Project description:To get insights in the electrogenic anaerobic lifestyle of P. putida KT2440 cultivated in a bioelectrochemical system (BES), we employed whole genome microarray expression profile.

Project description:Bioelectrochemical systems Metagenome

Project description:BioElectrochemical Systems Technology

Project description:Bioelectrochemical phenol degradation

Project description:Biocathode Sensor

Project description:Chitin sensor

Project description:Purple phototrophic bacteria (PPB) naturally accept CO2 into their metabolism as a primary redox sink system in photo-heterotrophy. Dedicated use of this feature for developing sustainable processes (e.g., through negative-emissions photo-bioelectrosynthesis) requires a deep knowledge of the inherent metabolic mechanisms. Here we provide evidence of the tuning of the PPB metabolic mechanisms upon redox stressing through negative polarization (-0.4 and -0.8 V vs. Ag/AgCl) in photo-bioelectrochemical devices. Using metaproteomic analysis at both reactor ans species level, we showed that a mixed PPB-culture up-regulates its ability to capture CO2 from organics oxidation through the Calvin-Besson-Bassam cycle and anaplerotic pathways, and the redox imbalance is promoted to polyhydroxyalkanoates production. The ecological relationship of PPB with mutualist bacteria stabilizes the system and opens the door for future development of photo-bioelectrochemical devices focused on CO2 up-cycling.

Project description:To determine if an endogenous 22G siRNA sensor transgene is subject to siRNA amplification, small RNAs were deep sequenced from the sensor and from a control transgene that is identical to the sensor but lacks an siRNA target site.

Project description:Anaerobic Bioelectrochemical Microbial Cultivation

Project description:Anaerobic Bioelectrochemical Microbial Cultivation