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.     

Purification and Characterization of Fumarase from Corynebacterium glutamicum

Fumarase (EC 4.2.1.2) from Corynebacterium glutamicum (Brevibacterium flavum) ATCC 14067 was purified to homogeneity. Its amino-terminal sequence (residues 1 to 30) corresponded to the sequence (residues 6 to 35) of the deduced product of the fumarase gene of C. glutamicum (GenBank accession no. BAB98403). The molecular mass of the native enzyme was 200 kDa. The protein was a homotetramer, with a 50-kDa subunit molecular mass. The homotetrameric and stable properties indicated that the enzyme belongs to a family of Class II fumarase. Equilibrium constants (K _eq) for the enzyme reaction were determined at pH 6.0, 7.0, and 8.0, resulting in K _eq=6.4, 6.1, and 4.6 respectively in phosphate buffer and in 16, 19, and 17 in non-phosphate buffers. Among the amino acids and nucleotides tested, ATP inhibited the enzyme competitively, or in mixed-type, depending on the buffer. Substrate analogs, meso-tartrate, D-tartrate, and pyromellitate, inhibited the enzyme competitively, and D-malate in mixed-type.     

Genetic Characterization of the Resorcinol Catabolic Pathway in Corynebacterium glutamicum

Corynebacterium glutamicum grew on resorcinol as a sole source of carbon and energy. By genome-wide data mining, two gene clusters, designated NCgl1110-NCgl1113 and NCgl2950-NCgl2953, were proposed to encode putative proteins involved in resorcinol catabolism. Deletion of the NCgl2950-NCgl2953 gene cluster did not result in any observable phenotype changes. Disruption and complementation of each gene at NCgl1110-NCgl1113, NCgl2951, and NCgl2952 indicated that these genes were involved in resorcinol degradation. Expression of NCgl1112, NCgl1113, and NCgl2951 in Escherichia coli revealed that NCgl1113 and NCgl2951 both coded for hydroxyquinol 1,2-dioxygenases and NCgl1112 coded for maleylacetate reductases. NCgl1111 encoded a putative monooxygenase, but this putative hydroxylase was very different from previously functionally identified hydroxylases. Cloning and expression of NCgl1111 in E. coli revealed that NCgl1111 encoded a resorcinol hydroxylase that needs NADPH as a cofactor. E. coli cells containing Ncgl1111 and Ncgl1113 sequentially converted resorcinol into maleylacetate. NCgl1110 and NCgl2950 both encoded putative TetR family repressors, but only NCgl1110 was transcribed and functional. NCgl2953 encoded a putative transporter, but disruption of this gene did not affect resorcinol degradation by C. glutamicum. The function of NCgl2953 remains unclear.     

Electrophysiological Characterization of the Mechanosensitive Channel MscCG in Corynebacterium glutamicum

Corynebacterium glutamicum MscCG, also referred to as NCgl1221, exports glutamate when biotin is limited in the culture medium. MscCG is a homolog of Escherichia coli MscS, which serves as an osmotic safety valve in E. coli cells. Patch-clamp experiments using heterogeneously expressed MscCG have shown that MscCG is a mechanosensitive channel gated by membrane stretch. Although the association of glutamate secretion with the mechanosensitive gating has been suggested, the electrophysiological characteristics of MscCG have not been well established. In this study, we analyzed the mechanosensitive gating properties of MscCG by expressing it in E. coli spheroplasts. MscCG is permeable to glutamate, but is also permeable to chloride and potassium. The tension at the midpoint of activation is 6.68 ± 0.63 mN/m, which is close to that of MscS. The opening rates at saturating tensions and closing rates at zero tension were at least one order of magnitude slower than those observed for MscS. This slow kinetics produced strong opening-closing hysteresis in response to triangular pressure ramps. Whereas MscS is inactivated under sustained stimulus, MscCG does not undergo inactivation. These results suggest that the mechanosensitive gating properties of MscCG are not suitable for the response to abrupt and harmful changes, such as osmotic downshock, but are tuned to execute slower processes, such as glutamate export.     

Characterization of pGA1, a new plasmid from Corynebacterium glutamicum LP-6.

A new plasmid, pGA1, has been isolated from Corynebacterium glutamicum LP-6, and its detailed restriction map has been prepared. The 4.9-kb plasmid has a G + C content of 57%. It replicates in C. glutamicum ATCC13032 and is compatible with the three other plasmids, pCC1, pBL1 and pHM1519, commonly used for vector construction for amino acid-producing corynebacteria. Fusions of pGA1 with different Escherichia coli replicons (transferred from E. coli to Corynebacterium via transformation of spheroplasts or by filter mating experiments with intact cells) are shown to be suitable as shuttle plasmids; some of them are highly stable in C. glutamicum, even when propagated without any selection pressure.     

Characterization of the cspB gene encoding PS2, an ordered surface-layer protein in Corynebacterium glutamicum

PS2 is one of two major proteins detected in the culture media of various Corynebacterium glutamicum strains. The coding and promoter regions of the cspB gene encoding PS2 were cloned in lambda gt11 using polyclonal antibodies raised against PS2 for screening. Expression of the cspB gene in Escherichia coli led to the production of a major anti-PS2 labelled peptide of 63 000 Da, corresponding presumably to the mature form of PS2. It was detected in the cytoplasm, periplasm and surrounding medium of E. coli. Three other slower migrating bands of 65000, 68 000 and 72 000 Da were detected. The largest one probably corresponds to the precursor form of PS2 in E. coli. Analysis of the nucleotide sequence revealed an open reading frame (ORF) of 1533 nucleotides. The deduced 510-amino-acid polypeptide had a calculated molecular mass of 55 426 Da. According to the predicted amino acid sequence, PS2 is synthesized with a W-terminal segment of 30-amino-acid residues reminiscent of eukaryotic and prokaryotic signal pep-tides, and a hydrophobic domain of 21 residues near the C-terminus. Although no significant homologies were found with other proteins, it appears that some characteristics and the amino acid composition of PS2 share several common features with surface-layer proteins. The cspB gene was then disrupted in C. glutamicum by gene replacement. Freeze-etching electron microscopy performed on the wild-type strain indicated that the cell wall of C. glutamicum is covered with an ordered surface of proteins (surface layer, S-layer) which is in very close contact with other cell-wall components. These structures are absent from the cspB-disrupted strain but are present after reintroduction of the cspB gene on a plasmid into this mutant. Thus we demonstrate that the Slayer protein is the product of the cspB gene.     

Characterization and partial purification of L-asparaginase from Corynebacterium glutamicum

A high L-asparaginase (L-asparagine amidohydrolase: EC 3.5.1.1) activity was found under conditions of lysine overproduction in cultures of Corynebacterium glutamicum. L-Asparaginase was purified 98-fold by protamine sulphate precipitation. DEAE-Sephacel anion exchange, ammonium sulphate precipitation and Sephacryl S-200 gel filtration. The asparaginase protein was subjected to PAGE under non-denaturing conditions, identified by an in situ reaction and eluted from the gel in an active form. The estimated Mr from gel filtration and SDS-PAGE was 80,000. The L-asparaginase activity was inhibited by the L-asparagine analogue 5-diazo-4-oxo-L-norvaline. Neither D-asparagine nor L-glutamine was a substrate for the enzyme. L-Asparaginase was produced constitutively: its role may be that of an overflow enzyme, converting excess asparagine into aspartic acid, the direct precursor of lysine and threonine.     

Subcellular Localization and Characterization of the ParAB System from Corynebacterium glutamicum

Faithful segregation of chromosomes and plasmids is a vital prerequisite to produce viable and genetically identical progeny. Bacteria use a specialized segregation system composed of the partitioning proteins ParA and ParB to segregate certain plasmids. Strikingly, homologues of ParA and ParB are found to be encoded in many chromosomes. Although mutations in the chromosomal Par system have effects on segregation efficiency, the exact mechanism by which the chromosomes are segregated into the daughter cells is not fully understood. We describe the polar localization of the ParB origin nucleoprotein complex in the actinomycete Corynebacterium glutamicum. ParB and the origin of replication were found to be stably localized to the cell poles. After replication, the origins move toward the opposite pole. Purified ParB was able to bind to the parS consensus sequence in vitro. C. glutamicum possesses two ParA-like partitioning ATPase proteins. Both proteins interact with ParB but show a slightly different subcellular localization and phenotype. While ParA might be part of a conventional partitioning system, PldP seems to play a role in division site selection.Bacterial cell division is a temporally and spatially tightly regulated process (1, 13, 16, 36, 37). Spatial regulation is achieved by division site selection and prevents fatal division across the nucleoids and aberrant division close to the cell poles (3, 40). Temporal control ensures that division does not precede chromosome replication and segregation. Replicated chromosomes are rapidly segregated into the daughter cells. However, the machinery that performs this active segregation is not fully elucidated. In contrast, plasmid segregation is somewhat better understood. Plasmids such as pB171 (8) encode a machinery composed of a tripartite system. Centromere-like DNA sequences, named parS sites, are composed of short inverted repeats. Centromere-binding proteins (ParB) are recruited to the parS sites, forming nucleoprotein complexes. Finally, a partitioning ATPase is recruited to the ParB-parS complex. The hydrolytic activity of ParA oligomers is believed to drive the active segregation process. Strikingly, many bacterial chromosomes encode orthologs of the plasmid partitioning genes parA and parB. A comparatively well-examined chromosomal partitioning system is that of Bacillus subtilis. B. subtilis encodes a ParA ATPase (called Soj) and a ParB protein (called Spo0J). B. subtilis contains eight parS sites that cluster around the oriC region and bind Spo0J. Subsequently Spo0J spreads across the DNA, thereby forming a huge nucleoprotein complex that could serve as a platform for anchoring the segregation machinery. The ParA protein Soj is a DNA-binding protein that dissociates from DNA upon ATP hydrolysis. A direct interaction of Soj and Spo0J has been described (35). Interestingly, analysis of knockout mutations revealed that only the loss of the ParB protein Spo0J increases the amount of anucleate cells slightly, while the loss of Soj has no significant effect on chromosome segregation (17, 18). However, knockout mutations in either parA or parB result only in subtle effects on chromosome segregation. Thus, although the two proteins might act together they have certainly multiple roles during chromosome segregation and cell division. Recently, it was shown that Spo0J (ParB) helps to recruit SMC proteins (for structural maintenance of chromosomes) to the oriC region, thereby ensuring correct chromosome organization, which seems essential for proper segregation (15, 39). The B. subtilis ParA homologue Soj was shown to play an role in the initiation of DNA replication by interacting with DnaA (32). Hence, the ParAB system is a central component connecting replication and segregation. Interestingly, Par proteins have been implicated with different developmental processes in other bacteria. In Caulobacter crescentus ParAB are involved in cell cycle progression and cell division. A ParA-like protein, MipZ, was shown to interact with ParB and directly inhibit FtsZ polymerization (42). Thus, chromosome segregation and cell division are directly coupled. Consequently, null mutations in ParA and ParB are lethal in C. crescentus. In Vibrio cholerae it was shown that ParA and ParB encoded on the large chromosome contribute to active chromosome segregation and anchor the oriC region of the chromosomes to the cell poles (10).Although these diverse properties of the Par system have been studied in some detail in the classical model organisms, the situation in other bacteria remains unknown. Corynebacteria are high GC Gram-positive bacteria and, depending on the growth medium, rod-shaped or club-shaped. A remarkable feature of corynebacteria and their close relatives is a special cell wall that has, in addition to the common peptidoglycan, an arabino-galactan and a mycolic acid layer. Notorious pathogens such as Mycobacterium tuberculosis, Mycobacterium leprae, and Corynebacterium diphtheriae are members of this family, and hence an understanding of fundamental cell biological mechanisms might reveal insights how to combat these organisms. We now report the subcellular localization of the chromosome partitioning system and the oriC in the actinomycete Corynebacterium glutamicum. We show localization and phenotypic consequences of the canonical ParAB proteins. Furthermore, we identified a ParA-like division protein (PldP) that plays a role in division site selection.     

Analysing overexpression of l-valine biosynthesis genes in pyruvate-dehydrogenase-deficient Corynebacterium glutamicum

l-Valine biosynthesis was analysed by comparing different plasmids in pyruvate-dehydrogenase-deficient Corynebacterium glutamicum strains in order to achieve an optimal production strain. The plasmids contained different combinations of the genes ilvBNCDE encoding for the l-valine forming pathway. It was shown that overexpression of the ilvBN genes encoding acetolactate synthase is obligatory for efficient pyruvate conversion and to prevent l-alanine as a by-product. In contrast to earlier studies, overexpression of ilvE encoding transaminase B is favourable in pyruvate-dehydrogenase-negative strains. Its amplification enhanced l-valine formation and avoided extra- and intracellular accumulation of ketoisovalerate.