We recently engineered Corynebacterium glutamicum for aerobic production of 2-ketoisovalerate by inactivation of the pyruvate dehydrogenase complex, pyruvate:quinone oxidoreductase, transaminase B, and additional overexpression of the ilvBNCD genes, encoding acetohydroxyacid synthase, acetohydroxyacid isomeroreductase, and dihydroxyacid dehydratase. Based on this strain, we engineered C. glutamicum for the production of isobutanol from glucose under oxygen deprivation conditions by inactivation of L-lactate and malate dehydrogenases, implementation of ketoacid decarboxylase from Lactococcus lactis, alcohol dehydrogenase 2 (ADH2) from Saccharomyces cerevisiae, and expression of the pntAB transhydrogenase genes from Escherichia coli. The resulting strain produced isobutanol with a substrate-specific yield (Y P/S ) of 0.60 ؎ 0.02 mol per mol of glucose. Interestingly, a chromosomally encoded alcohol dehydrogenase rather than the plasmid-encoded ADH2 from S. cerevisiae was involved in isobutanol formation with C. glutamicum, and overexpression of the corresponding adhA gene increased the Y P/S to 0.77 ؎ 0.01 mol of isobutanol per mol of glucose. Inactivation of the malic enzyme significantly reduced the Y P/S , indicating that the metabolic cycle consisting of pyruvate and/or phosphoenolpyruvate carboxylase, malate dehydrogenase, and malic enzyme is responsible for the conversion of NADH؉H ؉ to NADPH؉H ؉ . In fed-batch fermentations with an aerobic growth phase and an oxygen-depleted production phase, the most promising strain, C. glutamicum ⌬aceE ⌬pqo ⌬ilvE ⌬ldhA ⌬mdh(pJC4ilvBNCD-pntAB)(pBB1kivd-adhA), produced about 175 mM isobutanol, with a volumetric productivity of 4.4 mM h ؊1 , and showed an overall Y P/S of about 0.48 mol per mol of glucose in the production phase.
Corynebacterium glutamicum grows with a variety of carbohydrates and carbohydrate derivatives as sole carbon sources; however, growth with glucosamine has not yet been reported. We isolated a spontaneous mutant (M4) which is able to grow as fast with glucosamine as with glucose as sole carbon source. Glucosamine also served as a combined source of carbon, energy and nitrogen for the mutant strain. Characterisation of the M4 mutant revealed a significantly increased expression of the nagB gene encoding the glucosamine-6P deaminase NagB involved in degradation of glucosamine, as a consequence of a single mutation in the promoter region of the nagAB-scrB operon. Ectopic nagB overexpression verified that the activity of the NagB enzyme is in fact the growth limiting factor under these conditions. In addition, glucosamine uptake was studied, which proved to be unchanged in the wild-type and M4 mutant strains. Using specific deletion strains, we identified the PTS(Glc) transport system to be responsible for glucosamine uptake in C. glutamicum. The affinity of this uptake system for glucosamine was about 40-fold lower than that for its major substrate glucose. Because of this difference in affinity, glucosamine is efficiently taken up only if external glucose is absent or present at low concentrations. C. glutamicum was also examined for its suitability to use glucosamine as substrate for biotechnological purposes. Upon overexpression of the nagB gene in suitable C. glutamicum producer strains, efficient production of both the amino acid L-lysine and the diamine putrescine from glucosamine was demonstrated.
Many bacteria can utilize C 4 -carboxylates as carbon and energy sources. However, Corynebacterium glutamicum ATCC 13032 is not able to use tricarboxylic acid cycle intermediates such as succinate, fumarate, and L-malate as sole carbon sources. Upon prolonged incubation, spontaneous mutants which had gained the ability to grow on succinate, fumarate, and L-malate could be isolated. DNA microarray analysis showed higher mRNA levels of cg0277, which subsequently was named dccT, in the mutants than in the wild type, and transcriptional fusion analysis revealed that a point mutation in the promoter region of dccT was responsible for increased expression. The overexpression of dccT was sufficient to enable the C. glutamicum wild type to grow on succinate, fumarate, and L-malate as the sole carbon sources. Biochemical analyses revealed that DccT, which is a member of the divalent anion/Na ؉ symporter family, catalyzes the effective uptake of dicarboxylates like succinate, fumarate, L-malate, and likely also oxaloacetate in a sodium-dependent manner.Corynebacterium glutamicum is a predominantly aerobic nonsporulating and biotin-auxotrophic gram-positive bacterium which is used for the industrial production of amino acids, mainly of L-lysine (Ͼ750,000 tons/year) (61) and glutamate (Ͼ1,500,000 tons/year) (50). C. glutamicum is well studied not only with respect to amino acid biosynthesis but also regarding carbon metabolism and its regulation (2, 6, 57). C. glutamicum grows aerobically on a variety of carbohydrates and organic acids as the sole sources of carbon and energy, e.g., on sugars like glucose, fructose, and sucrose and on organic acids like gluconate, acetate, propionate, pyruvate, and L-lactate, but also on ethanol, glutamate, vanillate, 4-hydroxybenzoate, and protocatechuate (1, 7-9, 19, 31, 35, 59). In general, growth on substrate mixtures is characterized by coutilization, e.g., of glucose with acetate (59), and even a nongrowth substrate like serine can be utilized simultaneously with glucose (35). Rarely, preferential utilization of glucose before glutamate or ethanol, e.g., has been observed (1, 28).Citrate is the only tricarboxylic acid (TCA) cycle intermediate described as supporting the growth of C. glutamicum (42). C. glutamicum can grow on citrate as the sole carbon source and coutilizes citrate and glucose (42). In a combined DNA microarray and proteome analysis, it was revealed that the expression of genes for two citrate uptake systems, CitM and TctABC, was induced when citrate was present in the medium (42). Although succinate uptake by C. glutamicum has been observed in biochemical assays, growth on succinate has not been reported (11,41). Other bacteria, e.g., Bacillus subtilis, are able to grow not only with citrate but also with the dicarboxylic TCA cycle intermediates succinate, fumarate, and Lmalate (55). The transporter YdbH in B. subtilis is responsible for the uptake of fumarate and succinate (3) but not for that of L-malate, which is taken up via MaeN (52) or the malate/ lactate antipo...
Transporters of the dicarboxylate amino acid-cation symporter family often mediate uptake of C 4 -dicarboxylates, such as succinate or L-malate, in bacteria. A member of this family, dicarboxylate transporter A (DctA) from Corynebacterium glutamicum, was characterized to catalyze uptake of the C 4 -dicarboxylates succinate, fumarate, and L-malate, which was inhibited by oxaloacetate, 2-oxoglutarate, and glyoxylate. DctA activity was not affected by sodium availability but was dependent on the electrochemical proton potential. Efficient growth of C. glutamicum in minimal medium with succinate, fumarate, or L-malate as the sole carbon source required high dctA expression levels due either to a promoter-up mutation identified in a spontaneous mutant or to ectopic overexpression. Mutant analysis indicated that DctA and DccT, a C 4 -dicarboxylate divalent anion/sodium symporter-type transporter, are the only transporters for succinate, fumarate, and L-malate in C. glutamicum.In bacteria, the uptake of dicarboxylates, such as the tricarboxylic acid (TCA) cycle intermediates succinate, fumarate, and L-malate, is mediated by transporters of different protein families. Whereas Dcu-type transporters facilitate dicarboxylate uptake under anaerobic conditions, the most common aerobic dicarboxylate transporters are members of the dicarboxylate amino acid-cation symporter (DAACS), divalent anion sodium symporter (DASS), tripartite ATP-independent periplasmic (TRAP), and CitMHS transporter families. DAACS transporters are responsible for C 4 -dicarboxylate uptake under aerobic conditions in various bacteria, e.g., DctA from Escherichia coli, Bacillus subtilis, or Rhizobium leguminosarum, and are involved in different physiological functions (2, 4, 27, 41). The first described member of the TRAP family is the C 4 -dicarboxylate transporter DctPQM from Rhodobacter capsulatus, which facilitates substrate uptake by the use of an extracytoplasmic solute receptor (8). An example of the DASS family, members of which occur in bacteria, as well in eukaryotes, is the well-characterized transporter SdcS from Staphylococcus aureus (13). Members of the CitHMS family import citrate in symport with the cation Mg 2ϩ or Ca 2ϩ . Whereas E. coli possesses one DctA and four different Dcu carriers, no Dcu transporter-encoding genes were found in Corynebacterium glutamicum (16,19), which is used for the industrial production of amino acids, such as glutamate (33) or L-lysine (39), and is capable of succinate and L-lactate production under oxygen deprivation conditions. A dctA gene was annotated (19); however, C. glutamicum is not able to utilize succinate, malate, or fumarate as a sole carbon source. The uptake systems CitH and TctCBA have been characterized recently as citrate uptake systems (3, 26). Interestingly, we and others have shown that C. glutamicum possesses a DASS family transporter (DccT) for uptake of the C 4 -dicarboxylates succinate, fumarate, and L-malate (36, 40). Spontaneous mutants showing fast growth in succinate or fumarate mi...
Split intein-mediated selection of cells containing two plasmids using a single antibiotic
To build or dissect complex pathways in bacteria and mammalian cells, it is often necessary to recur to at least two plasmids, for instance harboring orthogonal inducible promoters. Here we present SiMPl, a method based on rationally designed split enzymes and intein-mediated protein trans-splicing, allowing the selection of cells carrying two plasmids with a single antibiotic. We show that, compared to the traditional method based on two antibiotics, SiMPl increases the production of the antimicrobial non-ribosomal peptide indigoidine and the non-proteinogenic aromatic amino acid para-amino-L-phenylalanine from bacteria. Using a human T cell line, we employ SiMPl to obtain a highly pure population of cells double positive for the two chains of the T cell receptor, TCRα and TCRβ, using a single antibiotic. SiMPl has profound implications for metabolic engineering and for constructing complex synthetic circuits in bacteria and mammalian cells.
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