Quaternary structure of pyruvate carboxylase from Pseudomonas citronellolis.

Physical-chemical studies of pyruvate carboxylase from Pseudomonas citronellolis demonstrate that the enzyme has an alpha 4 beta 4 structure. The individual polypeptides, alpha (Mr = 65,000) and beta (Mr = 54,000), were separated and isolated by preparative gel electrophoresis. Analysis of the relationship between Coomassie blue staining and protein quantity for each polypeptide indicated that the alpha and beta subunits are present in a 1:1 stoichiometry in the native enzyme. Determinations of the molecular weight of the protein by sedimentation equilibrium (Mr = 454,000), gel filtration analysis (Mr = 510,000), disc gel electrophoresis (Mr = 530,000), and mass measurement from the Scanning Transmission Electron Microscope (Mr = 530,000) are consistent with the proposed alpha 4 beta 4 structure. Disc gel electrophoresis studies revealed that under certain circumstances the enzyme may dissociate to a smaller molecular weight species (Mr = 228,000). This dissociation phenomenon could explain the earlier reported observation of Taylor et al. ((1972) J. Biol. Chem 22, 7388-8390) that the enzyme had a molecular weight of 265,000. Evidence from electron microscopic studies shows that the three-dimensional structure of this enzyme is quite distinct from other species of pyruvate carboxylase. The enzyme does not show the typical rhombic appearance which has been noted for chicken liver, sheep liver, and yeast pyruvate carboxylase.     

Decarboxylation of oxalacetate by pyruvate carboxylase

The decarboxylation of oxalacetate by pyruvate carboxylase in the absence of ADP and Pi is stimulated 400-fold by the presence of oxamate, which is an inhibitory analogue of pyruvate. The observation of substrate inhibition when either oxamate or oxalacetate is varied at a fixed concentration of the other indicates that both molecules bind at the same site on the enzyme. The pH profiles for this reaction show no evidence of the involvement of an enzymic acid-base catalyst, suggesting that the proton and CO2 units may be exchanged directly between the reactants (although CO2 sequestered in the active site may be an intermediate in the process). The pH profiles of the full reverse reaction of pyruvate carboxylase in which oxalacetate decarboxylation is coupled to ATP formation and where Pi is the variable substrate do, however, indicate that such an acid-base catalyst is involved in the other partial reaction of the enzyme in proton transfer to and from biotin. The enzyme also displays two oxamate-independent oxalacetate decarboxylating activities, one of which is biotin-dependent and the other is independent of biotin.     

Multiple acyl-coenzyme A carboxylases in Pseudomonas citronellolis.

Pseudomonas citronellolis was shown to contain four different acyl-coenzyme A carboxylases, including acetyl-, propionyl-, 3-methylcrotonyl-, and geranyl-CoA carboxylases, when grown on the appropriate carbon sources. Acetyl-CoA carboxylase activity in crude extracts was stimulated approximately 40-fold by inclusion of 0.4-0.5 M ammonium sulfate in the assay. Unexpectedly high levels of propionyl-CoA carboxylase activity, also stimulated by ammonium sulfate, were found in acetate-grown cells. That these acetyl- and propionyl-CoA carboxylase activities were due to different enzymes was shown by their resolution during purification by a procedure that stabilized acetyl-CoA carboxylase as a complex and separated propionyl-CoA carboxylase into two required protein fractions. Propionate- or valine-grown cells contained a propionyl-CoA carboxylase activity that was strongly inhibited by ammonium sulfate in the assay, and which may represent an inducible form of the enzyme. Geranyl- and 3-methylcrotonyl-CoA carboxylases that catalyze the carboxylation of the 3-methyl groups of homologous acyl-CoA acceptors, were induced by growth on the monoterpenes, citronellic or geranoic acid; only 3-methylcrotonyl-CoA carboxylase was induced by growth on leucine or isovaleric acid. Induction of either carboxylase was associated with the appearance of similar high-molecular-weight, biotin-containing proteins as measured by gel filtration. These two carboxylases are probably distinct enzymes since 3-methyl-crotonyl-CoA carboxylase from isovalerate-grown cells does not carboxylate geranyl-CoA, while geranyl-CoA carboxylase will carboxylate both acyl-CoA homologues. P. citronellolis appears to be a useful system for studying the structural aspects of pairs of homologous acyl-CoA carboxylases.     

pH studies on the chemical mechanism of rabbit muscle pyruvate kinase. 1. Alternate substrates oxalacetate, glycolate, hydroxylamine, and fluoride

The decarboxylation of oxalacetate shows equilibrium-ordered kinetics, with Mg2+ adding before oxalacetate. The Ki for Mg2+ increases below a pK of 6.9, corresponding to a ligand of the metal that is probably glutamate, and decreases above a pK of 9.2, corresponding to water coordinated to enzyme-bound Mg2+. Both V and V/KOAA decrease above the pK of 9.2, suggesting that the carbonyl oxygen of oxalacetate must replace water in the inner coordination sphere of Mg2+ prior to decarboxylation. The enzyme-Mg2+-oxalacetate complex must be largely an outer sphere one, however, since the pK of 9.2 is seen in the V profile. The phosphorylation of glycolate or N-hydroxycarbamate (the actual substrate that results from reaction of hydroxylamine with bicarbonate) occurs only above the pK of 9.2, with V/K profiles decreasing below this pH. The alkoxides of these substrates appear to be the active species, replacing water in the coordination sphere of Mg2+ prior to phosphorylation by MgATP. Glycolate, but not N-hydroxycarbamate, can bind when not an alkoxide, since the V profile for the former decreases below a pK of 8.9, while V for the latter is pH independent. Initial velocity patterns for phosphorylation of fluoride in the presence of bicarbonate show saturation by MgATP but not by fluoride. The V/K profile for fluoride decreases above the pK of 9.0, showing that fluoride must replace water in the coordination sphere of Mg2+ prior to phosphorylation. None of the above reactions is sensitive to the protonation state of the acid-base catalyst that assists the enolization of pyruvate in the physiological reaction.     

Decarboxylation of oxalacetate to pyruvate by purified avian liver phosphoenolpyruvate carboxykinase.

Phosphoenolpyruvate carboxykinase, which has been isolated from chicken liver mitochondria in essentially homogenous form, carries out the irreversible decarboxylation of oxalacetate to pyruvate in the presence of catalytic amounts of GDP or IDP, as well as the reversible decarboxylation of oxalacetate to phosphoenolpyruvate in the presence of substrate amounts of GTP or ITP. The pyruvate- and phosphoenolpyruvate-forming reactions are similar in their nucleoside specificity and appear to be carried out by the same protein. However, the two activities vary markedly in their response to added metal ions and sulfhydryl reagents. Phosphoenolpyruvate formation is completely dependent on the presence of a divalent metal ion, with Mn2+ the most effective species. This reaction is also stimulated by sulfhydryl reagents such as 2-mercaptoethanol. In contrast, the pyruvate-forming reaction is strongly inhibited by divalent metal ions, including Mn2+, and also by moderate concentrations of sulfhydryl reagents. These observations and the demonstration that pyruvate kinase-like activity is very low or absent make it unlikely that pyruvate formation proceeds via phosphoenolpyruvate as an intermediate. Although the pyruvate-forming reaction is inhibited by added metal ions, the reaction is also inhibited by metal-chelating agents such as 8-hydroxyquinoline and o-phenanthroline, suggesting that the reaction is dependent on the presence of a metal ion. It has not been possible, however, to demonstrate that the enzyme is a metalloprotein.     

Stabilization of an acetyl-coenzyme A carboxylase complex from Pseudomonas citronellolis.

Using stabilizing conditions the acetyl-CoA carboxylase (EC 6.4.1.2) of Pseudomonas citronellolis has been isolated as a complex containing four different polypeptide chains with molecular weights of 53 000, 36 000, 33 000 and 25 000. Evidence is presented to suggest that these polypeptide chains correspond to distinct biotin carboxylase, transcarboxylase and biotin carboxyl carrier protein subunits in analogy with similar subunits of Escherichia coli acetyl-CoA carboxylase, an unstable complex in vitro.     

Carbon-13 and deuterium isotope effects on oxalacetate decarboxylation by pyruvate carboxylase

Deuterium and 13C isotope effects for the enzymic decarboxylation of oxalacetate showed that both deuterium- and 13C-sensitive steps in the reaction are partially rate limiting. A normal alpha-secondary effect of 1.2 per deuterium was calculated for the reaction in which pyruvate-d3 was the substrate, suggesting that the enolate of pyruvate was an intermediate in the reaction. The large normal alpha-secondary deuterium isotope effect of 1.7 when oxalacetate-d2 was the substrate suggests that the motions of the secondary hydrogens are coupled to that of the primary hydrogen during the protonation of the enolate of pyruvate. The reduction in the magnitude of the 13C isotope effect for the oxamate-dependent decarboxylation of oxalacetate from 1.0238 to 1.0155 when the reaction was performed in D2O (primary deuterum isotope effect = 2.1) clearly indicates that the transfer of the proton and carboxyl group between biotin and pyruvate does not occur via a single concerted reaction. Mechanisms in which biotin is activated to react with CO2 (prior to transfer of the proton on N-1) by bond formation between the sulfur and the ureido carbon, or in which the sequence of events is decarboxylation of oxalacetate, proton transfer from biotin to enolpyruvate, and carboxylation of enolbiotin, predict that the 13C isotope effect in D2O should be substantially lower than the observed value. A stepwise mechanism that does fit the data is one in which a proton is removed from biotin by a sulfhydryl group on the enzyme prior to carboxyl transfer, as long as the sulfhydryl group has an abnormally low pK.(ABSTRACT TRUNCATED AT 250 WORDS)     

Studies on the mechanism and stereochemical properties of the oxalacetate decarboxylase activity of pyruvate kinase.

When cod fish muscle oxalacetate decarboxylase catalyzes the decarboxylation of oxalacetate in the presence of NaBH4, L-lactate results from the reduction of enzyme-bound pyruvate. However, D-lactate results when borohydride reduces the binary enzyme-pyruvate complex formed by adding pyruvate from solution, as reported by others. This observation suggests that there are alternate mechanisms for reduction that are either kinetically or sterically determined for the E-pyruvate forms produced in the two directions. In the process of investigating the mechanism of reduction, the cod fish muscle decarboxylase was discovered to be identical with pyruvate kinase. Decarboxylase activity appears to take place at a site which overlaps the phosphoenolpyruvate binding site on this enzyme, as discussed in the following paper. Crystalline rabbit muscle pyruvate kinase also contains significant decarboxylase activity indicating that the two reactions may be structurally related functions. In the presence of K+, orthophosphate, or ATP the rabbit muscle enzyme catalyzes the detritiation of enzyme-bound pyruvate formed during decarboxylation before release of pyruvate from the enzyme, in analogy with the detritiation of pyruvate formed from P-[3-3/]enolpyruvate in the kinase reaction. This observation is consistent with the formation of an enolpyruvate intermediate common to the kinetic pathways of both reactions. Since the decarboxylase reac.tion is completely stereospecific, within the limits of detection, going with retention of configuration, the protonation of the enolpyruvate intermediate is completely determined by the enzyme as is the case with the enolpyruvate intermediate generated from P-enolpyruvate in the kinase reaction.     

Analogs of oxalacetate as potential substrates for phosphoenolpyruvate carboxykinase

Structural analogs of the substrate oxalacetate were examined as potential substrates and inhibitors for chicken liver mitochondrial phosphoenolpyruvate (P-enolpyruvate) carboxykinase. Steady-state kinetics were employed to characterize the inhibitory effects of these substrate analogs with the enzyme. Assays were carried out in both carboxylation and decarboxylation reaction directions. Pyruvate, beta-hydroxypyruvate, beta-mercaptopyruvate, beta-fluoropyruvate, DL-lactate, glycolate, glycoaldehyde, glyoxylate, glyphosate, and DL-aspartate showed no inhibitory effects by steady-state kinetics. Oxalate, acetopyruvate, and DL-, D-, and L-glycerate exhibited weak noncompetitive inhibition of the P-enolpyruvate carboxykinase-catalyzed reaction. DL-3-Nitro-2-hydroxypropionic acid, 3-nitro-2-oxopropionic acid, DL-malate, malonate, tartronate, and alpha-ketobutyrate all show weak inhibition with estimated inhibition constants greater than 20 nM. Several of these compounds were investigated by 31P NMR to determine if they function as phosphoryl acceptors for GTP. None of the compounds tested act as phosphoryl acceptors in the enzyme-catalyzed reaction. Chicken liver mitochondrial phosphoenolpyruvate carboxykinase shows a remarkably high degree of specificity at the binding site of oxalacetate.     

Supra-operonic clustering of genes specifying glucose dissimilation in Pseudomonas putida.

Summary The linkage arrangements of genes governing glucolysis in Pseudomonas putida have been determined by transductional analysis. Five genes (gdh, kgtA, kgtB, edd and eda), comprising at least three operons, are cotransducible with each other, but not with ggu (glucose and gluconate uptake) nor with genes of a known supra-operonic cluster of genes specifying enzymes of other dissimilatory pathways, nor with a biochemically uncharacterized his marker. It thus appears that P. putida may have more than one chromosomal region in which genes with dissimilatory function are clustered in a supra-operonic fashion.     

Enzyme recruitment allows the biodegradation of recalcitrant branched hydrocarbons by Pseudomonas citronellolis.

Experiments were carried out to construct pseudomonad strains capable of the biodegradation of certain recalcitrant branched hydrocarbons via a combination of alkane and citronellol degradative pathways. To promote the metabolism of the recalcitrant hydrocarbon 2,6-dimethyl-2-octene we transferred the OCT plasmid to Pseudomonas citronellolis, a pseudomonad containing the citronellol pathway. This extended the n-alkane substrate range of the organism, but did not permit utilization of the branched hydrocarbon even in the presence of a gratuitous inducer of the OCT plasmid. In a separate approach n-decane-utilizing (Dec+) mutants of P. citronellolis were selected and found to be constitutive for the expression of medium- to long-chain alkane oxidation. The Dec+ mutants were capable of degradation of 2,6-dimethyl-2-octene via the citronellol pathway as shown by (i) conversion of the hydrocarbon to citronellol, determined by gas-liquid chromatography-mass spectrometry, (ii) induction of geranyl-coenzyme A carboxylase, a key enzyme of the citronellol pathway, and (iii) demonstration of beta-decarboxymethylation of the hydrocarbon by whole cells. The Dec+ mutants had also acquired the capacity to metabolize other recalcitrant branched hydrocarbons such as 3,6-dimethyloctane and 2,6-dimethyldecane. These studies demonstrate how enzyme recruitment can provide a pathway for the biodegradation of otherwise recalcitrant branched hydrocarbons.     

Plasmid-encoded dissimilation of condensed tannin in Pseudomonas solanacearum

Pseudomonas solanacearum degrades catechin to phloroglucinolcarboxylic acid, protocatechuic acid, catechol, phloroglucinol, resorcinol and hydroxyquinol, which is plasmid-encoded. This dissimilatory plasmid, designated as pAMB1, was effectively cured by mitomycin C treatment and was transferred to a Pseudomonas sp., with a transfer frequency of 2.2 × 10⁻⁵ transconjugants/donor cell. The cured strains did not utilize catechin or its intermediates, and lacked the plasmid.     

Plasmid- and chromosome-mediated dissimilation of naphthalene and salicylate in Pseudomonas putida PMD-1.

Pseudomonas putida PMD-1 dissimilates naphthalene (Nah), salicylate (Sal), and benzoate (Ben) via catechol which is metabolized through the meta (or alpha-keto acid) pathway. The ability to utilize salicylate but not naphthalene was transferred from P. putida PMD-1 to several Pseudomonas species. Agarose gel electrophoresis of deoxyribonucleic acid (DNA) from PMD-1 and Sal+ exconjugants indicated that a plasmid (pMWD-1) of 110 megadaltons is correlated with the Sal+ phenotype; restriction enzyme analysis of DNA from Sal+ exconjugants indicated that plasmid pMWD-1 was transmitted intact. Enzyme analysis of Sal+ exconjugants demonstrated that the enzymes required to oxidize naphthalene to salicylate are absent, but salicylate hydroxylase and enzymes of the meta pathway are present. Thus, naphthalene conversion to salicylate requires chromosomal genes, whereas salicylate degradation is plasmid encoded. Comparison of restriction digests of plasmid pMWD-1 indicated that it differs considerably from the naphthalene and salicylate degradative plasmids previously described in P. putida.