Classification of three corynebacterial strains isolated from a small paddock in North Rhine-Westphalia: proposal of Corynebacterium kalinowskii sp. nov., Corynebacterium comes sp. nov. and Corynebacterium occultum sp. nov.

Three novel corynebacterial species were isolated from soil sampled at a paddock in Vilsendorf, North Rhine-Westphalia, Germany. The strains were coccoid or irregular rod-shaped, catalase-positive and pale white to yellow-orange in colour. By whole genome sequencing and comparison of the 16S rRNA genes as well as the whole genome structure, it was shown that all three strains represent novel species of the family Corynebacteriaceae, order Corynebacteriales, class Actinobacteria. This project describes the isolation, identification, sequencing, and phenotypic characterization of the three novel Corynebacterium species. We propose the names Corynebacterium kalinowskii sp. nov. (DSM 110639T=LMG 31801T), Corynebacterium comes sp. nov. (DSM 110640T=LMG 31802T), and Corynebacterium occultum sp. nov. (DSM 110642T=LMG 31803T).

Stable integration of the Mrx1-roGFP2 biosensor to monitor dynamic changes of the mycothiol redox potential in Corynebacterium glutamicum.

Mycothiol (MSH) functions as major low molecular weight (LMW) thiol in the industrially important Corynebacterium glutamicum. In this study, we genomically integrated an Mrx1-roGFP2 biosensor in C. glutamicum to measure dynamic changes of the MSH redox potential (EMSH) during the growth and under oxidative stress. C. glutamicum maintains a highly reducing intrabacterial EMSH throughout the growth curve with basal EMSH levels of ~- 296 mV. Consistent with its H2O2 resistant phenotype, C. glutamicum responds only weakly to 40 mM H2O2, but is rapidly oxidized by low doses of NaOCl. We further monitored basal EMSH changes and the H2O2 response in various mutants which are compromised in redox-signaling of ROS (OxyR, SigH) and in the antioxidant defense (MSH, Mtr, KatA, Mpx, Tpx). While the probe was constitutively oxidized in the mshC and mtr mutants, a smaller oxidative shift in basal EMSH was observed in the sigH mutant. The catalase KatA was confirmed as major H2O2 detoxification enzyme required for fast biosensor re-equilibration upon return to non-stress conditions. In contrast, the peroxiredoxins Mpx and Tpx had only little impact on EMSH and H2O2 detoxification. Further live imaging experiments using confocal laser scanning microscopy revealed the stable biosensor expression and fluorescence at the single cell level. In conclusion, the stably expressed Mrx1-roGFP2 biosensor was successfully applied to monitor dynamic EMSH changes in C. glutamicum during the growth, under oxidative stress and in different mutants revealing the impact of Mtr and SigH for the basal level EMSH and the role of OxyR and KatA for efficient H2O2 detoxification under oxidative stress.

Transcriptional response of Corynebacterium glutamicum ATCC 13032 to hydrogen peroxide stress and characterization of the OxyR regulon.

The aerobic soil bacterium Corynebacterium glutamicum ATCC 13032 has a remarkable natural resistance to hydrogen peroxide. A major player in hydrogen peroxide defense is the LysR type transcriptional regulator OxyR, homologs of which are present in a wide range of bacteria. In this study, the global transcriptional response of C. glutamicum to oxidative stress induced by hydrogen peroxide was examined using whole genome DNA microarrays, demonstrating the dynamic reaction of the regulatory networks. Deletion of oxyR resulted in an increased resistance of the C. glutamicum mutant to hydrogen peroxide. By performing DNA microarray hybridizations and RT-qPCR, differentially expressed genes were detected in the mutant. The direct control by OxyR was verified by electrophoretic mobility shift assays for 12 target regions. The results demonstrated that OxyR in C. glutamicum acts as a transcriptional repressor under non-stress conditions for a total of 23 genes. The regulated genes encode proteins related to oxidative stress response (e.g. katA), iron homeostasis (e.g. dps) and sulfur metabolism (e.g. suf cluster). Besides the regulator of the suf cluster, SufR, OxyR regulated the gene cg1695 encoding a putative transcriptional regulator, indicating the role of OxyR as a master regulator in defense against oxidative stress. Using a modified DNase footprint approach, the OxyR-binding sites in five target promoter regions, katA, cydA, hemH, dps and cg1292, were localized and in each upstream region at least two overlapping binding sites were found. The DNA regions protected by the OxyR protein are about 56bp in length and do not have evident sequence similarities. Still, by giving an insight in the H2O2 stimulon and extending the OxyR regulon this study considerably contributes to the understanding of the response of C. glutamicum to hydrogen peroxide-mediated oxidative stress.

The dual transcriptional regulator CysR in Corynebacterium glutamicum ATCC 13032 controls a subset of genes of the McbR regulon in response to the availability of sulphide acceptor molecules.

BACKGROUND: Regulation of sulphur metabolism in Corynebacterium glutamicum ATCC 13032 has been studied intensively in the last few years, due to its industrial as well as scientific importance. Previously, the gene cg0156 was shown to belong to the regulon of McbR, a global transcriptional repressor of sulphur metabolism in C. glutamicum. This gene encodes a putative ROK-type regulator, a paralogue of the activator of sulphonate utilisation, SsuR. Therefore, it is an interesting candidate for study to further the understanding of the regulation of sulphur metabolism in C. glutamicum. RESULTS: Deletion of cg0156, now designated cysR, results in the inability of the mutant to utilise sulphate and aliphatic sulphonates. DNA microarray hybridisations revealed 49 genes with significantly increased and 48 with decreased transcript levels in presence of the native CysR compared to a cysR deletion mutant. Among the genes positively controlled by CysR were the gene cluster involved in sulphate reduction, fpr2 cysIXHDNYZ, and ssuR. Gel retardation experiments demonstrated that binding of CysR to DNA depends in vitro on the presence of either O-acetyl-L-serine or O-acetyl-L-homoserine. Mapping of the transcription start points of five transcription units helped to identify a 10 bp inverted repeat as the possible CysR binding site. Subsequent in vivo tests proved this motif to be necessary for CysR-dependent transcriptional regulation. CONCLUSION: CysR acts as the functional analogue of the unrelated LysR-type regulator CysB from Escherichia coli, controlling sulphide production in response to acceptor availability. In both bacteria, gene duplication events seem to have taken place which resulted in the evolution of dedicated regulators for the control of sulphonate utilisation. The striking convergent evolution of network topology indicates the strong selective pressure to control the metabolism of the essential but often toxic sulphur-containing (bio-)molecules.

The gene ncgl2918 encodes a novel maleylpyruvate isomerase that needs mycothiol as cofactor and links mycothiol biosynthesis and gentisate assimilation in Corynebacterium glutamicum.

Data mining of the Corynebacterium glutamicum genome identified 4 genes analogous to the mshA, mshB, mshC, and mshD genes that are involved in biosynthesis of mycothiol in Mycobacterium tuberculosis and Mycobacterium smegmatis. Individual deletion of these genes was carried out in this study. Mutants mshC- and mshD- lost the ability to produce mycothiol, but mutant mshB- produced mycothiol as the wild type did. The phenotypes of mutants mshC- and mshD- were the same as the wild type when grown in LB or BHIS media, but mutants mshC- and mshD- were not able to grow in mineral medium with gentisate or 3-hydroxybenzoate as carbon sources. C. glutamicum assimilated gentisate and 3-hydroxybenzoate via a glutathione-independent gentisate pathway. In this study it was found that the maleylpyruvate isomerase, which catalyzes the conversion of maleylpyruvate into fumarylpyruvate in the glutathione-independent gentisate pathway, needed mycothiol as a cofactor. This mycothiol-dependent maleylpyruvate isomerase gene (ncgl2918) was cloned, actively expressed, and purified from Escherichia coli. The purified mycothiol-dependent isomerase is a monomer of 34 kDa. The apparent Km and Vmax values for maleylpyruvate were determined to be 148.4 +/- 11.9 microM and 1520 +/- 57.4 micromol/min/mg, respectively (mycothiol concentration, 2.5 microM). Previous studies had shown that mycothiol played roles in detoxification of oxidative chemicals and antibiotics in streptomycetes and mycobacteria. To our knowledge, this is the first demonstration that mycothiol is essential for growth of C. glutamicum with gentisate or 3-hydroxybenzoate as carbon sources and the first characterization of a mycothiol-dependent maleylpyruvate isomerase.