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Iron is well-known for rusting, but this doesn't just happen on contact with oxygen and water. Some bacteria are also able to able to decompose iron anaerobically in a process referred to as electrobiocorrosion. The sediment-dwelling bacteriumGeobacter sulfurreducensuses electrically conductive protein threads for this purpose, as a team of researchers reports in the journalAngewandte Chemie. They produce magnetite from the iron, which promotes further corrosion in a positive feedback loop.
细菌生物膜微生物元的原因l corrosion, a destroyer of metals which causes more costly damage than all other biofilm-related damage put together. Electrobiocorrosion is often caused by bacteria such as those found in river sediments, for example, the anaerobic genusGeobacter.Geobacterdoes not use atmospheric oxygen for respiration; instead, it draws energy from the transfer of electrons from iron, forming magnetite in the process. Thus far, the way in whichGeobactercorrodes iron metal has been something of a mystery.
The exact mechanism of action of electrobiocorrosion has now been investigated more closely by Dake Xu and colleagues from Northeastern University in Shenyang, China. The team worked on the assumption that electrically conductive pili, thin filaments which grow out of the bacteria, could play an important role in this mechanism.Geobacterforms "e-pili" from conductive proteins, and these e-pili act like electric wires, conducting electricity. Before this study, it was unclear whether the e-pili could withdraw electrons directly from metal surfaces.
In order to prove the team's suspicions, namely direct electron withdrawal, they left two strains ofGeobacterto grow on a stainless-steel surface until biofilms formed. One of the two strains formed conductive e-pili, while the other still produced pili, but had been genetically modified so that the pili were formed from less conductive proteins. The researchers observed that the bacterial strain that grew e-pili fared significantly better on the steel plate. It grew more and made deeper pits in the metal, demonstrating how much metal it was consuming. The team also measured a corrosion current, a direct sign of the oxidation of iron.
The team concluded that the bacteria with the e-pili formed a sort of "electrical connection" to the metal. Bacteria located further away in the biofilm, not in direct contact with the metal, were also able to supply themselves with electrons using e-pili.
Because magnetite is formed during the corrosion of iron, and this mineral also conducts electricity, the team also investigated its influence on microbial corrosion. They noted that not only did adding magnetite to the biofilm increase the growth ofGeobacter, it also led to a stronger corrosion current measured at the surface of the metal: "The finding that magnetite, a common corrosion product, facilitates electrobiocorrosion has significant corrosion implications," the team emphasize. For future attempts to improve corrosion protection, therefore, they recommend taking the propensity of materials to form magnetite into consideration.
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