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.     

High-level heterologous production of propionate in engineered Escherichia coli

A propanologenic (i.e., 1-propanol-producing) bacterium Escherichia coli strain was previously derived by activating the genomic sleeping beauty mutase (Sbm) operon. The activated Sbm pathway branches out of the tricarboxylic acid (TCA) cycle at the succinyl-CoA node to form propionyl-CoA and its derived metabolites of 1-propanol and propionate. In this study, we targeted several TCA cycle genes encoding enzymes near the succinyl-CoA node for genetic manipulation to identify the individual contribution of the carbon flux into the Sbm pathway from the three TCA metabolic routes, that is, oxidative TCA cycle, reductive TCA branch, and glyoxylate shunt. For the control strain CPC-Sbm, in which propionate biosynthesis occurred under relatively anaerobic conditions, the carbon flux into the Sbm pathway was primarily derived from the reductive TCA branch, and both succinate availability and the SucCD-mediated interconversion of succinate/succinyl-CoA were critical for such carbon flux redirection. Although the oxidative TCA cycle normally had a minimal contribution to the carbon flux redirection, the glyoxylate shunt could be an alternative and effective carbon flux contributor under aerobic conditions. With mechanistic understanding of such carbon flux redirection, metabolic strategies based on blocking the oxidative TCA cycle (via ∆sdhA mutation) and deregulating the glyoxylate shunt (via ∆iclR mutation) were developed to enhance the carbon flux redirection and therefore propionate biosynthesis, achieving a high propionate titer of 30.9 g/L with an overall propionate yield of 49.7% upon fed-batch cultivation of the double mutant strain CPC-Sbm∆sdhA∆iclR under aerobic conditions. The results also suggest that the Sbm pathway could be metabolically active under both aerobic and anaerobic conditions.     

Phosphonate biosynthesis: molecular cloning of the gene for phosphoenolpyruvate mutase from Tetrahymena pyriformis and overexpression of the gene product in Escherichia coli.

The phosphoenolpyruvate mutase gene from Tetrahymena pyriformis has been cloned and overexpressed in Escherichia coli. To our knowledge, this is the first Tetrahymena gene to be expressed in E. coli, a task made more complicated by the idiosyncratic codon usage by Tetrahymena. The N-terminal amino acid sequence of phosphoenolpyruvate mutase purified from T. pyriformis has been used to generate a precise oligonucleotide probe for the gene, using in vitro amplification from total genomic DNA by the polymerase chain reaction. Use of this precise probe and oligo(T) as primers for in vitro amplification from a T. pyriformis cDNA library has allowed the cloning of the mutase gene. A similar amplification strategy from genomic DNA yielded the genomic sequence, which contains three introns. The sequence of the DNA that encodes 10 amino acids upstream of the N-terminal sequence of the isolated protein was found by oligonucleotide hybridization to a subgenomic library. These 10 N-terminal amino acids are cleanly removed in Tetrahymena in vivo. The full mutase gene sequence codes for a protein of 300 amino acids, and it includes two amber (TAG) codons in the open reading frame. In Tetrahymena, TAG codes for glutamine. When the two amber codons are each changed to a glutamine codon (CAG) that is recognized by E. coli and the gene is placed behind a promoter driven by the T7 RNA polymerase, expression in E. coli is observed. The mutase gene also contains a large number of arginine AGA codons, a codon that is very rarely used by E. coli. Cotransformation with a plasmid carrying the dnaY gene [which encodes tRNA(Arg)(AGA)] results in more than 4-fold higher expression. The mutase then comprises about 25% of the total soluble cell protein in E. coli transformants. The mutase gene bears significant similarity to one other gene in the available data bases, that of carboxyphosphonoenolpyruvate mutase from Streptomyces hygroscopicus, an enzyme that catalyzes a closely related transformation. Due to the large evolutionary distance between Tetrahymena and Streptomyces, this similarity can be interpreted as the first persuasive evidence that the biosynthesis of phosphonates is an ancient metabolic process.     

Heterologous production of 3-hydroxyvalerate in engineered Escherichia coli

3-Hydroxyacids are a group of valuable fine chemicals with numerous applications, and 3-hydroxybutyrate (3-HB) represents the most common species with acetyl-CoA as a precursor. Due to the lack of propionyl-CoA in most, if not all, microorganisms, bio-based production of 3-hydroxyvalerate (3-HV), a longer-chain 3-hydroxyacid member with both acetyl-CoA and propionyl-CoA as two precursors, is often hindered by high costs associated with the supplementation of related carbon sources, such as propionate or valerate. Here, we report the derivation of engineered Escherichia coli strains for the production of 3-HV from unrelated cheap carbon sources, in particular glucose and glycerol. Activation of the sleeping beauty mutase (Sbm) pathway in E. coli enabled the intracellular formation of non-native propionyl-CoA. A selection of enzymes involved in 3-HV biosynthetic pathway from various microorganisms were explored for investigating their effects on 3-HV biosynthesis in E. coli. Glycerol outperformed glucose as the carbon source, and glycerol dissimilation for 3-HV biosynthesis was primarily mediated through the aerobic GlpK-GlpD route. To further enhance 3-HV production, we developed metabolic engineering strategies to redirect more dissimilated carbon flux from the tricarboxylic acid (TCA) cycle to the Sbm pathway, resulting in an enlarged intracellular pool of propionyl-CoA. Both the presence of succinate/succinyl-CoA and their interconversion step in the TCA cycle were identified to critically limit the carbon flux redirection into the Sbm pathway and, therefore, 3-HV biosynthesis. A selection of E. coli host TCA genes encoding enzymes near the succinate node were targeted for manipulation to evaluate the contribution of the three TCA routes (i.e. oxidative TCA cycle, reductive TCA branch, and glyoxylate shunt) to the redirected carbon flux into the Sbm pathway. Finally, the carbon flux redirection into the Sbm pathway was enhanced by simultaneously deregulating glyoxylate shunt and blocking the oxidative TCA cycle, significantly improving 3-HV biosynthesis. With the implementation of these biotechnological and bioprocessing strategies, our engineered E. coli strains can effectively produce 3-HV up to 3.71 g l⁻¹ with a yield of 24.1% based on the consumed glycerol in shake-flask cultures.     

Metabolic engineering of a methylmalonyl-CoA mutase-epimerase pathway for complex polyketide biosynthesis in Escherichia coli

A barrier to heterologous production of complex polyketides in Escherichia coli is the lack of (2S)-methylmalonyl-CoA, a common extender substrate for the biosynthesis of complex polyketides by modular polyketide synthases. One biosynthetic route to (2S)-methylmalonyl-CoA involves the sequential actions of two enzymes, methylmalonyl-CoA mutase and methylmalonyl-CoA epimerase, which convert succinyl-CoA to (2R)- and then to (2S)-methylmalonyl-CoA. As reported [McKie, N., et al. (1990) Biochem. J. 269, 293-298; Haller, T., et al. (2000) Biochemistry 39, 4622-4629], when genes encoding coenzyme B(12)-dependent methylmalonyl-CoA mutases were expressed in E. coli, the inactive apo-enzyme was produced. However, when cells harboring the mutase genes from Propionibacterium shermanii or E. coli were treated with the B12 precursor hydroxocobalamin, active holo-enzyme was isolated, and (2R)-methylmalonyl-CoA represented approximately 10% of the intracellular CoA pool. When the E. coli BAP1 cell line [Pfeifer, B. A., et al. (2001) Science 291, 1790-1792] harboring plasmids that expressed P. shermanii methylmalonyl-CoA mutase, Streptomyces coelicolor methylmalonyl-CoA epimerase, and the polyketide synthase DEBS (6-deoxyerythronolide B synthase) was fed propionate and hydroxocobalamin, the polyketide 6-deoxyerythronolide B (6-dEB) was produced. Isotopic labeling studies using [(13)C]propionate showed that the starter unit for polyketide synthesis was derived exclusively from exogenous propionate, while the extender units stemmed from methylmalonyl-CoA via the mutase-epimerase pathway. Thus, the introduction of an engineered mutase-epimerase pathway in E. coli enabled the uncoupling of carbon sources used to produce starter and extender units of polyketides.     

2-Methylisocitrate lyases from the bacterium Escherichia coli and the filamentous fungus Aspergillus nidulans: characterization and comparison of both enzymes.

In Escherichia coli and Aspergillus nidulans, propionate is oxidized to pyruvate via the methylcitrate cycle. The last step of this cycle, the cleavage of 2-methylisocitrate to succinate and pyruvate is catalysed by 2-methylisocitrate lyase. The enzymes from both organisms were assayed with chemically synthesized threo-2-methylisocitrate; the erythro-diastereomer was not active. 2-Methylisocitrate lyase from E. coli corresponds to the PrpB protein of the prp operon involved in propionate oxidation. The purified enzyme has a molecular mass of approximately 32 kDa per subunit, which is lower than those of isocitrate lyases from bacterial sources ( approximately 48 kDa). 2-Methylisocitrate lyase from A. nidulans shows an apparent molecular mass of 66 kDa per subunit, almost equal to that of isocitrate lyase of the same organism. Both 2-methylisocitrate lyases have a native homotetrameric structure as identified by size-exclusion chromatography. The enzymes show no measurable activity with isocitrate. Starting from 250 mM pyruvate, 150 mM succinate and 10 microM PrpB, the enzymatically active stereoisomer could be synthesized in 1% yield. As revealed by chiral HPLC, the product consisted of a single enantiomer. This isomer is cleaved by 2-methylisocitrate lyases from A. nidulans and E. coli. The PrpB protein reacted with stoichiometric amounts of 3-bromopyruvate whereby the activity was lost and one amino-acid residue per subunit became modified, most likely a cysteine as shown for isocitrate lyase of E. coli. PrpB exhibits 34% sequence identity with carboxyphosphoenolpyruvate phosphonomutase from Streptomyces hygroscopicus, in which the essential cysteine residue is conserved.     

Alternative sites for proton entry from the cytoplasm to the quinone binding site in Escherichia coli succinate dehydrogenase

Escherichia coli succinate dehydrogenase (Sdh) belongs to the highly conserved complex II family of enzymes that reduce ubiquinone. These enzymes do not generate a protonmotive force during catalysis and are electroneutral. Because of its electroneutrality, the quinone reduction reaction must consume cytoplasmic protons which are released stoichiometrically during succinate oxidation. The X-ray crystal structure of E. coli Sdh shows that residues SdhB (G227), SdhC (D95), and SdhC (E101) are located at or near the entrance of a water channel that has been proposed to function as a proton wire connecting the cytoplasm to the quinone binding site. However, the pig and chicken Sdh enzymes show an alternative entrance to the water channel via the conserved SdhD (Q78) residue. In this study, site-directed mutants of these four residues were created and characterized by in vivo growth assays, in vitro activity assays, and electron paramagnetic resonance spectroscopy. We show that the observed water channel in the E. coli Sdh structure is the functional proton wire in vivo, while in vitro results indicate an alternative entrance for protons. In silico examination of the E. coli Sdh reveals a possible H-bonding network leading from the cytoplasm to the quinone binding site that involves SdhD (D15). On the basis of these results we propose an alternative proton pathway in E. coli Sdh that might be functional only in vitro.     

The priB and priC replication proteins of Escherichia coli. Genes, DNA sequence, overexpression, and purification.

The Escherichia coli DNA replication proteins n and n" function in vitro in the assembly of the primosome, a mobile multiprotein replication priming complex thought to operate on the lagging-strand template at the E. coli DNA replication fork. Both proteins have been purified from E. coli HMS83 cells based on their requirement for the reconstitution of bacteriophage phi X174 complementary strand DNA synthesis in vitro with purified proteins. As a step toward understanding the role of these proteins in vivo, the genes for primosomal proteins n and n", designated priB and priC, respectively, have been cloned molecularly. priB encodes a 104-amino acid 11.4-kDa polypeptide and corresponds to an previously identified open reading frame between rpsF and rps R within a ribosomal protein operon at 95.5 min on the E. coli chromosome. priC encodes a 175-amino acid 20.3-kDa polypeptide. These two gene products were overexpressed at least 1000-fold in E. coli using a bacteriophage T7 transient expression system. Both proteins have been purified to apparent homogeneity from extracts prepared from these overproducing strains.     

The presence and possible function of methylmalonyl CoA mutase and propionyl CoA carboxylase in Spirometra mansonoides.

Both spargana and adult forms of Spirometra mansonoides were shown to accumulate lactate, succinate, acetate, and propionate upon in vitro incubation. Adults differed markedly from the spargana in that quantitatively the most significant products of the former were acetate and propionate while the latter formed primarily acetate and lactate. The adults accumulated approximately 32 times more propionate than the spargana per gram of tissue. In accord with this propionate formation, propionyl CoA carboxylase and methylmalonyl CoA mutase have been found to be present in both stages of the parasite. As might be predicted, however, the activities of the carboxylase and mutase were 100-fold and 10-fold higher, respectively, in the adults as compared to the larvae. A possible physiological relationship between propionate formation and energy generation is suggested. Accordingly, inorganic 32P was incorporated into ATP upon incubation of methylmalonyl CoA with a homogenate obtained from adult S. mansonoides. Since methylmalonyl CoA mutase requires vitamin B12 coenzyme, a relationship between vitamin B12 content and propionate formation in helminths is suggested.     

大肠杆菌木糖生物合成琥珀酸的代谢工程研究

目的:对大肠杆菌进行代谢网络改造,考察木糖好氧发酵生产琥珀酸的可行性。方法:以有氧条件下大肠杆菌木糖生物合成琥珀酸的代谢途径分析为基础,以大肠杆菌BL21为出发菌株,通过P1噬菌体一步敲除法敲除琥珀酸脱氢酶基因(sdhA)、磷酸转乙酰基酶基因(pta)、丙酮酸脱氢酶基因(poxB)及异柠檬酸裂解酶阻遏物基因(iclR),构建木糖好氧发酵生产琥珀酸的大肠杆菌工程菌JLS400(△poxB△pta△iclR△sdhA)。将携带磷酸烯醇式丙酮酸羧化酶基因的质粒pJW225转化到JLS400中。结果:摇瓶发酵结果表明,构建的工程菌能以木糖为碳源,在好氧发酵条件下琥珀酸产率较高,副产物仅有少量乙酸和丙酮酸。结论:基因工程大肠杆菌JLS400pJW225的构建,为有氧条件下以木糖为原料生产琥珀酸的进一步研究奠定了基础。     

Autophosphorylation of phosphoglucosamine mutase from Escherichia coli

Phosphoglucosamine mutase (GlmM) catalyzes the formation of glucosamine-1-phosphate from glucosamine-6-phosphate, an essential step in the pathway for UDP-N-acetylglucosamine biosynthesis in bacteria. This enzyme must be phosphorylated to be active and acts according to a ping-pong mechanism involving glucosamine-1, 6-diphosphate as an intermediate (L. Jolly, P. Ferrari, D. Blanot, J. van Heijenoort, F. Fassy, and D. Mengin-Lecreulx, Eur. J. Biochem. 262:202-210, 1999). However, the process by which the initial phosphorylation of the enzyme is achieved in vivo remains unknown. Here we show that the phosphoglucosamine mutase from Escherichia coli autophosphorylates in vitro in the presence of [(32)P]ATP. The same is observed with phosphoglucosamine mutases from other bacterial species, yeast N-acetylglucosamine-phosphate mutase, and rabbit muscle phosphoglucomutase. Labeling of the E. coli GlmM enzyme with [(32)P]ATP requires the presence of a divalent cation, and the label is subsequently lost when the enzyme is incubated with either of its substrates. Analysis of enzyme phosphorylation by high-pressure liquid chromatography and coupled mass spectrometry confirms that only one phosphate has been covalently linked to the enzyme. Only phosphoserine could be detected after acid hydrolysis of the labeled protein, and site-directed mutagenesis of serine residues located in or near the active site identifies the serine residue at position 102 as the site of autophosphorylation of E. coli GlmM.