Metabolic fate of cyanocobalamin taken up by Spirometra mansonoides spargana.

Analysis of tissue from Spirometra mansonoides spargana has shown that cyanocobalamin (vitamin B12) is metabolized to adenosylcobalamin and hydroxocobalamin. No methylcobalamin was detected. When the tissues were examined for enzymes which are known to utilize coenzyme forms of vitamin B12, only methylmalonyl CoA mutase, which requires adenosylcobalamin was found. The enzyme, tetrahydropteroylglutamate methyltransferase, which requires methylcobalamin as a cofactor, was not detected. A sizable portion of the cyanocobalamin taken up was bound to ammonium sulfate-precipitable material, suggesting that the binding substance is a protein. Vitamin B12 taken up by spargana was found to be released in vivo with a biological half-life of about 7 weeks.     

Investigating the role of native propionyl‐CoA and methylmalonyl‐CoA metabolism on heterologous polyketide production in Escherichia coli

6‐Deoxyerythronolide B (6dEB) is the macrocyclic aglycone precursor of the antibiotic natural product erythromycin. Heterologous production of 6dEB in Escherichia coli was accomplished, in part, by designed over‐expression of a native prpE gene (encoding a propionyl‐CoA synthetase) and heterologous pcc genes (encoding a propionyl‐CoA carboxylase) to supply the needed propionyl‐CoA and (2S)‐methylmalonyl‐CoA biosynthetic substrates. Separate E. coli metabolism includes three enzymes, Sbm (a methylmalonyl‐CoA mutase), YgfG (a methylmalonyl‐CoA decarboxylase), and YgfH (a propionyl‐CoA:succinate CoA transferase), also involved in propionyl‐CoA and methylmalonyl‐CoA metabolism. In this study, the sbm, ygfG, and ygfH genes were individually deleted and over‐expressed to investigate their effect on heterologous 6dEB production. Our results indicate that the deletion and over‐expression of sbm did not influence 6dEB production; ygfG over‐expression reduced 6dEB production by fourfold while ygfH deletion increased 6dEB titers from 65 to 129 mg/L in shake flask experiments. It was also found that native E. coli metabolism could support 6dEB biosynthesis in the absence of exogenous propionate and the substrate provision pcc genes. Lastly, the effect of the ygfH deletion was tested in batch bioreactor cultures in which 6dEB titers improved from 206 to 527 mg/L. Biotechnol. Bioeng. 2010; 105: 567–573. © 2009 Wiley Periodicals, Inc.     

Interactions of methylmalonyl CoA mutase from normal human fibroblasts with adenosylcobalamin and methylmalonyl CoA: evidence for non-equivalent active sites

We have examined interactions between human methylmalonyl CoA mutase and two critical ligands, its cofactor adenosylcobalamin (AdoCbl) and its substrate methylmalonyl CoA, by performing in vitro experiments with preparations of mutase apoenzyme and holoenzyme from normal cultured human fibroblasts. When extracts are prepared from cells grown in medium containing high concentrations of hydroxocobalamin, a precursor of AdoCbl, mutase activity measured in Tris-containing buffers in the absence of added AdoCbl accounts maximally for only 50% of that activity measured in the presence of excess AdoCbl. A similar result is observed when mutase holoenzyme is formed in vitro by incubating cell extracts containing apoenzyme with AdoCbl and removing excess AdoCbl by gel filtration. When such holoenzyme preparations are heated at 45 °C and then assayed for activity, their thermostability is less than that of mutase holoenzyme heated in the presence of excess cofactor, but far greater than that of mutase apoenzyme. Methylmalonyl CoA modulates these enzyme-coenzyme interactions, since mutase holoenzyme formed in Triscontaining buffers is resolved to apoenzyme upon exposure to substrate. Qualitatively different data are obtained when buffers containing cations other than Tris are used. Under these conditions, mutase activity measured in the absence of added AdoCbl accounts for nearly 100% of the activity measured in the presence of excess cofactor, whether holoenzyme is formed in intact cells in culture or in cell extracts in vitro. Furthermore, holoenzyme formed in vitro in potassium phosphate buffer is not resolved to apoenzyme upon exposure to substrate. We suggest that the “holoenzyme” form of mutase obtained and assayed in Tris-containing buffers is that molecular species with only one of its two potential AdoCbl binding sites occupied in a catalytically active fashion, and that other ions can influence markedly the interactions between mutase, AdoCbl, and methylmalonyl CoA. These data are consistent, therefore, with the hypothesis that the dimeric mutase apoenzyme is characterized, under certain conditions, by nonequivalent active sites.     

Cloning of functional alpha propionyl CoA carboxylase and correction of enzyme deficiency in pccA fibroblasts.

Propionyl CoA carboxylase (PPC) is a heteromeric enzyme composed of alpha subunits (PCCA) and beta (PCCB) subunits. We describe cDNA clones expressing human PCCA and complementation of the genetic defect in pccA fibroblasts by DNA-mediated gene transfer. Two cDNA clones were constructed. The first corresponds to the previously reported, putatively full-length, open reading frame. The second encodes a chimera composed of the mitochondrial leader sequence of human methylmalonyl CoA mutase and the mature PCCA protein. Both clones reconstitute propionate flux to normal levels in fibroblasts from patients genetically deficient in PCCA (pccA). The maximal level of propionate flux approached, but never exceeded, the levels seen in control plates of normal cells. In contrast, the maximal level of PPC holoenzyme activity reached only 10%-20% that of normal controls, which corresponded roughly to the fraction of cells actually transformed with the recombinant gene. These data suggest that the level of PCCA expression in fibroblasts does not normally limit PCC holoenzyme activity or propionate flux. The fact that a small fraction of cells reconstitutes propionate flux to normal levels suggests that metabolic cooperation between cells is capable of increasing the metabolic capacity of recombinant enzyme in a subpopulation of cells. These factors may have important implications for the rational design of somatic gene therapy for PCCA deficiency.     

Localization of the murine methylmalonyl CoA mutase (Mut) locus on chromosome 17 by in situ hybridization

Murine methylmalonyl CoA mutase (Mut) has been localized to chromosome 17C-D by in situ hybridization in cell line containing a 2.17 Robertsonian translocation. This locus, which was mapped with the help of a murine methylmalonyl CoA mutase cDNA probe, and others on murine chromosome 17 are syntenic, though not necessarily colinear, with loci on human chromosome 6.     

Discovering new enzymes and metabolic pathways: conversion of succinate to propionate by Escherichia coli

The Escherichia coli genome encodes seven paralogues of the crotonase (enoyl CoA hydratase) superfamily. Four of these have unknown or uncertain functions; their existence was unknown prior to the completion of the E. coli genome sequencing project. The gene encoding one of these, YgfG, is located in a four-gene operon that encodes homologues of methylmalonyl CoA mutases (Sbm) and acyl CoA transferases (YgfH) as well as a putative protein kinase (YgfD/ArgK). We have determined that YgfG is methylmalonyl CoA decarboxylase, YgfH is propionyl CoA:succinate CoA transferase, and Sbm is methylmalonyl CoA mutase. These reactions are sufficient to form a metabolic cycle by which E. coli can catalyze the decarboxylation of succinate to propionate, although the metabolic context of this cycle is unknown. The identification of YgfG as methylmalonyl CoA decarboxylase expands the range of reactions catalyzed by members of the crotonase superfamily.     

Separation and functions of two acyl CoA transferases from Ascaris lumbricoides mitochondria

Many invertebrates accumulate propionate, or products derived from propionate, as products of fermentation. Evidence has been reported that the nematode, Ascaris suum, the cestode, Spirometra mansonoides, and the trematode, Fasciola hepatica, accumulate propionate by means of an adenosine triphosphate (ATP)-generating decarboxylation of succinate. To generate energy, an acyl coenzyme A (CoA) transferase that would transfer CoA to succinate is required as one component of the sequence of reactions. Recently, an acyl CoA transferase was isolated from Ascaris mitochondria and purified to electrophoretic homogeneity. However, upon examination of the substrate specificities of this enzyme, it was found essentially to lack the ability to use succinate or succinyl CoA as an acceptor or donor of CoA, respectively. Therefore, this transferase could not serve to activate succinate. This article describes the isolation of an additional acyl CoA transferase from Ascaris mitochondria that appears to be unique in its substrate specificity and that could easily account not only for the activation of succinate but also for the regulation of succinate metabolism primarily in the direction of decarboxylation to propionate. This is in contrast with mammalian tissues, which act in the opposite direction by catalyzing the fixation of CO2 into propionate, thereby forming succinate and accounting for the glycogenic nature of dietary propionate. Possible functions of the two acyl CoA transferases are discussed.     

Is there methylmalonyl CoA mutase in Aspergillus nidulans?

In most animal species and many prokaryotes, methylmalonyl CoA mutase catalyzes isomerization between methylmalonyl CoA and succinyl CoA using adenosylcobalamin as a cofactor. We describe the absence of this enzyme in Aspergillus nidulans based on the absence of enzyme activity in vitro and the failure to metabolize methylmalonate or grow in media containing this organic acid as the sole carbon source. These data contrast previous assumptions that propionate may be metabolized through propionyl CoA and methylmalonyl CoA to the TCA cycle in this organism. This is consistent with the separate evolution of these pathways in animals and lower eukaryotes due to the distinct endosymbiotic origin of their mitochondria.     

Functional characterization of a vitamin B12-dependent methylmalonyl pathway in Mycobacterium tuberculosis: implications for propionate metabolism during growth on fatty acids

Mycobacterium tuberculosis is predicted to subsist on alternative carbon sources during persistence within the human host. Catabolism of odd- and branched-chain fatty acids, branched-chain amino acids, and cholesterol generates propionyl-coenzyme A (CoA) as a terminal, three-carbon (C(3)) product. Propionate constitutes a key precursor in lipid biosynthesis but is toxic if accumulated, potentially implicating its metabolism in M. tuberculosis pathogenesis. In addition to the well-characterized methylcitrate cycle, the M. tuberculosis genome contains a complete methylmalonyl pathway, including a mutAB-encoded methylmalonyl-CoA mutase (MCM) that requires a vitamin B(12)-derived cofactor for activity. Here, we demonstrate the ability of M. tuberculosis to utilize propionate as the sole carbon source in the absence of a functional methylcitrate cycle, provided that vitamin B(12) is supplied exogenously. We show that this ability is dependent on mutAB and, furthermore, that an active methylmalonyl pathway allows the bypass of the glyoxylate cycle during growth on propionate in vitro. Importantly, although the glyoxylate and methylcitrate cycles supported robust growth of M. tuberculosis on the C(17) fatty acid heptadecanoate, growth on valerate (C(5)) was significantly enhanced through vitamin B(12) supplementation. Moreover, both wild-type and methylcitrate cycle mutant strains grew on B(12)-supplemented valerate in the presence of 3-nitropropionate, an inhibitor of the glyoxylate cycle enzyme isocitrate lyase, indicating an anaplerotic role for the methylmalonyl pathway. The demonstrated functionality of MCM reinforces the potential relevance of vitamin B(12) to mycobacterial pathogenesis and suggests that vitamin B(12) availability in vivo might resolve the paradoxical dispensability of the methylcitrate cycle for the growth and persistence of M. tuberculosis in mice.     

Essential arginine residues in the active sites of propionyl CoA carboxylase and beta-methylcrotonyl CoA carboxylase

At least one arginine residue is essential for substrate binding in or near the active sites of propionyl CoA carboxylase (PCC) and beta-methylcrotonyl CoA carboxylase (beta MCC) in cultured human fibroblasts. This conclusion is based on studies of enzyme inhibition by phenylglyoxal, a reagent which specifically modifies arginine residues. Human fibroblast PCC both in extracts and in a 20-fold purified preparation was nearly completely protected from phenylglyoxal inhibition following incubation with propionyl CoA or ATP. It appears that a phosphate group from either ATP or the CoA moiety of propionyl CoA reacts with the essential arginine residue(s). beta MCC which was similarly inhibited by phenylglyoxal was protected by beta-methylcrotonyl CoA and ATP. Thus phenylglyoxal may be used to label specific arginine residues within the active sites of previously sequenced carboxylases.     

Metabolic effects of propionate in normal and vitamin B12-deficient rats

1. Administration of propionate caused a twofold increase in the concentrations of lactate and pyruvate in the blood of vitamin B(12)-deficient rats, whereas there was a slight decrease in lactate and a 50% increase in pyruvate in normal rats. 2. Concentrations of total ketone bodies in the blood of normal rats were not significantly altered by propionate administration but the [3-hydroxybutyrate]/[acetoacetate] ratio decreased from 3.0 to 2.0. In the vitamin B(12)-deficient rats there was a 40% decrease in total ketone bodies and a change in the ratio from 3.4 to 1.2. 3. The changes in the concentration of ketone bodies in freeze-clamped liver preparations were similar in pattern to those observed in blood. 4. Propionate administration caused a decrease in the concentration of acetyl-CoA in the livers of both groups of animals, but the absolute decrease was greater in the vitamin B(12)-deficient group. The decrease in the concentration of CoA was similar in both groups. 5. As in blood, there were threefold increases in the concentrations of lactate and pyruvate in the livers of the vitamin B(12)-deficient rats after propionate administration, whereas there was no significant change in the concentrations of these metabolites in the normal rats. 6. There was a 50% inhibition of glucose synthesis in perfused livers from vitamin B(12)-deficient rats when lactate and propionate were substrates as compared with lactate alone. 7. It is concluded that the conversion of lactate into glucose is inhibited in vitamin B(12)-deficient rats after propionate administration, and that this effect is due to inhibition of the pyruvate carboxylase step resulting from a decrease in acetyl-CoA concentration and a postulated increase in methylmalonyl-CoA concentration.     

Inborn errors of cobalamin metabolism: Effect of cobalamin supplementation in culture on methylmalonyl CoA mutase activity in normal and mutant human fibroblasts

We have examined the effect of addition of hydroxocobalamin to growth medium on the activity of the adenosylcobalamin-requiring enzyme methylmalonyl CoA mutase in normal human fibroblasts and in mutant human fibroblasts derived from patients with inherited methylmalonicacidemia. The mutant cell lines were assigned to four distinct genetic complementation groups (cbl A, cbl B, cbl C, and cbl D), each deficient in some step in the synthesis of adenosylcobalamin from hydroxocobalamin. After control cells were grown in cobalamin-supplemented medium, mutase holoenzyme activity increased markedly in a time- and concentration-dependent fashion. Growth in cobalamin-supplemented medium had no effect on mutase activity in some mutant lines belonging to the cbl B group, while activity increased severalfold in other cbl B mutants and in all cbl A, cbl C, and cbl D mutants examined, although mutase activity was still <10% of control. Comparison of mutase holoenzyme activity and total propionate pathway activity suggests that enhancement of mutase activity in mutant cells after cobalamin supplementation to values 5–10% of control may be sufficient to overcome the inherited metabolic block and to restore total pathway activity to normal.This work was supported in part by a research grant from the National Institutes of Health (AM 12579). H. F. W. is a recipient of a traineeship from the National Institutes of Health (T01-GM02299).     

地中海拟无枝菌酸菌U32染色体特性的脉冲场电泳分析

地中海拟无枝菌酸菌(Amycolatopsis mediterranei)U32是产力复霉素SV的工业生产菌株。采用脉冲场电泳分析发现,地中海拟无枝菌酸菌U32仅有一条约10 Mb的线性染色体, 没有内源性质粒。利用Southern杂交法,对11个编码力复霉素生物合成、相关初级、次级代谢关键酶以及调控蛋白的基因,在U32染色体DNA的PshBI酶切片段上进行了定位。分析发现在一条长度约700kb的PshBI酶切片段上,分别存在着力复霉素合成基因簇(rif)、氮代谢的亚硝酸还原酶小亚基基因(nasD)、衔接初级与次级代谢的甲基丙二酰变位酶基因(mcm)、脂肪酸代谢的乙酰辅酶A羧化酶生物素载体蛋白基因(accA)以及一套核糖体RNA转录单元。同时还发现U32至少有5套核糖体RNA转录单元。其余定位的基因均只出现单一杂交信号。     

Heterozygous mutations at the mut locus in fibroblasts with mut0 methylmalonic acidemia identified by polymerase-chain-reaction cDNA cloning.

Genetic defects in the enzyme methylmalonyl CoA mutase cause a disorder of organic acid metabolism termed "mut methylmalonic acidemia." Various phenotypes of mut methylmalonic acidemia are distinguished by the presence (mut-) or absence (mut0) of residual enzyme activity. The recent cloning and sequencing of a cDNA for human methylmalonyl CoA mutase enables molecular characterization of mutations underlying mut phenotypes. We identified compound heterozygous mutations in a mut0 fibroblast cell (MAS) line by cloning the methylmalonyl CoA mutase cDNA by using the polymerase chain reaction (PCR), sequencing with internal primers, and confirming the pathogenicity of observed mutations by DNA-mediated gene transfer. Both mutations alter amino acids common to the normal human, mouse, and Propionibacterium shermanii enzymes. This analysis points to evolutionarily preserved determinants critical for enzyme structure or function. The application and limitation of cDNA cloning by PCR for the identification of mutations are discussed.     

Pathway of Succinate and Propionate Formation in Bacteroides fragilis

Cell suspensions of Bacteroides fragilis were allowed to ferment glucose and lactate labeled with (14)C in different positions. The fermentation products, propionate and acetate, were isolated, and the distribution of radioactivity was determined. An analysis of key enzymes of possible pathways was also made. The results of the labeling experiments showed that: (i) B. fragilis ferments glucose via the Embden-Meyerhof pathway; and (ii) there was a randomization of carbons 1, 2, and 6 of glucose during conversion to propionate, which is in accordance with propionate formation via fumarate and succinate. The enzymes 6-phosphofrucktokinase (pyrophosphate-dependent), fructose-1,6-diphosphate aldolase, phosphoenolpyruvate carboxykinase, malate dehydrogenase, fumarate reductase, and methylmalonyl-coenzyme A mutase could be demonstrated in cell extracts. Their presence supported the labeling results and suggested that propionate is formed from succinate via succinyl-, methylmalonyl-, and propionyl-coenzyme A. From the results it also is clear that CO(2) is necessary for growth because it is needed for the formation of C4 acids. There was also a randomization of carbons 1, 2, and 6 of glucose during conversion to acetate, which indicated that pyruvate kinase played a minor role in pyruvate formation from phosphoenolpyruvate. Phosphoenolpyruvate carboxykinase, oxaloacetate decarboxylase, and malic enzyme (nicotinamide adenine dinucleotide phosphate-dependent) were present in cell extracts of B. fragilis, and the results of the labeling experiments agreed with pyruvate synthesis via oxaloacetate and malate if these acids are in equilibrium with fumarate. The conversion of [2-(14)C]- and [3-(14)C]lactate to acetate was not associated with a randomization of radioactivity.     

Comparative aspects of propionate metabolism

1. The catabolism of propionate has been studied extensively in vertebrates and the major pathway has been shown to be its derivatization to propionyl-CoA, carboxylation to D-methylmalonyl-CoA, isomerization to L-methylmalonyl-CoA and then conversion to succinyl-CoA via a vitamin B12 dependent methylmalonyl-CoA mutase. 2. By contrast, in all insect species studied to date, many of which do not contain detectable levels of vitamin B12, the major metabolic pathway of propionate is its conversion to 3-hydroxypropionate and then to acetate. Carbon-3 of propionate becomes the carboxyl carbon of acetate and carbon-2 of propionate becomes the methyl carbon of acetate. 3. A number of species of non-insect arthropods and other invertebrates contain relatively high levels of vitamin B12 and catabolize propionate by the same pathway as that of vertebrates. Under anoxic conditions, some invertebrates, including bivalves, convert succinate to propionate. 4. In plants, evidence has been presented for the metabolism of propionate to both acetate and succinate. Micro-organisms possess a myriad of pathways by which they produce and catabolize propionate.     

Sequential changes in plasma methylmalonic acid and vitamin B12 in sheep eating cobalt-deficient grass

Methylmalonic acid (MMA) concentrations are elevated in plasma as a result of vitamin B12 deficiency. This study reports the sequential changes in plasma MMA in lambs maintained on a cobalt-deficient pasture compared with supplemented controls. The results indicate that MMA is elevated in the early stages of deficiency, preceding the onset of loss of production and clinical signs of disease. It remains elevated as long as the lambs are unsupplemented with cobalt (Co). The most striking clinical sign was a loss of body condition as opposed to weight. The defect in the methylmalonyl CoA mutase is obviously an early defect in cobalt deficiency.     

Insertional Inactivation of Methylmalonyl Coenzyme A (CoA) Mutase and Isobutyryl-CoA Mutase Genes in Streptomyces cinnamonensis: Influence on Polyketide Antibiotic Biosynthesis

The coenzyme B(12)-dependent isobutyryl coenzyme A (CoA) mutase (ICM) and methylmalonyl-CoA mutase (MCM) catalyze the isomerization of n-butyryl-CoA to isobutyryl-CoA and of methylmalonyl-CoA to succinyl-CoA, respectively. The influence that both mutases have on the conversion of n- and isobutyryl-CoA to methylmalonyl-CoA and the use of the latter in polyketide biosynthesis have been investigated with the polyether antibiotic (monensin) producer Streptomyces cinnamonensis. Mutants prepared by inserting a hygromycin resistance gene (hygB) into either icmA or mutB, encoding the large subunits of ICM and MCM, respectively, have been characterized. The icmA::hygB mutant was unable to grow on valine or isobutyrate as the sole carbon source but grew normally on butyrate, indicating a key role for ICM in valine and isobutyrate metabolism in minimal medium. The mutB::hygB mutant was unable to grow on propionate and grew only weakly on butyrate and isobutyrate as sole carbon sources. (13)C-labeling experiments show that in both mutants butyrate and acetoacetate may be incorporated into the propionate units in monensin A without cleavage to acetate units. Hence, n-butyryl-CoA may be converted into methylmalonyl-CoA through a carbon skeleton rearrangement for which neither ICM nor MCM alone is essential.     

Syntrophobacter pfennigii sp. nov., new syntrophically propionate-oxidizing anaerobe growing in pure culture with propionate and sulfate

A new strain of syntrophically propionate-oxidizing fermenting bacteria, strain KoProp1, was isolated from anoxic sludge of a municipal sewage plant. It oxidized propionate or lactate in cooperation with the hydrogen- and formate-utilizingMethanospirillum hungatei and grew as well in pure culture without a syntrophic partner with propionate or lactate plus sulfate as energy source. In all cases, the substrates were oxidized stoichiometrically to acetate and CO₂, with concomitant formation of methane or sulfide. Cells formed gas vesicles in the late growth phase and contained cytochromesb andc, a menaquinone-7, and desulforubidin, but no desulfoviridin. Enzyme measurements in cell-free extracts indicated that propionate was oxidized through the methylmalonyl CoA pathway. Protein pattern analysis by SDS-PAGE of cell-free extracts showed that strain KoProp1 differs significantly fromSyntrophobacter wolinii and from the propionate-oxidizing sulfate reducerDesulfobulbus propionicus. 16S rRNA sequence analysis revealed a significant resemblance toS. wolinii allowing the assignment of strain KoProp1 to the genusSyntrophobacter as a new species,S. pfennigii.