Researchers from the University of East Anglia (UEA) are a step closer to enhancing the generation of clean energy from bacteria.
A recently published report shows how electrons hop across otherwise electrically insulating areas of bacterial proteins, and that the rate of electron transfer is dependent on the orientation and proximity of electrically conductive ‘stepping stones’.
The hope is that this natural process can be used to improve ‘bio batteries’ which may be used to produce energy for portable technology such as mobile phones, tablets and laptops, powered by human or animal waste.
Unlike humans, many microorganisms can, survive without oxygen. Some bacteria survive by ‘breathing rocks’, especially minerals or iron. They derive their energy from the combustion of fuel molecules that have been taken into the cell’s interior.
A side product of this reaction is a flow of electricity that can be directed across the bacterial outer membrane and delivered to rocks in the natural environment, or graphite electrodes in fuel cells.
This means that the bacteria can release the electrical charge from inside the cell into the mineral, much like the neutral wire in a household plug.
The researchers looked at proteins called ‘multi-haem cytochromes’ contained in ‘rock breathing’ bacteria such as species of Shewanella.
Lead researcher Professor Julea Butt, from UEA’s School of Chemistry and School of Biological Sciences, said, “These bacteria can generate electricity in the right environment.”
“We wanted to know more about how the bacterial cells transfer electrical charge — and particularly how they move electrons from the inside to the outside of a cell over distances of up to tens of nanometers.
“Proteins conduct electricity by positioning metal centres — known as haems — to act in a similar way to stepping stones by allowing electrons to hop through an otherwise electrically insulating structure. This research shows that these centres should be considered as discs that the electrons hop across.
“The relative orientation of neighboring centres, in addition to their proximity, affects the rates that electrons move through the proteins.
“This is an exciting advance in our understanding of how some bacterial species move electrons from the inside to the outside of a cell and helps us understand their behavior as robust electron transfer modules.
“We hope that understanding how this natural process works will inspire the design of bespoke proteins which will underpin microbial fuel cells for sustainable energy production.”
The research was funded by the Biotechnology and Biological Sciences Research Council (BBSRC) and performed in collaboration with researchers at University College London, UK and the Pacific Northwest National Laboratory, USA.