Project description:Anode biofilms in microbial fuel cells

Project description:Microtoming Coupled with Microarray Analysis to Evaluate Potential Differences in the Metabolic Status of Geobacter sulfurreducens at Different Depths in Anode Biofilms Differences in the Metabolic Status of Geobacter sulfurreducens at Different Depths in A Current Producing Biofilm Further insight into the metabolic status of cells within anode biofilms is essential for understanding the functioning of microbial fuel cells and developing strategies to optimize their power output. In order to further compare the metabolic status of cells growing close to the anode versus cells in the outer portion of the anode biofilm, mature anode biofilms were treated to stop turnover over of mRNA and then encased in resin which was sectioned into 100 nm shavings with a diamond knife and pooled into inner (0-20 µm from anode surface) and outer (30-60 µm) fractions. Whole genome DNA microarray analysis of RNA extracted from the shavings revealed that, at a 2-fold lower threshold, there were 146 genes that had significant (p<0.05), differences in transcript abundance between the inner and outer portions of the biofilm. Only 1 gene, GSU0093, a hypothetical ABC transporter, had significantly higher transcript abundances in the outer biofilm. Genes with lower transcript abundance in the outer biofilm included genes for ribosomal proteins and NADH dehydrogenase, suggesting that cells in the outer biofilm had lower metabolic rates. However, the differences in transcript abundance were relatively low (<3-fold) and the outer biofilm did not have significantly lower expression of the genes for TCA cycle enzymes which previous studies have demonstrated are sensitive indicators of changes in rates of metabolism in G. sulfurreducens. There also was no significant difference in the transcript levels for outer-surface cell components thought to be important in electron transfer in anode biofilms. Lower expression of genes involved in stress responses in the outer biofilm may reflect the development of low pH near the surface of the anode. The results of the metabolic staining and gene expression studies suggest that cells throughout the biofilm are metabolically active and can potentially contribute to current production. The microtoming/microarray strategy described here may be useful for evaluating gene expression with depth in a diversity of microbial biofilms.

Project description:Microtoming Coupled with Microarray Analysis to Evaluate Potential Differences in the Metabolic Status of Geobacter sulfurreducens at Different Depths in Anode Biofilms Differences in the Metabolic Status of Geobacter sulfurreducens at Different Depths in A Current Producing Biofilm Further insight into the metabolic status of cells within anode biofilms is essential for understanding the functioning of microbial fuel cells and developing strategies to optimize their power output. In order to further compare the metabolic status of cells growing close to the anode versus cells in the outer portion of the anode biofilm, mature anode biofilms were treated to stop turnover over of mRNA and then encased in resin which was sectioned into 100 nm shavings with a diamond knife and pooled into inner (0-20 µm from anode surface) and outer (30-60 µm) fractions. Whole genome DNA microarray analysis of RNA extracted from the shavings revealed that, at a 2-fold lower threshold, there were 146 genes that had significant (p<0.05), differences in transcript abundance between the inner and outer portions of the biofilm. Only 1 gene, GSU0093, a hypothetical ABC transporter, had significantly higher transcript abundances in the outer biofilm. Genes with lower transcript abundance in the outer biofilm included genes for ribosomal proteins and NADH dehydrogenase, suggesting that cells in the outer biofilm had lower metabolic rates. However, the differences in transcript abundance were relatively low (<3-fold) and the outer biofilm did not have significantly lower expression of the genes for TCA cycle enzymes which previous studies have demonstrated are sensitive indicators of changes in rates of metabolism in G. sulfurreducens. There also was no significant difference in the transcript levels for outer-surface cell components thought to be important in electron transfer in anode biofilms. Lower expression of genes involved in stress responses in the outer biofilm may reflect the development of low pH near the surface of the anode. The results of the metabolic staining and gene expression studies suggest that cells throughout the biofilm are metabolically active and can potentially contribute to current production. The microtoming/microarray strategy described here may be useful for evaluating gene expression with depth in a diversity of microbial biofilms. Three biological replicates were hybridized in triplicate on a coustom affimetrix tilling array using prokaryotic protocol (p69Affy, p75 Adobe) for labeling, hybridization and scanning.

Project description:Anode biofilm in microbial fuel cells Metagenome

Project description:Microbial fuel cells anode community ARNr 16s analysis

Project description:Microbial communities in the anode chamber of microbial fuel cells

Project description:G. sulfurreducens can generate electricity from the oxidation of organic compounds. This is because it can take electrons from organic compounds and ship them out to the outer surface of the cell where they can then be deposited on various insoluble electron acceptors including electrodes. Cells attatched to the surface of an electrode oxidize acetate and and deposit the electrons derived from acetate onto the surface of the electrode after which they can travel through an electrical circuit, producing a current. Microbial fuel cells powered by acetate oxidation by Geobacter species are called Geobatteries. In this experiment we compared gene expression in a biofilm of the wild type strain growing on the surface of an electrode within a current-producing Geobattery to gene expression in a wild type biofilm that is not producing current, but is growing on the surface of an electrode. In both cases, the cells were growing in a flow-through two chambered H-cell Geobattery setup. This consists of two glass chambers, an anoxic anode chamber containing G. sulfurreducens, a graphite electrode, a reference electrode and growth medium and an oxic chamber containing the counter electrode. The two chambers are connected by a cation selective membrane and a wire connected to a potentionstat. A potentiostat is an instrument which maintains the redox potential of the anode at a fixed value relative to a reference electrode. Media continuously flowed through the anoxic anode chamber at a dilution rate of 0.15. In the experimental condition, the Geobattery was operational. The circuit was closed and G. sulfurreducens attached to the electrode generated current as it oxidized acetate. The redox potential at the anode was poised at 300 mV by the potentiostat. In the control condition, everything was the same, except that the medium in the anode chamber contained fumarate as electron acceptor, and the anode was not hooked up to the potentiostat i.e. the circuit was open. This prevented the anode from serving as an electron acceptor. Nevertheless a thick G. sulfurreducens biofilm grew on the surface of the electrode. The control and experimental geobatteries were harvested when current in the operational/experimental Geobatteries reached 10 mA. Keywords: two condition comparison

Project description:Geobacter sulfurreducens is a dissimilatory metal-reducing bacterium capable of forming thick electron-conducting biofilms on solid electrodes in the absence of alternative electron acceptors. The remarkable ability of such biofilms to transfer electrons, liberated from soluble organic electron donors, over long distances has attracted scientific interest as to the mechanism for this process, and technological interest for application to microbial fuel and electrolysis cells and sensors. Here, we employ comparative proteomics to identify key metabolic pathways involved in G. sulfurreducens respiration by planktonic cells versus electron-conducting biofilms, in an effort to elucidate long-range electron transfer mechanisms.

Project description:Microbial community of polyaniline coated anode microbial fuel cell

Project description:Anode and membrane biofouling microbial fuel cell samples