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.     

The chemical modification of papain with 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide.

The reaction of the water-soluble carbodimide, 1-ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC), with active papain in the presence of the nucleophile ethyl glycinate results in an irreversible inactivation of the enzyme. This inactivation is accompanied by the derivatization of the catalytically essential thiol group of the enzyme (Cys-25) and by the modification of 6 out of 14 of papain's carboxyl groups and up to 9 out of 19 of the enyzme's tyrosyl residues. No apparent irreversible modification of histidine residues is observed. Mercuripapain is also irreversibly inactivated by EDC/ethyl glycinate, again with the concomitant modification of 6 carboxyl groups, up to 10 tyrosyl residues, and no histidine residues; but in this case there is no thiol derivatization. Treatment of either modified native papain or modified mercuripapain with hydroxylamine results in the complete regeneration of free tyrosyl residues but does not restore any activity. The competitive inhibitor benzamidoacetonitrile substantially protects native papain against inactivation and against the derivatization of the essential thiol group as well as 2 of the 6 otherwise accessible carboxyl groups. The inhibitor has no effect upon tyrosyl modification. These findings are discussed in the context of a possible catalytic role for a carboxyl group in the active site of papain.     

Chemical modification of 3 alpha,20 beta-hydroxysteroid dehydrogenase with diethyl pyrocarbonate. Evidence for an essential, highly reactive, lysyl residue

Diethyl pyrocarbonate inactivated the tetrameric 3 alpha,20 beta-hydroxysteroid dehydrogenase with second-order rate constants of 1.63 M-1 s-1 at pH 6 and 25 degrees C or 190 M-1 s-1 at pH 9.4 and 25 degrees C. The activity was slowly and partially restored by incubation with hydroxylamine (81% reactivation after 28 h with 0.1 M hydroxylamine, pH 9, 25 degrees C). NADH protected the enzyme against inactivation with a Kd (10 microM) very close to the Km (7 microM) for the coenzyme. The ultraviolet difference spectrum of inactivated vs. native enzyme indicated that a single histidyl residue per enzyme subunit was modified by diethyl pyrocarbonate, with a second-order rate constant of 1.8 M-1 s-1 at pH 6 and 25 degrees C. The histidyl residue, however, was not essential for activity because in the presence of NADH it was modified without enzyme inactivation and modification of inactivated enzyme was rapidly reversed by hydroxylamine without concomitant reactivation. Progesterone, in the presence of NAD+, protected the histidyl residue against modification, and this suggests that the residue is located in or near the steroid binding site of the enzyme. Diethyl pyrocarbonate also modified, with unusually high reaction rate, one lysyl residue per enzyme subunit, as demonstrated by dinitrophenylation experiments carried out on the treated enzyme. The correlation between inactivation and modification of lysyl residues at different pHs and the protection by NADH against both inactivation and modification of lysyl residues indicate that this residue is essential for activity and is located in or near the NADH binding site of the enzyme.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

Spatial proximity of a tyrosyl and a lysyl residue in the active site region of yeast 3-phosphoglycerate kinase.

The effect of 7-chloro-4-nitrobenzofurazan on yeast 3-phosphoglycerate kinase causes a modification of one tyrosyl residue concomitantly with a total loss of activity of the enzyme. The modification is not accompanied by any significant conformational change. A total protection against inactivation is observed with the substrates : furthermore, AMP, tripolyphosphate and pyrophosphate afford an effective protection. At pH 9, a shift in the absorbance spectrum of the tyrosine O-nitrobenzofurazan derivative of 3-phosphoglycerate kinase is observed. It can be related to the transfer of the reagent from tyrosine to lysine. The N-nitrobenzofurazan derivative is also completely inactive. It is concluded that a lysine residue is located close to the essential tyrosyl residue.     

Effects of activators on chemically modified yeast hexokinase.

Enzymic studies performed with chemically modified yeast hexokinase (ATP : D-hexose-6-phosphotransferase) confirm previous results indicating that the sulfhydryl, imidazol and most of the reactive amino groups do not seem to be directly implicated in the enzyme active site. On the other hand the modification of these functional groups of the enzyme does not affect the transition between the acidic inactive form to an active enzyme form after deprotonation. The chemically modified forms of hexokinase and the native enzyme are affected in the same way by activators (citrate, D-malate, 3-phosphoglycerate and Pi) when the activity was measured at pH 6.6. Moreover the loss of enzyme activity observed in the course of the chemical modifications is accompanied by an increase of the activation effect. This increase must be related to some reorganization of the enzyme active site in presence of the effectors, since the same effect was observed when hexokinase was denatured with 3M urea at pH 7.5. However no increase in the activation effect was observed when the denaturation was carried out at pH 6.5 At this pH the loss in activity and the change of optical absorption at 286 nm were much slower than at pH 7.5, which indicates a great difference in the protein structure between these pHs.     

Chemical modification of Pseudomonas ochraceae 4-hydroxy-4-methyl-2-oxoglutarate aldolase by diethyl pyrocarbonate.

Diethyl pyrocarbonate inactivates Pseudomonas ochraceae 4-hydroxy-4-methyl-2-oxoglutarate aldolase [4-hydroxy-4-methyl-2-oxoglutarate pyruvate-lyase: EC 4.1.3.17] by a simple bimolecular reaction. The inactivation is not reversed by hydroxylamine. The pH curve of inactivation indicates the involvement of a residue with a pK of 8.8. Several lines of evidence show that the inactivation is due to the modification of epsilon-amino groups of lysyl residues. Although histidyl residue is also modified, this is not directly correlated to the inactivation. No cysteinyl, tyrosyl, or tryptophyl residue or alpha-amino group is significantly modified. The modification of three lysyl residues per enzyme subunit results in the complete loss of aldolase activity toward various 4-hydroxy-2-oxo acid substrates, whereas oxaloacetate beta-decarboxylase activity associated with the enzyme is not inhibited by this modification. Statistical analysis suggests that only one of the three lysyl residues is essential for activity. l-4-Carboxy-4-hydroxy-2-oxoadipate, a physiological substrate for the enzyme, strongly protects the enzyme against inactivation. Pi as an activator of the enzyme shows no specific protection. The molecular weight of the enzyme, Km for substrate or Mg2+, and activation constant for Pi are virtually unaltered after modification. These results suggest that the modification occurs at or near the active site and that the essential lysyl residue is involved in interaction with the hydroxyl group but not with the oxal group of the substrate.     

Affinity labelling of rat-muscle hexokinase type II by a glucose-derived alkylating agent.

The glucose-derived alkylating agent N-bromoacetylglucosamine (GlcNBrAc) is shown to cause a time-dependent irreversible inactivation of rat muscle hexokinase type II. The kinetics of inactivation are in accord with the reversible formation of an enzyme-inhibitor complex prior to modification, indicating that the reagent is active-site-directed. A Ki of 0.57 mM obtained for this reversible complexing is in agreement with a Ki of 0.65 mM obtained for the inhibition caused by N-propionylglucosamine, an isosteric analogue of GlcNBrAc and a competitive inhibitor with respect to glucose. Glucose itself protects competitively against inactivation. A KG of 0.26 mM obtained for the formation of enzyme-glucose complex from these studies is in agreement with the kinetically-determined Km of 0.2 mM. The substrate-unrelated but chemically similar alkylating agents bromoacetic acid and N-bromoacetylgalactosamine inactivate the enzyme at 20% of the rate caused by GlcNBrAc. The inactivation rate increases rapidly over the pH range 7--9. Analysis of this pH dependence shows that a single residue of pKa 8.9 is reacting with GlcNBrAc with a kmax (pH corrected, pseudo-first-order rate constant) of 1.5 x 10(-3) S-1. These values are typical of the reaction of model thiols with alkylating agents and suggests the reacting residue is probably a cysteine. Use of radioactively labelled GlcNBrAc indicates that uptake of 1 mol of reagent per mol protein causes complete activity loss. Finally the behaviour of this enzyme with active-site-directed alkylating agents is compared with published results of similar experiments carried out with yeast hexokinase and bovine brain hexokinase type I.     

Rat brain hexokinase: location of the substrate hexose binding site in a structural domain at the C-terminus of the enzyme

A glucose analog, N-(bromoacetyl)-D-glucosamine (GlcNBrAc), previously used to label the glucose binding sites of rat muscle Type II and bovine brain Type I hexokinases, also inactivates rat brain hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) with pseudo-first-order kinetics. Inactivation occurs predominantly via a "specific" pathway involving formation of a complex between hexokinase and GlcNBrAc, but significant nonspecific (i.e., without prior complex formation) inactivation also occurs, and equations to describe this behavior are derived. Inactivation is dependent on deprotonation of a residue with an alkaline pKa, consistent with the modified residue being a sulfhydryl group as reported to be the case with the hexokinase of bovine brain. The affinity label modifies three residues (per molecule of enzyme) at indistinguishable rates, but only one of these residues appears to be critical for activity. Amino acid analysis of the modified enzyme indicates derivatization of three cysteine residues; there was no indication of modification of other residues potentially reactive with haloacetyl derivatives. Kinetic analysis and effects of protective ligands were consistent with location of the critical sulfhydryl at the glucose binding site. Peptide mapping techniques permitted localization of the critical residue, and thus the glucose binding site, in a 40-kDa domain at the C-terminus of the enzyme. This is the same domain recently shown to include the ATP binding site. Thus, catalytic function is assigned to the C-terminal domain of rat brain hexokinase.     

Vitamin K2 (menaquinone) biosynthesis in Escherichia coli: evidence for the presence of an essential histidine residue in o-succinylbenzoyl coenzyme A synthetase.

o-Succinylbenzoyl coenzyme A (OSB-CoA) synthetase, when treated with diethylpyrocarbonate (DEP), showed a time-dependent loss of enzyme activity. The inactivation follows pseudo-first-order kinetics with a second-order rate constant of 9.2 x 10(-4) +/- 1.4 x 10(-4) microM(-1) min(-1). The difference spectrum of the modified enzyme versus the native enzyme showed an increase in A242 that is characteristic of N-carbethoxyhistidine and was reversed by treatment with hydroxylamine. Inactivation due to nonspecific secondary structural changes in the protein and modification of tyrosine, lysine, or cysteine residues was ruled out. Kinetics of enzyme inactivation and the stoichiometry of histidine modification indicate that of the eight histidine residues modified per subunit of the enzyme, a single residue is responsible for the enzyme activity. A plot of the log reciprocal of the half-time of inactivation against the log DEP concentration further suggests that one histidine residue is involved in the catalysis. Further, the enzyme was partially protected from inactivation by either o-succinylbenzoic acid (OSB), ATP, or ATP plus Mg2+ while inactivation was completely prevented by the presence of the combination of OSB, ATP, and Mg2+. Thus, it appears that a histidine residue located at or near the active site of the enzyme is essential for activity. When His341 present in the previously identified ATP binding motif was mutated to Ala, the enzyme lost 65% of its activity and the Km for ATP increased 5.4-fold. Thus, His341 of OSB-CoA synthetase plays an important role in catalysis since it is probably involved in the binding of ATP to the enzyme.     

Inactivation of Acinetobacter calcoaceticus acetate kinase by diethylpyrocarbonate

Acetate kinase purified from Acinetobacter calcoaceticus was inhibited by diethylpyrocarbonate with a second-order rate constant of 620 M-1.min-1 at pH 7.4 at 30 degrees C and showed a concomitant increase in absorbance at 240 nm due to the formation of N-carbethoxyhistidyl derivative. Activity could be restored by hydroxylamine and the pH curve of inactivation indicates the involvement of a residue with a pKa of 6.64. Complete inactivation of acetate kinase required the modification of seven residues per molecule of enzyme. Statistical analysis showed that among the seven modifiable residues, only one is essential for activity. 5,5'-dithiobis(2-nitrobenzoic acid), p-chloromercuryphenylsulfonate, N-ethylmaleimide and phenylglyoxal did not affect the enzyme activity. These results suggest that the inactivation is due to the modification of one histidine residue. The substrates, acetate and ATP, protected the enzyme against inactivation, indicating that the modified histidine residue is located at or near the active site.     

An essential arginyl residue in yeast hexokinase.

The inactivation of yeast hexokinase A (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) by phenylglyoxal obeys pseudo first-order kinetics. Formation of a reversible enzyme-reagent complex prior to modification is suggested by the observed saturation kinetics. Loss of activity correlates with the incorporation of 1 mol of [14C]phenylglyoxal per mol 50 000 dalton subunit. No significant conformational change occurs concomitantly. Inactivation is attributable to modification of an arginyl residue. The pattern of protection by substrates and analogs favors an interaction of this essential residue with the terminal phosphoryl group of ATP or glucose 6-phosphate.     

Tyrosine alpha 244 is derivatized when the bovine heart mitochondrial F1-ATPase is inactivated with 5'-p-fluorosulfonylbenzoylethenoadenosine

The bovine heart mitochondrial F1-ATPase (MF1) is inactivated by 5'-p-fluorosulfonylbenzoylethenoadenosine (FSB epsilon A) with pseudo-first order kinetics. The dependence of the rate of inactivation on the concentration of FSB epsilon A revealed an apparent Kd of 0.25 mM. ATP and ADP, and to a lesser extent, ITP and IDP provide partial protection against inactivation by the reagent. Isolation and sequence analysis of major radioactive fragments in peptic or cyanogen bromide digests of MF1 inactivated with [3H]FSB epsilon A indicate that modification of Tyr-alpha 244 is associated with the loss of activity observed. Assessment of the amount of Tyr-alpha 244 derivatized with [3H]FSB epsilon A at specific points during inactivation of the ATPase indicates that maximal inactivation is achieved on modification of this residue in slightly greater than one copy of the alpha subunit. The following characteristics of inactivation of MF1 by FSB epsilon A have also been determined. (a) The rate of inactivation of ITPase activity by FSB epsilon A is 1.4 times greater than that observed for inactivation of ATPase activity under identical conditions. (b) After maximally inactivating the capacity of MF1 to hydrolyze saturating ATP with FSB epsilon A, the modified enzyme retained its capacity to hydrolyze substoichiometric ATP. (c) Inactivation of the ATPase by FSB epsilon A is accelerated by Pi. In each of the above characteristics, MF1 modified by FSB epsilon A resembles enzyme inactivated with 5'-p-fluorosulfonylbenzoyladenosine (FSBA) more than it does enzyme inactivated with 5'-p-fluorosulfonylbenzoylinosine (FSBI). Furthermore, prior inactivation of MF1 with FSBA completely prevents labeling of Tyr-alpha 244 with [3H]FSB epsilon A, whereas prior inactivation of the enzyme with FSBI does not. Since a single catalytic site is modified when FSBI inactivates MF1 whereas three noncatalytic sites are modified when it is maximally inactivated with FSBA, it is concluded that FSB epsilon A also modifies noncatalytic sites.     

Inactivation of yeast hexokinase by o-phthalaldehyde: evidence for the presence of a cysteine and a lysine at or near the active site

Yeast hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1), a homodimer, was rapidly and irreversibly inactivated by o-phthalaldehyde at 25 degrees C (pH 7.3). The reaction followed pseudo-first-order kinetics over a wide range of the inhibitor concentration. The second-order-rate constant for the inactivation of hexokinase was estimated to be 45 M-1.s-1. Hexokinase was protected more by sugar substrates than by nucleoside triphosphates during inactivation by o-phthalaldehyde. Absorption spectrum (lambda max 338 nm), and fluorescence excitation (lambda max 363 nm) and emission (lambda max 403 nm) spectra of the hexokinase-o-phthalaldehyde adduct were consistent with the formation of an isoindole derivative. These results also suggest that sulfhydryl and epsilon-amino functions of the cysteine and lysine residues, respectively, participating in the isoindole formation are about 3 A apart in the native enzyme. About 2 mol of the isoindole per mol of hexokinase dimer were formed following complete loss of the phosphotransferase activity. Chemical modification of hexokinase by iodoacetamide in the presence of mannose resulted in the modification of six sulfhydryl groups per mol of hexokinase with retention of the phosphotransferase activity. Subsequent reaction of the iodoacetamide modified hexokinase with o-phthalaldehyde resulted in complete loss of the phosphotransferase activity with concomitant modification of the remaining two sulfhydryl groups of hexokinase. Chemical modification of hexokinase by iodoacetamide in the absence of mannose resulted in complete inactivation of the enzyme. The iodoacetamide inactivated hexokinase failed to react with o-phthalaldehyde as evidenced by the absence of a fluorescence emission maximum characteristic of the isoindole derivative. The holoenzyme failed to react with [5'-(p-fluorosulfonyl)benzoyl]adenosine. The dissociated hexokinase could be inactivated by [5'-(p-fluorosulfonyl)benzoyl]adenosine; the degree of inactivation paralleled the extent of reaction between o-phthalaldehyde and the nucleotide-analog modified enzyme. Thus, it is concluded that two cysteines and lysines at or near the active site of the hexokinase were involved in reaction with o-phthalaldehyde following complete loss of the phosphotransferase activity. An important finding of this investigation is that the lysines, involved in isoindole formation, located at or near the active site are probably buried.(ABSTRACT TRUNCATED AT 400 WORDS)     

An essential arginine residue in the ATP-binding centre of (Na+ + K+)-ATPase.

1. Incubation of purified (Na+ + K+)-ATPase (ATP phosphohydrolase EC 3.6.1.3) from rabbit kidney outer medulla with butanedione in borate buffer leads to reversible inactivation of the (Na+ + K+)-ATPase activity. 2. The reaction shows second-outer kinetics, suggesting that modification of a single amino acid residue is involved in the inactivation of the enzyme. 3. The pH dependence of the reaction and the effect of borate ions strongly suggest that modification of an arginine residue is involved. 4. Replacement of Na+ by K+ in the butanedione medium decreases inactivation. 5. ATP, ADP and adenylyl imido diphosphate, particularly in the presence of trans-1,2-diaminocyclohexane-N,N,N',N'-tetraacetic acid to complex Mg2+, protect the enzyme very efficiently against inactivation by butanedione. 6. The (Na+ + Mg2+)-dependent phosphorylation capacity of the enzyme is inhibited in the same degree as the (Na+ + K+)-ATPase activity by butanedione. 7. The K+-stimulated p-nitrophenylphosphatase activity is much less inhibited than the (Na+ + K+)ATPase activity. 8. The ATP stimulation of the K+-stimulated p-nitrophenylphosphatase activity is inhibited by butanedione to the same extent as the (Na+ + K+)-ATPase activity. 9. Modification of sulfhydryl groups with 5,5'-dithiobis(2-nitrobenzoic acid) protects partially against the inactivating effect of butanedione. 10. The results suggest that an arginine residue is present in the nucleotide binding centre of the enzyme.     

Yeast hexokinase A. Succinylation and properties of the active subunit.

Yeast hexokinase A (ATP:D-hexose 6-phosphotransferase, EC2.7.1.1) dissociates into its subunits upon reaction with succinic anhydride. The chemically modified subunits could be isolated in a catalytically active form. The Km values found for ATP and for glucose were of the some order as those found for the native enzyme. Of the 37 amino groups present per enzyme subunit, 2-3 of these groups might be located in the proximity of the region of subunit interactions. The 50% loss of the initial activity, which follows the succinylation of these more reactive amino groups, does not seem to be due to the modification of a residue on the enzyme active site or to a change of the tertiary structure of the protein. This 50%loss of the enzyme activity may be related to the dissociation of the dimer into monomers. Both native enzyme and the succinylated subunits have the same H-dependent denaturation rate profiles in response to 2 M urea. Moreover, the apparent pK of the group involved in the transition from a more stable conformation of the protein in the acid range to a less stable one at alkaline pH seems to be similar to the pK of the group implicated in the transition between the protonated inactive form of the enzyme and an active deprotonated form. The succinylated subunit presents 'negative co-operativity' with respect to ATP at slightly acid pH; however, the burst-type slow transient in the reaction progress curve and the activation effect induced by physiological polyanions, effects observed for the native enzyme, were not detected in the standard experimental conditions with the succinylated subunit.     

Modification of uridine phosphorylase from Escherichia coli by diethyl pyrocarbonate. Evidence for a histidine residue in the active site of the enzyme.

Uridine phosphorylase from Escherichia coli is inactivated by diethyl pyrocarbonate at pH 7.1 and 10 degrees C with a second-order rate constant of 840 M-1.min-1. The rate of inactivation increases with pH, suggesting participation of an amino acid residue with pK 6.6. Hydroxylamine added to the inactivated enzyme restores the activity. Three histidine residues per enzyme subunit are modified by diethyl pyrocarbonate. Kinetic and statistical analyses of the residual enzymic activity, as well as the number of modified histidine residues, indicate that, among the three modifiable residues, only one is essential for enzyme activity. The reactivity of this histidine residue exceeded 10-fold the reactivity of the other two residues. Uridine, though at high concentration, protects the enzyme against inactivation and the very reactive histidine residue against modification. Thus it may be concluded that uridine phosphorylase contains only one histidine residue in each of its six subunits that is essential for enzyme activity.     

Identification of histidine residues at the active site of Megalobatrachus japonicus alkaline phosphatase by chemical modification

Alkaline phosphatase from Megalobatrachus japonicus was inactivated by diethyl pyrocarbonate (DEP). The inactivation followed pseudo-first-order kinetics with a second-order rate constant of 176 M(-1) x min(-1) at pH 6.2 and 25 degrees C. The loss of enzyme activity was accompanied with an increase in absorbance at 242 nm and the inactivated enzyme was re-activated by hydroxylamine, indicating the modification of histidine residues. This conclusion was also confirmed by the pH profiles of inactivation, which showed the involvement of a residue with pK(a) of 6.6. The presence of glycerol 3-phosphate, AMP and phosphate protected the enzyme against inactivation. The results revealed that the histidine residues modified by DEP were located at the active site. Spectrophotometric quantification of modified residues showed that modification of two histidine residues per active site led to complete inactivation, but kinetic stoichiometry indicated that one molecule of modifier reacted with one active site during inactivation, probably suggesting that two essential histidine residues per active site are necessary for complete activity whereas modification of a single histidine residue per active site is enough to result in inactivation.     

Studies on (K+ + H+)-ATPase. I. Essential arginine residue in its substrate binding center

1. A membrane vesicle fraction containing a high (K+ + H+)-ATPase activity was isolated from porcine gastric mucosa. The enzyme has a pH optimum of 7.0 and is stimulated by T1+, K+, Rb+ and NH4+ with KA values of 0.13, 2.7, 7.6 and 26 mM, respectively, at this pH. 2. Incubation of the isolated membrane fraction with butanedione leads to inactivation of the (K+ + H+)-ATPase activity. The pH-dependence of the (K+ + H+)-ATPase activity. The pH-dependence of the inactivation and the reversibility of the reaction, observed after removal of excess butanedione and borate, indicate that modification of arginine is involved. 3. The inactivation of (K+ + H+)-ATPase activity by butanedione is time-dependent and follows second-order kinetics. From the dependence of the inactivation rate on the reagent concentration it appears that a single arginine residue is involved in the inactivation of the (K+ + H+)-ATPase activity. 4. ATP, deoxy-ATP, ADP and adenylyl imidodiphosphate (AMPPNP), but not CTP, GTP and ITP which are poor substrates, protect the enzyme against butanedione inactivation, suggesting that the essential arginine residue is located in the ATP binding centre. 5. In the presence of Mg2+ the butanedione inactivation is increased, and the protection by ATP, deoxy-ATP and ADP (but not that by AMPPNP) is less pronounced. This suggests that Mg2+ induces a conformational change in the enzyme, exposing the arginine group and coinciding with phosphorylation and subsequent release of ADP from its binding site.     

Chemical modification of thiol groups of mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe. Involvement of alpha- and gamma-subunits in the enzyme activity

Mitochondrial F1-ATPase from the yeast Schizosaccharomyces pombe has been prepared under a stable form and in relatively high amounts by an improved purification procedure. Specific chemical modification of the enzyme by the thiol reagent N-ethylmaleimide (NEM) at pH 6.8 leads to complete inactivation characterized by complex kinetics and pH dependence, indicating that several thiols are related to the enzyme activity. A complete protection against NEM effect is afforded by low concentrations of nucleotides in the presence of Mg2+, with ADP and ATP being more efficient than GTP. A total binding of 5 mol of [14C]NEM/mol of F1-ATPase is obtained when the enzyme is 85% inactivated: 3 mol of the label are located on the alpha-subunits and 2 on the gamma-subunit. Two out of the 3 mol on the alpha-subunits bind very rapidly before any inactivation occurs, indicating that the two thiols modified are unrelated to the inactivation process. Complete protection by ATP against inactivation by NEM prevents the modification of three essential thiols out of the group of five thiols labeled in the absence of ATP: one is located on a alpha-subunit and two on the gamma-subunit. These two essential thiols of the gamma-subunit can be differentiated by modification with 6,6'-dithiodinicotinic acid (CPDS), another specific thiol reagent. A maximal binding of 4 mol of [14C]CPDS/mol of enzyme is obtained, concomitant to a 25% inhibition. Sequential modification of the enzyme by CPDS and [14C]NEM leads to the same final deep inactivation as that obtained with [14C]NEM alone. One out of the two thiols of the gamma-subunit is no longer accessible to [14C]NEM after CPDS treatment. When incubated at pH 6.8 with [3H]ATP in the presence of Mg2+, F1-ATPase is able to bind 3, largely exchangeable, mol of nucleotide/mol of enzyme. Modification of the three essential thiols by NEM dramatically decreases the binding of 3H-nucleotide down to about 1 mol/mol of enzyme. Partial modification modifies the cooperative properties, the enzyme being no longer sensitive to anion activation.