Iron oxidizing bacteria aren’t exactly rare, but they’re hard to study in the lab because of the copious amounts of oxidized iron (Fe(III)) they produce. In mBio this week, a group at the University of Minnesota – Twin Cities describes a new method for growing iron-oxidizing bacteria
“It’s a new way to cultivate a microorganism that’s been very difficult to study. But the fact that these organisms can synthesize everything they need using only electricity makes us very interested in their abilities,” says Daniel Bond of the BioTechnology Institute at the University of Minnesota – Twin Cities, who co-authored the paper with Zarath Summers and Jeffrey Gralnick.
To respire, iron oxidizers take electrons off of dissolved iron, called Fe(II) – a process that produces copious amounts of rust, called Fe(III). Iron oxidizing bacteria are found around the world, almost anywhere the aerobic environment meets an anaerobic environment. They play a big role in the global cycling of iron and contribute to the corrosion of steel pipelines, bridges, piers, and ships, but their lifestyle at the interface of two very different habitats and the accumulation of cell-trapping Fe(III) makes iron oxidizers difficult to grow and study in the lab.
An electrode or “the world’s best buffet of iron atoms”?
Bond says the prevailing theory is that iron oxidizers must carry out the oxidation step on the surface of the cell. If that’s true, Bond reasoned, the outsides of the organisms should be covered with proteins that interact with Fe(II), so you should be able to provide a stream of pure electrons to the outsides of the bacteria and get them to grow.
Bond and his colleagues added the marine iron oxidizer Mariprofundus ferrooxydans PV-1, along
It worked. The bacteria multiplied and formed a film on the electrode, Bond says, and eventually they were able to grow M. ferrooxydans with no iron in the medium, proof that the bacteria were living off the electrons they absorbed from the electrode to capture carbon dioxide and replicate. And since the electron donor is a solid surface, say the authors, it’s pretty likely that the bacterial electron-harvesting machinery is exposed on the outer membrane of the cell.
A future in energy storage
It’s this capture of carbon dioxide that could enable electrochemical cultivation to create biofuels or other useful products one day, Bond says.
“Bacteria are experts at the capture of carbon dioxide. They build cells and compounds” with the carbon, he says. They might one day be exploited as microscopic energy packagers: bacteria like M. ferrooxydans could capture electricity from an electrode, combine it with carbon dioxide, and package it as a carbon-rich compound we could use as fuel. This would take the energy in electricity, which is ephemeral, and convert it into a tangible product that could be stored in a tank. But that kind of work is a long way off, cautions Bond.
“If there are 100 steps to making this work – this is step one,” he says.