Identification of an essential glutamic acid residue in the beta subunit of the adenosine triphosphatase from the thermophilic bacterium PS3

The TF1-ATPase from the thermophilic bacterium, PS3, is inactivated by dicyclohexylcarbodiimide (DCCD). This inactivation is stimulated by ADP and other specific nucleotides and is inhibited by Mg2+. When the inactivation is carried out with [14C]DCCD, about 2 g atoms of 14C are bound/mol of TF1 when the enzyme is nearly completely inactivated. The isolated subunits from TF1 inactivated with [14C]DCCD contain the following amounts of 14C/mol: alpha, 0.12 g atom; beta, 0.47 g atom; gamma, approximately 0.04 g atom; delta, none; and epsilon, 0.05 g atom. Fractionation of tryptic digests have shown that the 14C bound to the alpha subunit is nonspecifically associated with several peptides, and that the 14C bound to the beta subunit is associated with a single tryptic peptide with the amino acid sequence Ala-Gly-Val-Gly-Glu-Arg, where Glu represents the N-gamma-glutamyl derivative of dicyclohexyl[14C]urea.     

Identification of aspartate-184 as an essential residue in the catalytic subunit of cAMP-dependent protein kinase

The hydrophobic carbodiimide dicyclohexylcarbodiimide (DCCD) was previously shown to be an irreversible inhibitor of the catalytic subunit of cAMP-dependent protein kinase, and MgATP protected against inactivation [Toner-Webb, J., & Taylor, S. S. (1987) Biochemistry 26, 7371]. This inhibition by DCCD indicated that an essential carboxyl group was present at the active site of the enzyme even though identification of that carboxyl group was not possible. This presumably was because a nucleophile on the protein cross-linked to the electrophilic intermediate formed when the carbodiimide reacted with the carboxyl group. To circumvent this problem, the catalytic subunit first was treated with acetic anhydride to block accessible lysine residues, thus preventing intramolecular cross-linking. The DCCD reaction then was carried out in the presence of [14C]glycine ethyl ester in order to trap any electrophilic intermediates that were generated by DCCD. The modified protein was treated with trypsin, and the resulting peptides were separated by HPLC. Two major radioactive peptides were isolated as well as one minor peptide. MgATP protected all three peptides from covalent modification. The two major peaks contained the same modified carboxyl group, which corresponded to Asp-184. The minor peak contained a modified glutamic acid, Glu-91. Both of these acidic residues are conserved in all protein kinases, which is consistent with their playing essential roles. The positions of Asp-184 and Glu-91 have been correlated with the overall domain structure of the molecule. Asp-184 may participate as a general base catalyst at the active site. A third carboxyl group, Glu-230, also was identified.(ABSTRACT TRUNCATED AT 250 WORDS)     

The mitochondrial ATPase. Selective modification of a nitrogen residue in the beta subunit.

1. When mitochondrial ATPase, which has been modified on a single tyrosine residue by 4-chloro-7-nitrobenzofurazan, is incubated at pH 9.0, the 7-nitrobenzofurazan group undergoes an intramolecular transfer to a nitrogen residue. The rate of this transfer is sensitive to the binding of adenine nucleotides to the enzyme. The resulting N-nitrobenzofurazan ATPase has little or no activity. 2. The fluorescence of the N-nitrobenzofurazan group in the modified ATPase is quenched on binding of ADP. 3. Electrophoresis of the modified enzyme in sodium dodecyl sulphate on a 10% polyacrylamide gel shows that the fluorescence of the N-nitrobenzofurazan chromophore is exclusively in the beta subunit. 4. The rate of transfer of the nitrobenzofurazan group from tyrosyl oxygen to nitrogen on the enzyme is compared with the rate of transfer between model compounds. 5. The interaction of the N-nitrobenzofurazan ATPase with aurovertin is reported.     

Modification of an essential arginine residue associated with the plasma membrane ATPase of red beet (Beta vulgaris L.) storage tissue

The dicarbonyl compounds, phenylgloxyl and 2,3-butanedione were used to demonstrate the presence of an essential arginine residue in the mechanism of the red beet (Beta vulgaris L.) plasma membrane ATPase. Treatment of the red beet ATPase with either of these reagents resulted in an inhibition of ATP hydrolytic activity protectable by the inclusion of either ATP or ADP during inhibitor incubation. Ligands of the ATP hydrolytic reaction also protected against phenylglyoxyl inhibition and affected the ability of ADP to protect against inhibition by this reagent. Kinetic analysis of 2,3-butanedione and phenylglyoxyl inhibition suggested the presence of a single arginine residue susceptible to attack by these reagents. As similar results with these arginine modification reagents were found for both the plasma membrane-associated and solubilized forms of the ATPase, it is apparent that the function of this arginyl moiety is not affected by detergent treatment and removal of the enzyme from the membrane.     

Identification of an essential residue of pig heart aconitase

Treatment of aconitase with phenacyl bromide prior to activation with Fe(II) and reductant results in complete, irreversible enzyme inactivation. Inactivation is due to the alkylation of a cysteine residue at the active site of the enzyme, the inactivation being inhibited by the competitive inhibitor, tricarballylate. Active enzyme is similarly inactivated, citrate affording greater protection than tricarballylate.     

An essential arginine residue in human prostatic acid phosphatase

Treatment of human prostatic acid phosphatase (orthophosphoric-monoester phosphohydrolase (acid optimum), EC 3.1.3.2) with either of the arginine-specific modifiers 2,3-butanedione or 1,2-cyclohexanedione in borate buffer at pH 8.1 leads to loss of activity. The inactivation by cyclohexanedione can be partially reversed by 0.2 M hydroxylamine. The rate of inactivation by both modifiers is decreased in the presence of the competitive inhibitors L-(+)-tartrate or inorganic phosphate but not in the presence of the non-inhibitor D-(-)-tartrate. Amino acid analysis of modified acid phosphatase indicates that only arginines are modified and that L-(+)-tartrate protects at least two arginyl residues from modification. A likely role of these arginyl residues is their involvement in binding the negatively charged phosphate group of the substrate.     

Evidence for an essential arginine residue in the substrate binding site of the mammalian succinate dehydrogenase

Phenylglyoxal and 2,3-butanedione rapidly inactivate membrane-bound or soluble bovine heart succinate dehydrogenase. The inhibition of the enzyme by these reagents is completely prevented by saturating concentration of malonate. The modification of the active site sulfhydryl group by p-chloromercuribenzoate decreases the rate of the enzyme inhibition by phenylglyoxal and abolishes the protective effect of malonate. Kinetic data suggest that the inactivation by phenylglyoxal results from the modification of an essential arginine residue(s) which interacts with dicarboxylate to form the primary enzyme-substrate complex.     

Expression,purification, and characterization of subunit E,an essential subunit of the vacuolar ATPase

A recombinant form of subunit E (Vma4p) from yeast vacuolar ATPases (V-ATPases) has been overexpressed in Escherichia coli, purified to homogeneity, and explored by mass spectrometry. Analysis of the secondary structure of Vma4p by circular dichroism spectroscopy indicated 32% alpha-helix and 23% beta-sheet content. Vma4p formed a hybrid-complex with the nucleotide-binding subunits alpha and beta of the closely related F(1) ATPase of the thermophilic bacterium PS3 (TF(1)). The alpha(3)beta(3)E-hybrid-complex had 56% of the ATPase activity of the native TF(1). By comparison, an alpha(3)beta(3)-formation without Vma4p showed about 24% of total TF(1) ATPase activity. This is the first demonstration of a hydrolytically active hybrid-complex consisting of F(1) and V(1) subunits. The arrangement of subunit E in V(1) has been probed using the recombinant Vma4p, the alpha(3)beta(3)E-hybrid-complex together with V(1) and an A(3)B(3)HEG-subcomplex of the V(1) ATPase from Manduca sexta, respectively, indicating that subunit E is shielded in V(1).     

Characterization of an essential arginine residue in the plasma membrane H+-ATPase of Neurospora crassa

Treatment of the plasma membrane H+-ATPase of Neurospora crassa with the arginine-specific reagents phenylglyoxal or 2,3-butanedione at 30 degrees C, pH 7.0, leads to a marked inhibition of ATPase activity. MgATP, the physiological substrate of the enzyme, protects against inactivation. MgADP, a competitive inhibitor of ATPase activity with a measured Ki of 0.11 mM, also protects, yielding calculated KD values of 0.125 and 0.115 mM in the presence of phenylglyoxal and 2,3-butanedione, respectively. The excellent agreement between Ki and KD values makes it likely that MgADP exerts its protective effect by binding to the catalytic site of the enzyme. Loss of activity follows pseudo-first order kinetics with respect to phenylglyoxal and 2,3-butanedione concentration, and double log plots of pseudo-first order rate constants versus reagent concentration yield slopes of 0.999 (phenylglyoxal) and 0.885 (2,3-butanedione), suggesting that the modification of one reactive site/mol of H+-ATPase is sufficient for inactivation. This stoichiometry has been confirmed by direct measurements of the incorporation of [14C]phenylglyoxal. Taken together, the results support the notion that one arginine residue, either located at the catalytic site or shielded by a conformational change upon nucleotide binding, plays an essential role in Neurospora H+-ATPase activity.     

Modification of an arginine residue essential for the activity of NAD-malic enzyme from Ascaris suum

Purified NAD-malic enzyme from Ascaris suum is rapidly inactivated by the arginine reagent, 2,3-butanedione, and this inactivation is facilitated by 30 mM borate. Determination of the inactivation rate as a function of butanedione concentration suggests a second-order process overall, which is first order in butanedione. A second-order rate constant of 0.6 M-1 s-1 at pH 9 is obtained for the butanedione reaction. The inactivation is reversed by removal of the excess reagent upon dialysis. The enzyme is protected against inactivation by saturating amounts of malate in the presence and absence of borate. The divalent metal Mg2+ affords protection in the presence of borate but has no effect in its absence. The nucleotide reactant NAD+ has no effect on the inactivation rate in either the presence or absence of borate. A dissociation constant of 24 mM is obtained for E:malate from the decrease in the inactivation rate as a function of malate concentration. An apparent Ki of 0.5 mM is obtained for oxalate (an inhibitor competitive vs malate) from E:Mg:oxalate while no significant binding is observed for oxalate using the butanedione modified enzyme. The pH dependence of the first-order rate of inactivation by butanedione gives a pKa of 9.4 +/- 0.1 for the residue(s) modified, and this pK is increased when NAD is bound. The arginine(s) modified is implicated in the binding of malate.     

Stable structure of thermophilic proton ATPase beta subunit

F1-ATPase is the major enzyme for ATP synthesis in mitochondria, chloroplasts, and bacterial plasma membranes. F1-ATPase obtained from thermophilic bacterium PS3 (TF1) is the only ATPase which can be reconstituted from its primary structure. Its beta subunit constitutes the catalytic site, and is capable of forming hybrid F1's with E. coli alpha and gamma subunits. Since the stability of TF1 resides in its primary structure, we cloned a gene coding for TF1, and the primary structure of the beta subunit was deduced from the nucleotide sequence of the gene to compare the sequence with those of beta's of three major categories of F1's; prokaryotic membranes, chloroplasts, and mitochondria. The following results were obtained. Homology: The primary structure of the TF1 beta subunit (473 residues, Mr = 51,995.6) showed 89.3% homology with 270 residues which are identical in the beta subunits from human mitochondria, spinach chloroplasts, and E. coli. It contained regions homologous to several nucleotide-binding proteins. Secondary structure: The deduced alpha-helical (30.1%) and beta-sheet (22.3%) contents were consistent with those determined from the circular dichroism spectra. Residues forming reverse turns (Gly and Pro) were highly conserved among the F1 beta subunits. Substituted residues and stability of TF1: We compared the amino acid sequence of the TF1 beta subunit with those of the other F1 beta subunits mentioned above. The observed substitutions in the thermophilic subunit increased its propensities to form secondary structures, and its external polarity to form tertiary structure. Codon usage: The codon usage of the TF1 beta gene was found to be unique. The changes in codons that achieved these amino acid substitutions were much larger than those caused by minimal mutations, and the third letters of the optimal codons were either guanine or cytosine, except in codons for Gln, Lys, and Glu.     

Evidence for an essential arginine residue at the active site of Escherichia coli acetate kinase

Escherichia coli acetate kinase (ATP: acetate phosphotransferase, EC 2.7.2.1.) was inactivated in the presence of either 2,3-butanedione in borate buffer or phenylglyoxal in triethanolamine buffer. When incubated with 9.4 mM phenylglyoxal or 5.1 mM butanedione, the enzyme lost its activity with an apparent rate constant of inactivation of 0.079 min-1, respectively. The loss of enzymatic activity was concomitant with the loss of an arginine residue per active site. Phosphorylated substrates of acetate kinase, ATP, ADP and acetylphosphate as well as AMP markedly decreased the rate of inactivation by both phenylglyoxal and butanedione. Acetate neither provided any protection nor affected the protection rendered by the adenine nucleotides. However, it interfered with the protection afforded by acetylphosphate. These data suggest that an arginine residue is located at the active site of acetate kinase and is essential for its catalytic activity, probably as a binding site for the negatively charged phosphate group of the substrates.     

Identification of a tyrosine residue at a nucleotide binding site in the beta subunit of the mitochondrial ATPase with p-fluorosulfonyl[14C]-benzoyl-5'-adenosine.

The mitochondrial F1-ATPase is irreversibly inactivated by the adenine nucleotide analogue, p-fluorosulfonylbenzoyl-5'-adenosine. This inactivation is partly prevented by the presence of bound adenine nucleotides. Inactivations of the ATPase with p-fluorosulfonyl[14C]benzoyl-5'-adenosine were most efficiently accomplished with the nucleotide-free enzyme at pH 7.0, in a buffer containing 20% glycerol. Under these conditions, 4.2 g atoms of 14C are incorporated per 350,000 g of enzyme when the ATPase is inactivated by 90% by its reaction with 2 mM p-fluorosulfonyl[14C]benzoyl-5'-adenosine. Isolation of the component polypeptide chains of the labeled ATPase showed that all of the radioactivity was associated with the two largest subunits. The isolated alpha subunit contained 0.45 g atom of 14C/mol and the isolated beta subunit contained 0.88 g atom of 14C/mol. Hence, the inactivation can be correlated with the incorporation of 14C into the beta subunit. This suggests that the hydrolytic site of the enzyme resides on this subunit. The majority of the radioactivity in a tryptic digest of labeled beta subunit is contained ina tryptic peptide that has the following amino acid sequence: Ile-Met-Asp-Pro-Asn-Ile-Val-Gly-Ser-Glu-His-Tyr-Asp-Val-Ala-Arg, where Tyr is the radioactive derivative of the tyrosine residue that was sulfonylated during the inactivation.     

Evidence that the essential, photosensitive histidyl residue in the beta2 subunit of tryptophan synthetase is in the pyridoxyl peptide

The β₂ subunit of tryptophan synthetase of Escherichia coli is photoinactivated in the presence of pyridoxal 5′-phosphate and L-serine as a result of the destruction of one histidyl residue per chain (1). Two tryptic peptides are found in much lower amounts in the photoinactivated enzyme than in the control enzyme. These peptides have been identified from their amino acid composition as the 9 or 10 residue peptides which terminate with the lysyl residue which forms a Schiff base with pyridoxal 5′-phosphate. These peptides contain two histidyl residues, one of which appears to be photosensitive. Thus pyridoxal 5′-phosphate sensitizes the photooxidation of a nearby, essential histidyl residue.     

Replacement of arginine 246 by histidine in the beta subunit of Escherichia coli H+-ATPase resulted in loss of multi-site ATPase activity

A mutant strain KF43 of Escherichia coli defective in the beta subunit of H+-translocating ATPase (F0F1) was examined. In this mutant, replacement of Arg246 by His was identified by DNA sequencing of the mutant gene and confirmed by tryptic peptide mapping. The mutant F1-ATPase was defective in multi-site hydrolysis of ATP but was active in uni-site hydrolysis. Studies on the kinetics of uni-site hydrolysis indicated that the k1 (rate of ATP binding) was similar to that of the wild-type, but the k-1 (rate of release of ATP) could not be measured. The mutant enzyme had a k3 (rate of release of inorganic phosphate) about 15-fold higher than that of the wild-type and showed 3 orders of magnitude lower promotion from uni- to multi-site catalysis. These results suggest that Arg246 or the region in its vicinity is important in multi-site hydrolysis of ATP and is also related to the binding of inorganic phosphate. Reconstitution experiments using isolated subunits suggested that hybrid enzymes (alpha beta gamma complexes) carrying both the mutant and wild-type beta subunits were inactive in multi-site hydrolysis of ATP, supporting the notion that three intact beta subunits are required for activity of the F1 molecule.     

Identification of lysine-78 as an essential residue in the Saccharomyces cerevisiae xylose reductase

Yeast xylose reductases are hypothesized as hybrid enzymes as their primary sequences contain elements of both the aldo-keto reductases (AKR) and short chain dehydrogenase/reductase (SDR) enzyme families. During catalysis by members of both enzyme families, an essential Lys residue H-bonds to a Tyr residue that donates proton to the aldehyde substrate. In the Saccharomyces cerevisiae xylose reductase, Tyr49 has been identified as the proton donor. However, the primary sequence of the enzyme contains two Lys residues, Lys53 and Lys78, corresponding to the conserved motifs for SDR and AKR enzyme families, respectively, that may H-bond to Tyr49. We used site-directed mutagenesis to substitute each of these Lys residues with Met. The activity of the K53M variant was slightly decreased as compared to the wild-type, while that of the K78M variant was negligible. The results suggest that Lys78 is the essential residue that H-bonds to Tyr49 during catalysis and indicate that the active site residues of yeast xylose reductases match those of the AKR, rather than SDR, enzymes. Intrinsic enzyme fluorescence spectroscopic analysis suggests that Lys78 may also contribute to the efficient binding of NADPH to the enzyme.