Project description:Bacteria are known to cope with environmental changes by using alternative sigma factors binding to RNA polymerase core enzyme. Sigma factor is one of the targets to modify transcription regulation in bacteria and to influence production capacities. In this study, the effect of overexpressing all annotated sigma factor genes on C. glutamicum WT was assayed using an IPTG inducible plasmid system and different IPTG concentrations. It was revealed that growth was severely decreased when sigD or sigH were overexpressed with IPTG concentrations higher than 50 μM. Overexpression of sigH led to an obvious phenotypic change, a yellow-colored supernatant. HPLC analysis revealed that riboflavin was excreted to the medium when sigH was overexpressed and DNA Microarray analysis confirmed increased expression of riboflavin biosynthesis genes. In addition, genes for enzymes of the pentose phosphate pathway and for enzymes dependent on FMN, FAD or NADPH as cofactor were upregulated when sigH was overexpressed. To test if sigH overexpression can be exploited for production of riboflavin-derived FMN or FAD, the endogenous gene for bifunctional riboflavin kinase/FMN adenyltransferase was co-expressed with sigH from a plasmid. Balanced expression of sigH and ribF improved accumulation of riboflavin (19.8 ± 0.3 μM) and allowed for its conversion to FMN (33.1 ± 1.8 μM) in the supernatant. While a proof-of-concept was reached, conversion was not complete and titers were not high. This study revealed that inducible and gradable overexpression of sigma factor genes is an interesting approach to switch gene expression profiles and to discover untapped potential of bacteria for chemical production. Endogenous sigma factor gene, sigH, was overexpressed in C. glutamicum ATCC13032 from IPTG inducible vector, pEKEx3. Two different concentration of IPTG (10 μM and 15 μM) was used for induction of SigH expression.

Project description:The extracytoplasmic function sigma factor SigH is responsible for heat and oxidative stress response in a biotechnologically -important bacterium Corynebacterium glutamicum. Due to the hierarchical nature of the regulatory network, it has not been possible to fully determine the SigH regulon by previous transcriptome analyses. Here, we determined the direct genome-wide targets of SigH were determined by ChIP-chip analysis using a deletion mutant of rshA, encoding an anti-sigma factor of SigH. Seventy-five SigH-dependent promoters, including 39 new ones, were identified. Firstly, SigH-dependent heat induction was confirmed for several of the new targets, including two genes (ilvD and lipA) encoding Fe-S cluster containing enzymes. Internal SigH-dependent promoters were found in operon-like gene clusters involved in the pentose phosphate pathway, and riboflavin biosynthesis, and Zn uptake. Accordingly, deletion of rshA resulted in hyperproduction of riboflavin probably due to the coordinated upregulation of these genes. A SigH-dependent promoter was also found upstream of znuC1 in the znuA1C1B1 operon encoding an ABC-type transporter for Zn uptake. Overexpression of znuC1B1 by deletion of rshA and by an IPTG-inducible promoter and similarly affected expression of Zn-responsive genes, indicating that SigH-dependent upregulation of part of the operon potentiates Zn uptake. probably through Zn overload, indicating new physiological roles of SigH. Furthermore, reporter assays demonstrated that rshA in the sigH-rshA operon was heat-inducible under the control of an internal SigH-dependent promoters, identified upstream of rshA within the sigH-rshA operon, while the sigH promoter was independent of SigH, suggesting negative autoregulation of SigH activity. Finally, a SigH-dependent promoter identified and upstream of sigA encoding the primary sigma factor , wereas highly heat-inducible, but much weaker than the known SigA-dependent one.. The promoter upstream of sigH was independent of SigH but showed weak heat-shock response. The known SigA-dependent sigA promoter was much stronger than the SigH-dependent one. Taken together with the fact that SigH also regulates sigB encoding the primary-like sigma factor, Tthese findings uncovered a complicated regulatory network of the sigma factors.

Project description:The extracytoplasmic function sigma factor SigH is responsible for heat and oxidative stress response in a biotechnologically -important bacterium Corynebacterium glutamicum. Due to the hierarchical nature of the regulatory network, it has not been possible to fully determine the SigH regulon by previous transcriptome analyses. Here, we determined the direct genome-wide targets of SigH were determined by ChIP-chip analysis using a deletion mutant of rshA, encoding an anti-sigma factor of SigH. Seventy-five SigH-dependent promoters, including 39 new ones, were identified. Firstly, SigH-dependent heat induction was confirmed for several of the new targets, including two genes (ilvD and lipA) encoding Fe-S cluster containing enzymes. Internal SigH-dependent promoters were found in operon-like gene clusters involved in the pentose phosphate pathway, and riboflavin biosynthesis, and Zn uptake. Accordingly, deletion of rshA resulted in hyperproduction of riboflavin probably due to the coordinated upregulation of these genes. A SigH-dependent promoter was also found upstream of znuC1 in the znuA1C1B1 operon encoding an ABC-type transporter for Zn uptake. Overexpression of znuC1B1 by deletion of rshA and by an IPTG-inducible promoter and similarly affected expression of Zn-responsive genes, indicating that SigH-dependent upregulation of part of the operon potentiates Zn uptake. probably through Zn overload, indicating new physiological roles of SigH. Furthermore, reporter assays demonstrated that rshA in the sigH-rshA operon was heat-inducible under the control of an internal SigH-dependent promoters, identified upstream of rshA within the sigH-rshA operon, while the sigH promoter was independent of SigH, suggesting negative autoregulation of SigH activity. Finally, a SigH-dependent promoter identified and upstream of sigA encoding the primary sigma factor , wereas highly heat-inducible, but much weaker than the known SigA-dependent one.. The promoter upstream of sigH was independent of SigH but showed weak heat-shock response. The known SigA-dependent sigA promoter was much stronger than the SigH-dependent one. Taken together with the fact that SigH also regulates sigB encoding the primary-like sigma factor, Tthese findings uncovered a complicated regulatory network of the sigma factors.

Project description:Riboflavin (RF) and its cofactors (FMN and FAD) are essential molecules for vital metabolic processes in all organisms. Thus, the flavin metabolism must be tightly regulated in the cells. We previously demonstrated that the intracellular levels of flavins were tightly maintained by the enzymes involved in their synthesis and degradation, inducing a plastidic FAD hydrolase (AtNUDX23), in Arabidopsis. However, information of regulatory factors involved in the flavin homeostasis and transporters in each organelle are mostly limited. Terefore, we tried to identify novel factors involved in the flavin metabolism, such as transcription factors and transporters by a transcriptome analysis after exogenous FAD treatment.

Project description:To characterize regulons of alternative sigma factor SigH, SigL, and SigC in Listeria monocytogenes, in-frame mutant strains were created in the 10403S background. Regulons controlled by these 3 alternative sigma factors were characterized by whole-genome microarrays. The L. monocytogenes 10403S wild type and sigma factor null mutation strains were grown at 37 °C to stationary phase (defined in this study as growth to OD600 = 1.0, followed by incubation for an additional 3 h) prior to RNA isolation. Transcriptional profiles of 10403S wild type were compared to those of null mutation strain. In addition to stationary phase condition, SigC regulon was further characterized using heat stress (cultures grown to log phase at OD600 = 0.4, 37 °C and then exposed to heat at 55 °C for 10 min) and a condition with IPTG-inducible expression of sigC (sigC gene is placed under Pspac promoter using pLIV2 vector in wild type 10403S background). Under these conditions, expression profiles were compared between (i) wild type and sigC null mutant for heat stress and (ii) IPTG-inducible sigC strain and sigC null mutant, respectively. Using adjusted P < 0.05 and ≥ 1.5 fold change as cutoff values, microarray analyses identified 169 SigH-dependent, 51 SigL-dependent, and 3 SigC-dependent genes. Keywords: Listeria monocytogenes, alternative sigma factor, SigH, SigL, SigC

Project description:Like other bacterial species, Mycobacterium tuberculosis has multiple sigma (s) factors encoded in its genome. In previously published work, we and others have shown that mutations in some of these transcriptional activators render M. tuberculosis sensitive to various environmental stresses and, in some cases, cause attenuated virulence phenotypes. In this paper, we characterize a M. tuberculosis mutant lacking the ECF s factor sigma-H. This mutant was more sensitive than the wild type to heat shock and to various oxidative stresses, but did not show decreased ability to grow inside macrophages. Using quantitative reverse transcription-PCR and microarray technology, we have started to define the sigma-H regulon and its involvement in the global regulation of the response to heat shock and the thiol-specific oxidizing agent diamide. We identified 48 genes whose expression increased after exposure of M. tuberculosis to diamide; out of these, 39 were not induced in the sigH mutant, showing their direct or indirect dependence on sigma-H. Some of these genes encode proteins whose predicted function is related to thiol metabolism, such as thioredoxin, thioredoxin reductase and enzymes involved in cysteine and molybdopterine biosynthesis. Other genes under sigma-H control encode transcriptional regulators such as sigB, sigE, and sigH itself. Keywords: comparative genome hybridization design and genetic modification design

Project description:DNA microarray analysis of genes regulated by the alternative sigma factor, sigma 32 (rpoH). Sigma 32-dependent genes were initially identified by comparing a wild type (wt) E. coli K-12 strain that has a low level of sigma 32, with a strain over-expressing sigma 32 (following induction of rpoH from an inducible promoter by IPTG). We monitored changes in gene expression in 4 separate time-courses. Because sigma 32 is negatively regulated, its activity decreases 10 min after overexpression. Consequently, to identify genes regulated by sigma 32 we analyzed the expression data for 10 min after overexpression using SAM (Statistical Analysis of Microarrays). We identified 105 genes organized in 66 separate transcription units. This study is detailed in Nonaka et al 2006 (submitted). Keywords: time course

Project description:Mycobacterium avium subspecies paratuberculosis (a.k.a. M. paratuberculosis) causes Johne’s disease, an enteric infection in cattle and other ruminants, greatly afflicting the dairy industry worldwide. Once inside the cell, M. paratuberculosis is known to survive harsh microenvironments, especially those inside activated macrophages. To improve our understanding of M. paratuberculosis pathogenesis, we examined the phagosome maturation associated with transcriptional responses of M. paratuberculosis during macrophage infection. Monitoring cellular markers, only live M. paratuberculosis bacilli were able to prevent phagosome maturation and reduce its acidification. On the transcriptional level, over 300 of M. paratuberculosis genes were significantly, differentially regulated in both naïve and IFN-γ-activated macrophages. These genes include the sigma factor H (sigH) that was shown to be important during persistent infection in M. tuberculosis. Interestingly, a sigH-knockout mutant showed increased sensitivity to a sustained level of thiol-specific oxidative stress. Large-scale RNA sequence analysis revealed that a large number of genes belong to the sigH regulon, especially following diamide stress. Genes involved in oxidative stress and virulence were among the induced genes in the sigH regulon with a putative consensus sequence for SigH binding was recognized in a subset of these genes (N=30), suggesting direct regulation with SigH. Finally, mice infections showed a significant attenuation of the ∆sigH mutant compared to its parental strain suggesting a role for sigH in M. paratuberculosis virulence. Such analysis could identify potential targets for further testing as vaccine candidates against Johne’s disease.

Project description:Respiratory complex I plays a crucial role in the mitochondrial electron transport chain and shows promise as a therapeutic target for various human diseases. While most studies focus on inhibiting complex I at the Q-site, little is known about inhibitors targeting other sites within the complex. In this study, we demonstrate that diphenyleneiodonium (DPI), a known N-site inhibitor, uniquely affects the stability of complex I by inhibiting its flavin cofactor FMN. Treatment with DPI blocks the final stage of complex I assembly, leading to the accumulation of assembly intermediates that lack the N-module. Remarkably, high-dose DPI treatment can completely and reversibly degrade complex I in different cellular models. The mechanism involves the accumulation of DPI in mitochondria, where it reacts with FMN, depleting the effective pool of FMN and halting complex I maturation. Consistently, growing cells in medium lacking the FMN precursor riboflavin or knocking out the mitochondrial FAD carrier gene SLC25A32 results in complex I degradation and impairs complex I-dependent respiration. Overall, our findings establish a direct connection between mitochondrial flavin homeostasis and complex I stability and assembly, paving the way for novel pharmacological strategies to regulate respiratory complex I.

Project description:Genes encoding dodecin proteins are present in almost 20% of archaeal and in more than 50% of bacterial genomes. Archaeal dodecins bind riboflavin (vitamin B2), are thought to play a role in flavin homeostasis and possibly also help to protect cells from radical or oxygenic stress. Bacterial dodecins were found to bind riboflavin-5’-phosphate (also called flavin mononucleotide or FMN) and coenzyme A, but their physiological function remained unknown. In this study, we set out to investigate the relevance of dodecins for flavin metabolism and oxidative stress management in the phylogenetically related bacteria Streptomyces coelicolor and Streptomyces davawensis. Therfore we have treated Streptomyces coelicolor wildtype, Streptomyces davawensis wildytype and Streptomyces davawensis dodecin deletion strain with plumbagin, a compound, which induces oxidative stress in exponential and stationary growth phase and analysed the transcriptome via RNA-seq (Illumina TruSeq stranded mRNA libraries sequenced on Illumina HiSeq rapid mode 2 x 70nt PE).