CdbC: a disulfide bond isomerase involved in the refolding of mycoloyltransferases in Corynebacterium glutamicum cells exposed to oxidative conditions.

In Corynebacterium glutamicum cells, cdbC, which encodes a protein containing the CysXXCys motif, is regulated by the global redox-responsive regulator OsnR. In this study, we assessed the role of the periplasmic protein CdbC in disulfide bond formation and its involvement in mycomembrane biosynthesis. Purified CdbC efficiently refolded scrambled RNaseA, exhibiting prominent disulfide bond isomerase activity. The transcription of cdbC was decreased in cells grown in the presence of the reductant dithiothreitol (DTT). Moreover, unlike wild-type and cdbC-deleted cells, cdbC-overexpressing (P180-cdbC) cells grown in the presence of DTT exhibited retarded growth, abnormal cell morphology, increased cell surface hydrophobicity and altered mycolic acid composition. P180-cdbC cells cultured in a reducing environment accumulated trehalose monocorynomycolate, indicating mycomembrane deformation. Similarly, a two-hybrid analysis demonstrated the interaction of CdbC with the mycoloyltransferases MytA and MytB. Collectively, our findings suggest that CdbC, a periplasmic disulfide bond isomerase, refolds misfolded MytA and MytB and thereby assists in mycomembrane biosynthesis in cells exposed to oxidative conditions.

Gene nceA encodes a Ni/Co-sensing transcription factor to regulate metal efflux in Corynebacterium glutamicum.

The function of Corynebacterium glutamicum open reading frame (ORF) NCgl2684 (named nceA in this study), which was annotated to encode a metalloregulator, was assessed using physiological, genetic, and biochemical approaches. Cells with deleted-nceA (ΔnceA) showed a resistant phenotype to NiSO4 and CoSO4 and showed faster growth in minimal medium containing 20 µM NiSO4 or 10 µM CoSO4 than both the wild-type and nceA-overexpressing (P180-nceA) cells. In the ΔnceA strain, the transcription of the downstream-located ORF NCgl2685 (nceB), annotated to encode efflux protein, was increased approximately 4-fold, whereas gene transcription decreased down to 30% level in the P180-nceA strain. The transcriptions of the nceA and nceB genes were stimulated, even when as little as 5 nM NiSO4 was added to the growth medium. Protein NceA was able to bind DNA comprising the promoter region (from -14 to + 18) of the nceA--nceB operon. The protein-DNA interaction was abolished in the presence of 20 µM NiSO4, 50 µM CoSO4, or 50 µM CdSO4. Although manganese induced the transcription of the nceA and nceB genes, it failed to interrupt protein-DNA interaction. Simultaneously, the P180-nceA cells showed increased sensitivity to oxidants such as menadione, hydrogen peroxide, and cumene hydroperoxide, but not diamide. Collectively, our data show that NceA is a nickel- and cobalt-sensing transcriptional regulator that controls the transcription of the probable efflux protein-encoding nceB. The genes are able to suppress intracellular levels of nickel to prevent reactions, which can cause oxidative damage to cellular components.

The cysS gene (ncgl0127) of Corynebacterium glutamicum is required for sulfur assimilation and affects oxidative stress-responsive cysteine import.

The OsnR protein functions as a transcriptional repressor of genes involved in redox-dependent stress responses. Here, we studied Corynebacterium glutamicum ORF ncgl0127 (referred to as cysS in this study), one of the target genes of OsnR, to reveal its role in osnR-mediated stress responses. The ΔcysS strain was found to be a cysteine auxotroph, and the transcription levels of the sulfur assimilatory genes and cysR, the master regulatory gene for sulfur assimilation, were low in this strain. Complementation of the strain with cysR transformed the strain into a cysteine prototroph. Cells challenged with oxidants or cysteine showed transcriptional stimulation of the cysS gene and decreased transcription of the ncgl2463 gene, which encodes a cysteine/cystine importer. The transcription of the ncgl2463 gene was increased in the ΔcysS strain and further stimulated by cysteine. Unlike the wild-type strain, ΔcysS cells grown with an excess amount of cysteine showed an oxidant- and alkylating agent-resistant phenotype, suggesting deregulated cysteine import. Collectively, our data suggest that the cysS gene plays a positive role in sulfur assimilation and a negative role in cysteine import, in particular in cells under oxidative stress.

Trehalose biosynthetic gene otsB of Corynebacterium glutamicum is regulated by whcE in response to oxidative stress.

The gene whcE of Corynebacterium glutamicum plays a positive role in oxidative stress responses and the WhcE protein interacts with SpiE. By utilizing 2D-PAGE analysis, we identified the otsB gene to be under the control of whcE. The transcription of otsB, encoding trehalose 6-phosphatase, was stimulated by oxidative stress, and whcE and spiE were involved in diamide-mediated transcriptional stimulation. The ΔotsB strain was created and found to be sensitive to the thiol-specific oxidant diamide, suggesting a role of the gene in stress responses. Genes located upstream of otsB, such as NCgl2534 and otsA, formed an operon and purified WhcE was able to bind to the promoter region of the operon (PNCgl2534), but the binding was only possible in the presence of the oxidant diamide. In addition, the transcriptional activation of PNCgl2534 by WhcE was demonstrated in in vivo assays and the transcription was stimulated in cells exposed to the oxidant diamide. These findings indicate that WhcE is a transcriptional activator, and otsB, which is involved in trehalose biosynthesis, has a role in oxidative stress responses in C. glutamicum.

Myricetin Disturbs the Cell Wall Integrity and Increases the Membrane Permeability of Candida albicans.

The fungal cell wall and membrane are the principal targets of antifungals. Herein, we report that myricetin exerts antifungal activity against Candida albicans by damaging the cell wall integrity and notably enhancing the membrane permeability. In the presence of sorbitol, an osmotic protectant, the minimum inhibitory concentration (MIC) of myricetin against C. albicans increased from 20 to 40 and 80 µg/ml in 24 and 72 h, respectively, demonstrating that myricetin disturbs the cell wall integrity of C. albicans. Fluorescence microscopic images showed the presence of propidium iodidestained C. albicans cells, indicating the myricetin-induced initial damage of the cell membrane. The effects of myricetin on the membrane permeability of C. albicans cells were assessed using crystal violet-uptake and intracellular material-leakage assays. The percentage uptakes of crystal violet for myricetin-treated C. albicans cells at 1×, 2×, and 4× the MIC of myricetin were 36.5, 60.6, and 79.4%, respectively, while those for DMSO-treated C. albicans cells were 28.2, 28.9, and 29.7%, respectively. Additionally, myricetin-treated C. albicans cells showed notable DNA and protein leakage, compared with the DMSO-treated controls. Furthermore, treatment of C. albicans cells with 1× the MIC of myricetin showed a 17.2 and 28.0% reduction in the binding of the lipophilic probes diphenylhexatriene and Nile red, respectively, indicating that myricetin alters the lipid components or order in the C. albicans cell membrane, leading to increased membrane permeability. Therefore, these data will provide insights into the pharmacological worth of myricetin as a prospective antifungal for treating C. albicans infections.

OsnR is an autoregulatory negative transcription factor controlling redox-dependent stress responses in Corynebacterium glutamicum.

BACKGROUND: Corynebacterium glutamicum is used in the industrial production of amino acids and nucleotides. During the course of fermentation, C. glutamicum cells face various stresses and employ multiple regulatory genes to cope with the oxidative stress. The osnR gene plays a negative regulatory role in redox-dependent oxidative-stress responses, but the underlying mechanism is not known yet. RESULTS: Overexpression of the osnR gene in C. glutamicum affected the expression of genes involved in the mycothiol metabolism. ChIP-seq analysis revealed that OsnR binds to the promoter region of multiple genes, including osnR and cg0026, which seems to function in the membrane-associated redox metabolism. Studies on the role of the osnR gene involving in vitro assays employing purified OsnR proteins and in vivo physiological analyses have identified that OsnR inhibits the transcription of its own gene. Further, oxidant diamide stimulates OsnR-binding to the promoter region of the osnR gene. The genes affected by the overexpression of osnR have been found to be under the control of σH. In the osnR-overexpressing strain, the transcription of sigH is significantly decreased and the stimulation of sigH transcription by external stress is lost, suggesting that osnR and sigH form an intimate regulatory network. CONCLUSIONS: Our study suggests that OsnR not only functions as a transcriptional repressor of its own gene and of those involved in redox-dependent stress responses but also participates in the global transcriptional regulation by controlling the transcription of other master regulators, such as sigH.

Aucklandia lappa Causes Membrane Permeation of Candida albicans.

Candida albicans is a major fungal pathogen in humans. In our previous study, we reported that an ethanol extract from Aucklandia lappa weakens C. albicans cell wall by inhibiting synthesis or assembly of both (1,3)-ß-D-glucan polymers and chitin. In the current study, we found that the extract is involved in permeabilization of C. albicans cell membranes. While uptake of ethidium bromide (EtBr) was 3.0% in control cells, it increased to 7.4% for 30 min in the presence of the A. lappa ethanol extract at its minimal inhibitory concentration (MIC), 0.78 mg/ml, compared to uptake by heat-killed cells. Besides, leakage of DNA and proteins was observed in A. lappa-treated C. albicans cells. The increased uptake of EtBr and leakage of cellular materials suggest that A. lappa ethanol extract induced functional changes in C. albicans cell membranes. Incorporation of diphenylhexatriene (DPH) into membranes in the A. lappa-treated C. albicans cells at its MIC decreased to 84.8%, after 60 min of incubation, compared with that of the controls, indicate that there was a change in membrane dynamics. Moreover, the anticandidal effect of the A. lappa ethanol extract was enhanced at a growth temperature of 40°C compared to that at 35°C. The above data suggest that the antifungal activity of the A. lappa ethanol extract against C. albicans is associated with synergistic action of membrane permeabilization due to changes in membrane dynamics and cell wall damage caused by reduced formation of (1,3)-ß-D-glucan and chitin.

Thiol-specific oxidant diamide downregulates whiA gene of Corynebacterium glutamicum, thereby suppressing cell division and metabolism.

The whiA (NCgl1527) gene from Corynebacterium glutamicum plays a crucial role during cell growth, and WhiA is recognized as the transcription factor for genes involved in cell division. In this study, we assessed the regulatory role of the gene in cell physiology. Transcription of the gene was specifically downregulated by the thiol-specific oxidant, diamide, and by heat stress. Cells exposed to diamide showed decreased transcription of genes involved in cell division and these effects were more profound in ΔwhiA cells. In addition, the ΔwhiA cells showed sensitivity to thiol-specific oxidants, DNA-damaging agents, and high temperature. Further, downregulation of sigH (NCgl0733), the central regulator in stress responses, along with master regulatory genes in cell metabolism, was observed in the ΔwhiA strain. Moreover, the amount of cAMP in the ΔwhiA cells in the early stationary phase was only at 30% level of that for the wild-type strain. Collectively, our data indicate that the role of whiA is to downregulate genes associated with cell division in response to heat or thiol-specific oxidative stress, and may suggest a role for the gene in downshifting cell metabolism by downregulating global regulatory genes when growth condition is not optimal for cells.

Aucklandia lappa Causes Cell Wall Damage in Candida albicans by Reducing Chitin and (1,3)-ß-D-Glucan.

The fungal cell wall is a major target of antifungals. In this study, we report the antifungal activity of an ethanol extract from Aucklandia lappa against Candida albicans. We found that the extract caused cell wall injury by decreasing chitin synthesis or assembly and (1,3)-ß-D-glucan synthesis. A sorbitol protection assay demonstrated that the minimum inhibitory concentration (MIC) of the A. lappa extract against C. albicans cells increased eight-fold from 0.78 to 6.24 mg/ml in 72 h. Cell aggregates, which indicate damage to the cell wall or membrane, were commonly observed in the A. lappatreated C. albicans cells through microscopic analysis. In addition, the relative fluorescence intensities of the C. albicans cells incubated with the A. lappa extract for 3, 5, and 6 h were 92.1, 84.6, and 79.8%, respectively, compared to the controls, estimated by Calcofluor White binding assay. This result indicates that chitin content was reduced by the A. lappa treatment. Furthermore, synthesis of (1,3)-ß-D-glucan polymers was inhibited to 84.3, 79.7, and 70.2% of that of the control treatment following incubation of C. albicans microsomes with the A. lappa extract at a final concentration equal to its MIC, 2× MIC, and 4× MIC, respectively. These findings suggest that the A. lappa ethanol extract may aid the development of a new antifungal to successfully control Candida-associated disease.

Corynebacterium glutamicum whiA plays roles in cell division, cell envelope formation, and general cell physiology.

The whiA gene is widely distributed among Gram-positive bacteria. Although the encoded protein has conserved N-terminal homing endonuclease scaffold and C-terminal helix-turn-helix DNA-binding domains, whiA plays a unique physiological role in its host organisms, reflecting a long history of evolution. Here, we used genetic approaches to unveil the physiological function of whiA in Corynebacterium glutamicum. We found that cells lacking whiA (ΔwhiA) were unable to grow in minimal medium containing glucose, although reduced growth was observed in complex medium. The ΔwhiA strain showed altered transcription of the cell division genes ftsZ, sepF, ftsK, crgA, divIVA, and amiC genes. Accordingly, ΔwhiA cells exhibited large, elongated, branched, and bud-shaped morphologies. In addition, some genes, including fas-IA, fas-IB, accD1, and cmrA, which help synthesize the fatty acid and cell envelope component mycolic acid, showed altered transcription in the ΔwhiA strain. Further, treS, treY, otsA, and otsB, which are involved in the biosynthesis of the outer envelope component trehalose, were down-regulated in the ΔwhiA strain. 2D-PAGE analysis of the ΔwhiA mutant showed that proteins involved in other cellular activities were also affected by the loss of whiA. These findings suggest that C. glutamicum whiA plays a critical role in cell division, envelope formation, and general cell physiology.

The osnR gene of Corynebacterium glutamicum plays a negative regulatory role in oxidative stress responses.

Among the Corynebacterium glutamicum ORFs that have been implicated in stress responses, we chose ORF cg3230, designated osnR, and analyzed it further. Unlike the osnR-deleted strain (ΔosnR), the osnR-overexpressing strain (P180-osnR) developed growth defects and increased sensitivity to various oxidants including H2O2. Transcription in the P180-osnR strain of genes such as sodA (superoxide dismutase), ftn (ferritin biosynthesis), and ahpD (alkyl hydroperoxide reductase; cg2674), which are involved in the detoxification of reactive oxygen species, was only 40% that of the wild type. However, transcription of katA, encoding H2O2-detoxifying catalase, was unchanged in this strain. Genes such as trxB (thioredoxin reductase) and mtr (mycothiol disulfide reductase), which play roles in redox homeostasis, also showed decreased transcription in the strain. 2D-PAGE analysis indicated that genes involved in redox reactions were considerably affected by osnR overexpression. The NADPH/NADP+ ratio of the P180-osnR strain (1.35) was higher than that of the wild-type stain (0.78). Collectively, the phenotypes of the ΔosnR and P180-osnR strains suggest a global regulatory role as well as a negative role for the gene in stress responses, particularly in katA-independent oxidative stress responses.

The ahpD gene of Corynebacterium glutamicum plays an important role in hydrogen peroxide-induced oxidative stress response.

In this study, we analysed the ahpD gene from Corynebacterium glutamicum, which may function in a H2O2-mediated stress responses. Cells overexpressing C. glutamicum ahpD (P180-ahpD) showed increased sensitivity to H2O2 when exposed to the latter in concentrations of 8 mM or greater while showing reduced expression of katA, which encodes catalase. On the other hand, cells that lack ahpD (ΔahpD) displayed increased sensitivity when exposed to low levels of H2O2 while showing katA transcription that was comparable to the level in the wild-type strain. Accordingly, transcription of ahpD and katA was stimulated by low and high concentration of H2O2, respectively. Further, the NAD+/NADH ratio was severely reduced in the ΔahpD (3.03) and P180-ahpD (0.47) strains as compared with that in the wild-type (4.55) strain. Transcriptional analysis indicated that ahpD and upstream genes such as cg2675, cg2676, cg2677 and cg2678, which were annotated as ABC-type transporter, were organized into an operon. Collectively, these findings indicate that C. glutamicum possesses bi-level defence pathways against hydrogen peroxide, involving katA and ahpD. Further, ahpD, along with cg2675-cg2678 genes, may play a novel role in cellular activities against oxidative stress.

Development of Candida albicans Biofilms Is Diminished by Paeonia lactiflora via Obstruction of Cell Adhesion and Cell Lysis.

Candida albicans infections are often problematic to treat owing to antifungal resistance, as such infections are mostly associated with biofilms. The ability of C. albicans to switch from a budding yeast to filamentous hyphae and to adhere to host cells or various surfaces supports biofilm formation. Previously, the ethanol extract from Paeonia lactiflora was reported to inhibit cell wall synthesis and cause depolarization and permeabilization of the cell membrane in C. albicans. In this study, the P. lactiflora extract was found to significantly reduce the initial stage of C. albicans biofilms from 12 clinical isolates by 38.4%. Thus, to assess the action mechanism, the effect of the P. lactiflora extract on the adhesion of C. albicans cells to polystyrene and germ tube formation was investigated using a microscopic analysis. The density of the adherent cells was diminished following incubation with the P. lactiflora extract in an acidic medium. Additionally, the P. lactiflora-treated C. albicans cells were mostly composed of less virulent pseudohyphae, and ruptured debris was found in the serum-containing medium. A quantitative real-time PCR analysis indicated that P. lactiflora downregulated the expression of C. albicans hypha-specific genes: ALS3 by 65% (p = 0.004), ECE1 by 34.9% (p = 0.001), HWP1 by 29.2% (p = 0.002), and SAP1 by 37.5% (p = 0.001), matching the microscopic analysis of the P. lactiflora action on biofilm formation. Therefore, the current findings demonstrate that the P. lactiflora ethanol extract is effective in inhibiting C. albicans biofilms in vitro, suggesting its therapeutic potential for the treatment of biofilm-associated infections.

Corynebacterium glutamicum WhcD interacts with WhiA to exert a regulatory effect on cell division genes.

Corynebacterium glutamicum WhcD plays an important regulatory role in cell division. Binding of WhcD to the promoter region of its target genes, such as ftsZ, was observed by electrophoretic mobility shift assays (EMSA) using purified fusion proteins; however, binding could only be observed in the presence of WhiA. Although WhcD alone did not bind to the DNA, it stimulated binding of WhiA to the promoter region of the cell division gene ftsZ. Binding of WhcD and WhiA to DNA did not occur in the presence of the oxidant diamide. Purified WhcD and WhiA physically interacted in vitro. The presence of diamide did not disrupt the WhcD-WhiA interaction but affected binding of WhiA to the promoter region of ftsZ. The GACAC motif and adjacent sequences were found to be important for binding of the WhcD-WhiA complex to the DNA. Collectively, our results suggest that WhcD enhances the WhiA DNA-binding activity by physically interacting with WhiA. In addition, loss of WhiA DNA-binding activity in the presence of an oxidant agent may suggest a role for this protein as a switch that controls cell division in cells under oxidative stress.

Paeonia lactiflora Inhibits Cell Wall Synthesis and Triggers Membrane Depolarization in Candida albicans.

Fungal cell walls and cell membranes are the main targets of antifungals. In this study, we report on the antifungal activity of an ethanol extract from Paeonia lactiflora against Candida albicans, showing that the antifungal activity is associated with the synergistic actions of preventing cell wall synthesis, enabling membrane depolarization, and compromising permeability. First, it was shown that the ethanol extract from P. lactiflora was involved in damaging the integrity of cell walls in C. albicans. In isotonic media, cell bursts of C. albicans by the P. lactiflora ethanol extract could be restored, and the minimum inhibitory concentration (MIC) of the P. lactiflora ethanol extract against C. albicans cells increased 4-fold. In addition, synthesis of (1,3)-ß-D-glucan polymer was inhibited by 87% and 83% following treatment of C. albicans microsomes with the P. lactiflora ethanol extract at their 1× MIC and 2× MIC, respectively. Second, the ethanol extract from P. lactiflora influenced the function of C. albicans cell membranes. C. albicans cells treated with the P. lactiflora ethanol extract formed red aggregates by staining with a membrane-impermeable dye, propidium iodide. Membrane depolarization manifested as increased fluorescence intensity by staining P. lactiflora-treated C. albicans cells with a membrane-potential marker, DiBAC4(3) ((bis-1,3-dibutylbarbituric acid) trimethine oxonol). Membrane permeability was assessed by crystal violet assay, and C. albicans cells treated with the P. lactiflora ethanol extract exhibited significant uptake of crystal violet in a concentration-dependent manner. The findings suggest that P. lactiflora ethanol extract is a viable and effective candidate for the development of new antifungal agents to treat Candida-associated diseases.

The whcD gene of Corynebacterium glutamicum plays roles in cell division and envelope formation.

In this study, we analysed the whcD gene from Corynebacteriumglutamicum, which encodes a homologue of whiB, a Streptomycescoelicolor gene required for the sporulation of aerial hyphae. Deletion of the gene (ΔwhcD) severely affected cell growth in C. glutamicum. The ΔwhcD strain exhibited a large filamentous, branched and bud-shaped morphology with multiple septa. The transcription levels of the cell division genes involved in Z-ring assembly and septal peptidoglycan synthesis, including ftsZ, sepF, ftsQ and ftsI, were markedly decreased in the ΔwhcD strain. The divIVA gene, which is responsible for apical growth, also showed decreased transcription in the ΔwhcD strain. However, genes involved in the later stages of cell division, such as cell separation and chromosome segregation, did not show notable changes in their transcription levels. Moreover, the mutant strain was susceptible to inhibitors of transpeptidation, including penicillin and vancomycin. In addition, the transcription of genes fas-IA, fas-IB and accD1, which participate in the synthesis of fatty acid and cell envelope component mycolic acid, was altered in the ΔwhcD strain. This increased the cell surface hydrophobicity in the mutant strain, apparently leading to cell aggregation in liquid media. These findings indicate that whcD is a whiB-like gene with roles in the early stages of cell division and fatty acid synthesis, and the pleiotropic phenotypes of the ΔwhcD strain suggest that whcD may be a global regulatory gene.

Carboxyl-terminal domain characterization of polyene-specific P450 hydroxylase in Pseudonocardia autotrophica.

A polyene compound NPP identified in Pseudonocardia autotrophica was shown to contain an aglycone identical to nystatin, but to harbor a unique disaccharide moiety that led to higher solubility and reduced hemolytic activity. Recently, it was revealed that the final step of NPP (nystatin-like polyene) biosynthesis is C10 regio-specific hydroxylation by the cytochrome P450 hydroxylase (CYP) NppL (Kim et al. [7]). Through mutation and cross-complementation, here we found that NppL preferred a polyene substrate containing a disaccharide moiety for C10 hydroxylation, while its orthologue NysL involved in nystatin biosynthesis showed no substrate preference toward mono- and disaccharide moieties, suggesting that two homologous polyene CYPs, NppL and NysL might possess a unique domain recognizing a sugar moiety. Two hybrid NppL constructs containing the C-terminal domain of NysL exhibited no substrate preference toward 10-deoxy NPP and 10-deoxy nystatin-like NysL, implying that the C-terminal domain plays a major role in differentiating the sugar moiety responsible for substrate specificity. Further C-terminal domain dissection of NppL revealed that the last fifty amino acids play a critical role in determining substrate specificity of polyene-specific hydroxylation, setting the stage for the biotechnological application of hydroxyl diversification for novel polyene biosynthesis in actinomycetes.

Erratum to: The Actinobacterium Corynebacterium glutamicum, an Industrial Workhorse.

This erratum is being published to correct the 3rd author's name of above manuscript by Lee et al. that was published in Journal of Microbiology and Biotechnology (2016, 26: 807-822). The 3rd author name(Eungsoo Kim) should appear as 'Eung-Soo Kim'.

Identification of D-amino acid dehydrogenase as an upstream regulator of the autoinduction of a putative acyltransferase in Corynebacterium glutamicum.

Expression of a putative acyltransferase encoded by NCgl- 0350 of Corynebacterium glutamicum is induced by cell-free culture fluids obtained from stationary-phase growth of both C. glutamicum and Pseudomonas aeruginosa, providing evidence for interspecies communication. Here, we further confirmed that such communication occurs by showing that acyltransferase expression is induced by culture fluid obtained from diverse Gram-negative and -positive bacterial strains, including Escherichia coli, Salmonella Typhimurium, Bacillus subtilis, Staphylococcus aureus, Mycobacterium sp. strain JC1, and Mycobacterium smegmatis. A homologous acyltransferase encoded by PA5238 of P. aeruginosa was also induced by fluids obtained from P. aeruginosa as well as other bacterial strains, as observed for NCgl0350 of C. glutamicum. Because C. glutamicum is difficult to study using molecular approaches, the homologous gene PA5238 of P. aeruginosa was used to identify PA5309 as an upstream regulator of expression. A homologous D-amino acid dehydrogenase encoded by NCgl- 2909 of C. glutamicum was cloned based on amino acid similarity to PA5309, and its role in the regulation of NCgl0350 expression was confirmed. Moreover, NCgl2909 played positive roles in growth of C. glutamicum. Thus, we identified a D-amino acid dehydrogenase as an upstream regulator of the autoinduction of a putative acyltransferase in C. glutamicum.

SpiE interacts with Corynebacterium glutamicum WhcE and is involved in heat and oxidative stress responses.

The gene whcE in Corynebacterium glutamicum positively responds to oxidative and heat stress. To search for proteins that interact with WhcE, we employed a two-hybrid system with WhcE as the bait. Sequencing analysis of the isolated clones revealed peptide sequences, one of which showed high sequence identity to a hydrophobe/amphiphile efflux-1 family transporter encoded by NCgl1497. The interaction of the NCgl1497-encoded protein with WhcE in vivo was verified using reporter gene expression by real-time quantitative PCR (RT-qPCR). The WhcE protein strongly interacted with the NCgl1497-encoded protein in the presence of oxidative and heat stress. Furthermore, purified WhcE and NCgl1497-encoded proteins interacted in vitro, especially in the presence of the oxidant diamide, and the protein-protein interaction was disrupted in the presence of the reductant dithiothreitol. In addition, the transcription of NCgl1497 was activated approximately twofold in diamide- or heat-treated cells. To elucidate the function of the NCgl497 gene, an NCgl1497-deleted mutant strain was constructed. The mutant showed decreased viability in the presence of diamide and heat stress. The mutant strain also exhibited reduced transcription of the thioredoxin reductase gene, which is known to be regulated by whcE. Based on the results, NCgl1497 was named spiE (stress protein interacting with WhcE). Collectively, our data suggest that spiE is involved in the whcE-mediated oxidative stress response pathway of C. glutamicum.