L-threonine export: use of peptides to identify a new translocator from Corynebacterium glutamicum

Bacterial mechanisms for the uptake of peptides and their hydrolysis to amino acids are known in great detail, whereas much less is known about the fates of the peptide-derived amino acids. We show that the addition of L-threonine-containing di- or tripeptides results in reduction of the growth of Corynebacterium glutamicum, with concomitant high intracellular accumulation of L-threonine to up to 130 mM. Using transposon mutagenesis and isolation of mutants with increased Thr peptide sensitivity, nine open reading frames (ORFs) were identified, almost all encoding hypothetical proteins of unknown function. Three ORFs encode membrane proteins. Their individual functional characterizations in the wild-type background led to the identification of thrE. Upon thrE overexpression, growth is no longer sensitive to the presence of the Thr peptide, and L-threonine is exported at a rate of 3.8 nmol min(-1) mg of dry weight(-1), whereas the rate of export of a thrE inactivation mutant is reduced to 1.1 nmol min(-1) mg of dry weight(-1). In addition to L-threonine, L-serine is also a substrate for the exporter. The exporter exhibits nine predicted transmembrane-spanning helices with long charged C and N termini and with an amphipathic helix present within the N terminus. All these data suggest that the carrier encoded by thrE serves to export small molecules such as L-threonine and that the carrier is a prototype of a new translocator family. Homologues of ThrE are present in Mycobacterium tuberculosis and Streptomyces coelicolor.     

Reduced folate supply as a key to enhanced L-serine production by Corynebacterium glutamicum

The amino acid L-serine is required for pharmaceutical purposes, and the availability of a sugar-based microbial process for its production is desirable. However, a number of intracellular utilization routes prevent overproduction of L-serine, with the essential serine hydroxymethyltransferase (SHMT) (glyA) probably occupying a key position. We found that constructs of Corynebacterium glutamicum strains where chromosomal glyA expression is dependent on Ptac and lacIQ are unstable, acquiring mutations in lacIQ, for instance. To overcome the inconvenient glyA expression control, we instead considered controlling SHMT activity by the availability of 5,6,7,8-tetrahydrofolate (THF). The pabAB and pabC genes of THF synthesis were identified and deleted in C. glutamicum, and the resulting strains were shown to require folate or 4-aminobenzoate for growth. Whereas the C. glutamicum DeltasdaA strain (pserACB) accumulates only traces of L-serine, with the C. glutamicum DeltapabABCDeltasdaA strain (pserACB), L-serine accumulation and growth responded in a dose-dependent manner to an external folate supply. At 0.1 mM folate, 81 mM L-serine accumulated. In a 20-liter controlled fed-batch culture, a 345 mM L-serine accumulation was achieved. Thus, an efficient and highly competitive process for microbial l-serine production is available.     

Metabolic engineering of acetaldehyde production by Streptococcus thermophilus

The process of acetaldehyde formation by the yogurt bacterium Streptococcus thermophilus is described in this paper. Attention was focused on one specific reaction for acetaldehyde formation catalyzed by serine hydroxymethyltransferase (SHMT), encoded by the glyA gene. In S. thermophilus, SHMT also possesses threonine aldolase (TA) activity, the interconversion of threonine into glycine and acetaldehyde. In this work, several wild-type S. thermophilus strains were screened for acetaldehyde production in the presence and absence of L-threonine. Supplementation of the growth medium with L-threonine led to an increase in acetaldehyde production. Furthermore, acetaldehyde formation during fermentation could be correlated to the TA activity of SHMT. To study the physiological role of SHMT, a glyA mutant was constructed by gene disruption. Inactivation of glyA resulted in a severe reduction in TA activity and complete loss of acetaldehyde formation during fermentation. Subsequently, an S. thermophilus strain was constructed in which the glyA gene was cloned under the control of a strong promoter (P(LacA)). When this strain was used for fermentation, an increase in TA activity and in acetaldehyde and folic acid production was observed. These results show that, in S. thermophilus, SHMT, displaying TA activity, constitutes the main pathway for acetaldehyde formation under our experimental conditions. These findings can be used to control and improve acetaldehyde production in fermented (dairy) products with S. thermophilus as starter culture.     

Activity of exporters of Escherichia coli in Corynebacterium glutamicum, and their use to increase L-threonine production

L-Threonine is an important biotechnological product and Corynebacterium glutamicum is able to synthesize and accumulate this amino acid to high intracellular levels. We here use four exporters of Escherichia coli and show that three of them operate in C. glutamicum, with RhtA and RhtC being the most effective. Whereas RhtA was unspecific, resulting in L-homoserine together with L-threonine excretion, this was not the case with RhtC. Expression of rhtC reduced the intracellular L-threonine concentration from 140 to 11 mM and resulted in maximal excretion rates of 11.2 nmol min(-1) mg(-1) as compared to 2.3 nmol min(-1) mg(-1) obtained without rhtC expression. In combination with an ilvA mutation generated and introduced into the chromosome, an accumulation of up to 54 mM L-threonine was achieved as compared to 21 mM obtained with the ancestor strain. This shows that expression of rhtC is the pivotal point for industrial relevant L-threonine production with C. glutamicum, and might encourage in general the use of heterologous exporters in the field of white biotechnology to make full use of biosynthesis pathways.     

Bacterial catabolism of threonine. Threonine degradation initiated by L-threonine-NAD+ oxidoreductase.

1. Isolates representing seven bacterial genera capable of growth on L-threonine medium, and possessing high L-threonine 3-dehydrogenase activity, were examined to elucidate the catabolic route. 2. The results of growth, manometric and enzymic experiments indicated the catabolism of L-threonine by cleavage to acetyl-CoA plus glycine, the glycine being further metabolized via L-serine to pyruvate, in all cases. No evidence was obtained of a role for aminoacetone in threonine catabolism or for the metabolism of glycine by the glycerate pathway. 3. The properties of a number of key enzymes in L-threonine catabolism were investigated. The inducibly formed L-threonine 3-dehydrogenase, purified from Corynebacterium sp. B6 to a specific activity of about 30-35 mumol of product formed/min per mg of protein, exhibited a sigmoid kinetic response to substrate concentration. The half-saturating concentration of substrate, [S]0.5, was 20mM and the Hill constant (h) was 1.50. The Km for NAD+ was 0.8mM. The properties of the enzyme were studied in cell-free extracts of other bacteria. 4. New assays for 2-amino-3-oxobutyrate-CoA ligase were devised. The Km for CoA was determined for the first time and found to be 0.14mM at pH8, for the enzyme from Corynebacterium sp. B6. Evidence was obtained for the efficient linkage of the dehydrogenase and ligase enzymes. Cell-free extracts all possessed high activities of the inducibly formed ligase. 5. L-Serine hydroxymethyltransferase was formed constitutively by all isolates, whereas formation of the 'glycine-cleavage system' was generally induced by growth on L-threonine or glycine. The coenzyme requirements of both enzymes were established, and their linked activity in the production of L-serine from glycine was demonstrated by using extracts of Corynebacterium sp. B6. 6. L-Serine dehydratase, purified from Corynebacterium sp. B6 to a specific activity of about 4mumol of product formed/min per mg of protein, was found to exhibit sigmoid kinetics with an [S]0.5 of about 20mM and h identical to 1.4. Similar results were obtained with enzyme preparations from all isolates. The enzyme required Mg2+ for maximum activity, was different from the L-threonine dehydratase also detectable in extracts, and was induced by growth on L-threonine or glycine.     

Unbalance of L-lysine flux in Corynebacterium glutamicum and its use for the isolation of excretion-defective mutants.

We found that the simple addition of L-methionine to the wild type of Corynebacterium glutamicum results in excretion of the cellular building block L-lysine up to rates of 2.5 nmol/min/mg (dry weight). Biochemical analyses revealed that L-methionine represses the homoserine dehydrogenase activity and reduces the intracellular L-threonine level from 7 to less than 2 mM. Since L-lysine synthesis is regulated mainly by L-threonine (plus L-lysine) availability, the result is enhanced flux towards L-lysine. This indicates a delicate and not well controlled type of flux control at the branch point of aspartate semialdehyde conversion to either L-lysine or L-threonine, probably due to the absence of isoenzymes in C. glutamicum. The inducible system of L-lysine excretion discovered was used to isolate mutants defective in the excretion of this amino acid. One such mutant characterized in detail accumulated 174 mM L-lysine in its cytosol without extracellular excretion of L-lysine, whereas the wild type accumulated 53 mM L-lysine in the cytosol and 5.9 mM L-lysine in the medium. The mutant was unaffected in L-lysine uptake or L-isoleucine or L-glutamate excretion, and also the membrane potential was unaltered. This mutant therefore represents a strain with a defect in an excretion system for the primary metabolite L-lysine.     

Influence of threonine exporters on threonine production in Escherichia coli

Threonine production in Escherichia coli threonine producer strains is enhanced by overexpression of the E. coli rhtB and rhtC genes or by heterologous overexpression of the gene encoding the Corynebacterium glutamicum threonine excretion carrier, thrE. Both E. coli genes give rise to a threonine-resistant phenotype when overexpressed, and they decrease the accumulation of radioactive metabolites derived from [(14)C] L-threonine. The evidence presented supports the conclusion that both RhtB and RhtC catalyze efflux of L-threonine and other structurally related neutral amino acids, but that the specificities of these two carriers differ substantially.     

Identification of glyA as a symbiotically essential gene in Bradyrhizobium japonicum

A Bradyrhizobium japonicum Tn5 mutant (strain 3160) induced numerous, tiny, white nodules which were dispersed over the whole root system of its natural host plant, soybean (Glycine max). These ineffective, nitrogen non-fixing pseudonodules were disturbed at a very early step of bacteroid and nodule development. Subsequent cloning and sequencing of the DNA region mutated in strain 3160 revealed that the Tn5 insertion mapped in a gene that had 60% homology to the Escherichia coli glyA gene coding for serine hydroxymethyltransferase (SHMT; E.C.2.1.2.1.). SHMT catalyses the biosynthesis of glycine from serine and the transfer of a one-carbon unit to tetrahydrofolate. The B. japonicum glyA region was able to fully complement the glycine auxotrophy of an E. coli glyA deletion strain. Although the Tn5 insertion in B. japonicum mutant 3160 disrupted the glyA coding sequence, this strain was only a bradytroph (i.e. a leaky auxotroph). Thus, B. japonicum may have an additional pathway for glycine biosynthesis. Nevertheless, the glyA mutation was responsible for the drastic symbiotic phenotype visible on plants. It may be possible, therefore, that a sufficient supply with glycine and/or a functioning C1-metabolism are indispensable for the establishment of a fully effective, nitrogen-fixing root nodule symbiosis.     

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.     

大肠杆菌丝氨酸羟甲基转移酶基因(glyA)的克隆和表达

利用插入失活及营养缺陷型互补法将大肠杆菌K12 13kb的glyA基因克隆到质粒pBR329中。将重组质粒酶切,亚克隆,确定2.6kb PstI-EcoRI亚克隆片段带有完整的glyA基因。共获得12株glyA基因重组菌,对重组质粒进行了酶切鉴定。不同重组菌丝氨酸羟甲基转移酶(SHMT)活性及其酶表达量均不相同。受体菌未检测到丝氨酸的产生。重组菌株JM109(pSM13)、K12(pSM13)、K12(pSM14)和K12(pSM15)SHMT酶表达量分别占全菌可溶性蛋白的15.7％、15.4％、11.8％和9.48％。     

两种菌株来源的glyA基因的克隆、表达及酶活性检测

采用PCR方法,分别从大肠杆菌和嗜热链球菌基因组DNA中扩增获得glyA基因,分别克隆入载体pET-28 a(+)中并进行表达,分离和纯化得到两种不同来源的SHMT,分别检测两种SHMT的逆向酶活。比较来源于大肠杆菌K12与嗜热链球菌AS1.2471中的glyA基因表达的丝氨酸羟甲基转移酶(SHMT)的活性,以获得高活性的SHMT。结果成功获得两种菌中的glyA基因,并表达出具有较高活性的SHMT,其中嗜热链球菌中glyA基因表达出的SHMT的酶活性大约为大肠杆菌的两倍。从嗜热链球菌中克隆表达的SHMT具有更高的催化活性及良好的工业应用前景。     

Metabolic engineering of Corynebacterium glutamicum for L-serine production

Although L-serine proceeds in just three steps from the glycolytic intermediate 3-phosphoglycerate, and as much as 8% of the carbon assimilated from glucose is directed via L-serine formation, previous attempts to obtain a strain producing L-serine from glucose have not been successful. We functionally identified the genes serC and serB from Corynebacterium glutamicum, coding for phosphoserine aminotransferase and phosphoserine phosphatase, respectively. The overexpression of these genes, together with the third biosynthetic serA gene, serA(delta197), encoding an L-serine-insensitive 3-phosphoglycerate dehydrogenase, yielded only traces of L-serine, as did the overexpression of these genes in a strain with the L-serine dehydratase gene sdaA deleted. However, reduced expression of the serine hydroxymethyltransferase gene glyA, in combination with the overexpression of serA(delta197), serC, and serB, resulted in a transient accumulation of up to 16 mM L-serine in the culture medium. When sdaA was also deleted, the resulting strain, C. glutamicum delta sdaA::pK18mobglyA'(pEC-T18mob2serA(delta197)CB), accumulated up to 86 mM L-serine with a maximal specific productivity of 1.2 mmol h(-1) g (dry weight)(-1). This illustrates a high rate of L-serine formation and also utilization in the C. glutamicum wild type. Therefore, metabolic engineering of L-serine production from glucose can be achieved only by addressing the apparent key position of this amino acid in the central metabolism.     

Enzymatic production of L-serine

Serine hydroxymethyltransferase (SHMT) in the form of crude extract form a recombinant strain of Klebsiella aerogenes was used to study the production of L-serine from glycine and formaldehyde (HCHO). SHMT activity linearly increased with temperature (30-50 degrees C). Addition of exogenous cofactors, tetrahydrofolic acid and pyridoxal-phosphate, significantly increased SHMT activity. The pH optimum of the SHMT catalyzed L-serine synthesis step was between 8.0 and 8.5. The K(m) for glycine was 11.6mM at 37 degrees C and pH 8.0. A 87% molar conversion of glycine to serine was obtained at equilibrium (37 degrees C, pH 8.0). Tetrahydrofolic acid was stabilized by maintaining the redox potential of the reaction solution below -330 mV through the addition of a reducing reagent such as beta-mercaptoethanol. SHMT stability was very sensitive to HCHO concentration. By carefully balancing the HCHO feed rate against the enzymatic bioconversion rate in order to keep HCHO concentration low, a serine titer of 160 g/L was achieved, the residual glycine concentration was reduced to 40 g/L, a 70% molar conversion of glycine with quantitative yield was obtained, and the overall serine productivity was 5.2 g/L/h.     

glyA基因及其编码的丝氨酸羟甲基转移酶

glyA基因广泛存在于生物体中 ,其编码的丝氨酸羟甲基转移酶 (serinehydroxymethyltransferase,SHMT)催化丝氨酸和甘氨酸之间的相互转化 ,转化反应产生的 5,1 0 亚甲基四氢叶酸 (M THF)提供细胞新陈代谢—碳单位 ,此反应在细胞新陈代谢中处于重要地位。因此 ,研究 glyA基因及其编码的丝氨酸羟甲基转移酶具有重要的意义。介绍了 glyA基因的克隆、序列分析、调控组分和丝氨酸羟甲基转移酶的部分性质。     

Purification, properties, and N-terminal amino acid sequence of homogeneous Escherichia coli 2-amino-3-ketobutyrate CoA ligase, a pyridoxal phosphate-dependent enzyme

Starting with 100 g (wet weight) of a mutant of Escherichia coli K-12 forced to grow on L-threonine as sole carbon source, we developed a 6-step procedure that provides 30-40 mg of homogeneous 2-amino-3-ketobutyrate CoA ligase (also called aminoacetone synthetase or synthase). This ligase, which catalyzes the cleavage/condensation reaction between 2-amino-3-ketobutyrate (the presumed product of the L-threonine dehydrogenase-catalyzed reaction) and glycine + acetyl-CoA, has an apparent molecular weight approximately equal to 85,000 and consists of two identical (or nearly identical) subunits with Mr = 42,000. Computer analysis of amino acid composition data, which gives the best fit nearest integer ratio for each residue, indicates a total of 387 amino acids/subunit with a calculated Mr = 42,093. Stepwise Edman degradation provided the N-terminal sequence of the first 21 amino acids. It is a pyridoxal phosphate-dependent enzyme since (a) several carbonyl reagents caused greater than 90% loss of activity, (b) dialysis against buffer containing hydroxylamine resulted in 89% loss of activity coincident with an 86% decrease in absorptivity at 428 nm, (c) incubation of the apoenzyme with 20 microM pyridoxal phosphate showed a parallel recovery (greater than 90%) of activity and 428-nm absorptivity, and (d) reduction of the holoenzyme with NaBH4 resulted in complete inactivation, disappearance of a new absorption maximum at 333 nm. Strict specificity for glycine is shown but acetyl-CoA (100%), n-propionyl-CoA (127%), or n-butyryl-CoA (16%) is utilized in the condensation reaction. Apparent Km values for acetyl-CoA, n-propionyl-CoA, and glycine are 59 microM, 80 microM, and 12 mM, respectively; the pH optimum = 7.5. Added divalent metal ions or sulfhydryl compounds inhibited catalysis of the condensation reaction.     

Threonine formation via the coupled activity of 2-amino-3-ketobutyrate coenzyme A lyase and threonine dehydrogenase.

The enzymes L-threonine dehydrogenase and 2-amino-3-ketobutyrate coenzyme A (CoA) lyase are known to catalyze the net conversion of L-threonine plus NAD+ plus CoA to NADH plus glycine plus acetyl-CoA. When homogeneous preparations of these two enzymes from Escherichia coli were incubated together for 40 min at 25 degrees C with glycine, acetyl-CoA, and NADH, a 36% decrease in the level of glycine (with concomitant NADH oxidation) was matched by formation of an equivalent amount of threonine, indicating that this coupled sequence of enzyme-catalyzed reactions is reversible in vitro. Several experimental factors that affect the efficiency of this conversion in vitro were examined. A constructed strain of E. coli, MD901 (glyA thrB/C tdh), was unable to grow unless both glycine and threonine were added to defined rich medium. Introduction of the plasmid pDR121 (tdh+kbl+) into this strain enabled the cells to grow in the presence of either added glycine or threonine, indicating that interconversion of these two amino acids occurred. Threonine that was isolated from the total pool of cellular protein of MD901/pDR121 had the same specific radioactivity as the [14C]glycine added to the medium, establishing that threonine was formed exclusively from glycine in this strain. Comparative growth rate studies with several strains of E. coli containing plasmid pDR121, together with the finding that kcat values of pure E. coli 2-amino-3-ketobutyrate CoA lyase favor the cleavage of 2-amino-3-ketobutyrate over its formation by a factor of 50, indicate that the biosynthesis of threonine is less efficient than glycine formation via the coupled threonine dehydrogenase-2-amino-3-ketobutyrate lyase reactions.     

The preferential interaction of L-threonine with transport system ASC in cultured human fibroblasts.

The transport of L-threonine was studied in cultured human fibroblasts. A kinetic analysis of L-threonine transport in a range of extracellular concentrations from 0.01 to 20 mM indicated that this amino acid enters cells through both Na(+)-independent and Na(+)-dependent routes. These routes are: (1) a non-saturable, Na(+)-independent route formally indistinguishable from diffusion; (2) a saturable, Na(+)-independent route inhibitable by the analog BCH and identifiable with system L; (3) a low-affinity, Na(+)-dependent component (Km = 3 mM) which can be attributed to the activity of system A since it is adaptively enhanced by amino acid starvation and suppressed by the characterizing analog MeAIB and (4) a high-affinity, Na(+)-dependent route (Km = 0.05 mM). This latter route is identifiable with system ASC since it is insensitive to adaptive regulation, uninhibited by MeAIB, trans-stimulated by intracellular substrates of system ASC, markedly stereoselective, and relatively insensitive to changes in external pH. At an external concentration of 0.05 mM more than 90% of L-threonine transport is referrable to the activity of system ASC; in these conditions, the transport of the amino acid exhibits typical ASC-features even in the absence of inhibitors of other transport agencies, and, therefore, it can be employed as a reliable indicator of the activity of transport system ASC in cultured human fibroblasts.     

Regulation of hepatic glycine catabolism by glucagon

Glucagon stimulates 14CO2 production from [1-14C] glycine by isolated rat hepatocytes. Maximal stimulation (70%) of decarboxylation of glycine by hepatocytes was achieved when the concentration of glucagon in the medium reached 10 nM; half-maximal stimulation occurred at a concentration of about 2 nM. A lag period of 10 min was observed before the stimulation could be measured. Inclusion of beta-hydroxybutyrate (10 mM) or acetoacetate (10 mM) did not affect the magnitude of stimulation suggesting that the effects of glucagon were independent of mitochondrial redox state. Glucagon did not affect either the concentration or specific activity of intracellular glycine, thus excluding the possibilities that altered concentration or specific activity of intracellular glycine contributes to the observed stimulation. The stimulation of decarboxylation of glycine by glucagon was further studied by monitoring 14CO2 production from [1-14C]glycine by mitochondria isolated from rats previously injected with glucagon. Glycine decarboxylation was significantly stimulated in the mitochondria isolated from the glucagon-injected rats. We suggest that glucagon is a major regulator of hepatic glycine metabolism through the glycine cleavage enzyme system and may be responsible for the increased hepatic glycine removal observed in animals fed high-protein diets.