Sulfate-reducing microorganism
Sulfate-reducing microorganisms (SRM) or sulfate-reducing prokaryotes (SRP) are a group composed of sulfate-reducing bacteria (SRB) and sulfate-reducing archaea (SRA), both of which can perform anaerobic respiration utilizing sulfate (SO2−
4) as terminal electron acceptor, reducing it to hydrogen sulfide (H2S).[1][2] Therefore, these sulfidogenic microorganisms "breathe" sulfate rather than molecular oxygen (O2), which is the terminal electron acceptor reduced to water (H2O) in aerobic respiration.
Most sulfate-reducing microorganisms can also reduce some other oxidized inorganic sulfur compounds, such as sulfite (SO2−
3), dithionite (S
2O2−
4), thiosulfate (S
2O2−
3), trithionate (S
3O2−
6), tetrathionate (S
4O2−
6), elemental sulfur (S8), and polysulfides (S2−
n). Other than sulfate reduction, some sulfate-reducing microorganisms are also capable of other reactions like disproportionation of sulfur compounds. Depending on the context, "sulfate-reducing microorganisms" can be used in a broader sense (including all species that can reduce any of these sulfur compounds) or in a narrower sense (including only species that reduce sulfate, and excluding strict thiosulfate and sulfur reducers, for example).
Sulfate-reducing microorganisms can be traced back to 3.5 billion years ago and are considered to be among the oldest forms of microbes, having contributed to the sulfur cycle soon after life emerged on Earth.[3]
Many organisms reduce small amounts of sulfates in order to synthesize sulfur-containing cell components; this is known as assimilatory sulfate reduction. By contrast, the sulfate-reducing microorganisms considered here reduce sulfate in large amounts to obtain energy and expel the resulting sulfide as waste; this is known as dissimilatory sulfate reduction.[4] They use sulfate as the terminal electron acceptor of their electron transport chain.[5] Most of them are anaerobes; however, there are examples of sulfate-reducing microorganisms that are tolerant of oxygen, and some of them can even perform aerobic respiration.[6] No growth is observed when oxygen is used as the electron acceptor.[7] In addition, there are sulfate-reducing microorganisms that can also reduce other electron acceptors, such as
In terms of
Ecological importance and markers
Sulfate occurs widely in seawater, sediment, and water rich in decaying organic material.
The toxic hydrogen sulfide is a waste product of sulfate-reducing microorganisms; its rotten egg odor is often a marker for the presence of sulfate-reducing microorganisms in nature.[14] Sulfate-reducing microorganisms are responsible for the sulfurous odors of salt marshes and mud flats. Much of the hydrogen sulfide will react with metal ions in the water to produce metal sulfides. These metal sulfides, such as ferrous sulfide (FeS), are insoluble and often black or brown, leading to the dark color of sludge.[2]
During the Permian–Triassic extinction event (250 million years ago) a severe anoxic event seems to have occurred where these forms of bacteria became the dominant force in oceanic ecosystems, producing copious amounts of hydrogen sulfide.[15]
Sulfate-reducing bacteria also generate neurotoxic methylmercury as a byproduct of their metabolism, through methylation of inorganic mercury present in their surroundings. They are known to be the dominant source of this bioaccumulative form of mercury in aquatic systems.[16]
Uses
Some sulfate-reducing microorganisms can reduce hydrocarbons, and they have been used to clean up contaminated soils. Their use has also been proposed for other kinds of contaminations.[3]
Sulfate-reducing microorganisms are considered a possible way to deal with acid mine waters that are produced by other microorganisms.[17]
Problems caused by sulfate-reducing microorganisms
In engineering, sulfate-reducing microorganisms can create problems when metal structures are exposed to sulfate-containing water: Interaction of water and metal creates a layer of molecular hydrogen on the metal surface; sulfate-reducing microorganisms then oxidize the hydrogen while creating hydrogen sulfide, which contributes to corrosion.
Hydrogen sulfide from sulfate-reducing microorganisms also plays a role in the biogenic sulfide corrosion of concrete. It also occurs in sour crude oil.[3]
Some sulfate-reducing microorganisms play a role in the anaerobic oxidation of methane:[3]
- CH4 + SO42- → HCO3- + HS− + H2O
An important fraction of the methane formed by methanogens below the seabed is oxidized by sulfate-reducing microorganisms in the transition zone separating the methanogenesis from the sulfate reduction activity in the sediments. This process is also considered a major sink for sulfate in marine sediments.
In
Biochemistry
Before sulfate can be used as an electron acceptor, it must be activated. This is done by the enzyme
The enzyme dissimilatory (bi)sulfite reductase, dsrAB (EC 1.8.99.5), that catalyzes the last step of dissimilatory sulfate reduction, is the functional gene most used as a molecular marker to detect the presence of sulfate-reducing microorganisms.[18]
Phylogeny
The sulfate-reducing microorganisms have been treated as a phenotypic group, together with the other sulfur-reducing bacteria, for identification purposes. They are found in several different phylogenetic lines.[19] As of 2009, 60 genera containing 220 species of sulfate-reducing bacteria are known.[3]
Among the Thermodesulfobacteriota the orders of sulfate-reducing bacteria include Desulfobacterales, Desulfovibrionales, and Syntrophobacterales. This accounts for the largest group of sulfate-reducing bacteria, about 23 genera.[1]
The second largest group of sulfate-reducing bacteria is found among the Bacillota, including the genera Desulfotomaculum, Desulfosporomusa, and Desulfosporosinus.
In the Nitrospirota phylum we find sulfate-reducing Thermodesulfovibrio species.
Two more groups that include
There are also three known genera of sulfate-reducing archaea: Archaeoglobus, Thermocladium and Caldivirga. They are found in hydrothermal vents, oil deposits, and hot springs.
In July 2019, a scientific study of Kidd Mine in Canada discovered sulfate-reducing microorganisms living 7,900 feet (2,400 m) below the surface. The sulfate reducers discovered in Kidd Mine are lithotrophs, obtaining their energy by oxidizing minerals such as pyrite rather than organic compounds.[20][21][22] Kidd Mine is also the site of the oldest known water on Earth.[23]
See also
References
- ^ S2CID 22775967. Archived from the original(PDF) on 2012-04-25.
- ^ ISBN 9783540581031
- ^ )
- PMID 27461928.
- ^ ISBN 9780306448577
- PMID 15112804.
- ^
"Simone Dannenberg; Michael Kroder; Dilling Waltraud & Heribert Cypionka (1992). "Oxidation of H2, organic compounds and inorganic sulfur compounds coupled to reduction of O2 or nitrate by sulfate-reducing bacteria". Archives of Microbiology. 158 (2): 93–99. S2CID 36923153.
- PMID 21734907.
- ^ PMID 17572039.
- PMID 26863985.
- S2CID 22775967.
- S2CID 199636268.
- ^ "World's Oldest Groundwater Supports Life Through Water-Rock Chemistry". Deep Carbon Observatory. 29 July 2019. Retrieved 13 September 2019.
- ^ a b Dexter Dyer, Betsey (2003). A Field Guide to Bacteria. Comstock Publishing Associates/Cornell University Press.
- ^ Peter D. Ward (October 2006), "Impact from the Deep", Scientific American
- PMID 16346866
- PMID 30186280.
- PMID 25343514.
- ^ Pfennig N.; Biebel H. (1986), "The dissimilatory sulfate-reducing bacteria", in Starr; et al. (eds.), The Prokaryotes: a handbook on habitats, isolation and identification of bacteria, Springer
- ^ 'Follow the Water': Hydrogeochemical Constraints on Microbial Investigations 2.4 km Below Surface at the Kidd Creek Deep Fluid and Deep Life Observatory, Garnet S. Lollar, Oliver Warr, Jon Telling, Magdalena R. Osburn & Barbara Sherwood Lollar, Received 15 Jan 2019, Accepted 01 Jul 2019, Published online: 18 Jul 2019.
- ^ World's Oldest Groundwater Supports Life Through Water-Rock Chemistry, July 29, 2019, deepcarbon.net.
- ^ Strange life-forms found deep in a mine point to vast 'underground Galapagos', By Corey S. Powell, Sept. 7, 2019, nbcnews.com.
- ^ Oldest Water on Earth Found Deep Within the Canadian Shield, December 14, 2016, Maggie Romuld
External links
- 'Follow the Water': Hydrogeochemical Constraints on Microbial Investigations 2.4 km Below Surface at the Kidd Creek Deep Fluid and Deep Life Observatory, Garnet S. Lollar, Oliver Warr, Jon Telling, Magdalena R. Osburn & Barbara Sherwood Lollar, Received 15 Jan 2019, Accepted 01 Jul 2019, Published online: 18 Jul 2019.
- Deep fracture fluids isolated in the crust since the Precambrian era, G. Holland, B. Sherwood Lollar, L. Li, G. Lacrampe-Couloume, G. F. Slater & C. J. Ballentine, Nature volume 497, pages 357–360 (16 May 2013)
- Sulfur mass-independent fractionation in subsurface fracture waters indicates a long-standing sulfur cycle in Precambrian rocks, by L. Li, B. A. Wing, T. H. Bui, J. M. McDermott, G. F. Slater, S. Wei, G. Lacrampe-Couloume & B. Sherwood Lollar October 27, 2016. Nature Communications volume 7, Article number: 13252 (2016.)
- Earth's mysterious 'deep biosphere' may harbor millions of undiscovered species, By Brandon Specktor, Live Science, December 11, 2018, published online at nbcnews.com.