Extremophiles can also be useful players in the
bioremediation of contaminated sites as some species are capable of biodegradation under conditions too extreme for classic bioremediation candidate species. Anthropogenic activity causes the release of pollutants that may potentially settle in extreme environments as is the case with tailings and sediment released from deep-sea mining activity. While most bacteria would be crushed by the pressure in these environments, piezophiles can tolerate these depths and can metabolize pollutants of concern if they possess bioremediation potential.
Hydrocarbons There are multiple potential destinations for hydrocarbons after an oil spill has settled and currents routinely deposit them in extreme environments. Methane bubbles resulting from the
Deepwater Horizon oil spill were found 1.1 kilometers below water surface level and at concentrations as high as 183
μmol per kilogram. The combination of low temperatures and high pressures in this environment result in low microbial activity. However, bacteria that are present including species of
Pseudomonas,
Aeromonas and
Vibrio were found to be capable of bioremediation, albeit at a tenth of the speed they would perform at sea level pressure.
Polycyclic aromatic hydrocarbons increase in solubility and bioavailability with increasing temperature. Thermophilic
Thermus and
Bacillus species have demonstrated higher gene expression for the alkane mono-oxygenase
alkB at temperatures exceeding . The expression of this gene is a crucial precursor to the bioremediation process. Fungi that have been genetically modified with cold-adapted enzymes to tolerate differing pH levels and temperatures have been shown to be effective at remediating hydrocarbon contamination in freezing conditions in the Antarctic.
Metals Acidithiobacillus ferrooxidans has been shown to be effective in remediating mercury in acidic soil due to its
merA gene making it mercury resistant. Industrial effluent contain high levels of metals that can be detrimental to both human and ecosystem health. In extreme heat environments the extremophile
Geobacillus thermodenitrificans has been shown to effectively manage the concentration of these metals within twelve hours of introduction. Some acidophilic microorganisms are effective at metal remediation in acidic environments due to proteins found in their periplasm, not present in any mesophilic organisms, allowing them to protect themselves from high proton concentrations.
Rice paddies are highly oxidative environments that can produce high levels of lead or cadmium.
Deinococcus radiodurans are resistant to the harsh conditions of the environment and are therefore candidate species for limiting the extent of contamination of these metals. Some bacteria are known to also use
rare earth elements on their biological processes. For example,
Methylacidiphilum fumariolicum,
Methylorubrum extorquens, and
Methylobacterium radiotolerans are known to be able to use
lanthanides as cofactors to increase their
methanol dehydrogenase activity.
Acid mine drainage Acid mine drainage is a major environmental concern associated with many metal mines. This is due to the fact that this highly acidic water can mix with groundwater, streams, and lakes. The drainage turns the pH in these water sources from a more neutral pH to a pH lower than 4. This is close to the acidity levels of battery acid or stomach acid. Exposure to the polluted water can greatly affect the health of plants, humans, and animals. However, a productive method of remediation is to introduce the extremophile,
Thiobacillus ferrooxidans. This extremophile is useful for its bioleaching property. It helps to break down minerals in the waste water created by the mine. By breaking down the minerals
Thiobacillus ferrooxidans start to help neutralize the acidity of the waste water. This is a way to reduce the environmental impact and help remediate the damage caused by the acid mine drainage leaks.
Oil-based, hazardous pollutants in Arctic regions Psychrophilic microbes metabolize hydrocarbons which assists in the remediation of hazardous, oil-based pollutants in the Arctic and Antarctic regions. These specific microbes are used in this region due to their ability to perform their functions at extremely cold temperatures.
Radioactive materials Any bacteria capable of inhabiting radioactive mediums can be classified as an extremophile. Radioresistant organisms are therefore critical in the bioremediation of radionuclides. Uranium is particularly challenging to contain when released into an environment and very harmful to both human and ecosystem health. The NANOBINDERS project is equipping bacteria that can survive in uranium rich environments with gene sequences that enable proteins to bind to uranium in mining effluent, making it more convenient to collect and dispose of. Some examples are
Shewanella putrefaciens,
Geobacter metallireducens and some strains of
Burkholderia fungorum. Radiotrophic fungi, which use radiation as an energy source, have been found inside and around the
Chernobyl Nuclear Power Plant. Radioresistance has also been observed in certain species of macroscopic lifeforms. The lethal dose required to kill up to 50% of a tortoise population is 40,000
roentgens, compared to only 800 roentgens needed to kill 50% of a human population. In experiments exposing
lepidopteran insects to
gamma radiation, significant DNA damage was detected only at 20
Gy and higher doses, in contrast with human cells that showed similar damage at only 2 Gy. == Examples and recent findings==