Application of a propionyl coenzyme A synthetase for poly(3-hydroxypropionate-co-3-hydroxybutyrate) accumulation in recombinant Escherichia coli.

The genetic operon for propionic acid degradation in Salmonella enterica serovar Typhimurium contains an open reading frame designated prpE which encodes a propionyl coenzyme A (propionyl-CoA) synthetase (A. R. Horswill and J. C. Escalante-Semerena, Microbiology 145:1381-1388, 1999). In this paper we report the cloning of prpE by PCR, its overexpression in Escherichia coli, and the substrate specificity of the enzyme. When propionate was utilized as the substrate for PrpE, a K(m) of 50 microM and a specific activity of 120 micromol. min(-1). mg(-1) were found at the saturating substrate concentration. PrpE also activated acetate, 3-hydroxypropionate (3HP), and butyrate to their corresponding coenzyme A esters but did so much less efficiently than propionate. When prpE was coexpressed with the polyhydroxyalkanoate (PHA) biosynthetic genes from Ralstonia eutropha in recombinant E. coli, a PHA copolymer containing 3HP units accumulated when 3HP was supplied with the growth medium. To compare the utility of acyl-CoA synthetases to that of an acyl-CoA transferase for PHA production, PHA-producing recombinant strains were constructed to coexpress the PHA biosynthetic genes with prpE, with acoE (an acetyl-CoA synthetase gene from R. eutropha [H. Priefert and A. Steinbüchel, J. Bacteriol. 174:6590-6599, 1992]), or with orfZ (an acetyl-CoA:4-hydroxybutyrate-CoA transferase gene from Clostridium propionicum [H. E. Valentin, S. Reiser, and K. J. Gruys, Biotechnol. Bioeng. 67:291-299, 2000]). Of the three enzymes, PrpE and OrfZ enabled similar levels of 3HP incorporation into PHA, whereas AcoE was significantly less effective in this capacity.

Polyhydroxyalkanoate accumulation in Burkholderia sp.: a molecular approach to elucidate the genes involved in the formation of two homopolymers consisting of short-chain-length 3-hydroxyalkanoic acids.

Burkholderia sp. accumulates polyhydrox-yalkanoates (PHAs) containing 3-hydroxybutyrate and 3-hydroxy-4-pentenoic acid when grown on mineral media under limited phosphate or nitrogen, and using sucrose or gluconate as a carbon and energy source. Solvent fractionation and NMR spectroscopic characterization of these polyesters revealed the simultaneous accumulation of two homopolyesters rather than a co-polyester with random sequence distribution of the monomers [Valentin HE, Berger PA, Gruys KJ, Rodrigues MFA, Steinbuchel A, Tran M, Asrar J (1999) Macromolecules 32: 7389-7395]. To understand the genetic requirements for such unusual polyester accumulation, we probed total genomic DNA from Burkholderia sp. by Southern hybridization experiments using phaC-specific probes. These experiments indicated the presence of more than one PHA synthase gene within the genome of Burkholderia sp. However, when total genomic DNA from Burkholderia sp. was used to complement a PHA-negative mutant of Ralstonia eutropha for PHA accumulation, only one PHA synthase gene was obtained resembling the R. eutropha type of PHA synthases, based on amino acid sequence similarity. In addition to the PHA synthase gene, based on high sequence homology, genes encoding a beta-ketothiolase and acetoacetyl-CoA reductase were identified in a gene cluster with the PHA synthase gene. The arrangement of the three genes is quite similar to the R. eutropha poly-beta-hydroxybutyrate biosynthesis operon.

Characterization and cloning of an (R)-specific trans-2,3-enoylacyl-CoA hydratase from Rhodospirillum rubrum and use of this enzyme for PHA production in Escherichia coli.

An (R)-trans-2,3-enoylacyl-CoA hydratase was purified to near-homogeneity from Rhodospirillum rubrum. Protein sequencing of enriched protein fractions allowed the construction of a degenerate oligonucleotide. The gene encoding the (R)-specific hydratase activity was cloned following three rounds of colony hybridization using the oligonucleotide, and overexpression of the gene in E. coli led to the purification of the enzyme to homogeneity. The purified enzyme used crotonyl-CoA, trans-2,3-pentenoyl-CoA, and trans-2,3-hexenoyl-CoA with approximately equal specificity as substrates in the hydration reaction. However, no activity was observed using trans-2,3-octenoyl-CoA as a substrate, but this compound did partially inhibit crotonyl-CoA hydration. Based on the nucleotide sequence, the protein has a monomeric molecular weight of 15.4 kDa and is a homotetramer in its native form as determined by gel filtration chromatography and native PAGE. The hydratase was expressed together with the PHA synthase from Thiocapsa pfennigii in E. coli strain DH5alpha. Growth of these strains on oleic acid resulted in the production of the terpolyester poly(3-hydroxybutyrate-co-3-hydroxyvalerate-co-3-hydroxyhexanoate) .

Poly(3-hydroxybutyrate-co-4-hydroxybutyrate) formation from gamma-aminobutyrate and glutamate.

To provide 4-hydroxybutyryl-CoA for poly(3-hydroxybutyrate-co-4-hydroxybutyrate) formation from glutamate in Escherichia coli, an acetyl-CoA:4-hydroxybutyrate CoA transferase from Clostridium kluyveri, a 4-hydroxybutyrate dehydrogenase from Ralstonia eutropha, a gamma-aminobutyrate:2-ketoglutarate transaminase from Escherichia coli, and glutamate decarboxylases from Arabidopsis thaliana or E. coli were cloned and functionality tested by expression of single genes in E. coli to verify enzymatic activity, and uniquely assembled as operons under the control of the lac promoter. These operons were independently transformed into E. coli CT101 harboring the runaway replication vector pJM9238 for polyhydroxyalkanoate (PHA) production. Plasmid pJM9238 contains the PHA biosynthetic operon of R. eutropha under tac promoter control. Polyhydroxyalkanoate formation was monitored by nuclear magnetic resonance (NMR) spectroscopic analysis of the chloroform extracted and ethanol precipitated polyesters. Functionality of the biosynthetic pathway for copolymer production was demonstrated through feeding experiments using various carbon sources that supplied different precursors within the 4HB-CoA biosynthetic pathway.

Metabolic engineering of Arabidopsis and Brassica for poly(3-hydroxybutyrate-co-3-hydroxyvalerate) copolymer production.

Poly(hydroxyalkanoates) are natural polymers with thermoplastic properties. One polymer of this class with commercial applicability, poly(3-hydroxybutyrate-co-3-hydroxyvalerate) (PHBV) can be produced by bacterial fermentation, but the process is not economically competitive with polymer production from petrochemicals. Poly(hydroxyalkanoate) production in green plants promises much lower costs, but producing copolymer with the appropriate monomer composition is problematic. In this study, we have engineered Arabidopsis and Brassica to produce PHBV in leaves and seeds, respectively, by redirecting the metabolic flow of intermediates from fatty acid and amino acid biosynthesis. We present a pathway for the biosynthesis of PHBV in plant plastids, and also report copolymer production, metabolic intermediate analyses, and pathway dynamics.

PHA production, from bacteria to plants.

The genes encoding the polyhydroxyalkanoate (PHA) biosynthetic pathway in Ralstonia eutropha (3-ketothiolase, phaA or bktB; acetoacetyl-CoA reductase, phaB; and PHA synthase, phaC) were engineered for plant plastid targeting and expressed using leaf (e35S) or seed-specific (7s or lesquerella hydroxylase) promoters in Arabidopsis and Brassica. PHA yields in homozygous transformants were 12-13% of the dry mass in homozygous Arabidopsis plants and approximately 7% of the seed weight in seeds from heterozygous canola plants. When a threonine deaminase was expressed in addition to bktB, phaB and phaC, a copolyester of 3-hydroxybutyrate and 3-hydroxyvalerate was produced in both Arabidopsis and Brassica.

Metabolic modeling as a tool for evaluating polyhydroxyalkanoate copolymer production in plants.

The production of polyhydroxyalkanoates in plants is an interesting commercial prospect due to lower carbon feedstock costs and capital investments. The production of poly-(3-hydroxybutyrate) has already been successfully demonstrated in plant plastids, and the production of more complex polymers is under investigation. Using a mathematical simulation model this paper outlines the theoretical prospects of producing the copolymer poly-(3-hydroxybutyrate-co-3-hydroxyvalerate) [P(3HB-3HV)] in plant plastids. The model suggests that both the 3HV/3HB ratio and the copolymer production rate will vary considerably between dark and light conditions. Using metabolic control analysis we predict that the beta-ketothiolase predominately controls the copolymer production rate, but that the activity of all three enzymes influence the copolymer ratio. Dynamic simulations further suggest that controlled expression of the three enzymes at different levels may enable desirable changes in both the copolymer production rate and the 3HV/3HB ratio. Finally, we illustrate that natural variations in substrate and cofactor levels may have a considerable impact on both the production rate and the copolymer ratio, which must be taken into account when constructing a production system.

Multiple beta-ketothiolases mediate poly(beta-hydroxyalkanoate) copolymer synthesis in Ralstonia eutropha.

Polyhydroxyalkanoates (PHAs) are a class of carbon and energy storage polymers produced by numerous bacteria in response to environmental limitation. The type of polymer produced depends on the carbon sources available, the flexibility of the organism's intermediary metabolism, and the substrate specificity of the PHA biosynthetic enzymes. Ralstonia eutropha produces both the homopolymer poly-beta-hydroxybutyrate (PHB) and, when provided with the appropriate substrate, the copolymer poly(beta-hydroxybutyrate-co-beta-hydroxyvalerate) (PHBV). A required step in production of the hydroxyvalerate moiety of PHBV is the condensation of acetyl coenzyme A (acetyl-CoA) and propionyl-CoA to form beta-ketovaleryl-CoA. This activity has generally been attributed to the beta-ketothiolase encoded by R. eutropha phbA. However, we have determined that PhbA does not significantly contribute to catalyzing this condensation reaction. Here we report the cloning and genetic analysis of bktB, which encodes a beta-ketothiolase from R. eutropha that is capable of forming beta-ketovaleryl-CoA. Genetic analyses determined that BktB is the primary condensation enzyme leading to production of beta-hydroxyvalerate derived from propionyl-CoA. We also report an additional beta-ketothiolase, designated BktC, that probably serves as a secondary route toward beta-hydroxyvalerate production.

An EPSP synthase inhibitor joining shikimate 3-phosphate with glyphosate: synthesis and ligand binding studies.

A novel EPSP synthase inhibitor 4 has been designed and synthesized to probe the configurational details of glyphosate recognition in its herbicidal ternary complex with enzyme and shikimate 3-phosphate (S3P). A kinetic evaluation of the new 3-dephospho analog 12, as well as calorimetric and (31)P NMR spectroscopic studies of enzyme-bound 4, now provides a more precise quantitative definition for the molecular interactions of 4 with this enzyme. The very poor binding, relative to 4, displayed by the 3-dephospho analog 12 is indicative that 4 has a specific interaction with the S3P site. A comparison of Ki(calc) for 12 versus the Ki(app) for 4 indicates that the 3-phosphate group in 4 contributes about 4.8 kcal/mol to binding. This compares well with the 5.2 kcal/mol which the 3-phosphate group in S3P contributes to binding. Isothermal titration calorimetry demonstrates that 4 binds to free enzyme with an observed Kd of 0.53 +/- 0.04 microM. As such, 4 binds only 3-fold weaker than glyphosate and about 150-fold better than N-methylglyphosate. Consequently, 4 represents the most potent N-alkylglyphosate derivative identified to date. However, the resulting thermodynamic binding parameters clearly demonstrate that the formation of EPSPS x 4 is entropy driven like S3P. The binding characteristics of 4 are fully consistent with a primary interaction localized at the S3P subsite. Furthermore, (31)P NMR studies of enzyme-bound 4 confirm the expected interaction at the shikimate 3-phosphate site. However, the chemical shift observed for the phosphonate signal of EPSPS x 4 is in the opposite direction than that observed previously when glyphosate binds with enzyme and S3P. Therefore, when 4 occupies the S3P binding site, there is incomplete overlap at the glyphosate phosphonate subsite. As a glyphosate analog inhibitor, the potency of 4 most likely arises from predominant interactions which occur outside the normal glyphosate binding site. Consequently, 4 is best described as an S3P-based substrate-analog inhibitor. These combined results corroborate the previous kinetic model [Gruys, K. J., Marzabadi, M. R., Pansegrau, P. D., & Sikorski, J. A. (1993) Arch. Biochem. Biophys. 304, 345-351], which suggested that 4 interacts well with the S3P subsite but has little, if any, interaction at the expected glyphosate phosphonate or phosphoenolpyruvate-Pi subsites.

Reevaluating glyphosate as a transition-state inhibitor of EPSP synthase: identification of an EPSP synthase.EPSP.glyphosate ternary complex.

Numerous studies have confirmed that glyphosate forms a tight ternary complex with EPSP synthase and shikimate 3-phosphate. It has been proposed [Anton, D., Hedstrom, L., Fish, S., & Abeles, R. (1983) Biochemistry 22, 5903-5908; Steinrücken, H. C., & Amrhein, N. (1984) Eur. J. Biochem. 143, 351-357] that in this complex glyphosate functions as a transition-state analog of the putative phosphoenolpyruvoyl oxonium ion. For this to be true, glyphosate must occupy the space in the enzyme active site that is normally associated with PEP and, through turnover, the carboxyvinyl group of the product EPSP. According to this model, one would predict that, in the reverse EPSP synthase reaction with EPSP and phosphate as substrates, there should be little if any interaction of glyphosate with enzyme or enzyme.substrate complexes. In contrast to this expectation, rapid gel filtration experiments provided direct evidence that glyphosate could be trapped on the enzyme in the presence of EPSP to form a ternary complex of EPSPS.EPSP.glyphosate. The experimentally determined stoichiometry for this complex, 0.62 equiv of glyphosate/mole of EPSPS, is similar to that found for the EPSPS.S3P.glyphosate ternary complex (0.66). This direct binding result was corroborated and quantitated by fluorescence titration experiments which demonstrated that glyphosate forms a reasonably tight (Kd = 56 +/- 1 microM) ternary complex with enzyme and EPSP. This finding was further verified, and its impact on substrate turnover analyzed, by steady-state kinetics. Glyphosate was found to be an uncompetitive inhibitor versus EPSP with Kii(app) = 54 +/- 2 microM.(ABSTRACT TRUNCATED AT 250 WORDS)

Electron microscopy of cytochrome c oxidase crystals: labeling of subunit III with a monomaleimide undecagold cluster compound.

Two-dimensional crystals of beef heart mitochondrial cytochrome c oxidase dimers were labeled at Cys-115 of subunit III with a monomaleimide derivative of an undecagold cluster compound. The binding site of the gold cluster compound and hence the site of subunit III were identified by image processing of cryoelectron micrographs of the crystals preserved in a mixture of glucose and uranyl acetate. The shape of the cytochrome oxidase dimer can be approximated as a parallelogram which is 44 by 82 A with an included angle of 80 degrees oriented with its long dimension along the a axis of the crystal. Labeling of subunit III was confirmed by a shift in the mobility of approximately 50% of subunit III molecules upon electrophoresis in polyacrylamide gels in the presence of sodium dodecyl sulfate. Averaged images of undecagold cluster labeled crystals and of unlabeled crystals were calculated; each image represents an average of approximately 17,000 molecules of either labeled or unlabeled cytochrome oxidase. On the basis of a statistical analysis of the differences between the two images, the gold cluster binds along a line 30 degrees from the a axis and 29 A from the center of the dimer. This result is interpreted in the context of other structural studies including the site of cytochrome c binding which Frey and Murray found to be near the a axis and 18 A from the center of the dimer [Frey, T. G., & Murray, J. M. (1994) J. Mol. Biol. 237, 275-297].(ABSTRACT TRUNCATED AT 250 WORDS)

Steady-state kinetic evaluation of the reverse reaction for Escherichia coli 5-enolpyruvoylshikimate-3-phosphate synthase.

Recently it has been found that the kinetic mechanism for Escherichia coli 5-enolpyruvoylshikimate-3-phosphate synthase (EPSPS) in the forward direction is random with synergistic binding of substrates and inhibitors (K. J. Gruys, M. C. Walker, and J. A. Sikorski, 1992, Biochemistry 31, 5534). This work, however, did not address the reverse reaction with 5-enolpyruvoylshikimate-3-phosphate (EPSP) and phosphate (Pi) as substrates where a similar question of random versus ordered addition of substrates remained. Previous transient-state kinetic results led to a proposal for an equilibrium-ordered mechanism, where binding of EPSP occurs first followed by Pi (K. S. Anderson, and K. A. Johnson, 1990, Chem. Rev. 90, 1131). Steady-state kinetic results of the reverse reaction presented here suggest that, like the forward reaction, addition of substrates occurs randomly. Initial velocity studies with EPSP and Pi show a normal intersecting pattern in the reciprocal plots, consistent with a random or steady-state-ordered mechanism, but not with equilibrium-ordered addition of substrates. Inhibition of the EPSPS reverse reaction by 5-amino-S3P or the S3P-glyphosate hybrid molecule gave the expected competitive patterns versus EPSP, but mixed noncompetitive patterns versus Pi. These results also disfavor an equilibrium-ordered model, but again are consistent with a random or steady-state-ordered mechanism. A more quantitative mechanistic analysis of the inhibition data to determine the true rather than apparent Ki values provides evidence for a random over a steady-state-ordered addition of substrates. These results in combination with previous findings lead to the conclusion that the mechanism is random addition of EPSP and Pi since it is the only possible model for substrate addition that is consistent with the cumulative data from all kinetic (transient- as well as steady-state) and direct binding studies.

Substrate synergism and the steady-state kinetic reaction mechanism for EPSP synthase from Escherichia coli.

Previous studies of Escherichia coli 5-enolpyruvoylshikimate-3-phosphate synthase (EPSPS, EC 2.5.1.19) have suggested that the kinetic reaction mechanism for this enzyme in the forward direction is equilibrium ordered with shikimate 3-phosphate (S3P) binding first followed by phosphoenolpyruvate (PEP). Recent results from this laboratory, however, measuring direct binding of PEP and PEP analogues to free EPSPS suggest more random character to the enzyme. Steady-state kinetic and spectroscopic studies presented here indicate that E. coli EPSPS does indeed follow a random kinetic mechanism. Initial velocity studies with S3P and PEP show competitive substrate inhibition by PEP added to a normal intersecting pattern. Substrate inhibition is proposed to occur by competitive binding of PEP at the S3P site [Ki(PEP) = 6-8 mM]. To test for a productive EPSPS.PEP binary complex, the reaction order of EPSPS was evaluated with shikimic acid and PEP as substrates. The mechanism for this reaction is equilibrium ordered with PEP binding first giving a Kia value for PEP in agreement with the independently measured Kd of 0.39 mM (shikimate Km = 25 mM). Results from this study also show that the 3-phosphate moiety of S3P offers 8.7 kcal/mol in binding energy versus a hydroxyl in this position. Over 60% of this binding energy is expressed in binding of substrate to enzyme rather than toward increasing kcat. Glyphosate inhibition of shikimate turnover was poor with approximately 8 x 10(4) loss in binding capacity compared to the normal reaction, consistent with the independently measured Kd of 12 mM for the EPSPS.glyphosate binary complex. The EPSPS.glyphosate complex induces shikimate binding, however, by a factor of 7 greater than EPSPS.PEP. Carboxyallenyl phosphate and (Z)-3-fluoro-PEP were found to be strong inhibitors of the enzyme that have surprising affinity for the S3P binding domain in addition to the PEP site as measured both kinetically and by direct observation with 31P NMR. The collective data indicate that the true kinetic mechanism for EPSPS in the forward direction is random with synergistic binding occurring between substrates and inhibitors. The synergism explains how the mechanism can be random with S3P and PEP, but yet equilibrium ordered with PEP binding first for shikimate turnover. Synergism also accounts for how glyphosate can be a strong inhibitor of the normal reaction, but poor versus shikimate turnover.

2-Acetylthiamin pyrophosphate (acetyl-TPP) pH-rate profile for hydrolysis of acetyl-TPP and isolation of acetyl-TPP as a transient species in pyruvate dehydrogenase catalyzed reactions.

Rate constants for the hydrolysis of acetyl-TPP were measured between pH values of 2.5 and 7.5 and plotted as log kobs versus pH. The pH-rate profile defined two legs, each with a slope of +1 but separated by a region of decreased slope between pH 4 and pH 6. The rates were insensitive to buffer concentrations. Each leg of the profile reflected specific-base-catalyzed hydrolysis of acetyl-TPP, analogous to the hydrolysis of 2-acetyl-3,4-dimethylthiazolium ion [Lienhard, G.E. (1966) J. Am. Chem. Soc. 88, 5642-5649]. The separation of the two legs of this profile has been shown to be caused by the ionization of a group exhibiting a pKa of 4.73 within acetyl-TPP that is remote from the acetyl group, the amino-pyrimidine ring, which is protonated below pH 4.73. The protonation level of this ring has been shown to control the equilibrium partitioning of acetyl-TPP among its carbinolamine, keto, and hydrate forms. The differential partitioning of these species is a major factor causing the separation between the two legs of the pH-rate profile. The characteristic pH-rate profile and the availability of synthetic acetyl-TPP [Gruys, K.J., Halkides, C.J., & Frey, P.A. (1987) Biochemistry 26, 7575-7585] have facilitated the isolation and identification of [1-14C]acetyl-TPP from acid-quenched enzymatic reaction mixtures at steady states. [1-14C]Acetyl-TPP was identified as a transient species in reactions catalyzed by the PDH complex or the pyruvate dehydrogenase component of the complex (E1). The pH-rate profile for hydrolysis of [1-14C]-acetyl-TPP isolated from enzymatic reactions was found to be indistinguishable from that for authentic acetyl-TPP, which constituted positive identification of the 14C-labeled enzymic species.

Synthesis and properties of 2-acetylthiamin pyrophosphate: an enzymatic reaction intermediate.

The synthesis of 2-acetylthiamin pyrophosphate (acetyl-TPP) is described. The synthesis of this compound is accomplished at 23 degrees C by the oxidation of 2-(1-hydroxyethyl)thiamin pyrophosphate using aqueous chromic acid as the oxidizing agent under conditions where Cr(III) coordination to the pyrophosphoryl moiety and hydrolysis of both the pyrophosphate and acetyl moieties were prevented. Although the chemical properties exhibited by acetyl-TPP are similar to those of the 2-acetyl-3,4-dimethylthiazolium ion examined by Lienhard [Lienhard, G.E. (1966) J. Am. Chem. Soc. 88, 5642-5649], significant differences exist because of the pyrimidine ring in acetyl-TPP. Characterization of acetyl-TPP by ultraviolet spectroscopy, 1H NMR, 13C NMR, and 31P NMR provided evidence that the compound in aqueous solution exists as an equilibrium mixture of keto, hydrate, and intramolecular carbinolamine forms. The equilibria for the hydration and carbinolamine formation reactions at pD 1.3 as determined by 1H NMR are strongly dependent on the temperature, showing an increase in the hydrate and carbinolamine forms at the expense of the keto form with decreasing temperature. The concentration of keto form also decreases with increasing pH. Acetyl-TPP is stable in aqueous acid but rapidly deacetylates at higher pH to form acetate and thiamin pyrophosphate. Trapping of the acetyl moiety in aqueous solution occurs efficiently with 1.0 M hydroxylamine at pH 5.5-6.5 to form acetohydroxamic acid and to a much smaller extent with 1.0 M 2-mercaptoethanol at pH 4.0 and 5.0 to form thio ester. Transfer of the acetyl group to 0.5 M dihydrolipoic acid at pH 5.0 and 1.0 M phosphate dianion at pH 7.0 is not observed to any significant extent in water. The kinetic and thermodynamic reactivity of acetyl-TPP with water and other nucleophiles is compatible with a hypothetical role for acyl-TPPs as enzymatic acyl-transfer intermediates.

Kinetic studies on the conformational isomerization reaction of the four diastereomers of beta,gamma-bidentate CrATP.

The rates of the conformational isomerization reaction of the diastereomers of beta,gamma-bidentate CrATP were studied as a function of pH, buffer concentration, ionic strength, and temperature. The progress of the reaction was monitored by quenching the reaction at various times, and then isolating the individual diastereomers and quantitating the percent of each. This was accomplished using the reverse-phase high-performance liquid chromatography separation technique developed in this laboratory [K. J. Gruys, and S. M. Schuster, Anal. Biochem. 125, 66-73 (1982)]. The rate constants for this isomerization were then determined by obtaining the best computer fit of the data to a reversible binary mechanism (i.e., A in equilibrium B) using interative descent methods. The reaction rate was shown to be dependent on pH, temperature, and ionic strength, but independent of buffer concentration. Keq. constants were independent of all variables except ionic strength. The results from this study are interpreted in terms of a reaction mechanism involving a preequilibrium ionization of the diastereomers followed by a rate-limiting interconversion process.

Synthesis of gamma-monodentate and beta, gamma-bidentate CrITP. Isolation and characterization of the two chelation isomers and the individual diastereomers of beta, gamma-bidentate CrITP.

The two chelation isomers of CrITP, gamma-monodentate and beta, gamma-bidentate CrITP, as well as the diastereomers of beta, gamma-bidentate CrITP were synthesized, isolated, and characterized. Synthesis of these complexes was done using pH titration methods similar to that described by Cleland [W.W. Cleland, Methods Enzymol. 87, 159 (1982)], and separation of the two chelation isomers was accomplished with DEAE-sephadex A-25 using 0-0.3 N linear HCl gradient. Diastereomer separation (analytical and preparative scales) of beta, gamma-bidentate CrITP using reverse-phase high-performance liquid chromatography, and then analysis of the diastereomers with circular dichroism spectroscopy, shows four diastereomers that exist as two pairs of mirror-image isomers, similar to the four diastereomers of beta, gamma-bidentate CrATP as presented by Dunaway-Mariano and Cleland [D. Dunaway-Mariano and W.W. Cleland, Biochemistry 19, 1496 (1980)]. Reverse-phase high-performance liquid chromatography analysis of gamma-monodentate CrITP shows the presence of two major peaks, both of which convert to beta, gamma-bidentate CrITP upon incubation at pH 6.0 for 1 hr.

alpha-Ketoglutarate dehydrogenase complex of Escherichia coli. A hybrid complex containing pyruvate dehydrogenase subunits from pyruvate dehydrogenase complex.

The alpha-ketoglutarate dehydrogenase complex of Escherichia coli utilizes pyruvate as a poor substrate, with an activity of 0.082 units/mg of protein compared with 22 units/mg of protein for alpha-ketoglutarate. Pyruvate fully reduces the FAD in the complex and both alpha-keto[5-14C]glutarate and [2-14C]pyruvate fully [14C] acylate the lipoyl groups with approximately 10 nmol of 14C/mg of protein, corresponding to 24 lipoyl groups. NADH-dependent succinylation by [4-14C]succinyl-CoA also labels the enzyme with approximately 10 nmol of 14C/mg of protein. Therefore, pyruvate is a true substrate. However, the pyruvate and alpha-ketoglutarate activities exhibit different thiamin pyrophosphate dependencies. Moreover, 3-fluoropyruvate inhibits the pyruvate activity of the complex without affecting the alpha-ketoglutarate activity, and 2-oxo-3-fluoroglutarate inhibits the alpha-ketoglutarate activity without affecting the pyruvate activity. 3-Fluoro[1,2-14C]pyruvate labels about 10% of the E1 components (alpha-ketoacid dehydrogenases). The dihydrolipoyl transsuccinylase-dihydrolipoyl dehydrogenase subcomplex (E2E3) is activated as a pyruvate dehydrogenase complex by addition of E. coli pyruvate dehydrogenase, the E1 component of the pyruvate dehydrogenase complex. All evidence indicates that the alpha-ketoglutarate dehydrogenase complex purified from E. coli is a hybrid complex containing pyruvate dehydrogenase (approximately 10%) and alpha-ketoglutarate dehydrogenase (approximately 90%) as its E1 components.

Metal-nucleotide structural characteristics during catalysis by beef heart mitochondrial F1.

This study examined the nature of the metal-nucleotide complexes which serve as substrates, products, and intermediates in the beef heart mitochondrial ATPase reaction. The two methods employed involved the use of phosphorothioate ATP analogs as substrates in the presence of Mg2+ or Cd2+ and the use of substitution inert Cr X ATP complexes (the isolated diastereomers of the bidentate complexes) along with the newly synthesized Cr X ITP complexes as inhibitors of both the F1-ATPase and F1-ITPase activities. Little stereoselectivity was observed in the inhibition of F1-ATPase and F1-ITPase activities by the isolated diastereomers of beta,gamma-bidentate CrATP, while the inhibition by the delta,alpha,beta-bidentate CrADP diastereomer was greater than that of the lambda epimer. gamma-Monodentate CrITP was a weak inhibitor of both the ATPase and ITPase activities, whereas beta,gamma-bidentate CrITP failed to show any inhibition at all up to a concentration of 3.2 mM. When adenosine 5'-O-(2-thiotriphosphate) (ATP beta S) was used as the substrate, (VmSp]/(Vm(Rp] with Mg2+ present was 2.7 at 31 degrees C and 3.5 at 13 degrees C. The (Vm/Km(Sp]/(Vm/Km(Rp] ratios with Mg2+ present were 15.3 at 31 degrees C and 73.3 at 13 degrees C. With Cd2+ present, the (Vm(Sp]/(Vm(Rp] ratios were 0.81 and 0.65 at 31 and 13 degrees C, respectively. The (Vm/Km(Sp]/(Vm/Km(Rp] ratios with Cd2+ present were 1.17 at 31 degrees C and 1.34 at 13 degrees C. The large activation energy observed for the isomers of CdATP beta S was not observed for MgATP beta S, MgATP, or CdATP. The Vm for Cd adenosine 5'-O-thiotriphosphate (ATP gamma S) hydrolysis was the largest of all the metal-phosphorothioate nucleotide complexes, while that for MgATP gamma S was the smallest. The results are interpreted in terms of a catalytic model for F1-catalyzed nucleotide hydrolysis describing metal-nucleotide chelation during the reaction.

Metal interactions with beef heart mitochondrial ATPase.

Atomic absorption and electron paramagnetic resonance spectroscopy were used to study the metal binding sites of beef heart mitochondrial ATPase (F1). Quantitative and qualitative properties of these sites are described. Two different separation techniques were able to distinguish two very tight sites from one tight (easily exchangeable) metal binding site on F1. Of these sites, two are specific for magnesium while one can be substituted with Mn2+, Co2+, or Zn2+. When MgAMP-PNP was incubated with F1, a fourth metal was bound to the enzyme. The carboxyl group modified by dicyclohexylcarbodiimide is shown not to be involved in binding of any of the tightly bound metals. Qualitative properties of the metal binding sites using the Mn2+-enzyme complex as a probe were ascertained using EPR at pH 6.8 and 8.0. CrATP and Mn2+ appear to bind to different metal sites on F1. The possible role of the metals in regulation of catalysis, and their relation to nucleotide binding is discussed.