-92, which were found to play a crucial role in the biological activity of RNAase T1, were included in the regions cited here. 3. Detailed evidence for the amino acid sequence of the sequence of the proteins has been deposited as Supplementary Publication SUP 50041 (33 PAGES) AT THE British Library (Lending Division)(formerly the National Lending Library for Science and Technology), Boston Spa, Yorks. LS23 7BQ, U.K., from whom copies can be obtained on the terms indicated in Biochem. J. (1975), 145, 5.     

Effects of cobalt-substitution of the active zinc ion in thermolysin on its activity and active-site microenvironment.

Thermolysin is remarkably activated in the presence of high concentrations (1-5 M) of neutral salts [Inouye, K. (1992) J. Biochem. 112, 335-340]. The activity is enhanced 13-15 times with 4 M NaCl at pH 7.0 and 25 degrees C. Substitution of the active site zinc with other transition metals alters the activity of thermolysin [Holmquist, B. and Vallee, B.L. (1974) J. Biol. Chem. 249, 4601-4607]. Cobalt is the most effective among the transition metals and doubles the activity toward N-[3-(2-furyl)acryloyl]-glycyl-L-leucine amide. In this study, the effect of NaCl on the activity of cobalt-substituted thermolysin was examined. Cobalt-substituted thermolysin, with 2.8-fold increased activity compared with the native enzyme, is further activated by the addition of NaCl in an exponential fashion, and the activity is enhanced 13-15 times at 4 M NaCl. The effects of cobalt-substitution and the addition of salt are independent of each other. The activity of cobalt-substituted thermolysin, expressed as k(cat)/K(m), is pH-dependent and controlled by at least two ionizing residues with pK(a) values of 6.0 and 7.8, the acidic pK(a) being slightly higher compared to 5.6 of the native enzyme. These pK(a) values remain constant in the presence of 4 M NaCl, indicating that the electrostatic environment of cobalt-substituted thermolysin is more stable than that of the native enzyme, the acidic pK(a) of which shifts remarkably from 5.6 to 6.7 at 4 M NaCl. Zincov, a competitive inhibitor, binds more tightly to the cobalt-substituted than to native thermolysin at pH 4.9-9.0, probably because of its preference for cobalt in the fivefold coordination. The cobalt substitution has been shown to be a favorable tool with which to explore the active-site microenvironment of thermolysin.     

Inactivation of tobacco ribulosebisphosphate carboxylase by 2,3-butanedione.

Treatment of crystalline tobacco ribulosebisphosphate carboxylase (EC 4.1.1.39) with the arginine-selective α-dicarbonyl, 2,3-butanedione, results in a time- and concentration-dependent loss of activity. Inactivation is markedly enhanced by borate buffer and alkaline pH and is partially reversed upon removal of excess reagent and borate by gel filtration. Of the various ligands examined, only the phosphorylated substrate, ribulosebisphosphate, protects against inactivation. These results suggest an essential role for arginyl residues in the enzymic mechanism of ribulosebisphosphate carboxylase, probably as binding sites for the negatively charged phosphate groups of the non-gaseous substrate.