Project description:The BarA/UvrY two-component system is well conserved in numerous species of the γ-proteobacteria. However, the regulatory output of this system differs significantly between the species. In this study, we characterized the BarA/UvrY two-component system in Shewanella oneidensis MR-1. Sensor kinase BarA and the cognate response regulator UvrY were identified by bioinformatic analysis and subsequent in vivo interaction and phosphotransfer studies. The expression of two putative small regulatory RNAs (sRNAs), CsrB1 and CsrB2, was demonstrated to be dependent on UvrY. In contrast, a third predicted sRNA, CsrC, was expressed independently of UvrY. Transcriptomic analysis by microarrays revealed that UvrY is a global regulator and affects transcription of key enzymes of carbon metabolism such as ackA, aceAB, and pflAB. Subsequent growth experiments demonstrated that mutants lacking UvrY have a significant growth advantage over the wild type during aerobic growth on N-acetylglucosamine while under under anaerobic conditions the mutant grew more slowly. This effect was absent during growth with lactate as carbon source or in complex medium. Based on these results, we conclude that, in S.oneidensis MR-1, the global BarA/UvrY regulatory system is involved in central carbon metabolism processes. In the study presented, expression profiles of three independent replicates of Shewanella oneidensis MR-1 ∆uvrY were compared to three independent replicates of Shewanella oneidensis MR-1 wild type cells. All samples were obtained from exponentially aerobically grown cells in LB to stationary phase (OD600nm=4.0)

Project description:The BarA/UvrY two-component system is well conserved in numerous species of the γ-proteobacteria. However, the regulatory output of this system differs significantly between the species. In this study, we characterized the BarA/UvrY two-component system in Shewanella oneidensis MR-1. Sensor kinase BarA and the cognate response regulator UvrY were identified by bioinformatic analysis and subsequent in vivo interaction and phosphotransfer studies. The expression of two putative small regulatory RNAs (sRNAs), CsrB1 and CsrB2, was demonstrated to be dependent on UvrY. In contrast, a third predicted sRNA, CsrC, was expressed independently of UvrY. Transcriptomic analysis by microarrays revealed that UvrY is a global regulator and affects transcription of key enzymes of carbon metabolism such as ackA, aceAB, and pflAB. Subsequent growth experiments demonstrated that mutants lacking UvrY have a significant growth advantage over the wild type during aerobic growth on N-acetylglucosamine while under under anaerobic conditions the mutant grew more slowly. This effect was absent during growth with lactate as carbon source or in complex medium. Based on these results, we conclude that, in S.oneidensis MR-1, the global BarA/UvrY regulatory system is involved in central carbon metabolism processes.

Project description:Electrochemically active bacteria (EAB) are capable of electrochemical interactions with electrodes via extracellular electron transfer (EET) pathways and serve as essential components in bioelectrochemical systems. Previous studies have suggested that EAB, such as Shewanella oneidensis MR-1, use cyclic AMP (cAMP) receptor proteins for coordinately regulating the expression of catabolic and EET-related genes, allowing us to hypothesize that the intracellular cAMP concentration is an important factor determining electrochemical activities of EAB. The present study constructed an MR-1 mutant, cyaC-OE that overexpressed cyaC, a gene encoding a membrane-bound class III adenylate cyclase, and examined its electrochemical and transcriptomic characteristics. We show that intracellular cAMP concentration in cyaC-OE is more than double that in wild-type MR-1, and cya-OE generates approximately two-fold higher current in BES than the wild type. In addition, the expression of genes involved in EET and anaerobic carbon catabolism is up-regulated in cya-OE as compared to that in the wild type. These results suggest that enhancement of the intracellular cAMP level is a promising approach for constructing an EAB with high catabolic and electrochemical activities.

Project description:S. oneidensis MR-1 was grown with different electron acceptors: an electrode at 0.4 V vs. SHE, 50 mM Fe(III)citrate, and oxygen. The gene expression pattern for each experiment was analyzed and the differences in gene expression for the different experimental conditions were compared.

Project description:. In this study we show successful use of SWATH-MS for quantitative proteomic analysis of a microbial electrochemically active biofilm. Shewanella oneidensis MR-1 was grown on carbon cloth electrodes under continuous anodic electrochemical polarizations in a bioelectrochemical system. Using lactate as the electron donor, anodes serving as terminal microbial electron acceptors were operated at three different electrode potentials (+0.71V, +0.21V & -0.19V vs. SHE) and the development of catalytic activity was monitored by measuring the current traces over time. Once maximum current was reached (usually within 21-29 hours) the electrochemical systems were shut off and biofilm proteins were extracted from the electrodes for proteomic assessment.

Project description:Bioelectrochemical systems employing mixed microbial communities as biocatalysts are gaining importance as potential renewable energy, bioremediation, or biosensing devices. While we are beginning to understand how individual microorganism species interact with an electrode as electron donor, not much is known about the interactions between different microbial species in a community. Here, we compare the bioelectrochemical performance of Shewanella oneidensis in a pure-culture and in a co-culture with the homolactic acid fermenter Lactococcus lactis. While S. oneidensis alone can only use lactate as electron donor for current production, the co-culture is able to convert glucose into current with a similar coulombic efficiency of approximately 17%, respectively. With (electro)-chemical analysis and transcription profiling, we found that the BES performance and S. oneidensis physiology were not significantly different whether grown as a pure- or co-culture. These co-culture experiments represent a first step in understanding microbial interactions in BES communities with the goal to design complex microbial communities, which specifically convert target substrates into electricity. Further, for the first time, we elucidated S. oneidensis gene expression with an electrode as the only electron acceptor. The expression pattern confirms many previous studies regarding the enzymatic requirements for electrode respiration, and it generates new hypotheses on the functions of proteins, which are so far not known to be involved in electrode respiration. The BES was either operated with S. oneidensis alone, fed with lactate, or it was operated with S. oneidensis and L. lactis with glucose as primary substrate. The basic medium was a modified M4 medium containing 0.5 g/L yeast extract, 0.5 g/L trypton and 5 g/L glycerol phosphate, besides the commen M4 incredients. S. oneidensis oxidizes lactate to acetate and electrons in a BES - the latter generate a current at a graphite anode. The anode biofilm was harvested after about 4 weeks of continuous BES operation and subjected to total RNA extraction.

Project description:Shewanella oneidensis was grown in open circuit (control) and closed circuit (current collecting) to observe the difference in extracellular electron transfer (EET) mechanisms. mRNA was extracted, amplified and used on Combimatrix custom arrays to obtain an expression profile. Analysis was performed using R.

Project description:Electrochemically active bacteria (EAB) receive considerable attention for their utility in bioelectrochemical processes. Although electrode potentials are known to affect the metabolic activity of EAB, it is unclear whether EAB are able to sense and respond to electrode potentials. Here, we show that, in the presence of a high-potential electrode, a model EAB Shewanella oneidensis MR-1 can utilize NADH-dependent catabolic pathways and a background formate-dependent pathway to achieve high growth yield. We also show that an Arc regulatory system is involved in sensing electrode potentials and regulating the expression of catabolic genes, including those for NADH dehydrogenase. We suggest that these findings may facilitate the use of EAB in biotechnological processes and offer the molecular bases for their ecological strategies in natural habitats.

Project description:Bioelectrochemical systems employing mixed microbial communities as biocatalysts are gaining importance as potential renewable energy, bioremediation, or biosensing devices. While we are beginning to understand how individual microorganism species interact with an electrode as electron donor, not much is known about the interactions between different microbial species in a community. Here, we compare the bioelectrochemical performance of Shewanella oneidensis in a pure-culture and in a co-culture with the homolactic acid fermenter Lactococcus lactis. While S. oneidensis alone can only use lactate as electron donor for current production, the co-culture is able to convert glucose into current with a similar coulombic efficiency of approximately 17%, respectively. With (electro)-chemical analysis and transcription profiling, we found that the BES performance and S. oneidensis physiology were not significantly different whether grown as a pure- or co-culture. These co-culture experiments represent a first step in understanding microbial interactions in BES communities with the goal to design complex microbial communities, which specifically convert target substrates into electricity. Further, for the first time, we elucidated S. oneidensis gene expression with an electrode as the only electron acceptor. The expression pattern confirms many previous studies regarding the enzymatic requirements for electrode respiration, and it generates new hypotheses on the functions of proteins, which are so far not known to be involved in electrode respiration.

Project description:Shewanella oneidensis and Enterococcus faecium were grown in open circuit (control) and closed circuit (current collecting) to observe the difference in extracellular electron transfer (EET) mechanisms. mRNA was extracted, amplified and used on Combimatrix custom arrays to obtain an expression profile. Analysis was performed using R.