N-terminal amino acid sequences of acid proteases: acid proteases from Penicillium roqueforti and Rhizopus chinensis and alignment with penicillopepsin and mammalian proteases.

The amino-terminal sequence (33 residues) of the acid protease from Penicillium roqueforti has been determined with an automated sequencer. The amino-terminal sequence of Rhizopus pepsin (published by Sepulveda, P., Jackson, K. W. & Tang, J. (1975) Biochem. Biophys. Res. Commun. 63, 1106-1112) has been extended from 27 residues to 39 residues. Also, it was found that two forms of Rhizopus pepsin differ in position 15, where Rhizopus pepsin I has an isoleucine and Rhizopus pepsin II a valine residue. The new sequences have been aligned with the amino-terminal sequences of penicillopepsin (EC 3.4.23.7), pig pepsin (EC 3.4.23.1), calf chymosin (EC 3.4.23.4), human pepsin (EC 3.4.23.2), human gastricsin (EC 3.4.23.3), and cow pepsin (EC 3.4.23.1). Residues 31-35 (numbering based on pig pepsin, Tang, J., Sepulveda, P., Marciniszyn, Jr., J., Chen, K.S.C., Huang, W.-Y. , Tao, N., Liu, D. & Lanier, P. (1973) Proc. Natl. Acad. Sci. U.S.A. 70, 3437-3739) are identical in all enzymes. This section contains one of the two aspartic acids (Asp-32) implicated in the active site. The similarity of the sequences provides strong evidence for the homology of these acid proteases.     

Primary structure, physicochemical properties, and chemical modification of NAD(+)-dependent D-lactate dehydrogenase. Evidence for the presence of Arg-235, His-303, Tyr-101, and Trp-19 at or near the active site.

The NAD(+)-dependent D-lactate dehydrogenase was purified to apparent homogeneity from Lactobacillus bulgaricus and its complete amino acid sequence determined. Two gaps in the polypeptide chain (10 residues) were filled by the deduced amino acid sequence of the polymerase chain reaction amplified D-lactate dehydrogenase gene sequence. The enzyme is a dimer of identical subunits (specific activity 2800 +/- 100 units/min at 25 degrees C). Each subunit contains 332 amino acid residues; the calculated subunit M(r) being 36,831. Isoelectric focusing showed at least four protein bands between pH 4.0 and 4.7; the subunit M(r) of each subform is 36,000. The pH dependence of the kinetic parameters, Km, Vm, and kcat/Km, suggested an enzymic residue with a pKa value of about 7 to be involved in substrate binding as well as in the catalytic mechanism. Treatment of the enzyme with group-specific reagents 2,3-butanedione, diethylpyrocarbonate, tetranitromethane, or N-bromosuccinimide resulted in complete loss of enzyme activity. In each case, inactivation followed pseudo first-order kinetics. Inclusion of pyruvate and/or NADH reduced the inactivation rates manyfold, indicating the presence of arginine, histidine, tyrosine, and tryptophan residues at or near the active site. Spectral properties of chemically modified enzymes and analysis of kinetics of inactivation showed that the loss of enzyme activity was due to modification of a single arginine, histidine, tryptophan, or tyrosine residue. Peptide mapping in conjunction with peptide purification and amino acid sequence determination showed that Arg-235, His-303, Tyr-101, and Trp-19 were the sites of chemical modification. Arg-235 and His-303 are involved in the binding of 2-oxo acid substrate whereas other residues are involved in binding of the cofactor.     

Identification of essential amino acid residues of an alpha-amylase inhibitor from Phaseolus vulgaris white kidney beans.

Kidney bean (Phaseolus vulgaris) alpha-amylase inhibitors, which are bivalent inhibitors with the subunit stoichiometry of (alphabeta)(2) complex, have been inferred to contain unique arginine, tryptophan, and tyrosine residues essential for the inhibitory activity. To test the validity of this inference, an attempt was made to identify the essential amino acid residues of a white kidney bean (P. vulgaris) alpha-amylase inhibitor (PHA-I) by using the chemical modification technique combined with amino acid sequencing and mass spectrometry. Exhaustive modification of the arginine residues by phenylglyoxal did not lead to a marked loss of activity, suggesting that no arginine residue is directly associated with the inhibitory activity. N-Bromosuccinimide treatment of PHA-I in the presence or absence of a substrate alpha-amylase revealed the involvement of two tryptophan residues in alpha-amylase inhibition, and they were identified as Trp188 of the beta-subunit by amino acid sequencing and mass spectrometry of lysylendopeptidase peptides. Further, two tyrosine residues were preferentially modified either by N-acetylimidazole or by tetranitromethane, resulting in a concomitant loss of most of the PHA-I activity. Amino acid sequencing of the lysylendopeptidase peptides from a tetranitromethane-modified PHA-I identified Tyr186 of the beta-subunit as an essential residue.     

Penicillopepsin-JT2, a recombinant enzyme from Penicillium janthinellum and the contribution of a hydrogen bond in subsite S3 to k(cat)

The nucleotide sequence of the gene (pepA) of a zymogen of an aspartic proteinase from Penicillium janthinellum with a 71% identity in the deduced amino acid sequence to penicillopepsin (which we propose to call penicillopepsin-JT1) has been determined. The gene consists of 60 codons for a putative leader sequence of 20 amino acid residues, a sequence of about 150 nucleotides that probably codes for an activation peptide and a sequence with two introns that codes for the active aspartic proteinase. This gene, inserted into the expression vector pGPT-pyrG1, was expressed in an aspartic proteinase-free strain of Aspergillus niger var. awamori in high yield as a glycosylated form of the active enzyme that we call penicillopepsin-JT2. After removal of the carbohydrate component with endoglycosidase H, its relative molecular mass is between 33,700 and 34,000. Its kinetic properties, especially the rate-enhancing effects of the presence of alanine residues in positions P3 and P2' of substrates, are similar to those of penicillopepsin-JT1, endothiapepsin, rhizopuspepsin, and pig pepsin. Earlier findings suggested that this rate-enhancing effect was due to a hydrogen bond between the -NH- of P3 and the hydrogen bond accepting oxygen of the side chain of the fourth amino acid residue C-terminal to Asp215. Thr219 of penicillopepsin-JT2 was mutated to Ser, Val, Gly, and Ala. Thr219Ser showed an increase in k(cat) when a P3 residue was present in the substrate, which was similar to that of the wild-type, whereas the mutants Thr219Val, Thr219Gly, and Thr219Ala showed no significant increase when a P3 residue was added. The results show that the putative hydrogen bond alone is responsible for the increase. We propose that by locking the -NH- of P3 to the enzyme, the scissile peptide bond between P1 and P1' becomes distorted toward a tetrahedral conformation and becomes more susceptible to nucleophilic attack by the catalytic apparatus without the need of a conformational change in the enzyme.     

Amino acid sequence of endothiapepsin. Complete primary structure of the aspartic protease from Endothia parasitica

The amino acid sequence of endothiapepsin, the aspartic protease from Endothia parasitica has been determined. The enzyme consists of 330 residues. The sequence determination was performed exclusively at the protein level. The homology of this fungal milk-clotting enzyme with aspartic proteases is demonstrated by alignment with pepsin, chymosin, gastricsin, renin, and cathepsin D from various vertebrates and proteinase A from Saccharomyces cerevisiae showing 25-30% identity. The identity with mucor rennin from Mucor pucillus was 21% and with penicillopepsin from Penicillium janthinellum 53%, the fungal enzymes thus representing the lowest as well as the highest degree of homology.     

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.     

Chemical modification of the bifunctional human serum pseudocholinesterase. Effect on the pseudocholinesterase and aryl acylamidase activities

The effect of chemical modification on the pseudocholinesterase and aryl acylamidase activities of purified human serum pseudocholinesterase was examined in the absence and presence of butyrylcholine iodide, the substrate of pseudocholinesterase. Modification by 2-hydroxy-5-nitrobenzyl bromide, N-bromosuccinimide, diethylpyrocarbonate and trinitrobenzenesulfonic acid caused a parallel inactivation of both pseudocholinesterase and aryl acylamidase activities that could be prevented by butyrylcholine iodide. With phenylglyoxal and 2,4-pentanedione as modifiers there was a selective activation of pseudocholinesterase alone with no effect on aryl acylamidase. This activation could be prevented by butyrylcholine iodide. N-Ethylmaleimide and p-hydroxy-mercuribenzoate when used for modification did not have any effect on the enzyme activities. The results suggested essential tryptophan, lysine and histidine residues at a common catalytic site for pseudocholinesterase and aryl acylamidase and an arginine residue (or residues) exclusively for pseudocholinesterase. The use of N-acetylimidazole, tetranitromethane and acetic anhydride as modifiers indicated a biphasic change in both pseudocholinesterase and aryl acylamidase activities. At low concentrations of the modifiers a stimulation in activities and at high concentrations an inactivation was observed. Butyrylcholine iodide or propionylcholine chloride selectively protected the inactivation phase without affecting the activation phase. Protection by the substrates at the inactivation phase resulted in not only a reversal of the enzyme inactivation but also an activation. Spectral studies and hydroxylamine treatment showed that tyrosine residues were modified during the activation phase. The results suggested that the modified tyrosine residues responsible for the activation were not involved in the active site of pseudocholinesterase or aryl acylamidase and that they were more amenable for modification in comparison to the residues responsible for inactivation. Two reversible inhibitors of pseudocholinesterase, namely ethopropazine and imipramine, were used as protectors during modification. Unlike the substrate butyrylcholine iodide, these inhibitors could not protect against the inactivation resulting from modification by 2-hydroxy-5-nitrobenzyl bromide, N-bromosuccinimide and trinitrobenzenesulfonic acid. But they could protect against the activation of pseudocholinesterase and aryl acylamidase by low concentrations of N-acetylimidazole and acetic anhydride thereby suggesting that the binding site of these inhibitors involves the non-active-site tyrosine residues.     

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.     

Comparison of pepsins isolated from porcine, bovine and Penicillium jathiuellum

1. The reactivities of pepsins, isolated from three different sources (porcine, bovine, and Penicillium jathiuelum), toward ester and peptide substrates were compared. 2. Porcine pepsin showed the highest activity followed by penicillopepsin with bovine pepsin being the least active. 3. The esterase activity of penicillopepsin was greater than that of porcine pepsin with bovine pepsin again showing the least activity. 4. The CD spectra indicate that porcine and bovine pepsin have similar conformations, even though bovine pepsin shows less ellipticity at 220 nm. 5. Penicillopepsin showed a completely opposite sign in the near-u.v. region of the CD spectrum. 6. The far-u.v. region of the CD spectrum of penicillopepsin strongly suggests a beta-sheet structure. 7. Previously reported X-ray crystallographic data suggest that porcine pepsin has a compact three-dimensional structure, while the structures of bovine and penicillopepsins are partially unfolded.     

Chemical modification of dipeptidyl peptidase iv: involvement of an essential tryptophan residue at the substrate binding site

Inactivation of pig kidney dipeptidyl peptidase IV (EC 3.4.14.5) by photosensitization in the presence of methylene blue at pH 7.5 was observed to have pseudo-first-order kinetics. During the process, until over 95% inactivation was achieved, the histidine and tryptophan residues were decreased from 14.0 to 2.7 and 12.6 to 7.1, respectively, per 94,000-Da subunit, without any detectable changes in other photosensitive amino acids. Modification of four histidine residues per subunit using diethylpyrocarbonate resulted in only 30% inactivation of the enzyme, while N-bromosuccinimide almost completely inactivated the enzyme with the modification of only one tryptophan residue per subunit, as determined by absorption spectrophotometry at 280 nm. The protective action of the substrate and inhibitors such as Ala-Pro-Ala and Pro-Pro against the modification of tryptophan residues with N-bromosuccinimide was observed both fluorometrically and by measurement of activity. On the basis of these results it is suggested that one of the tryptophan residues in the enzyme subunit is essential for the functioning of the substrate binding site of pig kidney dipeptidyl peptidase IV.     

Further studies on the reactions of phenylglyoxal and related reagents with proteins.

1. The reactivities of phenylglyoxal (PGO), glyoxal (GO), and/or methylglyoxal (MGO) with several proteins, including ribonuclease A [EC 3.1.4.22] and its derivatives, alpha-chymotrypsin [EC 3.4.21.1], trypsin [EC 3.4.21.4], lysozyme [EC 3.2.1.17], pepsin [EC 3.4.23.1], rennin [EC 3.4.23.4], thermolysin, and insulin and its B chain, have been examined. From analyses of the reaction products, PGO was shown to be the most specific for arginine residues. GO and MGO also reacted rapidly with arginine residues, but they also reacted with lysine residues to a significant extent. A side reaction with N-terminal alpha-amino groups was observed with each of these reagents. 2. Two arginine residues out of four in ribonuclease A, two out of three in alpha-chymotrypsin, one out of two in trypsin, one out of two in pepsin, and one out of five in rennin appeared to react with PGO fairly rapidly, indicating a difference in the relative accessibility of these residues by the reagent. Extensive modification of the arginine residues by PGO occurred with RCM-derivatives of ribonuclease A and insulin B chain. The N-terminal isoleucine residues of alpha-chymotrypsin and trypsin appeared to be unreactive with PGO because of salt bridge formation with an aspartyl residue. The activity of alpha-chymotrypsin toward N-benzoyl-L-tyrosine ethyl ester and the lytic activity of lysozyme were lost rapidly on treatment with PGO, as in the case of ribonuclease A. Pepsin and rennin were only partially inactivated by reaction with PGO.     

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.     

Chemical modification studies of Rhizomucor miehei protease: evidence for the role of basic amino acids in enzyme catalysis.

The effect of chemical modification on milk clotting and proteolytic activities of aspartyl protease obtained from Rhizomucor miehei NRRL 3500 was examined in the absence and the presence of its specific inhibitor pepstatin A. The effect on the ratio of milk clotting activity (MC) to proteolytic activity (PA), an index of the quality of milk clotting proteases was also determined. Modification of the enzyme with trinitrobenzenesulfonic acid, diethylpyrocarbonate and phenylglyoxal produced an increase in the ratio of MC/PA, while modification with 2- hydroxy-5-nitrobenzyl bromide did not affect the ratio. Modification with N-acetylimidazole resulted in a marginal increase in MC/PA ratio. Protection using pepstatin A during modification with phenylglyoxal, N-acetylimidazole and 2-hydroxy-5-nitrobenzyl bromide, protected both MC and PA. In the case of modification by diethylpyrocarbonate, pepstatin A protected only MC. Pepstatin A did not protect both the activities on the modification of the enzyme by trinitrobenzene sulfonic acid. These observations indicate the presence of arginine, tyrosine and tryptophan at the catalytic site of the enzyme, for eliciting MC and PA of the enzyme. In general, modification of the positively charged residues increases the MC/PA ratio of the enzyme. In addition the modified lysine residues responsible for the inactivation of the enzyme were not involved in the active site of the enzyme. Thus the lysine residues might have a secondary role in enzyme catalysis. Further, histidine at the catalytic site was found to be exclusively involved in milk clotting activity. The enzyme with modified histidine residues were more susceptible to autocatalysis, indicating that histidine residues protect the enzyme against autolysis.     

A reactive arginine in adenylate kinase.

Adenylate kinase (ATP:AMP phosphotransferase, EV 2.7.4.3) from pig heart is inactivated by the specific arginyl reagent phenylglyoxal. During inactivation two molecules of phenyglyoxal are incorporated into the protein indicating the modification of one of the 11 arginine residues. The modification of other amino acids is ruled out. Chemical modification of this essential residue is prevented by high concentrations of the substrates AMP, ADP and MgATP2-. The protection of the substrates is explained by the formation of a ternary abortive enzyme-substrate complex ESS. The dissociation constants KD = [ES] - [S]/[ESS] are determined from the kinetic data of inactivation and protection.     

The primary structure of calf chymosin.

The complete amino acid sequence of calf chymosin (rennin) (EC 3.4.23.4) has been determined. The sequence consists of a single peptide chain of 323 amino acid residues. The primary structure of the precursor part of calf prochymosin was published previously (Pedersen, V.B., and Foltmann, B. (1975) Eur. J. Biochem. 55, 95-103), thus we are now able to account for the total 365 amino acid residues of calf prochymosin. Comparison of the sequence of calf prochymosin with that of pig pepsinogen A (EC 3.4.23.1) shows extensive homology. In the precursor part of the sequence, 15 residues are located at identical positions, as compared to 189 identical residues in the respective enzymes. Furthermore comparison to Penicillium janthinellum acid proteinase (penicillopepsin) (EC 3.4.23.7) shows that 76 residues are common to this enzyme and to the two gastric proteinases. These homologies in sequence further suggest that the folding of the peptide chain in chymosin is very similar to that of other acid proteinases.     

Effect of chemical modification on the cryoprecipitation of monoclonal human cryoglobulin M

The effect of the chemical modification of lysine, histidine, arginine, tyrosine, tryptophan residues and carboxylic groups on the cryoproperties of monoclonal human cryoglobulin M has been studied. The modification of 35-40 lysine residues and that of 42-45 arginine residues in the molecule of cryo-IgM has been shown to result in practically complete inhibition of the cryoprecipitation. The same effect is observed on the modification of 60 histidine residues per molecule and on modification of 50 or 51 carboxylic groups. At the same time the modification of practically all the reagent-exposed tryptophan (10 residues per molecule) and tyrosine residues (55 residues per molecule) does not lead to any noticeable decrease in the cryoprecipitation. The conformations of the modified and native proteins are identical according to the circular dichroism data.     

Irreversible inactivation of human erythrocyte pyruvate kinase by 2,3-butanedione

Human erythrocyte pyruvate kinase was found to be irreversibly inactivated by butanedione in the dark. The second-order rate constants for inactivation at pH 8.0 and 25 degrees C were 2.14 and 2.74 M-1 min-1 in the absence and presence of 50 mM borate, respectively. The pH profile of the inactivation indicated the involvement of a residue with an apparent pK alpha of 8.1-8.3. ADP and phosphoenolpyruvate acted as partial inhibitors of the inactivation process. Certain details of the inactivation, spectral studies, and fluorometric determinations gave evidence for arginine as the only target residue. A total of 23 +/- 3 residues per subunit were modified within the period required for inactivation. In the same period the presence of 4 mM ADP reduced the extent of inactivation by 70% and the number of modified residues to 18 +/- 4. The number of the arginine residues protected by ADP from butanedione modification was 5.0 +/- 1.3 per subunit.     

Proton-nuclear-magnetic-resonance study of the conformation of neurotoxin II from Middle-Asian cobra (Naja naja oxiana) venom.

A proton nuclear magnetic resonance (NMR) study at 100 and 300 MHz of neurotoxin II from the venom of Middle-Asian cobra Naja naja oxiana has been performed in 2H2O and H2O solutions. By means of chemical modification and double resonance all the aromatic residue resonances have been assigned. From the NMR titration curves, pK values of histidine 4 and histidine 31 residues have been determined. For one of the two neighbouring tryptophan residues pH dependence (in the 2-8-pH range) of the chemical shifts of indole protons has been revealed. According to the different sensitivity of the linewidth of indole NH resonances to pH in H2O solution, the accessibility of each of the tryptophan residues has been estimated. Temperature dependence has been observed for the linewidth of the aromatic resonances of the tyrosine 24 residue. Deuterium exchange rates have been measured for amide protons as well as for C(2)H histidine resonances. The NMR data obtained have allowed the conclusions to be made that the two histidine residues and one of the tryptophan residues should be localized on the surface of the protein globule, that arginine residues should be present in the environment of histidine 4, that histidine 31 and the buried tryptophan are possibly localized in close spatial proximity and that the side chain of tyrosine 24 is buried within the protein globule.     

1,2-Cyclohexanedione modification of arginine residues in egg-white riboflavin-binding protein

1. Reaction of 1,2-cyclohexanedione with arginine residues of egg white riboflavin-binding protein results in a loss of the binding activity. 2. In borate buffer pH 8.0, with 0.15 M cyclohexanedione, the inactivation proceeds with a pseudo-first-order rate constant 0.084 hr.-1. 3. At least 65% of lost riboflavin binding capacity can be recovered on 12 hr incubation in 0.5 M hydroxylamine pH 7.0. 4. All 5 arginine residues are modified, 2-3 of them seem to react much easier than others. 5. The correlation between modification of arginines and protein inactivation, as analyzed by kinetic and statistical methods, suggests that one of low-reactivity residues is "essential" for riboflavin binding. 6. In the holoprotein, one arginine residue is almost completely protected from 1,2-cyclohexanedione modification. 7. Riboflavin does not dissociate from holoprotein, even on prolongated incubation with the reagent. 8. The protected arginine residue seems to be located in the riboflavin binding pocket of protein macromolecule.     

Acetyl-coenzyme A:alpha-glucosaminide N-acetyltransferase. Evidence for an active site histidine residue

The lysosomal membrane enzyme acetyl-CoA:alpha-glucosaminide N-acetyltransferase catalyzes the transfer of the acetyl group from acetyl-CoA to terminal alpha-linked glucosamine residues of heparan sulfate. The reaction appears to be a transmembrane process: the enzyme is acetylated on the outside of the lysosome, and the acetyl group is transferred across the membrane to the inside of the lysosome where it is used to acetylate glucosamine. To determine the reactive site residues involved in the acetylation reaction, lysosomal membranes were treated with various amino acid modification reagents and assayed for enzyme activity. Although four thiol modification reagents were examined, only one, p-chloromercuribenzoate inactivated the N-acetyltransferase. Thiol modification by p-chloromercuribenzoate did not appear to occur at the active site since inactivation was still observed in the presence of the substrate acetyl-CoA. N-Acetyltransferase could be inactivated by N-bromosuccinimide, even after pretreatment with reagents specific for tyrosine and tryptophan, suggesting that the modified residue is a histidine. Diethyl pyrocarbonate, another histidine modification reagent, could also inactivate the enzyme; this inactivation could be reversed by incubation with hydroxylamine. N-Bromosuccinimide and diethyl pyrocarbonate modifications appear to be at the active site of the enzyme since co-incubation with acetyl-CoA protects the N-acetyltransferase from inactivation. This protection is lost if glucosamine is also present. Pre-acetylated lysosomal membranes are also able to provide protection from N-bromosuccinimide inactivation, providing further evidence for a histidine moiety at the active site and for the existence of an acetyl-enzyme intermediate.