Biology:Hydrogenotroph

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Hydrogenotrophs are organisms that are able to metabolize molecular hydrogen as a source of energy. An example of hydrogenotrophy is performed by carbon dioxide-reducing organisms[1] which use CO2 and H2 to produce methane (CH4) by the following reaction:

  • CO2 + 4H2 → CH4 + 2H2O

Other hydrogenotrophic metabolic pathways include acetogenesis, sulfate reduction, and other hydrogen oxidizing bacteria. Those that metabolize methane are called methanogenic.[2] Hydrogenotrophs belong to a group of organisms known as methanogens, organisms that carry out anaerobic processes that are responsible for the production of methane through carbon dioxide reduction. Methanogens also include a group of organisms called methylotrophs, organisms that can use single-carbon molecules or molecules with no carbon-carbon bonds.[3]

Background Information

Hydrogenotrophic bacteria were first experimented with by NASA in the 1960s in order to find a replenishable food source.[4] Hydrogenotrophic bacteria have been found to have a high protein and carbohydrate content and have been a guiding principle in developing sustainable agricultural methods.[citation needed] Experimentation has revealed that hydrogenotrophic bacteria can convert carbon dioxide into food more rapidly than plants, making them an efficient and sustainable alternative to implement into plant-based high-protein diets and as a substitute in products that use plant extracts and oils.[5]

Hydrogenotrophs are commonly found in the human gut, along with other fermentative bacteria which live in symbiosis with one another.[4] They are also found in soils and in sediments of freshwater and marine ecosystems around the world.[6]

See also

  • Single cell protein[7]

References

  1. Stams, J.M., and Plugge, C.M. (2010) The microbiology of methanogenesis. In Reay, D., Smith, P., and Van Amstel, A., eds. Methane and Climate Change, 14-26.
  2. Vianna, M. E.; Holtgraewe, S.; Seyfarth, I.; Conrads, G.; Horz, H. P. (2008). "Quantitative Analysis of Three Hydrogenotrophic Microbial Groups, Methanogenic Archaea, Sulfate-Reducing Bacteria, and Acetogenic Bacteria, within Plaque Biofilms Associated with Human Periodontal Disease". Journal of Bacteriology 190 (10): 3779–3785. doi:10.1128/JB.01861-07. PMID 18326571. 
  3. Costa, Kyle C; Leigh, John A (2014-10-01). "Metabolic versatility in methanogens". Current Opinion in Biotechnology. Cell and Pathway Engineering 29: 70–75. doi:10.1016/j.copbio.2014.02.012. ISSN 0958-1669. PMID 24662145. 
  4. 4.0 4.1 "Retro spacetech microbes revived to make food from CO2" (in en). 2016-08-11. https://www.thefuturescentre.org/signals-of-change/retro-spacetech-microbes-revived. 
  5. "A forgotten Space Age technology could change how we grow food" (in en-US). 24 August 2017. https://www.performancemagazine.org/space-technology-grow-food/. 
  6. Gaci, Nadia; Borrel, Guillaume; Tottey, William; O’Toole, Paul William; Brugère, Jean-François (2014-11-21). "Archaea and the human gut: New beginning of an old story". World Journal of Gastroenterology 20 (43): 16062–16078. doi:10.3748/wjg.v20.i43.16062. ISSN 1007-9327. PMID 25473158. 
  7. Kiverdi: about