The molecular structure of the Corynebacterium glutamicum threonine synthase gene

Analysis of Corynebacterium glutamicum promoters and their applications

Promoters are DNA sequences which function as regulatory signals of transcription initiation catalyzed by RNA polymerase. Since promoters substantially influence levels of gene expression, they have become powerful tools in metabolic engineering. Methods for their localization used in Corynebacterium glutamicum and techniques for the analysis of their function are described in this review. C. glutamicum promoters can be classified according to the respective σ factors which direct RNA polymerase to these structures. C. glutamicum promoters are recognized by holo-RNA polymerase formed by subunits α(2)ββ'ω + σ. C. glutamicum codes for seven different sigma factors: the principal sigma factor σ(A) and alternative sigma factors σ(B), σ(C), σ(D), σ(E), σ(H) and σ(M), which recognize various classes of promoters. The promoters of housekeeping genes recognized by σ(A), which are active during the exponential growth, form the largest described group. These promoters and their mutant derivatives are the most frequently used elements in modulation of gene expression in C. glutamicum. Promoters recognized by alternative sigma factors and their consensus sequences are gradually emerging.

The complete Corynebacterium glutamicum ATCC 13032 genome sequence and its impact on the production of L-aspartate-derived amino acids and vitamins

The complete genomic sequence of Corynebacterium glutamicum ATCC 13032, well-known in industry for the production of amino acids, e.g. of L-glutamate and L-lysine was determined. The C. glutamicum genome was found to consist of a single circular chromosome comprising 3282708 base pairs. Several DNA regions of unusual composition were identified that were potentially acquired by horizontal gene transfer, e.g. a segment of DNA from C. diphtheriae and a prophage-containing region. After automated and manual annotation, 3002 protein-coding genes have been identified, and to 2489 of these, functions were assigned by homologies to known proteins. These analyses confirm the taxonomic position of C. glutamicum as related to Mycobacteria and show a broad metabolic diversity as expected for a bacterium living in the soil. As an example for biotechnological application the complete genome sequence was used to reconstruct the metabolic flow of carbon into a number of industrially important products derived from the amino acid L-aspartate.

The threonine story

L-Threonine is an essential amino acid which has recently been brought into agricultural industry for balancing the livestock feed. L-Threonine is produced by microbial synthesis using glucose or sucrose as substrates. For the process to be cost-effective, the microbial strain must be capable of threonine overproduction. This paper reviews the biochemical pathways of L-threonine synthesis in bacteria and the regulation of these pathways, the principles and the techniques of constructing high-producing strains, and the most efficient strains thus developed.

Identification of glyA (encoding serine hydroxymethyltransferase) and its use together with the exporter ThrE to increase L-threonine accumulation by Corynebacterium glutamicum

L-threonine can be made by the amino acid-producing bacterium Corynebacterium glutamicum. However, in the course of this process, some of the L-threonine is degraded to glycine. We detected an aldole cleavage activity of L-threonine in crude extracts with an activity of 2.2 nmol min(-1) (mg of protein)(-1). In order to discover the molecular reason for this activity, we cloned glyA, encoding serine hydroxymethyltransferase (SHMT). By using affinity-tagged glyA, SHMT was isolated and its substrate specificity was determined. The aldole cleavage activity of purified SHMT with L-threonine as the substrate was 1.3 micromol min(-1) (mg of protein)(-1), which was 4% of that with L-serine as substrate. Reduction of SHMT activity in vivo was obtained by placing the essential glyA gene in the chromosome under the control of P(tac), making glyA expression isopropylthiogalactopyranoside dependent. In this way, the SHMT activity in an L-threonine producer was reduced to 8% of the initial activity, which led to a 41% reduction in glycine, while L-threonine was simultaneously increased by 49%. The intracellular availability of L-threonine to aldole cleavage was also reduced by overexpressing the L-threonine exporter thrE. In C. glutamicum DR-17, which overexpresses thrE, accumulation of 67 mM instead of 49 mM L-threonine was obtained. This shows that the potential for amino acid formation can be considerably improved by reducing its intracellular degradation and increasing its export.

Lipoamide dehydrogenase from Corynebacterium glutamicum: molecular and physiological analysis of the lpd gene and characterization of the enzyme

Lipoamide dehydrogenase (LPD) is an essential component of the pyruvate dehydrogenase and 2-oxoglutarate dehydrogenase complexes, both playing a crucial role within the central metabolism of aerobic organisms. Using oligonucleotides designed according to conserved regions of LPD amino acid sequences from several organisms, the lpd gene from Corynebacterium glutamicum was identified and subsequently subcloned. The cloned lpd gene expressed in C. glutamicum cells harbouring the gene on a plasmid showed a 12-fold higher specific LPD activity when compared to the wild-type strain. DNA sequence analysis of a 4524 bp segment containing the lpd gene and adjacent regions revealed that the lpd gene is not flanked by genes encoding other subunits of the pyruvate or 2-oxoglutarate dehydrogenase complexes and predicted an LPD polypeptide of 469 amino acids with an M(r) of 50619. The amino acid sequence of this polypeptide shows between 26 and 58% identity when compared to LPD enzymes from other organisms. Transcriptional analyses revealed that the lpd gene from C. glutamicum is monocistronic (1.45 kb mRNA) and that its transcription is initiated exactly at the nucleotide defined as the translational start. LPD was purified and biochemically characterized. This analysis revealed that the enzyme catalyses the reversible reoxidation of dihydrolipoic acid and NADH:NAD(+) transhydrogenation, and is able to transfer electrons from NADH to various redox-active compounds and quinones. An in vivo participation of C. glutamicum LPD in facilitation of quinone redox cycling is proposed.

Expression of threonine synthase from Solanum tuberosum L. is not metabolically regulated by photosynthesis-related signals or by nitrogenous compounds

Although the control of carbon fixation and nitrogen assimilation has been studied in detail, little is known about the regulation of carbon and nitrogen flow into amino acids. In this paper the isolation of a cDNA encoding threonine synthase is reported (TS; EC 4.2.99.2) from a leaf lambda ZAP II-library of Solanum tuberosum L. and the transcriptional regulation of the respective gene expression in response to metabolic changes. The pattern of expression of TS by feeding experiments of detached petioles revealed that TS expression is regulated neither by photosynthesis-related metabolites nor by nitrogenous compounds. The present study suggests that the regulation of the conversion of aspartate to threonine is not controlled at the transcript level of TS. The nucleotide and deduced amino acid sequences of potato TS show homology to other known sequences from Arabidopsis thaliana and microorganisms. TS is present as a low copy gene in the genome of potato as demonstrated in Southern blot analysis. When cloned into a bacterial expression vector, the cDNA did functionally complement the Escherichia coli mutant strain Gif41. TS transcript was found in all tissues of potato and was most abundant in flowers and source leaves.

A test case for structure-based functional assignment: the 1.2 A crystal structure of the yjgF gene product from Escherichia coli

The YER057c/YIL051c/YjgF protein family is a set of 24 full-length homologs, each approximately 130 residues in length, and each with no known function or relationship to proteins of known structure. To determine the function of this family, the structure of one member--the YjgF protein from Escherichia coli--was solved and refined at a resolution of 1.2 A. The YjgF molecule is a homotrimer with exact threefold symmetry. Its tertiary and quaternary structures are related to that of Bacillus subtilis chorismate mutase, although their active sites are completely different. The YjgF protein has an active site curiously similar to protein tyrosine phosphatases, including a covalently modified cysteine, but it is unlikely to be functionally related. The lessons learned from this attempt to deduce function from structure may be useful to future projects in structural genomics.

Characterization of an Arabidopsis thaliana cDNA encoding an S-adenosylmethionine-sensitive threonine synthase. Threonine synthase from higher plants

An Arabidopsis thaliana cDNA encoding an S-adenosylmethionine-sensitive threonine synthase (EC 4.2.99.2) has been isolated by functional complementation of an Escherichia coli mutant devoid of threonine synthase activity. Threonine synthase from A. thaliana was shown to be synthesized with a transit peptide. The recombinant protein is activated by S-adenosylmethionine in the same range as the plant threonine synthase and evidence is presented for an involvement of the N-terminal part of the mature enzyme in the sensitivity to S-adenosylmethionine.

Cloning and transcriptional analysis of two threonine biosynthetic genes from Lactococcus lactis MG1614

Two genes, hom and thrB, involved in threonine biosynthesis in Lactococcus lactis MG1614, were cloned and sequenced. These genes, which encode homoserine dehydrogenase and homoserine kinase, were initially identified by the homology of their gene products with known homoserine dehydrogenases and homoserine kinases from other organisms. The identification was supported by construction of a mutant containing a deletion in hom and thrB that was unable to grow in a defined medium lacking threonine. Transcriptional analysis showed that the two genes were located in a bicistronic operon with the order 5' hom-thrB 3' and that transcription started 66 bp upstream of the translational start codon of the hom gene. A putative -10 promoter region (TATAAT) was located 6 bp upstream of the transcriptional start point, but no putative -35 region was identified. A DNA fragment covering 155 bp upstream of the hom translational start site was functional in pAK80, an L. lactis promoter probe vector. In addition, transcriptional studies showed no threonine-dependent regulation of hom-thrB transcription.

Promoters from Corynebacterium glutamicum: cloning, molecular analysis and search for a consensus motif

Relatively limited information about promoter structures in Corynebacterium glutamicum has been available until now. With the aim of isolating and characterizing such transcription initiation signals, random Sau3A fragments of C. glutamicum chromosomal DNA and of the corynebacterial phage phi GA1 were cloned into the promoter probe vector pEKplCm and selected for promoter activity by chloramphenicol resistance of transformed C. glutamicum cells. The nucleotide sequence of ten chromosomal and three phage fragments was determined and the transcriptional start (TS) sites were localized by primer extension analyses. Additionally, the promoters of five previously isolated C. glutamicum genes were cloned and mapped. All of the isolated promoters were also functional in the heterologous host Escherichia coli. A comparative analysis of the newly characterized promoter sequences together with published promoters from C. glutamicum revealed conserved sequences centred about 35 bp (ttGcca) and 10 bp (TA.aaT) upstream of the TS site. The position of these motifs and the motifs themselves are comparable to the -35 and -10 promoter consensus sequences of other Gram-positive and Gram-negative bacteria, indicating that they represent transcription initiation signals in C. glutamicum. However, the C. glutamicum consensus hexamer of the -35 region is much less conserved than in E. coli, Bacillus, Lactobacillus and Streptococcus.

AgTHR4, a new selection marker for transformation of the filamentous fungus Ashbya gossypii, maps in a four-gene cluster that is conserved between A. gossypii and Saccharomyces cerevisiae

Single-read sequence analysis of the termini of eight randomly picked clones of Ashbya gossypii genomic DNA revealed seven sequences with homology to Saccharomyces cerevisiae genes (15% to 69% on the amino acid level). One of these sequences appeared to code for the carboxy-terminus of threonine synthase, the product of the S. cerevisiae THR4 gene (52.4% identity over 82 amino acids). We cloned and sequenced the complete putative AgTHR4 gene of A. gossypii. It comprises 512 codons, two less than the S. cerevisiae THR4 gene. Overall identity at the amino acid sequence level is 67.4%. A continuous stretch of 32 amino acids displaying complete identity between these two fungal threonine synthases presumably contains the pyridoxal phosphate attachment site. Disruption of the A. gossypii gene led to threonine auxotrophy, which could be complemented by transformation with replicating plasmids carrying the AgTHR4 gene and various S. cerevisiae ARS elements. Using these plasmids only very weak complementation of a S. cerevisiae thr4 mutation was observed. Investigation of sequences adjacent to the AgTHR4 gene identified three additional ORFs. Surprisingly, the order and orientation of these four ORFs is conserved in A. gossypii and S. cerevisiae.

Molecular cloning of the hom-thrC-thrB cluster from Bacillus sp. ULM1: expression of the thrC gene in Escherichia coli and corynebacteria, and evolutionary relationships of the threonine genes

A 6.5 kb DNA fragment containing the gene (thrC) encoding threonine synthase, the last enzyme of the threonine biosynthetic pathway, has been cloned from the DNA of Bacillus sp. ULM1 by complementation of Escherichia coli and Brevibacterium lactofermentum thrC auxotrophs. Complementation studies showed that the thrB gene (encoding homoserine kinase) is found downstream from the thrC gene, and analysis of nucleotide sequences indicated that the hom gene (encoding homoserine dehydrogenase) is located upstream of the thrC gene. The organization of this cluster of genes is similar to the Bacillus subtilis threonine operon (hom-thrC-thrB). An 1.9 kb BclI fragment from the Bacillus sp. ULM1 DNA insert 351 amino acids was found corresponding to a protein of 37462 Da. The thrC gene showed a low G + C content (39.4%) and the encoded threonine synthase is very similar to the B. subtilis enzyme. Expression of the 1.9 kb BcI DNA fragment in E. coli minicells resulted in the formation of a 37 kDa protein. The upstream region of this gene shows promoter activity in E. coli but not in corynebacteria. A peptide sequence, including a lysine that is known to bind the pyridoxal phosphate cofactor, is conserved in all threonine synthase sequences and also in the threonine and serine dehydratase genes. Amino acid comparison of nine threonine synthases revealed evolutionary relationships between different groups of bacteria.

Recent advances in the physiology and genetics of amino acid-producing bacteria

Corynebacterium glutamicum and its close relatives, C. flavum and C. lactofermentum, have been used for over 3 decades in the industrial production of amino acids by fermentation. Since 1984, several research groups have started programs to develop metabolic engineering principles for amino acid-producing Corynebacterium strains. Initially, the programs concentrated on the isolation of genes encoding (deregulated) biosynthetic enzymes and the development of general molecular biology tools such as cloning vectors and DNA transfer methods. With most of the genes and tools now available, recombinant DNA technology can be applied in strain improvement. To accomplish these improvements, it is critical and advantageous to understand the mechanisms of gene expression and regulation as well as the biochemistry and physiology of the species being engineered. This review explores the advances made in the understanding and application of amino acid-producing bacteria in the early 1990s.

Effect of inducible thrB expression on amino acid production in Corynebacterium lactofermentum ATCC 21799

Amplification of the operon homdr-thrB encoding a feedback-insensitive homoserine dehydrogenase and a wild-type homoserine kinase in a Corynebacterium lactofermentum lysine-producing strain resulted in both homoserine and threonine accumulation, with some residual lysine production. A plasmid enabling separate transcriptional control of each gene was constructed to determine the effect of various enzyme activity ratios on metabolite accumulation. By increasing the activity of homoserine kinase relative to homoserine dehydrogenase activity, homoserine accumulation in the medium was essentially eliminated and the final threonine titer was increased by about 120%. Furthermore, a fortuitous result of the cloning strategy was an unexplained increase in homoserine dehydrogenase activity. This resulted in a further decrease in lysine production along with a concomitant increase in threonine accumulation.

Transcriptional analysis and regulatory signals of the hom-thrB cluster of Brevibacterium lactofermentum

Two genes, hom (encoding homoserine dehydrogenase) and thrB (encoding homoserine kinase), of the threonine biosynthetic pathway are clustered in the chromosome of Brevibacterium lactofermentum in the order 5' hom-thrB 3', separated by only 10 bp. The Brevibacterium thrB gene is expressed in Escherichia coli, in Brevibacterium lactofermentum, and in Corynebacterium glutamicum and complements auxotrophs of all three organisms deficient in homoserine kinase, whereas the Brevibacterium hom gene did not complement two different E. coli auxotrophs lacking homoserine dehydrogenase. However, complementation was obtained when the homoserine dehydrogenase was expressed as a fusion protein in E. coli. Northern (RNA) analysis showed that the hom-thrB cluster is transcribed, giving two different transcripts of 2.5 and 1.1 kb. The 2.5-kb transcript corresponds to the entire cluster hom-thrB (i.e., they form a bicistronic operon), and the short transcript (1.1 kb) originates from the thrB gene. The promoter in front of hom and the hom-internal promoter in front of thrB were subcloned in promoter-probe vectors of E. coli and corynebacteria. The thrB promoter is efficiently recognized both in E. coli and corynebacteria, whereas the hom promoter is functional in corynebacteria but not in E. coli. The transcription start points of both promoters have been identified by primer extension and S1 mapping analysis. The thrB promoter was located in an 87-bp fragment that overlaps with the end of the hom gene. A functional transcriptional terminator located downstream from the cluster was subcloned in terminator-probe vectors.

Analysis and expression of the thrC gene of Brevibacterium lactofermentum and characterization of the encoded threonine synthase

The thrC gene of Brevibacterium lactofermentum was cloned by complementation of Escherichia coli thrC auxotrophs. The gene was located by deletion mapping and complementation analysis in a 2.9-kb Sau3AI-HindIII fragment of the genome. This fragment also complemented a B. lactofermentum UL1035 threonine auxotroph that was deficient in threonine synthase. A 1,892-bp DNA fragment of this region was sequenced; this fragment contained a 1,446-bp open reading frame that encoded a 481-amino-acid protein having a deduced M(r) of 52,807. The gene was expressed in E. coli, by using the phage T7 system, as a 53-kDa protein. The promoter region subcloned in promoter-probe plasmids was functional in E. coli. A Northern analysis revealed that the gene was expressed as a monocistronic 1,400-nucleotide transcript. The transcription start point of the thrC gene was located by S1 mapping 6 bp upstream from the translation initiation codon, which indicated that this promoter was one of the leaderless transcription-initiating sequences. The threonine synthase overexpressed in B. lactofermentum UL1035 was purified almost to homogeneity. The active form corresponded to a monomeric 52.8-kDa protein, as shown by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. The purified enzyme required pyridoxal phosphate as its only cofactor to convert homoserine phosphate into threonine.

Molecular aspects of lysine, threonine, and isoleucine biosynthesis in Corynebacterium glutamicum

The Gram-positive bacterium Corynebacterium glutamicum is used for the industrial production of amino acids, e.g. of L-glutamate and L-lysine. In the last ten years genetic engineering methods were developed for C. glutamicum and consequently, recombinant DNA technology was employed to study the biosynthetic pathways and to improve the amino acid productivity by manipulation of enzymatic, transport and regulatory functions of this bacterium. The present review summarizes the current knowledge on the synthesis and over-production of the aspartate derived amino acids L-lysine, L-threonine and L-isoleucine in C. glutamicum. A special feature of C. glutamicum is its ability to convert the lysine intermediate piperideine2,6-dicarboxylate to diaminopimelate by two different routes, i.e. by reactions involving succinylated intermediates or by the single reaction of diaminopimelate dehydrogenase. The flux distribution over the two pathways is regulated by the ammonium availability. The overall carbon flux from aspartate to lysine, however, is governed by feedback-control of the aspartate kinase and by the level of dihydrodipicolinate synthase. Consequently, expression of lysCFBR encoding a deregulated aspartate kinase and/or the overexpression of dapA encoding dihydrodipicolinate synthase led to overproduction of lysine. As a further specific feature C. glutamicum possesses a specific lysine export carrier which shows high activity in lysine overproducing mutants. Threonine biosynthesis is in addition to control by the aspartate kinase tightly regulated at the level of homoserine dehydrogenase which is subject to feedback-inhibition and to repression. C. glutamicum strains possessing a deregulated aspartate kinase and a deregulated homoserine dehydrogenase produce lysine and threonine. Amplification of deregulated homoserine dehydrogenase in such strains led to an almost complete redirection of the carbon flux to threonine. For a further flux from threonine to isoleucine the allosteric control of threonine dehydratase and of the acetohydroxy acid synthase are important. The expression of the genes encoding the latter enzyme is additionally regulated at the transcriptional level. By addition of 2-oxobutyrate as precursor and by bypassing the expression control of the acetohydroxy acid synthase genes high isoleucine overproduction can be obtained.

Transcriptional analysis of the gap-pgk-tpi-ppc gene cluster of Corynebacterium glutamicum

The transcriptional organization of the Corynebacterium glutamicum gap-pgk-tpi-ppc gene cluster, encoding glyceraldehyde-3-phosphate dehydrogenase, 3-phosphoglycerate kinase, triosephosphate isomerase, and phosphoenolpyruvate carboxylase, was investigated by Northern (RNA) blot and primer extension analyses. Four transcripts corresponding to gap, to gap-pgk-tpi, to pgk-tpi, and to pgk-tpi-ppc were identified. The respective transcriptional initiation sites in front of gap and pgk were located, and, from the analysis of DNA sequences upstream of these and of previously determined transcriptional start sites, common structures which may be important for promoter function in C. glutamicum are discussed.

The cloning and nucleotide sequence of a Corynebacterium glutamicum 3-deoxy-D-arabinoheptulosonate-7-phosphate synthase gene

The aro gene of Corynebacterium glutamicum CCRC 18310 encoding 3-deoxy-D-arabinoheptulosonate-7-phosphate (DAHP) synthase was isolated by complementation of a DAHP synthase-deficient mutant of Escherichia coli AB3257. The specific activity of DAHP synthase was increased four-fold in a C. glutamicum strain harboring the cloned aro gene. The complete nucleotide sequence of the aro gene and its 5' and 3' flanking regions has been determined. The sequence contained an open reading frame of 368 codons, from which a protein with a molecular mass of 39,340 Da could be predicted. The deduced amino acid sequence shows high identity with the aro gene products of E. coli and Salmonella typhimurium.

Evolutionary comparisons of three enzymes of the threonine biosynthetic pathway among several microbial species

As an approach in the study of the evolution of threonine biosynthetic pathways throughout various organisms, the sequences of three enzymes, namely homoserine dehydrogenase, homoserine kinase and threonine synthase, originating from six organisms, namely Escherichia coli, Bacillus subtilis, Corynebacterium glutamicum, Brevibacterium lactofermentum, Pseudomonas aeruginosa and Saccharomyces cerevisiae, were compared. As a general trend all three enzymatic activities were carried out by proteins sharing sequence relatedness (except for the homoserine kinase of P aeruginosa). Unexpectedly however, for each step one or two enzymes stood out of the main stream: i) for homoserine dehydrogenase, the yeast protein is atypically similar to the E coli enzyme; ii) for homoserine kinase, the P aeruginosa protein shares no similarity with any other species; and iii) for threonine synthase, the B subtilis protein is far distant from the enzymes of other species. Hence in contrast to other biosynthetic pathways such as the tryptophan one, the threonine pathway seems not to have evolved as a whole throughout different organisms but rather each step seems to have been subjected to multiple constraints including substrate-mediated ones and host-specific ones.

Functional and structural analyses of threonine dehydratase from Corynebacterium glutamicum

Threonine dehydratase activity is an important element in the flux control of isoleucine biosynthesis. The enzyme of Corynebacterium glutamicum demonstrates a marked sigmoidal dependence of initial velocity on the threonine concentration, a dependence that is consistent with substrate-promoted conversion of the enzyme from a low-activity to a high-activity conformation. In the presence of the negative allosteric effector isoleucine, the K0.5 increased from 21 to 78 mM and the cooperativity, as expressed by the Hill coefficient increased from 2.4 to 3.7. Valine promoted opposite effects: the K0.5 was reduced to 12 mM, and the enzyme exhibited almost no cooperativity. Sequence determination of the C. glutamicum gene for this enzyme revealed an open reading frame coding for a polypeptide of 436 amino acids. From this information and the molecular weight determination of the native enzyme, it follows that the dehydratase is a tetramer with a total mass of 186,396 daltons. Comparison of the deduced polypeptide sequence with the sequences of known threonine dehydratases revealed surprising differences from the C. glutamicum enzyme in the carboxy-terminal portion. This portion is greatly reduced in size, and a large gap of 95 amino acids must be introduced to achieve homology. Therefore, the C. glutamicum enzyme must be considered a small variant of threonine dehydratase that is typically controlled by isoleucine and valine but has an altered structure reflecting a topological difference in the portion of the protein most likely to be important for allosteric regulation.

Isolation, organization and expression of the Pseudomonas aeruginosa threonine genes

Three genes from Pseudomonas aeruginosa involved in threonine biosynthesis, hom, thrB and thrC, encoding homoserine dehydrogenase (HDH), homoserine kinase (HK) and threonine synthase (TS), respectively, have been cloned and sequenced. The hom and thrc genes lie at the thr locus of the P. aeruginosa chromosome map (31 min) and are likely to be organized in a bicistronic operon. The encoded proteins are quite similar to the Hom and TS proteins from other bacterial species. The thrB gene was located by pulsed-field gel electrophoresis experiments at 10 min on the chromosome map. The product of this gene does not share any similarity with other known ThrB proteins. No phenotype could be detected when the chromosomal thrB gene was inactivated by an insertion. Therefore the existence of isozymes for this activity is postulated. HDH activity was feedback inhibited by threonine; the expression of all three genes was constitutive. The overall organization of these three genes appears to differ from that in other bacterial species.

Molecular analysis of the Corynebacterium glutamicum gdh gene encoding glutamate dehydrogenase

The Corynebacterium glutamicum gdh gene encoding NADP-dependent glutamate dehydrogenase (GDH) has been isolated by complementation of the Escherichia coli gdh mutant PA340. The gdh gene was subcloned into the E. coli/C. glutamicum shuttle vector pEK0 and introduced into C. glutamicum. Recombinant strains showed approximately eightfold higher specific GDH activity (15U mg protein-1) relative to the wild type (1.8U mg protein-1). Physiological studies with wild-type and recombinant C. glutamicum strains revealed no indication of significant regulation of gdh expression. The DNA sequence of 2082 bp, including the gdh gene, 5'-, and 3'-flanking regions, was determined. The structural gene consists of 1344 bp and codes for a polypeptide of 448 amino acid residues (Mr 49,152) showing up to 53.6% identity with reported amino acid sequences of glutamate dehydrogenases from other organisms. Northern blot hybridization revealed a 1.65kb mRNA transcript, indicating that the gdh gene of C. glutamicum is monocistronic. Transcription occurred from a G residue located 284 bp upstream of the AUG considered to be the translational initiation codon.

A C-terminal deletion in Corynebacterium glutamicum homoserine dehydrogenase abolishes allosteric inhibition by L-threonine

In Escherichia coli, Bacillus subtilis and Corynebacterium glutamicum, homoserine dehydrogenase (HD), the enzyme after the branch point of the threonine/methionine and lysine biosynthetic pathways, is allosterically inhibited by L-threonine. To investigate the regulation of the C. glutamicum HD enzyme by L-threonine, the structural gene, hom, was mutated by UV irradiation of whole cells to obtain a deregulated allele, homdr. L-Threonine inhibits the wild-type (wt) enzyme with a Ki of 0.16 mM. The deregulated enzyme remains 80% active in the presence of 50 mM L-threonine. The homdr gene mutant was isolated and cloned in E. coli. In a C. glutamicum wt host background, but not in E. coli, the cloned homdr gene is genetically unstable. The cloned homdr gene is overexpressed tenfold in C. glutamicum and is active in the presence of over 60 mM L-threonine. Sequence analysis revealed that the homdr mutation is a single nucleotide (G1964) deletion in codon 429 within the hom reading frame. The resulting frame-shift mutation radically alters the structure of the C terminus, resulting in ten amino acid (aa) changes and a deletion of the last 7 aa relative to the wt protein. These observations suggest that the C terminus may be associated with the L-threonine allosteric response. The homdr mutation is unstable and probably deleterious to the cell. This may explain why only one mutation was obtained despite repeated mutagenesis.

Amplification of three threonine biosynthesis genes in Corynebacterium glutamicum and its influence on carbon flux in different strains

The hom-thrB operon (homoserine dehydrogenase/homoserine kinase) and the thrC gene (threonine synthase) of Corynebacterium glutamicum ATCC 13,032 and the homFBR (homoserine dehydrogenase resistant to feedback inhibition by threonine) alone as well as homFBR-thrB operon of C. glutamicum DM 368-3 were cloned separately and in combination in the Escherichia coli/C. glutamicum shuttle vector pEK0 and introduced into different corynebacterial strains. All recombinant strains showed 8- to 20-fold higher specific activities of homoserine dehydrogenase, homoserine kinase, and/or threonine synthase compared to the respective host. In wild-type C. glutamicum, amplification of the threonine genes did not result in secretion of threonine. In the lysine producer C. glutamicum DG 52-5 and in the lysine-plus-threonine producer C. glutamicum DM 368-3 overexpression of hom-thrB resulted in a notable shift of carbon flux from lysine to threonine whereas cloning of homFBR-thrB as well as of homFBR in C. glutamicum DM 368-3 led to a complete shift towards threonine or towards threonine and its precursor homoserine, respectively. Overexpression of thrC alone or in combination with that of homFBR and thrB had no effect on threonine or lysine formation in all recombinant strains tested.

Nucleotide sequence and organization of the upstream region of the Corynebacterium glutamicum lysA gene

Maximum expression of the Corynebacterium glutamicum lysA gene is dependent upon the presence of a 2.3 kb region immediately 5' of the lysA reading frame. Subcloning and functional analysis of the upstream region implied that this region contained the lysA promoter. Sequence determination of the upstream region revealed a single open reading frame, orfX, in the same orientation as lysA. The orfX coding sequence exhibited all the sequence characteristics of a gene with the potential for a 550-amino-acid polypeptide product. Expression of lysA is coupled to that of orfX via a common promoter located immediately 5' of orfX. The RNA start site has been determined by S1 nuclease mapping. Both the orfX and the lysA gene are expressed as a single 3.0 kb RNA transcript. These data indicate that orfX and lysA are genes within a two-gene operon. Expression of the lysA gene is not subject to regulation by lysine. The orfX gene product was shown not to be directly linked to the lysine biosynthetic pathway, nor is it the enzyme incorporating DAP into the peptidoglycan precursor.