Glutamate production by <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis>: dependence on the oxoglutarate dehydrogenase inhibitor protein OdhI and protein kinase PknG

We recently showed that the activity of the 2-oxoglutarate dehydrogenase complex (ODHC) in Corynebacterium glutamicum is controlled by a novel regulatory mechanism that involves a 15-kDa protein called OdhI and serine/threonine protein kinase G (PknG). In its unphosphorylated state, OdhI binds to the E1 subunit (OdhA) of ODHC and, thereby, inhibits its activity. Inhibition is relieved by phosphorylation of OdhI at threonine-14 by PknG under conditions requiring high ODHC activity. In this work, evidence is provided that the dephosphorylation of phosphorylated OdhI is catalyzed by a phospho-Ser/Thr protein phosphatase encoded by the gene cg0062, designated ppp. As a decreased ODHC activity is important for glutamate synthesis, we investigated the role of OdhI and PknG for glutamate production under biotin limitation and after addition of Tween-40, penicillin, or ethambutol. A ΔodhI mutant formed only 1–13% of the glutamate synthesized by the wild type. Thus, OdhI is essential for efficient glutamate production. The effect of a pknG deletion on glutamate synthesis was dependent on the induction conditions. Under strong biotin limitation and in the presence of ethambutol, the ΔpknG mutant showed significantly increased glutamate production, offering a new way to improve production strains. Dedicated to Prof. Dr. Hermann Sahm on the occasion of his 65th birthday     

Requirement of de novo synthesis of the OdhI protein in penicillin-induced glutamate production by Corynebacterium glutamicum

We found that penicillin-induced glutamate production by Corynebacterium glutamicum is inhibited when a de novo protein synthesis inhibitor, chloramphenicol, is added simultaneously with penicillin. When chloramphenicol was added 4 h after penicillin addition, glutamate production was essentially unaffected. ³H-Leucine incorporation experiments revealed that protein synthesis continued for 1 h after penicillin addition and then gradually decreased. These results suggest that de novo protein synthesis within 4 h of penicillin treatment is required for the induction of glutamate production. To identify the protein(s) necessary for penicillin-induced glutamate production, proteome analysis of penicillin-treated C. glutamicum cells was performed with two-dimensional gel electrophoresis. Of more than 500 proteins detected, the amount of 13 proteins, including OdhI (an inhibitory protein for 2-oxoglutarate dehydrogenase complex), significantly increased upon penicillin treatment. Artificial overexpression of the odhI gene resulted in the decreased specific activity of the 2-oxoglutarate dehydrogenase complex and increased glutamate production without any triggers. These results suggest that the de novo synthesis of OdhI is the necessary factor for penicillin-induced glutamate overproduction by C. glutamicum. Moreover, continuous glutamate production was achieved by overexpression of odhI without any triggers. Thus, the odhI-overexpressing strain of C. glutamicum can be useful for efficient glutamate production.     

Effect of odhA overexpression and odhA antisense RNA expression on Tween-40-triggered glutamate production by Corynebacterium glutamicum

Recent studies have suggested that a decrease in the specific activity of the 2-oxoglutarate dehydrogenase complex (ODHC) is important for glutamate overproduction by Corynebacterium glutamicum. To further investigate the role of the odhA gene and its product in this process, we constructed the recombinant strains of C. glutamicum in which the expression of the odhA and its product could be controlled by odhA overexpression and odhA antisense RNA expression. We examined changes in glutamate production and ODHC specific activity of the constructed strains during glutamate production triggered by Tween 40 addition. The ODHC specific activity increased with odhA overexpression, resulting in dramatically reduced glutamate production despite Tween 40 addition, indicating that a decrease in the specific activity of ODHC is required for glutamate production induced by Tween 40 addition. However, odhA antisense RNA expression alone did not result in glutamate overproduction in spite of the decrease in ODHC specific activity. Rather, it enhanced glutamate production triggered by Tween 40 addition due to the additional decrease in ODHC specific activity, suggesting that odhA antisense RNA expression is effective in enhancing Tween-40-triggered glutamate overproduction. Our results suggest that a change in ODHC specific activity is critical but is not the only factor responsible for glutamate overproduction by C. glutamicum.     

Effect of lysine succinylation on the regulation of 2-oxoglutarate dehydrogenase inhibitor,OdhI, involved in glutamate production in Corynebacterium glutamicum

In Corynebacterium glutamicum, the activity of the 2-oxoglutarate dehydrogenase (ODH) complex is negatively regulated by the unphosphorylated form of OdhI protein, which is critical for L-glutamate overproduction. We examined the potential impact of protein acylation at lysine (K)-132 of OdhI in C. glutamicum ATCC13032. The K132E succinylation-mimic mutation reduced the ability of OdhI to bind OdhA, the catalytic subunit of the ODH complex, which reduced the inhibition of ODH activity. In vitro succinylation of OdhI protein also reduced the ability to inhibit ODH, and the K132R mutation blocked the effect. These results suggest that succinylation at K132 may attenuate the OdhI function. Consistent with these results, the C. glutamicum mutant strain with OdhI-K132E showed decreased L-glutamate production. Our results indicated that not only phosphorylation but also succinylation of OdhI protein may regulate L-glutamate production in C. glutamicum.     

The FHA domain of OdhI interacts with the carboxyterminal 2-oxoglutarate dehydrogenase domain of OdhA in Corynebacterium glutamicum

In Corynebacterium glutamicum, the unphosphorylated 15-kDa OdhI protein inhibits the activity of the 2-oxoglutarate dehydrogenase complex (ODHc) by binding to OdhA, which in corynebacteria and mycobacteria is a large fusion protein with two major domains exhibiting structural features of E1o and E2 proteins. Using copurification and surface plasmon resonance experiments with different OdhI and OdhA length variants it was shown that the entire forkhead-associated (FHA) domain of OdhI and the C-terminal dehydrogenase domain of OdhA are required for interaction. The FHA domain was also sufficient for inhibition of ODHc activity. Phosphorylated OdhI was binding-incompetent and did not inhibit ODHc activity.

Structured summary

MINT-7713362:OdhI (uniprotkb:Q8NQJ3) binds (MI:0407) to OdhA (uniprotkb:Q8NRC3) by surface plasmon resonance (MI:0107)MINT-7713261:OdhI (uniprotkb:Q8NQJ3) physically interacts (MI:0915) with OdhA (uniprotkb:Q8NRC3) by pull down (MI:0096)     

OdhI dephosphorylation kinetics during different glutamate production processes involving Corynebacterium glutamicum

In Corynebacterium glutamicum, the activity of the 2-oxoglutarate dehydrogenase complex was shown to be controlled by the phosphorylation of a 15-kDa protein OdhI by different serine/threonine protein kinases. In this paper, the phosphorylation status and kinetics of OdhI dephosphorylation were assessed during glutamate producing processes triggered by either a biotin limitation or a temperature upshock from 33°C to 39°C. A dephosphorylation of OdhI in C. glutamicum 2262 was observed during the biotin-limited as well as the temperature-induced glutamate-producing process. Deletion of pknG in C. glutamicum 2262 did not affect the phosphorylation status of OdhI during growth and glutamate production phases triggered by a temperature upshock, though a 40% increase in the specific glutamate production rate was measured. These results suggest that, under the conditions analyzed, PknG is not the kinase responsible for the phosphorylation of OdhI in C. glutamicum 2262. The phosphorylation status of OdhI alone is, as expected, not the only parameter that determines the performance of a specific strain, as no clear relation between the specific glutamate production rate and OdhI phosphorylation level was demonstrated.     

Study on roles of anaplerotic pathways in glutamate overproduction of <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis> by metabolic flux analysis

Background  

Corynebacterium glutamicum has several anaplerotic pathways (anaplerosis), which are essential for the productions of amino acids, such as lysine and glutamate. It is still not clear how flux changes in anaplerotic pathways happen when glutamate production is induced by triggers, such as biotin depletion and the addition of the detergent material, Tween 40. In this study, we quantitatively analyzed which anaplerotic pathway flux most markedly changes the glutamate overproduction induced by Tween 40 addition.     

Regulation of glutamate metabolism by protein kinases in mycobacteria

Protein kinase G of Mycobacterium tuberculosis has been implicated in virulence and in regulation of glutamate metabolism. Here we show that this kinase undergoes a pattern of autophosphorylation that is distinct from that of other M. tuberculosis protein kinases characterized to date and we identify GarA as a substrate for phosphorylation by PknG. Autophosphorylation of PknG has little effect on kinase activity but promotes binding to GarA, an interaction that is also detected in living mycobacteria. PknG phosphorylates GarA at threonine 21, adjacent to the residue phosphorylated by PknB (T22), and these two phosphorylation events are mutually exclusive. Like the homologue OdhI from Corynebacterium glutamicum, the unphosphorylated form of GarA is shown to inhibit α‐ketoglutarate decarboxylase in the TCA cycle. Additionally GarA is found to bind and modulate the activity of a large NAD⁺‐specific glutamate dehydrogenase with an unusually low affinity for glutamate. Previous reports of a defect in glutamate metabolism caused by pknG deletion may thus be explained by the effect of unphosphorylated GarA on these two enzyme activities, which may also contribute to the attenuation of virulence.     

Altered metabolic flux due to deletion of odhA causes L-glutamate overproduction in Corynebacterium glutamicum

L-glutamate overproduction in Corynebacterium glutamicum, a biotin auxotroph, is induced by biotin limitation or by treatment with certain fatty acid ester surfactants or with penicillin. We have analyzed the relationship between the inductions, 2-oxoglutarate dehydrogenase complex (ODHC) activity, and L-glutamate production. Here we show that a strain deleted for odhA and completely lacking ODHC activity produces L-glutamate as efficiently as the induced wild type (27.8 mmol/g [dry weight] of cells for the ohdA deletion strain compared with only 1.0 mmol/g [dry weight] of cells for the uninduced wild type). This level of production is achieved without any induction or alteration in the fatty acid composition of the cells, showing that L-glutamate overproduction can be caused by the change in metabolic flux alone. Interestingly, the L-glutamate productivity of the odhA-deleted strain is increased about 10% by each of the L-glutamate-producing inductions, showing that the change in metabolic flux resulting from the odhA deletion and the inductions have additive effects on L-glutamate overproduction. Tween 40 was indicated to induce drastic metabolic change leading to L-glutamate overproduction in the odhA-deleted strain. Furthermore, optimizing the metabolic flux from 2-oxoglutarate to L-glutamate by tuning glutamate dehydrogenase activity increased the l-glutamate production of the odhA-deleted strain.     

Dynamics of glutamate synthesis and excretion fluxes in batch and continuous cultures of temperature-triggered Corynebacterium glutamicum

Corynebacterium glutamicum 2262 strain, when triggered for glutamate excretion, experiences a rapid decrease in growth rate and increase in glutamate efflux. In order to gain a better quantitative understanding of the factors controlling the metabolic transition, the fermentation dynamics was investigated for a temperature-sensitive strain cultivated in batch and glucose-limited continuous cultures. For non-excreting cells at 33°C, increasing the growth rate resulted in strong increases in the central metabolic fluxes, but the intracellular glutamate level, the oxoglutarate dehydrogenase complex (ODHC) activity and the flux distribution at the oxoglutarate node remained essentially constant. When subjected to a temperature rise to 39°C, at both high- and low-metabolic activities, the bacteria showed a rapid attenuation in ODHC activity and an increase from 28% to more than 90% of the isocitrate dehydrogenase flux split towards glutamate synthesis. Simultaneously to the reduction in growth rate, the cells activated a high capacity export system capable of expelling the surplus of synthesized glutamate.     

Corynebacterial protein kinase G controls 2-oxoglutarate dehydrogenase activity via the phosphorylation status of the OdhI protein

A novel regulatory mechanism for control of the ubiquitous 2-oxoglutarate dehydrogenase complex (ODH), a key enzyme of the tricarboxylic acid cycle, was discovered in the actinomycete Corynebacterium glutamicum, a close relative of important human pathogens like Corynebacterium diphtheriae and Mycobacterium tuberculosis. Based on the finding that a C. glutamicum mutant lacking serine/threonine protein kinase G (PknG) was impaired in glutamine utilization, proteome comparisons led to the identification of OdhI as a putative substrate of PknG. OdhI is a 15-kDa protein with a forkhead-associated domain and a homolog of mycobacterial GarA. By using purified proteins, PknG was shown to phosphorylate OdhI at threonine 14. The glutamine utilization defect of the delta pknG mutant could be abolished by the additional deletion of odhI, whereas transformation of a delta odhI mutant with a plasmid encoding OdhI-T14A caused a defect in glutamine utilization. Affinity purification of OdhI-T14A led to the specific copurification of OdhA, the E1 subunit of ODH. Because ODH is essential for glutamine utilization, we assumed that unphosphorylated OdhI inhibits ODH activity. In fact, OdhI was shown to strongly inhibit ODH activity with a Ki value of 2.4 nM. The regulatory mechanism described offers a molecular clue for the reduced ODH activity that is essential for the industrial production of 1.5 million tons/year of glutamate with C. glutamicum. Moreover, because this signaling cascade is likely to operate also in mycobacteria, our results suggest that the attenuated pathogenicity of mycobacteria lacking PknG might be caused by a disturbed tricarboxylic acid cycle.     

Double deletion of <Emphasis Type="Italic">dtsR1</Emphasis> and <Emphasis Type="Italic">pyc</Emphasis> induce efficient <Emphasis Type="SmallCaps">l</Emphasis>-glutamate overproduction in <Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis>

Corynebacterium glutamicum strains are used for the fermentative production of l-glutamate. Five C. glutamicum deletion mutants were isolated by two rounds of selection for homologous recombination and identified by Southern blot analysis. The growth, glucose consumption and glutamate production of the mutants were analyzed and compared with the wild-type ATCC 13032 strain. Double disruption of dtsR1 (encoding a subunit of acetyl-CoA carboxylase complex) and pyc (encoding pyruvate carboxylase) caused efficient overproduction of l-glutamate in C. glutamicum; production was much higher than that of the wild-type strain and ΔdtsR1 strain under glutamate-inducing conditions. In the absence of any inducing conditions, the amount of glutamate produced by the double-deletion strain ΔdtsR1Δpyc was more than that of the mutant ΔdtsR1. The activity of phosphoenolpyruvate carboxylase (PEPC) was found to be higher in the ΔdtsR1Δpyc strain than in the ΔdtsR1 strain and the wild-type strain. Therefore, PEPC appears to be an important anaplerotic enzyme for glutamate synthesis in ΔdtsR1 derivatives. Moreover, this conclusion was confirmed by overexpression of ppc and pyc in the two double-deletion strains (ΔdtsR1Δppc and ΔdtsR1Δpyc), respectively. Based on the data generated in this investigation, we suggest a new method that will improve glutamate production strains and provide a better understanding of the interaction(s) between the anaplerotic pathway and fatty acid synthesis.     

Characterization of lysine acetylation of a phosphoenolpyruvate carboxylase involved in glutamate overproduction in Corynebacterium glutamicum

Protein Nε‐acylation is emerging as a ubiquitous post‐translational modification. In Corynebacterium glutamicum, which is utilized for industrial production of l ‐glutamate, the levels of protein acetylation and succinylation change drastically under the conditions that induce glutamate overproduction. Here, the acylation of phosphoenolpyruvate carboxylase (PEPC), an anaplerotic enzyme that supplies oxaloacetate for glutamate overproduction was characterized. It was shown that acetylation of PEPC at lysine 653 decreased enzymatic activity, leading to reduced glutamate production. An acetylation‐mimic (KQ) mutant of K653 showed severely reduced glutamate production, while the corresponding KR mutant showed normal production levels. Using an acetyllysine‐incorporated PEPC protein, we verified that K653‐acetylation negatively regulates PEPC activity. In addition, NCgl0616, a sirtuin‐type deacetylase, deacetylated K653‐acetylated PEPC in vitro. Interestingly, the specific activity of PEPC was increased during glutamate overproduction, which was blocked by the K653R mutation or deletion of sirtuin‐type deacetylase homologues. These findings suggested that deacetylation of K653 by NCgl0616 likely plays a role in the activation of PEPC, which maintains carbon flux under glutamate‐producing conditions. PEPC deletion increased protein acetylation levels in cells under glutamate‐producing conditions, supporting the hypothesis that PEPC is responsible for a large carbon flux change under glutamate‐producing conditions.     

Comparative study of flux redistribution of metabolic pathway in glutamate production by two coryneform bacteria

In amino acid production by coryneform bacteria, study on relationship between change in enzyme activities and production of a target amino acid is important. In glutamate production, Kawahara et al. discovered that the effect of decrease in 2-oxoglutamate dehydrogenase complex (ODHC) on glutamate production is essential (Kawahara et al., Biosci. Biotechnol. Biochem. 61(7) (1997) 1109). Significant reduction of the ODHC activity was observed in the cells under the several glutamate-productive conditions in Corynebacterium glutamicum. Recent progress in metabolic engineering enables us to quantitatively compare the flux redistribution of the different strains after change in enzyme activity precisely. In this paper, relationship between flux redistribution and change in enzyme activities after biotin deletion and addition of detergent (Tween 40) was studied in two coryneform bacteria, C. glutamicum and a newly isolated strain, Corynebacterium efficiens (Fudou et al., Int. J. Syst. Evol. Microbiol. 52(Part 4) 1127), based on metabolic flux analysis (MFA). It was observed that in both species the specific activities of isocitrate dehydrogenase (ICDH) and glutamate dehydrogenase (GDH) did not significantly change throughout the fermentation, while that of the ODHC significantly decreased after biotin depletion and Tween 40 addition. Flux redistribution clearly occurred after the decrease in ODHC specific activity. The difference in glutamate production between C. glutamicum and C. efficiens was caused by the difference in the degree of decrease in ODHC specific activity. The difference in Michaelis-Menten constants or K(m) value between ICDH, GDH, and ODHC explained the mechanism of flux redistribution at the branch point of 2-oxoglutarate. It was found that the K(m) values of ICDH and ODHC were much lower than that of GDH for both strains. It was quantitatively proved that the ODHC plays the most important role in controlling flux distribution at the key branch point of 2-oxoglutarate in both coryneform bacteria. Flux redistribution mechanism was well simulated by a Michaelis-Menten-based model with kinetic parameters. The knowledge of the mechanism of flux redistribution will contribute to improvement of glutamate production in coryneform bacteria.     

The E2 Domain of OdhA of Corynebacterium glutamicum Has Succinyltransferase Activity Dependent on Lipoyl Residues of the Acetyltransferase AceF

Oxoglutarate dehydrogenase (ODH) and pyruvate dehydrogenase (PDH) complexes catalyze key reactions in central metabolism, and in Corynebacterium glutamicum there is indication of an unusual supercomplex consisting of AceE (E1), AceF (E2), and Lpd (E3) together with OdhA. OdhA is a fusion protein of additional E1 and E2 domains, and odhA orthologs are present in all Corynebacterineae, including, for instance, Mycobacterium tuberculosis. Here we show that deletion of any of the individual domains of OdhA in C. glutamicum resulted in loss of ODH activity, whereas PDH was still functional. On the other hand, deletion of AceF disabled both PDH activity and ODH activity as well, although isolated AceF protein had solely transacetylase activity and no transsuccinylase activity. Surprisingly, the isolated OdhA protein was inactive with 2-oxoglutarate as the substrate, but it gained transsuccinylase activity upon addition of dihydrolipoamide. Further enzymatic analysis of mutant proteins and mutant cells revealed that OdhA specifically catalyzes the E1 and E2 reaction to convert 2-oxoglutarate to succinyl-coenzyme A (CoA) but fully relies on the lipoyl residues provided by AceF involved in the reactions to convert pyruvate to acetyl-CoA. It therefore appears that in the putative supercomplex in C. glutamicum, in addition to dihydrolipoyl dehydrogenase E3, lipoyl domains are also shared, thus confirming the unique evolutionary position of bacteria such as C. glutamicum and M. tuberculosis.Pyruvate dehydrogenase (PDH) and 2-oxoglutarate dehydrogenase (ODH) activities catalyze key reactions in central metabolism. They exist as huge enzyme complexes of up to 11 MDa to convert a 2-oxoacid to an acyl-coenzyme A (CoA) derivative, which is acetyl- or succinyl-CoA, respectively (for reviews, see references 28 and 29 and references therein). The reaction requires distinct enzyme activities and involves the sequential actions of thiamine-pyrophosphate-dependent oxidative decarboxylation (E1, EC 1.2.4.2), with the concomitant transfer of the respective acyl group to a lipoamide residue. This is followed by the acyl group transfer to CoA, catalyzed by dihydrolipoyl transacylase activity (E2, EC 2.3.1.6), and, finally, the last step is dihydrolipoamide reoxidation to lipoamide by an FAD-dependent dihydrolipoyl dehydrogenase (E3, EC 1.8.1.4), thus enabling the initiation of a new catalytic cycle. As a result, the energy of the C₁-C₂ bond of an α-oxoacid is preserved in acetyl-CoA and succinyl-CoA, respectively, and NADH.PDH and ODH are structurally closely related assemblies. Structural data for the three-dimensional organization of PDH of Bacillus stearothermophilus have culminated in the current view that the complex consists of an E2 core, to which E1 and E3 are flexibly tethered (20-22). This has similarly been disclosed for the PDH of Escherichia coli (23), as well as for components of ODH (6, 8, 18, 37). The PDH possesses specific E1p and E2p proteins, and ODH possesses specific E1o and E2o proteins, whereas the dihydrolipoyl dehydrogenase component E3 is shared by the two multienzyme complexes (28, 29). Thus, PDH and ODH complexes share one identical polypeptide plus very similar polypeptides, and they also have a similar overall quaternary structure (21, 23).Within the Gram-positives, the Corynebacterineae, such as Mycobacterium tuberculosis and Corynebacterium glutamicum, have a number of distinctive features. This includes the synthesis of mycolic acids enabling the formation of a periplasmic space as in Gram-negatives (15) and the possession of unusual glycans and lipoylated glycans in their cell wall (1). It now has become clear that also the PDH and ODH of these organisms have unique properties, with respect to their protein components, three-dimensional organization, and regulation (25, 36). There is only one E2 protein present and with the isolated protein, it is shown to reconstitute PDH activity together with E1 and E3 proteins (35). An E2 protein specific to ODH is absent in M. tuberculosis, as is the case with C. glutamicum as well. Instead, Corynebacterineae possess one large fusion protein, termed OdhA in C. glutamicum and Kgd in M. tuberculosis, consisting of an E2 domain plus an E1 domain (36). However, as a lipoylated protein in Mycobacterium, only the E2 protein, which confers PDH activity in the reconstitution assay, is known, and no ODH activity is detectable in M. tuberculosis (35). A further remarkable feature found for C. glutamicum is the formation of a mixed 2-oxoacid dehydrogenase complex, since tagged OdhA copurified with the E2, E3, and E1p proteins, and vice versa, tagged E1p copurified with the E2 and E3 proteins together with OdhA (25). Another conspicuous feature shared by the OdhA and Kgd proteins is their interaction with a small regulatory protein which contains a phosphopeptide recognition domain (FHA domain) well characterized for many eukaryotic regulatory proteins. The protein is termed OdhI for C. glutamicum and GarA for M. tuberculosis (4, 25), and the structure of OdhI has recently been resolved (3). These proteins themselves are phosphorylated by one or several serine/threonine protein kinases present in the Corynebacterineae (25, 32), and they interact in their unphosphorylated form with OdhA or Kgd, respectively, to inhibit the activity of these proteins (25, 26).Due to these remarkable features of activities and structures enabling pyruvate and 2-oxoglutarate conversion in the Corynebacterineae, we decided to study PDH and ODH as well as features of their constituent polypeptides in C. glutamicum in somewhat more detail, leading to the detection of the unprecedented structural and functional organization of these important enzyme complexes within central metabolism.     

Glutamate Is Excreted Across the Cytoplasmic Membrane through the NCgl1221 Channel of Corynebacterium glutamicum by Passive Diffusion

The NCgl1221 gene, which encodes a mechanosensitive channel, has been reported to be critically involved in glutamate (Glu) overproduction by Corynebacterium glutamicum, but direct evidence of Glu excretion through this channel has not yet been provided. In this study, by electrophysiological methods, we found direct evidence of Glu excretion through this channel by passive diffusion. We found that the introduction into Phe-producing Escherichia coli of mutant NCgl1221 genes that induce Glu overproduction by C. glutamicum improved productivity. This suggests a low-substrate preference of this channel, indicates its potential as a versatile exporter, and more broadly, indicates the potential of exporter engineering.     

<Emphasis Type="Italic">Corynebacterium glutamicum</Emphasis> mechanosensitive channels: towards unpuzzling “glutamate efflux” for amino acid production

Corynebacterium glutamicum has been utilized for industrial amino acid production, especially for monosodium glutamate (MSG), the food-additive for the “UMAMI” category of taste sensation, which is one of the five human basic tastes. Glutamate export from these cells is facilitated by the opening of mechanosensitive channels in the cell membrane within the bacterial cell envelope following specific treatments, such as biotin limitation, addition of Tween 40 or penicillin. A long-unsolved puzzle still remains how and why C. glutamicum mechanosensitive channels are activated by these treatments to export glutamate. Unlike mechanosensitive channels in other bacteria, these channels are not simply osmotic safety valves that prevent these bacteria from bursting upon a hypo-osmotic shock. They also function as metabolic valves to continuously release glutamate as components of a pump-and-leak mechanism regulating the cellular turgor pressure. Recent studies have demonstrated that the opening of the mechanosensitive channel, MscCG, mainly facilitates the efflux of glutamate and not of other amino acids and that the “force-from-lipids” gating mechanism of channels also applies to the MscCG channel. The bacterial types of mechanosensitive channels are found in cell-walled organisms from bacteria to land plants, where their physiological functions have been specialized beyond their basic function in bacterial osmoregulation. In the case of the C. glutamicum MscCG channels, they have evolved to function as specialized glutamate exporters.     

Glutamate as an inhibitor of phosphoenolpyruvate carboxylase activity in<Emphasis Type="Italic"> Corynebacterium glutamicum</Emphasis>

The glutamate-producing bacterium, Corynebacterium glutamicum is known to possess two anaplerotic enzymes: pyruvate carboxylase (Pc) and phosphoenolpyruvate carboxylase (PEPc). In vitro, this latter enzyme appeared to be inhibited by different glutamic acid salts, whereas ammonium-glutamate had no influence on Pc activity. To investigate the in vivo relevance of PEPc activity inhibition, the intracellular concentration of glutamate was determined throughout the glutamate-producing process. The intracellular concentration was then shown to be sufficient to induce a dramatic inhibition of PEPc activity during the process. As a consequence, intracellular accumulation of glutamate could be at least partially responsible for the weak participation of PEPc within the anaplerosis activity in amino-acid-producing strains of C. glutamicum.     

l-Valine biosynthesis during batch and fed-batch cultivations of Corynebacterium glutamicum: Relationship between changes in bacterial growth rate and intracellular metabolism

A transition in the bacterial growth rate to below maximum was found to be an optimum parameter of cellular physiology to increase the activity of acetohydroxy acid synthase, a regulatory enzyme in l-valine synthesis, and amino acid overproduction by Corynebacterium glutamicum ATCC 13032 recombinants under batch and fed-batch cultivation conditions. An increase in l-valine synthesis under transient situations when cellular growth rate was downregulated was correlated to a decrease in the activity of aconitase, a key enzyme in the tricarboxylic acid cycle (TCA) of C. glutamicum, and, in contrast, to an increase in the activity of glucose-6-phosphate dehydrogenase, a key enzyme in the pentose phosphate pathway (PPP). The increase in amino acid synthesis was also directly related to a drastic increase in intracellular pyruvate concentration. Thus, an increase in intracellular pyruvate availability and NADPH₂ generation by PPP could be the metabolic origins of the increased l-valine overproduction by growth restrained C. glutamicum cell culture.