Characterization of the Dicarboxylate Transporter DctA in Corynebacterium glutamicum

Transporters of the dicarboxylate amino acid-cation symporter family often mediate uptake of C₄-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 C₄-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 C₄-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 C₄-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 C₄-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 Mg²⁺ or Ca²⁺. 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 C₄-dicarboxylates succinate, fumarate, and l-malate (36, 40). Spontaneous mutants showing fast growth in succinate or fumarate minimal medium were isolated and shown to possess promoter-up mutations in the dccT gene (40). In l-malate minimal medium, these spontaneous mutants showed relatively slow growth, and the affinity of DccT for succinate and fumarate was found to be 5- and 12-fold higher than for l-malate, respectively (40). These findings prompted us to search for other uptake systems for l-malate in C. glutamicum. Here, we describe the identification and characterization of the DAACS family protein DctA from C. glutamicum as a proton motive force-driven uptake system for C₄-dicarboxylate intermediates of the TCA cycle. Additionally, we compare both uptake systems, DccT and DctA, from C. glutamicum.     

Functional Characterization of SdcF from Bacillus licheniformis, a Homolog of the SLC13 Na+/Dicarboxylate Transporters

The SdcF transporter from Bacillus licheniformis (gene BL02343) is a member of the divalent anion sodium symporter (DASS)/SLC13 family that includes Na⁺/dicarboxylate transporters from bacteria to humans. SdcF was functionally expressed in Escherichia coli (BL21) and assayed in right side out membrane vesicles. ScdF catalyzed the sodium-coupled transport of succinate and α-ketoglutarate. Succinate transport was strongly inhibited by malate, fumarate, tartrate, oxaloacetate and l-aspartate. Similar to the other DASS transporters, succinate transport by SdcF was inhibited by anthranilic acids, N-(p-amylcinnamoyl) anthranilic acid and flufenamate. SdcF transport was cation-dependent, with a K _0.5 for sodium of ~1.5 mM and a K _0.5 for Li⁺ of ~40 mM. Succinate transport kinetics by SdcF were sigmoidal, suggesting that SdcF may contain two cooperative substrate binding sites. The results support an ordered binding mechanism for SdcF in which sodium binds first and succinate binds last. We conclude that SdcF is a secondary active transporter for four- and five-carbon dicarboxylates that can use Na⁺ or Li⁺ as a driving cation.     

Functional characterization of a Na+-coupled dicarboxylate transporter from Bacillus licheniformis

The Na⁺-coupled dicarboxylate transporter, SdcL, from Bacillus licheniformis is a member of the divalent anion/Na⁺ symporter (DASS) family that includes the bacterial Na⁺/dicarboxylate cotransporter SdcS (from Staphyloccocus aureus) and the mammalian Na⁺/dicarboxylate cotransporters, NaDC1 and NaDC3. The transport properties of SdcL produced in Escherichia coli are similar to those of its prokaryotic and eukaryotic counterparts, involving the Na⁺-dependent transport of dicarboxylates such as succinate or malate across the cytoplasmic membrane with a K_m of ～ 6 μM. SdcL may also transport aspartate, α-ketoglutarate and oxaloacetate with low affinity. The cotransport of Na⁺ and dicarboxylate by SdcL has an apparent stoichiometry of 2:1, and a K_0.5 for Na⁺ of 0.9 mM. Our findings represent the characterization of another prokaryotic protein of the DASS family with transport properties similar to its eukaryotic counterparts, but with a broader substrate specificity than other prokaryotic DASS family members. The broader range of substrates carried by SdcL may provide insight into domains of the protein that allow a more flexible or larger substrate binding pocket.     

Functional characterization of a Na+-dependent dicarboxylate transporter from Vibrio cholerae

The SLC13 transporter family, whose members play key physiological roles in the regulation of fatty acid synthesis, adiposity, insulin resistance, and other processes, catalyzes the transport of Krebs cycle intermediates and sulfate across the plasma membrane of mammalian cells. SLC13 transporters are part of the divalent anion:Na⁺ symporter (DASS) family that includes several well-characterized bacterial members. Despite sharing significant sequence similarity, the functional characteristics of DASS family members differ with regard to their substrate and coupling ion dependence. The publication of a high resolution structure of dimer VcINDY, a bacterial DASS family member, provides crucial structural insight into this transporter family. However, marrying this structural insight to the current functional understanding of this family also demands a comprehensive analysis of the transporter’s functional properties. To this end, we purified VcINDY, reconstituted it into liposomes, and determined its basic functional characteristics. Our data demonstrate that VcINDY is a high affinity, Na⁺-dependent transporter with a preference for C₄- and C₅-dicarboxylates. Transport of the model substrate, succinate, is highly pH dependent, consistent with VcINDY strongly preferring the substrate’s dianionic form. VcINDY transport is electrogenic with succinate coupled to the transport of three or more Na⁺ ions. In contrast to succinate, citrate, bound in the VcINDY crystal structure (in an inward-facing conformation), seems to interact only weakly with the transporter in vitro. These transport properties together provide a functional framework for future experimental and computational examinations of the VcINDY transport mechanism.     

Redirecting carbon flux through <Emphasis Type="Italic">pgi</Emphasis>-deficient and heterologous transhydrogenase toward efficient succinate production in <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis>

Corynebacterium glutamicum is particularly known for its potentiality in succinate production. We engineered C. glutamicum for the production of succinate. To enhance C₃–C₄ carboxylation efficiency, chromosomal integration of the pyruvate carboxylase gene pyc resulted in strain NC-4. To increase intracellular NADH pools, the pntAB gene from Escherichia coli, encoding for transhydrogenase, was chromosomally integrated into NC-4, leading to strain NC-5. Furthermore, we deleted pgi gene in strain NC-5 to redirect carbon flux to the pentose phosphate pathway (PPP). To solve the drastic reduction of PTS-mediated glucose uptake, the ptsG gene from C. glutamicum, encoding for the glucose-specific transporter, was chromosomally integrated into pgi-deficient strain resulted in strain NC-6. In anaerobic batch fermentation, the production of succinate in pntAB-overexpressing strain NC-5 increased by 14% and a product yield of 1.22 mol/mol was obtained. In anaerobic fed-batch process, succinic acid concentration reached 856 mM by NC-6. The yields of succinate from glucose were 1.37 mol/mol accompanied by a very low level of by-products. Activating PPP and transhydrogenase in combination led to a succinate yield of 1.37 mol/mol, suggesting that they exhibited a synergistic effect for improving succinate yield.     

Functional characterization of a Na(+)-coupled dicarboxylate carrier protein from Staphylococcus aureus

We have cloned and functionally characterized a Na(+)-coupled dicarboxylate transporter, SdcS, from Staphylococcus aureus. This carrier protein is a member of the divalent anion/Na(+) symporter (DASS) family and shares significant sequence homology with the mammalian Na(+)/dicarboxylate cotransporters NaDC-1 and NaDC-3. Analysis of SdcS function indicates transport properties consistent with those of its eukaryotic counterparts. Thus, SdcS facilitates the transport of the dicarboxylates fumarate, malate, and succinate across the cytoplasmic membrane in a Na(+)-dependent manner. Furthermore, kinetic work predicts an ordered reaction sequence with Na(+) (K(0.5) of 2.7 mM) binding before dicarboxylate (K(m) of 4.5 microM). Because this transporter and its mammalian homologs are functionally similar, we suggest that SdcS may serve as a useful model for DASS family structural analysis.     

Engineering of Acetate Recycling and Citrate Synthase to Improve Aerobic Succinate Production in Corynebacterium glutamicum

Corynebacterium glutamicum lacking the succinate dehydrogenase complex can produce succinate aerobically with acetate representing the major byproduct. Efforts to increase succinate production involved deletion of acetate formation pathways and overexpression of anaplerotic pathways, but acetate formation could not be completely eliminated. To address this issue, we constructed a pathway for recycling wasted carbon in succinate-producing C. glutamicum. The acetyl-CoA synthetase from Bacillus subtilis was heterologously introduced into C. glutamicum for the first time. The engineered strain ZX1 (pEacsA) did not secrete acetate and produced succinate with a yield of 0.50 mol (mol glucose)⁻¹. Moreover, in order to drive more carbon towards succinate biosynthesis, the native citrate synthase encoded by gltA was overexpressed, leading to strain ZX1 (pEacsAgltA), which showed a 22% increase in succinate yield and a 62% decrease in pyruvate yield compared to strain ZX1 (pEacsA). In fed-batch cultivations, strain ZX1 (pEacsAgltA) produced 241 mM succinate with an average volumetric productivity of 3.55 mM h⁻¹ and an average yield of 0.63 mol (mol glucose) ⁻¹, making it a promising platform for the aerobic production of succinate at large scale.     

Biochemical Characterization of the C4-Dicarboxylate Transporter DctA from Bacillus subtilis

Bacterial secondary transporters of the DctA family mediate ion-coupled uptake of C₄-dicarboxylates. Here, we have expressed the DctA homologue from Bacillus subtilis in the Gram-positive bacterium Lactococcus lactis. Transport of dicarboxylates in vitro in isolated membrane vesicles was assayed. We determined the substrate specificity, the type of cotransported ions, the electrogenic nature of transport, and the pH and temperature dependence patterns. DctA was found to catalyze proton-coupled symport of the four C₄-dicarboxylates from the Krebs cycle (succinate, fumurate, malate, and oxaloacetate) but not of other mono- and dicarboxylates. Because (i) succinate-proton symport was electrogenic (stimulated by an internal negative membrane potential) and (ii) the divalent anionic form of succinate was recognized by DctA, at least three protons must be cotransported with succinate. The results were interpreted in the light of the crystal structure of the homologous aspartate transporter Glt_Ph from Pyrococcus horikoshii.The DctA family is one of several diverse families of secondary transporters that catalyze the uptake of C₄-dicarboxylates from the Krebs cycle in bacteria (16, 27). In Escherichia coli, DctA mediates the uptake of succinate, fumurate, and malate under aerobic conditions; genomic disruption of dctA in E. coli prevents growth with malate or fumarate as the sole carbon source, and the mutant grows poorly on succinate (5). Similarly, a dctA knockout mutant of Bacillus subtilis cannot grow with succinate or fumarate as the sole carbon source (1). DctA plays a major role in the symbiotic relationship between nitrogen-fixing rhizobia (43) and root nodule-forming plants (30, 37, 38). Transport assays with Sinorhizobium meliloti cells showed previously that in addition to succinate, malate, and fumarate, orotate is transported and that a range of other substrates such as succinamic acid and succinamide may be transported, because they inhibit the transport of orotate (42). In Corynebacterium glutamicum, malate transport by DctA is inhibited by α-ketoglutarate, oxaloacetate, and glyoxylate, indicating that these compounds may be substrates also (41).DctA transporters belong to a large family of secondary transporters (the DAACS [dicarboxylate/amino acid:cation symporter] family), which also comprises well-characterized glutamate/aspartate transporters and neutral amino acid transporters (32, 33). While DctA-type dicarboxylate transporters are found only in bacteria, glutamate/aspartate transporters of the DAACS family are found both in prokaryotes (e.g., GltT in Bacillus stearothermophilus, GltP in E. coli, and Glt_Ph in Pyrococcus horikoshii [2, 7, 34]) and in higher eukarya, where they play a pivotal role in the reuptake of the excitatory neurotransmitter glutamate from the synaptic cleft (4). Neutral amino acid (alanine, serine, and threonine) transporters are found in mammals (see, e.g., references 36 and 44) as well as bacteria (17).Secondary transporters of the DAACS family use (electro)chemical gradients of cations across the membrane to drive transport. The type of cotransported ions varies among family members: eukaryotic glutamate transporters couple the transport of glutamate to the symport of one proton and three sodium ions and the antiport of one potassium ion (24, 45). Bacterial and archaeal glutamate transporters utilize either sodium ions or protons for symport (2) and are independent of potassium ions (28, 31). The bacterial and mammalian neutral amino acid transporters are sodium ion coupled. Glutamate/aspartate transporters and bacterial serine/threonine transporters (SstTs) are electrogenic, but mammalian neutral amino acid transporters are obligate electroneutral amino acid antiporters (44).Insight into the structure-function relationships of the DAACS family members has greatly increased since crystal structures of the P. horikoshii aspartate transporter Glt_Ph have been determined (2, 29, 40). The protein consists of eight membrane-spanning helices and two reentrant regions (helical hairpins HP1 and HP2) (40). The C-terminal part of the protein (helices 7 and 8 and HP1 and HP2) is most strongly conserved with respect to other family members and binds the substrate and cotransported ions, with HP1 and HP2 functioning as lids that allow alternating access to the substrate- and ion-binding sites from either side of the membrane (3, 29). Glt_Ph forms a homotrimeric complex in which each protomer functions independently of the other subunits (11, 12, 18, 19, 23). The fold and oligomeric state are likely to be conserved throughout the family.Whereas the transport mechanisms of bacterial glutamate and neutral amino acid transporters of the DAACS family have been studied extensively in vitro, the C₄-dicarboxylate transporters of the DAACS family (DctA proteins) have been studied using whole cells only. To fully characterize these transporters, in vitro activity assays using either membrane vesicles or proteoliposomes containing purified protein are necessary. In such assays, the internal and external buffer compositions can be controlled, thus allowing manipulation of the chemical ion gradients and the electrical potential across the membrane. Here, we present the first biochemical characterization of a DctA family member in membrane vesicles. We have studied the DctA homologue from B. subtilis, which is annotated as DctP (1) but which we propose to rename DctA to reflect the homology to other DctA proteins. B. subtilis DctA (DctA_Bs) has 30 to 32% sequence identity to the aspartate transporter Glt_Ph and human excitatory amino acid transporter (EAAT) family members, over 40% sequence identity to the characterized bacterial glutamate transporters from E. coli and B. stearothermophilus, and 41 and 56% identity to DctA homologues from C. glutamicum and E. coli, respectively. We determined the substrate specificity of DctA_Bs, the type of cotransported ions, the electrogenic nature of transport, and the pH and temperature dependence patterns.     

atp Mutants of Escherichia coli Fail To Grow on Succinate Due to a Transport Deficiency

Escherichia coli atp mutants, which lack a functional H⁺-ATPase complex, are capable of growth on glucose but not on succinate or other C₄-dicarboxylates (Suc⁻ phenotype). Suc⁺ revertants of an atp deletion strain were isolated which were capable of growth on succinate even though they lack the entire H⁺-ATPase complex. Complementation in trans with the yhiF gene suppressed the growth of the Suc⁺ mutants on succinate, which implicates the yhiF gene product in the regulation of C₄-dicarboxylate metabolism. Indeed, when the E. coli C₄-dicarboxylate transporter (encoded by the dctA gene) was expressed in trans, the Suc⁻ phenotype of the atp deletion strain reverted to Suc⁺, which shows that the reason why the E. coli atp mutant is unable to grow aerobically on C₄-dicarboxylates is insufficient transport capacity for these substrates.     

Conserved residues in the aromatic acid/H symporter family are important for benzoate uptake by NCgl2325 in Corynebacterium glutamicum

Corynebacterium glutamicum is a model organism for genetic and physiological studies in Gram-positive bacteria. NCgl2325 in C. glutamicum, a transporter belonging to the aromatic acid/H⁺ symporter family, has previously been reported to be involved in benzoate assimilation. Here, we showed that this transporter, fused with GFP, was associated with the cell membrane in Escherichia coli and C. glutamicum. Uptake assays with [¹⁴C]-labeled benzoate demonstrated that NCgl2325 transported benzoate into the cells at a V_max of 0.19 ± 0.01 nmol/min/mg of dry weight, and the K_m value was determined to be 1.11 ± 0.24 ??M. Among the competing substrates tested, hydroxyl-substituted benzoates resulted in significant inhibition (>50%) of benzoate uptake. Site-directed mutagenesis of conserved residues in the hydrophilic cytoplasmic loops (Gly-80, Asp-84 and Asp-312) and the hydrophobic transmembrane regions (Asp-35, Arg-119, Glu-139 and Arg-386) resulted in loss of benzoate transport activity. This is the first study to investigate the molecular basis of benzoate transport.     

Engineering a glycerol utilization pathway in Corynebacterium glutamicum for succinate production under O<Subscript>2</Subscript> deprivation

Objective

To explore the glycerol utilization pathway in Corynebacterium glutamicum for succinate production under O₂ deprivation.

Result

Overexpression of a glycerol facilitator, glycerol dehydrogenase and dihydroxyacetone kinase from Escherichia coli K-12 in C. glutamicum led to recombinant strains NC-3G diverting glycerol utilization towards succinate production under O₂ deprivation. Under these conditions, strain NC-3G efficiently consumed glycerol and produced succinate without growth. The recombinant C. glutamicum utilizing glycerol as the sole carbon source showed higher intracellular NADH/NAD⁺ ratio compare with utilizing glucose. The mass conversion of succinate increased from 0.64 to 0.95. Using an anaerobic fed-batch fermentation process, the final strain produced 38.4 g succinate/l with an average yield of 1.02 g/g.

Conclusions

The metabolically-engineered strains showed an efficient succinate production using glycerol as sole carbon source under O₂ deprivation.

     

Glycerol as a substrate for aerobic succinate production in minimal medium with Corynebacterium glutamicum

Corynebacterium glutamicum, an established microbial cell factory for the biotechnological production of amino acids, was recently genetically engineered for aerobic succinate production from glucose in minimal medium. In this work, the corresponding strains were transformed with plasmid pVWEx1-glpFKD coding for glycerol utilization genes from Escherichia coli. This plasmid had previously been shown to allow growth of C. glutamicum with glycerol as sole carbon source. The resulting strains were tested in minimal medium for aerobic succinate production from glycerol, which is a by-product in biodiesel synthesis. The best strain BL-1/pVWEx1-glpFKD formed 79 mM (9.3 g l⁻¹) succinate from 375 mM glycerol, representing 42% of the maximal theoretical yield under aerobic conditions. A specific succinate production rate of 1.55 mmol g⁻¹ (cdw) h⁻¹ and a volumetric productivity of 3.59 mM h⁻¹ were obtained, the latter value representing the highest one currently described in literature. The results demonstrate that metabolically engineered strains of C. glutamicum are well suited for aerobic succinate production from glycerol.     

Next-generation sequencing-based genome-wide mutation analysis of l-lysine-producing Corynebacterium glutamicum ATCC 21300 strain

In order to identify single nucleotide polymorphism and insertion/deletion mutations, we performed whole-genome re-sequencing of the enhanced l-lysine-producing Corynebacterium glutamicum ATCC 21300 strain. In total, 142 single nucleotide polymorphisms and 477 insertion/deletion mutations were identified in the ATCC 21300 strain when compared to 3,434 predicted genes of the wild-type C. glutamicum ATCC 13032 strain. Among them, 110 transitions and 29 transversions of single nucleotide polymorphisms were found from genes of the ATCC 21300 strain. In addition, 11 genes, involved in the L-lysine biosynthetic pathway and central carbohydrate metabolism, contained mutations including single nucleotide polymorphisms and insertions/deletions. Interestingly, RT-PCR analysis of these 11 genes indicated that they were normally expressed in the ATCC 21300 strain. This information of genome-wide gene-associated variations will be useful for genome breeding of C. glutamicum in order to develop an industrial amino acid-producing strain with minimal mutation.     

Transport of C4-dicarboxylic acids in salmonella typhimurium.

C₄-Dicarboxylic acids are transported into Salmonella typhimurium by stereospecific systems of both high and low affinity. Succinate and l-malate are accumulated in a tricarboxylic acid cycle mutant as was d(+)-malate in induced wild-type cells. Accumulated dicarboxylates are exchangeable with exogenous dicarboxylates. The trichloroacetic acid cycle dicarboxylates are the best inducers of their own transport. Specific mutants devoid of dicarboxylate transport activity (dct) were isolated and differed from tricarboxylate transport mutants (tct) with respect to growth and transport. A mutant devoid of α-ketoglutarate dehydrogenase was unable to transport dicarboxylic acids but citrate transport remained unaffected. Tricarboxylic acid cycle mutants were markedly dependent on an exogenous energy source for the transport of succinate, proline, or leucine. Dicarboxylate transport was largely inhibited by various metabolic inhibitors but could only be inhibited by N,N'-dicyclohexylcarbodiimide anaerobically. ATPase mutants were unimpaired in their ability to transport succinate or proline aerobically.     

Functional reconstitution of SdcS, a Na+-coupled dicarboxylate carrier protein from Staphylococcus aureus

In Staphylococcus aureus, the transport of dicarboxylates is mediated in part by the Na+-linked carrier protein SdcS. This transporter is a member of the divalent-anion/Na+ symporter (DASS) family, a group that includes the mammalian Na+/dicarboxylate cotransporters NaDC1 and NaDC3. In earlier work, we cloned and expressed SdcS in Escherichia coli and found it to have transport properties similar to those of its eukaryotic counterparts (J. A. Hall and A. M. Pajor, J. Bacteriol. 187:5189-5194, 2005). Here, we report the partial purification and subsequent reconstitution of functional SdcS into liposomes. These proteoliposomes exhibited succinate counterflow activity, as well as Na+ electrochemical-gradient-driven transport. Examination of substrate specificity indicated that the minimal requirement necessary for transport was a four-carbon terminal dicarboxylate backbone and that productive substrate-transporter interaction was sensitive to substitutions at the substrate C-2 and C-3 positions. Further analysis established that SdcS facilitates an electroneutral symport reaction having a 2:1 cation/dicarboxylate ratio. This study represents the first characterization of a reconstituted Na+-coupled DASS family member, thus providing an effective method to evaluate functional, as well as structural, aspects of DASS transporters in a system free of the complexities and constraints associated with native membrane environments.     

A Novel Amidase (Half-Amidase) for Half-Amide Hydrolysis Involved in the Bacterial Metabolism of Cyclic Imides

A novel amidase involved in bacterial cyclic imide metabolism was purified from Blastobacter sp. strain A17p-4. The enzyme physiologically functions in the second step of cyclic imide degradation, i.e., the hydrolysis of monoamidated dicarboxylates (half-amides) to dicarboxylates and ammonia. Enzyme production was enhanced by cyclic imides such as succinimide and glutarimide but not by amide compounds which are conventional substrates and inducers of known amidases. The purified amidase showed high catalytic efficiency toward half-amides such as succinamic acid (K_m = 6.2 mM; k_cat = 5.76 s⁻¹) and glutaramic acid (K_m = 2.8 mM; k_cat = 2.23 s⁻¹). However, the substrates of known amidases such as short-chain (C₂ to C₄) aliphatic amides, long-chain (above C₁₆) aliphatic amides, amino acid amides, aliphatic diamides, α-keto acid amides, N-carbamoyl amino acids, and aliphatic ureides were not substrates for the enzyme. Based on its high specificity toward half-amides, the enzyme was named half-amidase. This half-amidase exists as a monomer with an M_r of 48,000 and was strongly inhibited by heavy metal ions and sulfhydryl reagents.     

Corynebacterium glutamicum,a natural overproducer of succinic acid?

Corynebacterium glutamicum is well known as an important industrial amino acid producer. For a few years, its ability to produce organic acids, under micro‐aerobic or anaerobic conditions was demonstrated. This study is focused on the identification of the culture parameters influencing the organic acids production and, in particular, the succinate production, by this bacterium. Corynebacterium glutamicum 2262, used throughout this study, was a wild‐type strain, which was not genetically designed for the production of succinate. The oxygenation level and the residual glucose concentration appeared as two critical parameters for the organic acids production. The maximal succinate concentration (4.9 g L^?1) corresponded to the lower k_La value of 5 h^?1. Above 5 h^?1, a transient accumulation of the succinate was observed. Interestingly, the stop in the succinate production was concomitant with a lower threshold glucose concentration of 9 g L^?1. Taking into account this threshold, a fed‐batch culture was performed to optimize the succinate production with C. glutamicum 2262. The results showed that this wild‐type strain was able to produce 93.6 g L^?1 of succinate, which is one of the highest concentration reported in the literature.     

Identification of succinate exporter in Corynebacterium glutamicum and its physiological roles under anaerobic conditions

Corynebacterium glutamicum produces succinate from glucose via the reductive tricarboxylic acid cycle under microaerobic and anaerobic conditions. We identified a NCgl2130 gene of C. glutamicum as a novel succinate exporter that functions in succinate production, and designated sucE1. sucE1 expression levels were higher under microaerobic conditions than aerobic conditions, and overexpression or disruption of sucE1 respectively increased or decreased succinate productivity during fermentation. Under microaerobic conditions, the sucE1 disruptant sucE1Δ showed 30% less succinate productivity and a lower sugar-consumption rate than the parental strain. Under anaerobic conditions, succinate production by sucE1Δ ceased. The intracellular succinate and fructose-1,6-bisphosphate levels of sucE1Δ under microaerobic conditions were respectively 1.7-fold and 1.6-fold higher than those of the parental strain, suggesting that loss of SucE1 function caused a failure of succinate removal from the cells, leading to intracellular accumulation that inhibited upstream sugar metabolism. Homology and transmembrane helix searches identified SucE1 as a membrane protein belonging to the aspartate:alanine exchanger (AAE) family. Partially purified 6x-histidine-tagged SucE1 (SucE1-[His]₆) reconstituted in succinate-loaded liposomes clearly demonstrated counterflow and self-exchange activities for succinate. Together, these findings suggest that sucE1 encodes a novel succinate exporter that is induced under microaerobic conditions, and is important for succinate production under both microaerobic and anaerobic conditions.     

Implication of gluconate kinase activity in l-ornithine biosynthesis in Corynebacterium glutamicum

With the purpose of generating a microbial strain for l-ornithine production in Corynebacterium glutamicum, genes involved in the central carbon metabolism were inactivated so as to modulate the intracellular level of NADPH, and to evaluate their effects on l-ornithine production in C. glutamicum. Upon inactivation of the 6-phosphoglucoisomerase gene (pgi) in a C. glutamicum strain, the concomitant increase in intracellular NADPH concentrations from 2.55 to 5.75?mmol?g^?1 (dry cell weight) was accompanied by reduced growth rate and l-ornithine production, suggesting that l-ornithine production is not solely limited by NADPH availability. In contrast, inactivation of the gluconate kinase gene (gntK) led to a 51.8?% increase in intracellular NADPH concentration, which resulted in a 49.9?% increase in l-ornithine production. These results indicate that excess NADPH is not necessarily rate-limiting, but is required for increased l-ornithine production in C. glutamicum.