Identification of acetyl phosphate as the product of clostridial glycine reductase: Evidence for an acyl enzyme intermediate

It has been reported [Tanaka, H., & Stadtman, T. C. (1979) J. Biol. Chem. 254, 447-452] that glycine reductase from Clostridium sticklandii catalyzes the reaction glycine + ADP + P(i) + 2(e)- - acetate + ATP + NH(4)+. Glycine reductase consists of three proteins, designated A, B, and C. Only A has been purified to homogeneity. A dithiol serves as an electron donor. We find that ADP is not essential for the reaction and that in its absence acetyl phosphate is formed. Upon further purification of components B and C, an acetate kinase activity can be separated from both proteins. This observation establishes that acetate kinase activity is not an intrinsic property of glycine reductase, and therefore the reaction catalyzed by glycine reductase is glycine + P(i) + 2(e)- - acetyl phosphate + NH(4)+. Experiments with [(14)C]glycine and unlabeled acetate show that free acetate is not a precursor of acetyl phosphate. When glycine labeled with l8(O) is converted to product, l8(O) is lost. The l 8 (O) content of unreacted glycine remains unchanged after approximately 50% is converted to product. We propose that an acyl enzyme, most probably an acetyl enzyme,is an intermediate in the reaction and that the acetyl enzyme reacts with P(i) to form acetyl phosphate. A mechanism is proposed for the formation of the acetyl enzyme.     

The development and application of a novel chromophoric substrate for investigation of the mechanism of yeast fatty acid synthase

The acetyl transacylase activity of the fatty acid synthase from yeast has been investigated using p-nitrophenylthiol acetate. The chromophoric nature of the nitrophenylthiol moiety affords a convenient spectrophotometric assay for the transacylase function as well as a means to investigate the kinetics and the mechanism of this process. A probable kinetic scheme for enzyme catalyzed transacetylation from p-nitrophenylthiol acetate to an acyl acceptor (CoA or N-acetylcysteamine) is proposed and the kinetic constants for acetylation of enzyme and for acetyl transfer to an acceptor were determined. It was also demonstrated that p-nitrophenylthiol acetate can replace acetyl-CoA as a substrate in fatty acid synthesis.     

Mutagen Stability of Alkylation-Sensitive Mutants of Bacillus subtilis

The phosphotransacetylase of Veillonella alcalescens catalyzes a reversible reaction with Michaelis-Menten kinetics for all substrates. The rate of the reverse reaction (the synthesis of acetyl coenzyme A from acetyl phosphate) was 6.5 times greater than the rate of the forward reaction (the synthesis of acetyl phosphate from acetyl coenzyme A). The apparent K(m) values determined for the forward reaction were 8.6 x 10(-6)m for acetyl coenzyme A and 9.3 x 10(-3)m for phosphate. In the reverse reaction, the K(m) values were 3.3 x 10(-4)m for coenzyme A and 5.9 x 10(-4)m for acetyl phosphate. The results of an analysis of the inhibition by end products in the forward and reverse directions were compatible with a random bi- bi- mechanism. The enzyme was inhibited by adenosine triphosphate and adenosine diphosphate but was not affected by reduced nicotinamide adenine dinucleotide or pyruvate. The inhibition by adenosine triphosphate was noncompetitive with respect to acetyl phosphate and competitive with respect to coenzyme A. MgCl(2) reversed the inhibition by adenosine triphosphate or adenosine diphosphate. The role of Mg(2+) and adenylates in the regulation of phosphotranscetylase activity is discussed.     

Non-enzymic protein phosphorylation. Phosphorylation of 6-phosphogluconate dehydrogenase by acyl phosphates.

Incubation of 6-phosphogluconate dehydrogenase from Candida utilis with either acetyl phosphate, 1,3-diphosphoglycerate or carbamoyl phosphate results in the phosphorylation of the protein. The binding of one phosphate residue per enzyme subunit does not affect significantly the kinetic properties, but makes the enzyme less reactive toward thiol reagents, trypsin and pyridoxal 5'-phosphate. We suggest indicate that: (1) 6-phosphogluconate dehydrogenase from C. utilis is phosphorylated non-enzymically by physiological acyl phosphates and (2) the phosphorylation of the enzyme modifies the rate of protein inactivation.     

Purification and characterization of two extremely thermostable enzymes, phosphate acetyltransferase and acetate kinase, from the hyperthermophilic eubacterium Thermotoga maritima

Phosphate acetyltransferase (PTA) and acetate kinase (AK) of the hyperthermophilic eubacterium Thermotoga maritima have been purified 1,500- and 250-fold, respectively, to apparent homogeneity. PTA had an apparent molecular mass of 170 kDa and was composed of one subunit with a molecular mass of 34 kDa, suggesting a homotetramer (alpha4) structure. The N-terminal amino acid sequence showed significant identity to that of phosphate butyryltransferases from Clostridium acetobutylicum rather than to those of known phosphate acetyltransferases. The kinetic constants of the reversible enzyme reaction (acetyl-CoA + Pi -->/<-- acetyl phosphate + CoA) were determined at the pH optimum of pH 6.5. The apparent Km values for acetyl-CoA, Pi, acetyl phosphate, and coenzyme A (CoA) were 23, 110, 24, and 30 microM, respectively; the apparent Vmax values (at 55 degrees C) were 260 U/mg (acetyl phosphate formation) and 570 U/mg (acetyl-CoA formation). In addition to acetyl-CoA (100%), the enzyme accepted propionyl-CoA (60%) and butyryl-CoA (30%). The enzyme had a temperature optimum at 90 degrees C and was not inactivated by heat upon incubation at 80 degrees C for more than 2 h. AK had an apparent molecular mass of 90 kDa and consisted of one 44-kDa subunit, indicating a homodimer (alpha2) structure. The N-terminal amino acid sequence showed significant similarity to those of all known acetate kinases from eubacteria as well that of the archaeon Methanosarcina thermophila. The kinetic constants of the reversible enzyme reaction (acetyl phosphate + ADP -->/<-- acetate + ATP) were determined at the pH optimum of pH 7.0. The apparent Km values for acetyl phosphate, ADP, acetate, and ATP were 0.44, 3, 40, and 0.7 mM, respectively; the apparent Vmax values (at 50 degrees C) were 2,600 U/mg (acetate formation) and 1,800 U/mg (acetyl phosphate formation). AK phosphorylated propionate (54%) in addition to acetate (100%) and used GTP (100%), ITP (163%), UTP (56%), and CTP (21%) as phosphoryl donors in addition to ATP (100%). Divalent cations were required for activity, with Mn2+ and Mg2+ being most effective. The enzyme had a temperature optimum at 90 degrees C and was stabilized against heat inactivation by salts. In the presence of (NH4)2SO4 (1 M), which was most effective, the enzyme did not lose activity upon incubation at 100 degrees C for 3 h. The temperature optimum at 90 degrees C and the high thermostability of both PTA and AK are in accordance with their physiological function under hyperthermophilic conditions.     

Mechanism of action of clostridial glycine reductase: isolation and characterization of a covalent acetyl enzyme intermediate

Clostridial glycine reductase consists of proteins A, B, and C and catalyzes the reaction glycine + Pi + 2e(-)----acetyl phosphate + NH4+. Evidence was previously obtained that is consistent with the involvement of an acyl enzyme intermediate in this reaction. We now demonstrate that protein C catalyzes exchange of [32P]Pi into acetyl phosphate, providing additional support for an acetyl enzyme intermediate on protein C. Furthermore, we have isolated acetyl protein C and shown that it is qualitatively catalytically competent. Acetyl protein C can be obtained through the forward reaction from protein C and Se-(carboxymethyl)selenocysteine-protein A, which is generated by the reaction of glycine with proteins A and B [Arkowitz, R. A., & Abeles, R. H. (1990) J. Am. Chem. Soc. 112, 870-872]. Acetyl protein C can also be generated through the reverse reaction by the addition of acetyl phosphate to protein C. Both procedures lead to the same acetyl enzyme. The acetyl enzyme reacts with Pi to give acetyl phosphate. When [14C]acetyl protein C is denaturated with TCA and redissolved with urea, radioactivity remained associated with the protein. At pH 11.5 radioactivity was released with t1/2 = 57 min, comparable to the hydrolysis rate of thioesters. Exposure of 4 N neutralized NH2OH resulted in the complete release of radioactivity. Treatment with KBH4 removes all the radioactivity associated with protein C, resulting in the formation of [14C]ethanol. We conclude that a thiol group on protein C is acetylated. Proteins A and C together catalyze the exchange of tritium atoms from [3H]H2O into acetyl phosphate.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cys359 of GrdD is the active-site thiol that catalyses the final step of acetyl phosphate formation by glycine reductase from Eubacterium acidaminophilum.

In the amino-acid-fermenting anaerobe Eubacterium acidaminophilum, acetyl phosphate is synthesized by protein C of glycine reductase from a selenoprotein A-bound carboxymethyl-selenoether. We investigated specific thiols present in protein C for responsibility for acetyl phosphate liberation. After cloning of the genes encoding the large and the small subunit (grdC1, grdD1), they were expressed separately in Escherichia coli and purified as Strep-tag proteins. GrdD was the only subunit that catalysed arsenate-dependent hydrolysis of acetyl phosphate (up to 274 U.mg-1), whereas GrdC was completely inactive. GrdD contained two cysteine residues that were exchanged by site-directed mutagenesis. The GrdD(C98S) mutant enzyme still catalysed the hydrolysis of acetyl phosphate, but the GrdD(C359A) mutant enzyme was completely inactive. Next, these thiols were analysed further by chemical modification. After iodoacetate treatment of GrdD, the enzyme activity was lost, but in the presence of acetyl phosphate enzyme activity was protected. Subsequently, the inactivated carboxymethylated enzyme and the protected enzyme were both denatured, and the remaining thiols were pyridylethylated. Peptides generated by proteolytic cleavage were separated and subjected to mass spectrometry. Cys98 was not accessible to carboxymethylation by iodoacetate in the native enzyme in the presence or absence of the substrate, but could be alkylated after denaturation. Cys359, in contrast, was protected from carboxymethylation in the presence of acetyl phosphate, but became accessible to pyridylethylation upon prior denaturation of the protein. This clearly confirmed the catalytic role of Cys359 as the active site thiol of GrdD responsible for liberation of acetyl phosphate.     

Characterization of the acetate binding pocket in the Methanosarcina thermophila acetate kinase

Acetate kinase catalyzes the reversible magnesium-dependent synthesis of acetyl phosphate by transfer of the ATP gamma-phosphoryl group to acetate. Inspection of the crystal structure of the Methanosarcina thermophila enzyme containing only ADP revealed a solvent-accessible hydrophobic pocket formed by residues Val(93), Leu(122), Phe(179), and Pro(232) in the active site cleft, which identified a potential acetate binding site. The hypothesis that this was a binding site was further supported by alignment of all acetate kinase sequences available from databases, which showed strict conservation of all four residues, and the recent crystal structure of the M. thermophila enzyme with acetate bound in this pocket. Replacement of each residue in the pocket produced variants with K(m) values for acetate that were 7- to 26-fold greater than that of the wild type, and perturbations of this binding pocket also altered the specificity for longer-chain carboxylic acids and acetyl phosphate. The kinetic analyses of variants combined with structural modeling indicated that the pocket has roles in binding the methyl group of acetate, influencing substrate specificity, and orienting the carboxyl group. The kinetic analyses also indicated that binding of acetyl phosphate is more dependent on interactions of the phosphate group with an unidentified residue than on interactions between the methyl group and the hydrophobic pocket. The analyses also indicated that Phe(179) is essential for catalysis, possibly for domain closure. Alignments of acetate kinase, propionate kinase, and butyrate kinase sequences obtained from databases suggested that these enzymes have similar catalytic mechanisms and carboxylic acid substrate binding sites.     

Acetate kinase from Veillonella alcalescens. Regulation by succinate and substrates.

The kinetic properties of acetate kinase from Veillonella alcalescens were investigated. In the presence of high concentrations of nucleotide both forward and reverse reactions were observed. In the presence of succinate the degree of cooperativity between subunits of the homodimer decreased, i.e. the Hill coefficient, n, decreased from 2.5 to 1.4 for acetyl phosphate in the presence of succinate. At low substrate concentrations hyperbolic kinetic data were observed with succinate. We have proposed a modified version of the concerted symmetry model to describe the kinetics observed with this enzyme. The primary differentiating feature of the proposed model is the requirement for activator ligand binding for catalysis. In the absence of succinate, the substrate (acetate or acetyl phosphate) also functions as an activating ligand.     

Phosphotransacetylase from Clostridium acidiurici

The phosphotransacetylase from Clostridium acidiurici has two properties not observed for this enzyme in other bacteria: (i) it requires a divalent metal for activity, and (ii) it is not subject to uncoupling by arsenate. The enzyme has been obtained in highly purified form, with a specific activity 500-fold higher than crude extracts. Ferrous or manganous ions are required for maximal activity, with Mn(2+) being 50 to 75% as effective as Fe(2+). The acetyl group can be transferred from acetyl phosphate to coenzyme A in 20 mm arsenate without a net decrease in high-energy acyl linkages. Likewise, H(32)PO(4) (2-) will exchange with acetyl-PO(4) (2-) in the presence of arsenate without loss of acetyl phosphate. This suggests that the active site on the enzyme is capable of discriminating between phosphate and arsenate while permitting the reversible transfer of acyl groups between CoA and phosphate.     

Kinetic and chemical mechanism of arylamine N-acetyltransferase from Mycobacterium tuberculosis

Arylamine N-acetyltransferases (NATs) are cytosolic enzymes that catalyze the transfer of the acetyl group from acetyl coenzyme A (AcCoA) to the free amino group of arylamines and hydrazines. Previous studies have reported that overexpression of NAT from Mycobacterium smegmatis and Mycobacterium tuberculosis may be responsible for increased resistance to the front-line antitubercular drug, isoniazid, by acetylating and hence inactivating the prodrug. We report the kinetic characterization of M. tuberculosis NAT which reveals that substituted anilines are excellent substrates but that isoniazid is a very poor substrate for this enzyme. We propose that the expression of NAT from M. tuberculosis (TBNAT) is unlikely to be a significant cause of isoniazid resistance. The kinetic parameters for a variety of TBNAT substrates were examined, including 3-amino-4-hydroxybenzoic acid and AcCoA, revealing K m values of 0.32 +/- 0.03 and 0.14 +/- 0.02 mM, respectively. Steady-state kinetic analysis of TBNAT reveals that the enzyme catalyzes the reaction via a bi-bi ping-pong kinetic mechanism. The pH dependence of the kinetic parameters reveals that one enzyme group must be deprotonated for optimal catalytic activity and that two amino acid residues at the active site of the free enzyme are involved in binding and/or catalysis. Solvent kinetic isotope effects suggest that proton transfer steps are not rate-limiting in the overall reaction for substituted aniline substrates but become rate-limiting when poor hydrazide substrates are used.     

Control of poly-beta-hydroxybutyrate synthase mediated by acetyl phosphate in cyanobacteria.

Poly-beta-hydroxybutyrate (PHB) synthesis in a cyanobacterium, Synechococcus sp. strain MA19, is controlled at the enzyme level and is dependent on the C/N balance in the culture medium. The control involves at least two enzymes. The first enzyme is PHB synthase. Little PHB synthase activity was detected in crude extracts from cells grown under nitrogen-sufficient conditions (MA19(+N)). The activity was detected exclusively in membrane fractions from nitrogen-deprived cells (MA19(-N)) under light but not dark conditions. The shift in the enzyme activity was insensitive to chloramphenicol, which suggests posttranslational activation. Acetyl phosphate activated PHB synthase in membrane fractions from MA19(+N). In vitro, the activation level of PHB synthase changed, depending on the concentration of acetyl phosphate. The second enzyme was phosphotransacetylase (EC 2.3.1.8), which catalyzes the conversion of acetyl coenzyme A (acetyl-CoA) to acetyl phosphate. The activity was detected in crude extracts from MA19(-N) but not in those from MA19(+N). The results suggested that intracellular acetyl phosphate concentration could be controlled, depending on C/N balance and intracellular acetyl-CoA concentration. Acetyl phosphate probably acts as a signal of C/N balance affecting PHB metabolism in MA19.     

Escherichia coli phosphoenolpyruvate carboxylase: studies on the mechanism of multiple allosteric interactions.

Some kinetic studies of the interactions between Escherichia coli phosphoenolpyruvate carboxylase (orthophosphate:oxaloacetate carboxylase (phosphorylating) EC 4.1.1.31) acetyl coenzyme A, fructose 1,6-bisphosphate, and aspartate were performed. Activation of the enzyme by fructose 1,6-bisphosphate is anomalous by comparison with acetyl coenzyme A in that it confers hysteretic properties on the enzyme. In the presence of both activators and aspartate, hysteresis is observed also, but the approach to optimum catalytic activity can be fit to an equation for a second-order reaction with respect to enzyme concentration. Since, however, hysteresis is not a result of any apparent association-dissociation reaction, the apparent fit to a second-order kinetic equation is probably not real but is the result of a multistep activation mechanism. Hysteresis is not eliminated by preincubation of the enzyme with fructose 1,6-bisphosphate, acetyl coenzyme A, or phosphoenolpyruvate singly or in any pair of combinations. Hysteresis is associated, therefore, with the slow conformation change from the inactive species to the active species under the influence of all three of those reactants. The enzyme complex resulting from the binding of each activator, including phosphoenolpyruvate, has an increased affinity for the other activators. A kinetic method for estimating the relative changes in affinity of these complexes for some of the other reactants is presented. At concentrations of the activators below their K_a, synergistic effects are evident, particularly in their ability to relieve aspartate inhibition. Aspartate inhibition is competitive with acetyl coenzyme A both in the absence and in the presence of low concentrations of fructose 1,6-bisphosphate. Increasing the concentrations of fructose 1,6-bisphosphate results in an increase in the apparent K_l for aspartate, suggesting that synergistic activation by fructose 1,6-bisphosphate is a result of the increased affinity of the fructose 1,6-bisphosphate-enzyme complex for acetyl coenzyme A, and a shift in the concentration of enzyme species away from the one(s) to which aspartate can bind most easily. In the presence of fructose 1,6-bisphosphate alone optimal activation can be achieved, but the concentrations required in vitro are high and suggest that fructose 1,6-bisphosphate alone does not function in that capacity physiologically, but primes the enzyme for more effective activation by acetyl coenzyme A and/or phosphoenolpyruvate.     

Novel Pyrophosphate-Forming Acetate Kinase from the Protist Entamoeba histolytica

Acetate kinase (ACK) catalyzes the reversible synthesis of acetyl phosphate by transfer of the γ-phosphate of ATP to acetate. Here we report the first biochemical and kinetic characterization of a eukaryotic ACK, that from the protist Entamoeba histolytica. Our characterization revealed that this protist ACK is the only known member of the ASKHA structural superfamily, which includes acetate kinase, hexokinase, and other sugar kinases, to utilize inorganic pyrophosphate (PP_i)/inorganic phosphate (P_i) as the sole phosphoryl donor/acceptor. Detection of ACK activity in E. histolytica cell extracts in the direction of acetate/PP_i formation but not in the direction of acetyl phosphate/P_i formation suggests that the physiological direction of the reaction is toward acetate/PP_i production. Kinetic parameters determined for each direction of the reaction are consistent with this observation. The E. histolytica PP_i-forming ACK follows a sequential mechanism, supporting a direct in-line phosphoryl transfer mechanism as previously reported for the well-characterized Methanosarcina thermophila ATP-dependent ACK. Characterizations of enzyme variants altered in the putative acetate/acetyl phosphate binding pocket suggested that acetyl phosphate binding is not mediated solely through a hydrophobic interaction but also through the phosphoryl group, as for the M. thermophila ACK. However, there are key differences in the roles of certain active site residues between the two enzymes. The absence of known ACK partner enzymes raises the possibility that ACK is part of a novel pathway in Entamoeba.     

Acetate kinase from Veillonella alcalescens. Regulation of enzyme activity by succinate and substrates.

Acetate kinase of Veillonella alcalescens has been shown to be highly regulated enzyme exhibiting two levels of control: the requirement for succinate as a heterotropic allosteric effector, and cooperative binding at the substrate level. Succinate addition was necessary for enzymatic activity in both the direction of acyl phosphate synthesis and that of ATP synthesis. Control at the substrate level was apparent in the cooperative binding (Hill coefficients of 2) of acetyl phosphate, ATP, and ADP. Typical Michaelis kinetic data were observed for succinate (Ka = 20 mM for acetyl phosphate synthesis, 0.4 mM for ATP synthesis), acetate, and propionate. The primary effect of succinate was to increase the apparent Vmax of the enzymatic reaction for the variable substrates, ATP, ADP, and acetyl phosphate. The results are interpreted as evidence that, as a heterotropic effector of the acetate kinase reaction, succinate may regulate levels of propionyl-CoA (produced from propionyl phosphate by action of phosphotransacetylase), a compound required for the conversion of succinate to propionate. Acetase kinase has been shown to be a probable dimeric protein composed of two subunits of molecular weight 44,000 each.     

Investigation of the Methanosarcina thermophila acetate kinase mechanism by fluorescence quenching

Acetate kinase, a member of the acetate and sugar kinase/Hsc 70/actin (ASKHA) structural superfamily, catalyzes the reversible transfer of the gamma-phosphoryl group from ATP to acetate, yielding ADP and acetyl phosphate. A catalytic mechanism for the enzyme from Methanosarcina thermophila has been proposed on the basis of the crystal structure and kinetic analyses of amino acid replacement variants. The Gln43Trp variant was generated to further investigate the catalytic mechanism via changes in fluorescence. The dissociation constants for ADP.Mg2+ and ATP.Mg2+ ligands were determined for the Gln43Trp variant and double variants generated by replacing Arg241 and Arg91 with Ala and Lys. The dissociation constants and kinetic analyses indicated roles for the arginines in transition state stabilization for catalysis but not in nucleotide binding. The results also provide the first experimental evidence for domain motion and evidence that catalysis does not occur as two independent active sites of the homodimer but the active site activities are coordinated in a half-the-sites manner.     

Structural and functional studies suggest a catalytic mechanism for the phosphotransacetylase from Methanosarcina thermophila

Phosphotransacetylase (EC 2.3.1.8) catalyzes reversible transfer of the acetyl group from acetyl phosphate to coenzyme A (CoA), forming acetyl-CoA and inorganic phosphate. Two crystal structures of phosphotransacetylase from the methanogenic archaeon Methanosarcina thermophila in complex with the substrate CoA revealed one CoA (CoA1) bound in the proposed active site cleft and an additional CoA (CoA2) bound at the periphery of the cleft. The results of isothermal titration calorimetry experiments are described, and they support the hypothesis that there are distinct high-affinity (equilibrium dissociation constant [KD], 20 microM) and low-affinity (KD, 2 mM) CoA binding sites. The crystal structures indicated that binding of CoA1 is mediated by a series of hydrogen bonds and extensive van der Waals interactions with the enzyme and that there are fewer of these interactions between CoA2 and the enzyme. Different conformations of the protein observed in the crystal structures suggest that domain movements which alter the geometry of the active site cleft may contribute to catalysis. Kinetic and calorimetric analyses of site-specific replacement variants indicated that there are catalytic roles for Ser309 and Arg310, which are proximal to the reactive sulfhydryl of CoA1. The reaction is hypothesized to proceed through base-catalyzed abstraction of the thiol proton of CoA by the adjacent and invariant residue Asp316, followed by nucleophilic attack of the thiolate anion of CoA on the carbonyl carbon of acetyl phosphate. We propose that Arg310 binds acetyl phosphate and orients it for optimal nucleophilic attack. The hypothesized mechanism proceeds through a negatively charged transition state stabilized by hydrogen bond donation from Ser309.     

Purification and Properties of Acetate Kinase from Acholeplasma laidlawii

Acetate kinase (EC 2.7.2.1) was purified from Acholeplasma laidlawii cytoplasm by a combination of ammonium sulfate fractionation, gel filtration, diethylaminoethyl-cellulose chromatography, and affinity chromatography on 8-(6-aminohexylamino)-adenosine 5'-triphosphate conjugated to Sepharose 4B. The enzyme was composed of polypeptide chains of about 50,000 molecular weight as estimated from sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Under nondenaturating conditions, apparent molecular weights between 64,000 and 130,000 were obtained, depending upon mainly the ionic strength of the test solution. The enzyme had a narrow specificity for phosphate acceptor acids, whereas both purine and pyrimidine nucleoside triphosphates were suitable phosphate donors. Na(+) and K(+) inhibited both acetyl phosphate and adenosine 5'-triphosphate synthesis, and the latter was also inhibited by high concentrations of adenosine 5'-diphosphate and acetyl phosphate. This substrate inhibition was partially abolished by 0.5 M NaCl. The enzyme catalyzed the independent adenosine 5'-diphosphate<-->adenosine 5'-triphosphate and acetate<-->acetyl phosphate exchanges. The rate of the latter was enhanced by the addition of cosubstrate Mg(2+)-adenosine 5'-triphosphate. The high affinity for substrates, except for acetate, indicated that under physiological conditions the direction of the enzymic reaction favors adenosine 5'-triphosphate synthesis. Thus, a mechanism for adenosine 5'-triphosphate generation in mycoplasmas is suggested.     

Reaction of the anionic acetylation agent methyl acetyl phosphate with D-3-hydroxybutyrate dehydrogenase

Methyl acetyl phosphate is a competitive inhibitor of the reduction of acetoacetate by D-3-hydroxybutyrate dehydrogenase. The material also irreversibly inactivates the enzyme. The kinetics of the inactivation are consistent with methyl acetyl phosphate acetylating the conjugate base of a hydrogen bond donor. Protection offered by a substrate analogue (methyl acetonylphosphonate) in the presence of coenzyme implicates reaction at the cationic active site. Reversible protection by the amino group reagent 2,3-dimethylmaleic anhydride suggests that methyl acetyl phosphate reacts with an amino group. Sulfhydryl reagents and acetyl phosphate, a poorer acetylating agent, do not inactivate the enzyme. The pH dependence of the inactivation suggests that the acetylation occurs at a site that has a pKa of 8.2. The utility of methyl acetyl phosphate and other acyl phosphate monoesters in reacting with lysines adjacent to cationic sites of enzymes, hemoglobin, and histones is noted.     

Photosynthetic accumulation of poly-(hydroxybutyrate) by cyanobacteria--the metabolism and potential for CO2 recycling.

Regulatory mechanism in PHB [poly-(hydroxybutyrate)] accumulation by cyanobacteria, especially by a thermophilic isolate, Synechococcus MA19 was reviewed in comparison with a genetically engineered strain. The strain, MA19 accumulates PHB under nitrogen starved and photoautotrophic conditions (MA19-N). Little PHB synthase activity was detected in crude extracts from the cells grown in nitrogen sufficient conditions (MA19 + N). The activity was detected exclusively in membrane fractions from MA19 + N. The change of the enzyme activity was insensitive to chloramphenicol, which suggests post-translational activation. In vitro, acetyl phosphate activated PHB synthase in membrane fractions from MA19 + N, and the extent of activation depended on the concentration of acetyl phosphate. Phosphotransacetylase which catalyzes the conversion of acetyl-CoA to acetyl phosphate was detected in crude extracts from MA19-N but not in those from MA19 + N. These results suggested that intracellular acetyl phosphate concentration could be controlled, depending on C-N balance and intracellular acetyl-CoA concentration. On the contrary, in genetically-engineered cyanobacterium (transformant with PHB synthesizing genes from Ralstonia eutropha), it did not seem to be PHB synthase but acetyl-CoA flux that limits PHB synthesis. The closer association of PHB granules with thylakoid membranes in MA19 is suggested than that in the genetically-engineered cyanobacterium, which may reflect the difference of distribution of PHB synthase. Transposon-mutagenesis was used to acquire mutants of its altered PHB regulatory mechanism. PHA production by cyanobacteria was considered from the aspects of photobioreactors.