Identification of Middle Chain Fatty Acyl-CoA Ligase Responsible for the Biosynthesis of 2-Alkylmalonyl-CoAs for Polyketide Extender Unit.

Understanding the biosynthetic mechanism of the atypical polyketide extender unit is important for the development of bioactive natural products. Reveromycin (RM) derivatives produced by Streptomyces sp. SN-593 possess several aliphatic extender units. Here, we studied the molecular basis of 2-alkylmalonyl-CoA formation by analyzing the revR and revS genes, which form a transcriptional unit with the revT gene, a crotonyl-CoA carboxylase/reductase homolog. We mainly focused on the uncharacterized adenylate-forming enzyme (RevS). revS gene disruption resulted in the reduction of all RM derivatives, whereas reintroduction of the gene restored the yield of RMs. Although RevS was classified in the fatty acyl-AMP ligase clade based on phylogenetic analysis, biochemical characterization revealed that the enzyme catalyzed the middle chain fatty acyl-CoA ligase (FACL) but not the fatty acyl-AMP ligase activity, suggesting the molecular evolution for acyl-CoA biosynthesis. Moreover, we examined the in vitro conversion of fatty acid into 2-alkylmalonyl-CoA using purified RevS and RevT. The coupling reaction showed efficient conversion of hexenoic acid into butylmalonyl-CoA. RevS efficiently catalyzed C8-C10 middle chain FACL activity; therefore, we speculated that the acyl-CoA precursor was truncated via ß-oxidation and converted into (E)-2-enoyl-CoA, a RevT substrate. To determine whether the ß-oxidation process is involved between the RevS and RevT reaction, we performed the feeding experiment using [1,2,3,4-(13)C]octanoic acid. (13)C NMR analysis clearly demonstrated incorporation of the [3,4-(13)C]octanoic acid moiety into the structure of RM-A. Our results provide insight into the role of uncharacterized RevS homologs that may catalyze middle chain FACL to produce a unique polyketide extender unit.

Engineered biosynthesis of 16-membered macrolides that require methoxymalonyl-ACP precursors in Streptomyces fradiae.

Development of host microorganisms for heterologous expression of polyketide synthases (PKS) that possess the intrinsic capacity to overproduce polyketides with a broad spectrum of precursors supports the current demand for new tools to create novel chemical structures by combinatorial engineering of modular and other classes of PKS. Streptomyces fradiae is an ideal host for development of generic polyketide-overproducing strains because it contains three of the most common precursors--malonyl-CoA, methylmalonyl-CoA and ethylmalonyl-CoA--used by modular PKS, and is a host that is amenable to genetic manipulation. We have expanded the utility of an overproducing S. fradiae strain for engineered biosynthesis of polyketides by engineering a biosynthetic pathway for methoxymalonyl-ACP, a fourth precursor used by many 16-membered macrolide PKS. This was achieved by introducing a set of five genes, fkbG-K from Streptomyces hygroscopicus, putatively encoding the methoxymalonyl-ACP biosynthetic pathway, into the S. fradiae chromosome. Heterologous expression of the midecamycin PKS genes in this strain resulted in 1 g/l production of a midecamycin analog. These results confirm the ability to engineer unusual precursor pathways to support high levels of polyketide production, and validate the use of S. fradiae for overproduction of 16-membered macrolides derived from heterologous PKS that require a broad range of precursors.

Covalent binding of chloroacetamide herbicides to the active site cysteine of plant type III polyketide synthases.

Chloroacetamide herbicides inhibit very-long-chain fatty acid elongase, and it has been suggested that covalent binding to the active site cysteine of the condensing enzyme is responsible [Pest Manage Sci 56 (2000), 497], but direct evidence was not available. The proposal implied that other condensing enzymes might also be targets, and therefore we have investigated four purified recombinant type III plant polyketide synthases. Chalcone synthase (CHS) revealed a high sensitivity to the chloroacetamide metazachlor, with 50% inhibition after a 10 min pre-incubation with 1-2 molecules per enzyme subunit, and the inactivation was irreversible. Stilbene synthase (STS) inactivation required 20-fold higher amounts, and 4-coumaroyltriacetic acid synthase and pyrone synthase revealed no response at the highest metazachlor concentrations tested. A similar spectrum of differential responses was detected with other herbicides that also inhibit fatty acid elongase (metolachlor and cafenstrole). The data indicate that type III polyketide synthases are potential targets of these herbicides, but each combination has to be investigated individually. The interaction of metazachlor with CHS was investigated by mass spectrometric peptide mapping, after incubation of the enzymes with the herbicides followed by tryptic digestion. A characteristic mass shift and MS/MS sequencing of the respective peptide showed that metazachlor was covalently bound to the cysteine of the active site, and the same was found with STS. This is the first direct evidence that the active site cysteine in condensing enzymes is the primary common target of these herbicides.

Subunit interactions in Propionibacterium shermanii methylmalonyl-CoA mutase studied by analytical ultracentrifugation.

The effect of increasing ionic strength on adenosylcobalamin-dependent methylmalonyl-CoA mutase from Propionibacterium shermanii was studied by using analytical ultracentrifugation. Both sedimentation-velocity and low-speed sedimentation-equilibration measurements show that the enzyme dissociates progressively into its two dissimilar subunits with increasing ionic strength. Equilibrium between the alpha beta-dimer and the separated subunits is rapidly established under these conditions. Dissociation is accompanied by loss of enzymic activity, but the position of the equilibrium is unaffected by the presence of either substrate or adenosylcobalamin cofactor.

Regulation of carbon and electron flow in Propionispira arboris: relationship of catabolic enzyme levels to carbon substrates fermented during propionate formation via the methylmalonyl coenzyme A pathway.

A detailed study of the glucose fermentation pathway and the modulation of catabolic oxidoreductase activities by energy sources (i.e., glucose versus lactate or fumarate) in Propionispira arboris was performed. 14C radiotracer data show the CO2 produced from pyruvate oxidation comes exclusively from the C-3 and C-4 positions of glucose. Significant specific activities of glyceraldehyde-3-phosphate dehydrogenase and fructose-1,6-bisphosphate aldolase were detected, which substantiates the utilization of the Embden-Meyerhoff-Parnas path for glucose metabolism. The methylmalonyl coenzyme A pathway for pyruvate reduction to propionate was established by detection of significant activities (greater than 16 nmol/min per mg of protein) of methylmalonyl coenzyme A transcarboxylase, malate dehydrogenase, and fumarate reductase in cell-free extracts and by 13C nuclear magnetic resonance spectroscopic demonstration of randomization of label from [2-13C]pyruvate into positions 2 and 3 of propionate. The specific activity of pyruvate-ferredoxin oxidoreductase, malate dehydrogenase, fumarate reductase, and transcarboxylase varied significantly in cells grown on different energy sources. D-Lactate dehydrogenase (non-NADH linked) was present in cells of P. arboris grown on lactate but not in cells grown on glucose or fumarate. These results indicate that growth substrates regulate synthesis of enzymes specific for the methylmalonyl coenzyme A path and initial substrate transformation.

Stereochemistry of the methylmalonyl-CoA decarboxylation reaction.

The steric course of the decarboxylation of (S)-methylmalonyl-CoA to propionyl-CoA, catalyzed by the biotin-dependent sodium pump methylmalonyl-CoA decarboxylase of Veillonella alcalescens was determined. The decarboxylation of (S)-methylmalonyl-CoA in 3H2O yielded (R)-[2-3H]propionyl-CoA; and the decarboxylation of (S)-[2-3H]methylmalonyl-CoA in H2O produced (S)-[2-3H]propionyl-CoA. The results demonstrate retention of configuration during the decarboxylation reaction. The substrate stereochemistry of methylmalonyl-CoA decarboxylase is thus the same as that of all other biotin-containing enzymes investigated.

Synthesis of methyl-branched fatty acids from methylmalonyl-CoA by fatty acid synthase from both the liver and the harderian gland of the guinea pig.

Partially purified fatty acid synthase preparations from both the liver and the harderian gland of guinea pig showed the same relative rates of utilization of methylmalonyl-CoA when compared to malonyl-CoA. Radio gas-liquid chromatographic analysis of the products generated from [methyl-14C]methylmalonyl-CoA and from [2-14C]malonyl-CoA in the presence of unlabeled methylmalonyl-CoA showed that the enzyme from both tissues generated identical mixtures of branched fatty acids. Therefore, it is concluded that the production of methyl-branched acids only by the harderian gland is not due to any unique specificity of the fatty acid synthase of this gland, in contrast to the conclusion reached from results obtained from mass spectrometry of the products generated by crude extracts (Y. Seyama, H. Otsuka, A. Kawaguchi, and T. Yamakawa J. Biochem. 90, 789-797, 1981).

Synthesis and NMR spectra of 13C-labeled coenzyme A esters.

The synthesis of coenzyme A thioesters of 13C-labeled acetate, propionate, succinate, and methyl malonate is described. The average yields were 94%. The 13C-NMR spectra were determined to provide a reference for the resonance positions of these metabolites. The synthesis of coenzyme thioesters of small-molecular-weight acids labeled with 13C has not been described previously, nor have the resonance positions been previously reported.

On the mechanism of action of methylmalonyl-CoA mutase. Change of the steric course on isotope substitution.

When (methyl-2H3)methylmalonyl-CoA was reacted with partially purified methylmalonyl-CoA mutase, 1H-NMR revealed that about 24% of the migrating deuterium was lost after 88% conversion. When [methyl-3H]methylmalonyl-CoA was incubated with highly purified methylmalonyl-CoA mutase, tritium exchange with the medium depended on added methylmalonyl-CoA epimerase. With highly purified preparations of methylmalonyl-CoA mutase, effective tritium exchange from [5'-3H]adenosylcobalamin to water required the addition of methylmalonyl-CoA epimerase and of substrate (e.g. succinyl-CoA). By addition of [14C]succinyl-CoA to a partially purified preparation of methylmalonyl-CoA mutase, it was shown that the mutase binds one substrate molecule very tightly. Coupling the mutase reaction with the transcarboxylase reaction and using variously labelled succinyl-CoA as substrate, revealed that only (2R)- and not (2S)-methylmalonyl-CoA will be formed by the mutase with a kinetic isotope effect of 3.5 using (2H4)succinyl-CoA. When (1-13C) propionyl-CoA was reacted with a mixture of highly purified methylmalonyl-CoA carboxylase, epimerase and mutase, 13C-NMR signals were obtained for the thioester carbonyl of succinyl-CoA (relative intensity 100%) and of methylmalonyl-CoA (5%) as well as for the carboxyl of free succinic acid (27%) and of succinyl-CoA (less than 4.5%). Thus very little, if any, migration of the CoA from one carboxyl to the other appears to take place. (1,4-13C2)Succinic acid and (1,4-13C2)succinyl-CoA were synthesised and their 13C-NMR chemical shifts were exactly determined. Evidence is provided for a strict stereospecificity of the mutase toward the (2R)-epimer of methylmalonyl-CoA and for an incomplete stereospecificity toward the two diastereotopic 3-H atoms of succinyl-CoA. The latter, combined with a high intramolecular isotope discrimination, causes rapid washing-out of the migrating 2H and 3H to water and slow washing-in from the medium. Whenever migration of protium from the sterically less preferred 3-pro(S)- position of succinyl-CoA occurs and simultaneously a heavy isotope is maneuvered from the migratable 3-pro(R)- position into the labile alpha-position of methylmalonyl-CoA, the substitution by the COSCoA group takes place with inversion of configuration. When the sterically preferred 3-pro(R)-hydrogen atom migrates, the previously reported stereochemical retention occurs. A mechanistic and stereochemical scheme is discussed that fully accounts for all observations.

Fatty acid biosynthesis in Mycobacterium tuberculosis var. bovis Bacillus Calmette-Guérin. Purification and characterization of a novel fatty acid synthase, mycocerosic acid synthase, which elongates n-fatty acyl-CoA with methylmalonyl-CoA.

A crude extract from Mycobacterium tuberculosis var. bovis Bacillus Calmette-Guérin was previously shown to incorporate methylmalonyl-CoA into mycocerosic acids, exemplified by 2,4,6,8-tetramethyloctacosanoic acid, and malonyl-CoA into n-fatty acids (Rainwater D. L., and Kolattukudy, P. E. (1983) J. Biol. Chem. 258, 2979-2985). The presence of several fatty acid synthases with differences in substrate preference and product chain length was detected in the crude extract of M. tuberculosis var. bovis. Among them was a mycocerosic acid synthase which was purified to homogeneity using anion-exchange chromatography, gel filtration, affinity chromatography, and hydroxylapatite chromatography. This fatty acid synthase elongated long-chain fatty acyl-CoA primers using methylmalonyl-CoA and NADPH to produce multimethyl-branched mycocerosic acids. The enzyme was specific for methylmalonyl-CoA and would not incorporate malonyl-CoA into fatty acids. It elongated n-C6 to n-C20 CoA esters to generate primarily the corresponding tetramethyl-branched mycocerosic acids. Exogenous [1-14C]acyl-CoA and trideuteromethylmalonyl-CoA were incorporated into the multimethyl-branched fatty acids. Dodecyl sulfate electrophoresis showed that the enzyme had a molecular weight of 238,000, whereas gel filtration showed a native molecular weight of 490,000, indicating that the enzyme is composed of two monomers of identical molecular weight. The enzyme contained an acyl carrier protein-like segment as indicated by incorporation of [1-14C] pantothenate into the 238-kDa protein and production of 1 mol of taurine/mol of the monomer upon hydrolysis of performic acid-oxidized enzyme. It is concluded that the mycocerosic acid synthase is a multifunctional enzyme similar to the well-characterized multifunctional fatty acid synthases except for the substrate specificity.

Nicotinic acid metabolism. Dimethylmaleate hydratase.

The partial enrichment of a new enzyme, dimethylmaleate hydratase from Clostridium barkeri and some of its characteristics are described. The unstable and oxygen-sensitive hydratase depends on ferrous ions and is induced during growth of C. barkeri on nicotinic acid. The enzyme uses both dimethylmaleate and the hydration product, 2,3-dimethylmalate, as substrates to establish an equilibrium that is 70% in favour of the latter acid; dimethylfumarate is not attacked. A 2,3-dimethyl[3-3H]malate specimen was prepared from dimethylmaleate with the hydratase in tritiated water. Based on proton attack at the re-face of the double bond, experimental results indicate the (2R,3S)-configuration for this malate. The hydration reaction takes an anti-course. The tritium label was lost in the sequence (2R,3S)-2,3-dimethyl[3-3H]malate----(R)-[2-3H1]-propionate----(2R) - [2-3H1]propionyl-CoA----(2S)-methylmalonyl-CoA. This result confirms the stereochemical course of the 2,3-dimethylmalate lyase reaction, inversion of configuration, by an independent approach. The hydratase reaction completes the degradation scheme of nicotinic acid by C. barkeri. The pathway is briefly reviewed.

Source of methylmalonyl-coenzyme A for erythromycin synthesis: methylmalonyl-coenzyme A mutase from Streptomyces erythreus.

Streptomyces erythreus produces erythromycin, presumably from methylmalonyl-coenzyme A (CoA), which could be generated by the isomerization of succinyl-CoA. In S. erythreus cultures, [1,4-14C,2,3-3H]succinate was incorporated into erythromycin with a doubling of the 3H/14C ratio. This result is consistent with the hypothesis that succinyl-CoA is isomerized to methylmalonyl-CoA before incorporation into the macrocyclic lactone of erythromycin. The presence of methylmalonyl-CoA mutase, which catalyzes this isomerization, was demonstrated in cell-free extracts prepared from this organism. Consistent with the suggested role for this enzyme, methylmalonyl-CoA mutase activity increased over 12-fold at the time of the most rapid antibiotic production, and the activity level drastically declined when the antibiotic production ceased. The mutase was partially purified from this organism with DEAE-cellulose, ammonium sulfate precipitation, and affinity chromatography on a B12-coenzyme Sepharose column. The enzyme was stimulated 2.5-fold by the addition of B12-coenzyme. The enzyme showed a typical Michaelis-Menten type substrate saturation patterns, with KmS of 0.31 mM and 0.09 microM for methylmalonyl-CoA and B12-coenzyme, respectively, and a V of 0.5 mumol/min per mg. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of the purified enzyme showed a major band with a molecular weight of 63,000. The properties of this enzyme appear to be fairly similar to those of the mutase previously obtained from other sources.

Inhibition in vitro of lipogenic enzymes from bovine (Bos taurus) mammary tissue by methylmalonyl-coenzyme A and coenzyme A.

Bovine mammary fatty acid synthetase was inhibited by approximately 50% by 40 microM methylmalonyl-CoA; this inhibition was competitive with respect to malonyl-CoA (apparent Ki = 11 microM). Similarly, 6.25 microM coenzyme A inhibited the synthetase by 35% and this inhibition was again competitive (apparent Ki = 1.7 microM). Apparent Km for malonyl-CoA was 29 microM. The short-chain dicarboxylic acids malonic, methylmalonic and ethylmalonic at high concentrations (160-320 microM) and ATP (5 mM) enhanced the synthetase activity by about 50% respectively; the activating effects of methylmalonic acid and ATP on the synthetase were additive. Methylmalonyl-CoA at 50 microM concentration inhibited the partially purified acetyl-CoA carboxylase uncompetitively by 10% and the propionyl-CoA carboxylase activity of the enzyme preparation competitively (apparent Ki = 21 microM) by 40%. Malonyl-CoA also inhibited the acetyl-CoA carboxylase activity competitively (apparent Ki = 7 microM) by 35% and the propionyl-CoA carboxylating activity of the preparation competitively (apparent Ki = 4 microM) by 82%. The possibility that methylmalonyl-CoA may be a causal factor in the aetiology of the low milk-fat syndrome in high yielding dairy cows is discussed.

Proton transfer in methylmalonyl-CoA epimerase from Propionibacterium shermanii. Studies with specifically tritiated (2R)-methylmalonyl-CoA as substrate.

(2R)-Methyl[2-3H]malonyl-CoA was used as the substrate for methylmalonyl-CoA epimerase from Propionibacterium shermanii, under conditions where the (2S)-methylmalonyl-CoA product was removed enzymically as fast as it was formed, and the fate of the label was monitored at different extents of reaction. Very little, if any, tritium is found attached to the C-2 position in the (2S)-epimer product (isolated as propionyl-CoA). Evidently, the hydrogen atom of the new C-H bond in the product is essentially solvent-derived. The rate of tritium release into the solvent is lower than the rate of product formation, and shows a primary kinetic tritium-isotope effect on kcat./Km of 2.3 +/- 0.1. The specific radioactivity of the remaining substrate rises slowly during the epimerase-catalysed reaction, and this provides an independent estimate of the primary kinetic tritium-isotope effect on kcat./Km of 1.6 +/- 0.5. These results, taken together, indicate that the mechanistic pathway of the epimerase-catalysed reaction resembles that established for proline racemase [Cardinale & Abeles, (1968) Biochemistry 7, 3970-3978], in which two enzyme bases are involved in catalysis. One base removes the proton from the substrate, the second provides the new proton, and there is no fast isotopic exchange between enzyme-bound intermediates and solvent protons.

Proton transfer in methylmalonyl-CoA epimerase from Propionibacterium shermanii. The reaction of (2R)-methylmalonyl-CoA in tritiated water.

The reaction catalysed by methylmalonyl-CoA epimerase from Propionibacterium shermanii was studied in tritiated water, in the direction with (2R)-methylmalonyl-CoA as substrate, under 'irreversible' conditions. After partial reaction, even when most of the substrate had been converted into product (isolated as propionyl-CoA) essentially no solvent tritium appeared in residual (2R)-methylmalonyl-CoA. The product, however, did contain tritium, and the specific radioactivity of the (2S)-epimer was deduced to be 0.33 times that of the solvent. These results provide further support for the mechanism proposed for the epimerase-catalysed reaction in the accompanying paper [Leadlay & Fuller (1983) Biochem. J. 213, 635-642], in which two enzyme bases act respectively as proton donor and acceptor. The observed low discrimination against solvent tritium entering the product can be accounted for by a mechanism in which the release of product is slow, and the re-protonation step on the enzyme is reversible, without leading to isotopic exchange with the solvent.

Recognition, isolation, and characterization of rat liver D-methylmalonyl coenzyme A hydrolase.

Certain amino acids and other compounds are metabolized via: Propionyl-CoA carboxylase in equilibrium D-methylmalonyl-CoA racemase in equilibrium L-methylmalonyl-CoA (adenosylcobalamin) mutase in equilibrium succinyl-CoA in equilibrium tricarboxylic acid cycle. In cobalamin deficiency and in genetic disorders involving adenosylcobalamin or the mutase, large amounts of methylmalonic acid are excreted in the urine. Its origin is unknown, however, since nonesterified methylmalonic acid is not present in the above or other known pathways. To investigate the origin of methylmalonic acid, we fractionated rat liver by gel filtration and found a single peak (Mr = 35,000) of activity for the hydrolysis of DL-methylmalonyl-CoA to methylmalonic acid and CoA. The enzyme has been purified 3,100-fold with a yield of 2.1% from 1.6 kg of rat liver using a purification scheme consisting of ammonium sulfate fractionation, ion exchange chromatography on CM (carboxymethyl)-cellulose and DEAE-cellulose, affinity chromatography on CoA-agarose, and gel filtration on Sephadex G-100. The final preparation gave a single band on polyacrylamide gel electrophoresis. The molecular weight of the purified enzyme is 35,000 based on gel filtration, and sodium dodecyl sulfate-polyacrylamide electrophoresis in the presence and absence of 1% 2-mercaptoethanol. The enzyme was shown to be active on the D-isomer, but not on the L-isomer, of methylmalonyl-CoA by CD spectropolarimetry. The Km for D-methylmalonyl-CoA is 0.7 mM and the molar activity is 1,400 molecules of substrate/min/molecule of enzyme. At substrate concentrations of 0.5 mM, the relative rate of hydrolysis of CoA esters was as follows: D-methylmalonyl-CoA (100%), malonyl-CoA (16%), propionyl-CoA (3%), acetyl-CoA (1%), succinyl-CoA (less than 1%), and palmitoyl-CoA (less than 1%). This enzyme appears to account for the markedly increased amounts of methylmalonic acid that are excreted in the urine in cobalamin deficiency and in genetic disorders involving adenosylcobalamin or L-methylmalonyl-CoA mutase.