Biofuel and electricity producing fuel cells and systems and methods related to same

What is claimed is: 1. A microbial fuel cell comprising: an anode electrode contained in an anode chamber, a cathode electrode contained in a cathode chamber, and a reference electrode contained in the anode chamber or the cathode chamber, wherein the anode electrode, the cathode electrode and the reference electrode are electronically connected to each other; a first biocatalyst located in the anode chamber and comprising a mesophilic consolidated bioprocessing organism configured to hydrolyze and/or ferment biomass to produce one or more fermentation waste byproducts, wherein the mesophilic consolidated bioprocessing organism is also configured to anaerobically co-ferment six- and five-carbon sugars and comprises Cellulomonas uda (Cuda); and a second biocatalyst located in the anode chamber and comprising an alcohol-tolerant electricigen cultured at a temperature not greater than 40° C. and configured to convert substantially all of the fermentation waste byproducts to electricity by transferring substantially all electrons present therein to the anode electrode, wherein the fermentation waste byproducts converted to electricity include acetate, formate, and/or lactate. 2. The microbial fuel cell of claim 1 wherein the biomass is cellulosic biomass. 3. The microbial fuel cell of claim 1 wherein the biomass is a polyol-containing product. 4. The microbial fuel cell of claim 3 wherein the polyol-containing product is glycerin-containing water. 5. The microbial fuel cell of claim 1 further comprising an exchange membrane located between the anode chamber and the cathode chamber, the exchange membrane configured to transfer electrons and protons. 6. The microbial fuel cell of claim 1 wherein the alcohol-tolerant electricigen is Geobacter sulfurreducens (Gsu) or an alcohol-tolerant strain of Gsu (GsuA). 7. The microbial fuel cell of claim 1 wherein the one or more fermentation products further includes hydrogen, and the first biocatalyst is also configured to produce ethanol. 8. The microbial fuel cell of claim 7 wherein the microbial fuel cell can yield at least 80% of a theoretical maximum of ethanol. 9. The microbial fuel cell of claim 1 further comprising an electronic device connected to the anode electrode, the cathode electrode and the reference electrode. 10. The microbial fuel cell of claim 1 wherein the Cuda is an alcohol-tolerant strain. 11. The microbial fuel cell of claim 1 wherein the fermentation can be completed in less than 50 hours. 12. A microbial fuel cell comprising: an anode electrode, a cathode electrode and a reference electrode located in a single chamber and electronically connected to each other; a first biocatalyst located in the anode chamber and comprising a mesophilic consolidated bioprocessing organism configured to hydrolyze and/or ferment biomass to produce one or more fermentation waste byproducts, wherein the mesophilic consolidated bioprocessing organism is also configured to anaerobically co-ferment six- and five-carbon sugars and comprises Cellulomonas uda (Cuda); and a second biocatalyst located in the anode chamber and comprising an alcohol-tolerant electricigen cultured at a temperature not greater than 40° C. and configured to convert the fermentation waste byproducts to electricity by transferring substantially all electrons present therein to the anode electrode, wherein the fermentation waste byproducts converted to electricity include acetate, formate, and/or lactate. 13. A system comprising: a biofuel production facility configured to produce a biofuel and a biomass wastestream, wherein the biofuel is produced from biomass; and a microbial fuel cell system configured to produce alcohol and electricity from the biomass waste stream, the microbial fuel cell system comprising: an anode electrode and a reference electrode contained in an anode chamber, a cathode electrode contained in a cathode chamber, wherein the anode electrode, the cathode electrode and the reference electrode are electronically connected to each other; a first biocatalyst located in the anode chamber and comprising a mesophilic consolidated bioprocessing organism configured to hydrolyze and/or ferment biomass to produce fermentation waste byproducts, wherein the one or more mesophilic consolidated bioprocessing organism is configured to anaerobically co-ferment six- and five-carbon sugars and comprises Cellulomonas uda (Cuda); and a second biocatalyst located in the anode chamber and comprising an alcohol-tolerant electricigen cultured at a temperature not greater than 40° C. and configured to convert the fermentation waste byproducts to electricity by transferring substantially all electrons present therein to the anode electrode wherein the fermentation waste byproducts converted to electricity include acetate, formate, and/or lactate. 14. The system of claim 13 wherein the biofuel production facility is a biodiesel production facility and the biomass wastestream is a glycerin-containing biomass wastewater stream. 15. The system of claim 13 further comprising a computer system connected to the microbial fuel cell system for monitoring and controlling fuel cell activity. 16. The system of claim 15 wherein the anode electrode, the cathode electrode and the reference electrode are located in one chamber. 17. A method for producing electricity with a microbial fuel cell comprising: providing an anode electrode contained in an anode chamber, a cathode electrode contained in a cathode chamber, and a reference electrode contained in the anode chamber or the cathode chamber, wherein the anode electrode, the cathode electrode and the reference electrode are electronically connected to each other; allowing a first biocatalyst located in the anode chamber and comprising a mesophilic consolidated bioprocessing organism configured to hydrolyze and/or ferment biomass to produce one or more fermentation waste byproducts, wherein the mesophilic consolidated bioprocessing organism is also configured to anaerobically co-ferment six- and five-carbon sugars and comprises Cellulomonas uda (Cuda); and allowing a second biocatalyst located in the anode chamber and comprising an alcohol-tolerant electricigen cultured at a temperature not greater than 40° C. configured to convert substantially all of the fermentation waste byproducts to electricity by transferring substantially all electrons present therein to the anode electrode, wherein the fermentation waste byproducts converted to electricity include acetate, formate, and/or lactate.