A hyperthermophile is an organism that thrives in extremely hot environments—from 60 °C (140 °F) upwards. An optimal temperature for the existence of hyperthermophiles is often above 80 °C (176 °F).[1] Hyperthermophiles are often within the domain Archaea, although some bacteria are also able to tolerate extreme temperatures. Some of these bacteria are able to live at temperatures greater than 100 °C, deep in the ocean where high pressures increase the boiling point of water. Many hyperthermophiles are also able to withstand other environmental extremes, such as high acidity or high radiation levels. Hyperthermophiles are a subset of extremophiles. Their existence may support the possibility of extraterrestrial life, showing that life can thrive in environmental extremes.

History

edit

Hyperthermophiles isolated from hot springs in Yellowstone National Park were first reported by Thomas D. Brock in 1965.[2][3] Since then, more than 70 species have been established.[4] The most extreme hyperthermophiles live on the superheated walls of deep-sea hydrothermal vents, requiring temperatures of at least 90 °C for survival. An extraordinary heat-tolerant hyperthermophile is Geogemma barossii (Strain 121),[5] which has been able to double its population during 24 hours in an autoclave at 121 °C (hence its name). The current record growth temperature is 122 °C, for Methanopyrus kandleri.

Although no hyperthermophile has shown to thrive at temperatures >122 °C, their existence is possible. Strain 121 survives 130 °C for two hours, but was not able to reproduce until it had been transferred into a fresh growth medium, at a relatively cooler 103 °C.

Research

edit

Early research into hyperthermophiles speculated that their genome could be characterized by high guanine-cytosine content; however, recent studies show that "there is no obvious correlation between the GC content of the genome and the optimal environmental growth temperature of the organism."[6][7]

The protein molecules in the hyperthermophiles exhibit hyperthermostability—that is, they can maintain structural stability (and therefore function) at high temperatures. Such proteins are homologous to their functional analogs in organisms that thrive at lower temperatures but have evolved to exhibit optimal function at much greater temperatures. Most of the low-temperature homologs of the hyperthermostable proteins would be denatured above 60 °C. Such hyperthermostable proteins are often commercially important, as chemical reactions proceed faster at high temperatures.[8][9]

Physiology

edit

General physiology

edit
 
Different morphologies and classes of hyperthermophilic microorganisms

Due to their extreme environments, hyperthermophiles can be adapted to several variety of factors such as pH, redox potential, level of salinity, and temperature. They grow (similar to mesophiles) within a temperature range of about 25–30 °C between the minimal and maximal temperature. The fastest growth is obtained at their optimal growth temperature which may be up to 106 °C.[10] The main characteristics they present in their morphology are:

  • Cell wall: the outermost part of archaea, it is arranged around the cell and protects the cell contents. It does not contain peptidoglycan, which makes them naturally resistant to lysozyme. The most common wall is a paracrystalline surface layer formed by proteins or glycoproteins of hexagonal symmetry. An exception is the genus Thermoplasma which lacks a wall, a deficiency that is filled by the development of a cell membrane with a unique chemical structure, containing a lipid tetraether unit and glucose in a very high proportion to the total lipids. In addition, it is accompanied by glycoproteins that together with lipids give the membrane of Thermoplasma species stability against the acidic and thermophilic conditions in which it lives.[11]
  • Cytoplasmic membrane: is the main adaptation to temperature. This membrane is radically different from that known from eukaryotes. The membrane of Archaea is built on a tetraether unit, thus establishing ether bonds between glycerol molecules and hydrophobic side chains that do not consist of fatty acids. These side chains are mainly composed of repeating isoprene units.[11] At certain points of the membrane, side chains linked by covalent bonds and a monolayer are found at these points. Thus, the membrane is much more stable and resistant to temperature alterations than the acidic bilayers present in eukaryotic organisms and bacteria.
  • Proteins: denature at elevated temperatures and so also must adapt. Protein complexes known as heat shock proteins assist with proper folding. Their function is to bind or engulf the protein during synthesis, creating an environment conducive to its correct tertiary conformation. In addition, heat shock proteins can collaborate in transporting newly folded proteins to their site of action.[11]
  • DNA: is also adapted to elevated temperatures by several mechanisms. The first is cyclic potassium 2,3-diphosphoglycerate, which has been isolated in only a few species of the genus. Methanopyrus is characterized by the fact that it prevents DNA damage at these temperatures.[10] Topoisomerase is an enzyme found in all hyperthermophiles. It is responsible for the introduction of positive spins which confer greater stability against high temperatures. Sac7d this protein has been found in the genus and characterized by an increase, up to 40 °C, in the melting temperature of DNA. The histones with which these proteins are associated collaborate in its supercoiling.[12][10]

Metabolism

edit

Hyperthermophiles have a great diversity in metabolism including chemolithoautotrophy and chemoorganoheterotrophy, while there are no phototrophic hyperthermophiles known. Sugar catabolism involves non-phosphorylated versions of the Entner-Doudoroff pathway some modified versions of the Embden-Meyerhof pathway, the canonical Embden-Meyerhof pathway being present only in hyperthermophilic bacteria but not archaea.[13][14]

Most of what is known about sugar catabolism in hyperthermophiles comes from observation on Pyrococcus furiosus. It grows on many different sugars such as starch, maltose, and cellobiose, that once in the cell are transformed to glucose, but other organic substrates can be used as carbon and energy sources.

Some differences discovered concerned the sugar kinases of starting reactions of this pathway: instead of conventional glucokinase and phosphofructokinase, two novel sugar kinases have been discovered. These enzymes are ADP-dependent glucokinase (ADP-GK) and ADP-dependent phosphofructokinase (ADP-PFK), they catalyse the same reactions but use ADP as phosphoryl donor, instead of ATP, producing AMP.[15]

Adaptations

edit

As a rule, hyperthermophiles do not propagate at 50 °C or below, some not even below 80 or 90º.[16] Although unable to grow at ambient temperatures, they are able to survive there for many years. Based on their simple growth requirements, hyperthermophiles could grow in any hot water-containing site, potentially even on other planets and moons like Mars and Europa. Thermophiles and hyperthermophiles employ different mechanisms to adapt their cells to heat, especially to the cell wall, plasma membrane, and its biomolecules (DNA, proteins, etc.):[12]

  • The presence in their plasma membrane of long-chain and saturated fatty acids in bacteria and "ether" bonds (diether or tetraether) in archaea. In some archaea the membrane has a monolayer structure which further increases its heat resistance.
  • Overexpression of GroES and GroEL chaperones that help the correct folding of proteins in situations of cellular stress such as the temperature in which they grow.
  • Accumulation of compounds such as potassium diphosphoglycerate that prevent chemical damage (depurination or depyrimidination) to DNA.
  • Production of spermidine that stabilizes DNA, RNA and ribosomes.
  • Presence of a DNA reverse DNA gyrase that produces positive supercoiling and stabilizes DNA against heat.
  • Presence of proteins with higher content in α-helix regions, more resistant to heat.

DNA repair

edit

The hyperthermophilic archaea appear to have special strategies for coping with DNA damage that distinguish these organisms from other organisms.[17] These strategies include an essential requirement for key proteins employed in homologous recombination (a DNA repair process), an apparent lack of the DNA repair process of nucleotide excision repair, and a lack of the MutS/MutL homologs (DNA mismatch repair proteins).[17]

Specific hyperthermophiles

edit

Archaea

edit

Gram-negative Bacteria

edit

See also

edit

References

edit
  1. ^ Stetter, K. (2006). "History of discovery of the first hyperthermophiles". Extremophiles. 10 (5): 357–362. doi:10.1007/s00792-006-0012-7. PMID 16941067. S2CID 36345694.
  2. ^ Seckbach, Joseph; Oren, Aharon; Stan-Lotter, Helga, eds. (2013). Polyextremophiles — Life under multiple forms of stress. Cellular Origin, Life in Extreme Habitats and Astrobiology. Vol. 27. Springer. pp. xviii. doi:10.1007/978-94-007-6488-0. ISBN 978-94-007-6487-3. In June 1965, Thomas Brock, a microbiologist at Indiana University, discovered a new form of bacteria in the thermal vents of Yellowstone National Park. They can survive at near-boiling temperatures. At that time the upper temperature for life was thought to be 73 °C. He found that one particular spring, Octopus Spring, had large amounts of pink, filamentous bacteria at temperatures of 82–88 °C.
  3. ^ Brock TD (August 1997). "The value of basic research: discovery of Thermus aquaticus and other extreme thermophiles". Genetics. 146 (4): 1207–10. doi:10.1093/genetics/146.4.1207. PMC 1208068. PMID 9258667.
  4. ^ Stetter, K.O. (2002). "Hyperthermophilic Microorganisms". In Horneck, G.; Baumstark-Khan, C. (eds.). Astrobiology. Springer. pp. 169–184. doi:10.1007/978-3-642-59381-9_12. ISBN 978-3-642-59381-9.
  5. ^ "Microbe from depths takes life to hottest known limit". Archived from the original on 2023-10-04. Retrieved 2018-04-06.
  6. ^ Hurst LD, Merchant AR (March 2001). "High guanine-cytosine content is not an adaptation to high temperature: a comparative analysis amongst prokaryotes". Proc Biol Sci. 268 (1466): 493–7. doi:10.1098/rspb.2000.1397. PMC 1088632. PMID 11296861.
  7. ^ Zheng H, Wu H; Wu (December 2010). "Gene-centric association analysis for the correlation between the guanine-cytosine content levels and temperature range conditions of prokaryotic species". BMC Bioinformatics. 11 (Suppl 11): S7. doi:10.1186/1471-2105-11-S11-S7. PMC 3024870. PMID 21172057.
  8. ^ Das S, Paul S, Bag SK, Dutta C (July 2006). "Analysis of Nanoarchaeum equitans genome and proteome composition: indications for hyperthermophilic and parasitic adaptation". BMC Genomics. 7: 186. doi:10.1186/1471-2164-7-186. PMC 1574309. PMID 16869956.
  9. ^ Saiki, R. K.; Gelfand, d. h.; Stoffel, S; Scharf, S. J.; Higuchi, R; Horn, G. T.; Mullis, K. B.; Erlich, H. A. (1988). "Primer-directed enzymatic amplification of DNA with a thermostable DNA polymerase". Science. 239 (4839): 487–91. Bibcode:1988Sci...239..487S. doi:10.1126/science.239.4839.487. PMID 2448875.
  10. ^ a b c Fernández, P.G.; Ruiz, M.P. (2007). "Archaeabacterias hipertermófilas: vida en ebullición" (PDF). Revista Complutense de Ciencias Veterinarias. 1 (2)): 560.
  11. ^ a b c Vázquez Bringas FJ, Santiago I, Gil L, Ribera T, Gracia-Salinas MJ, Román LS, Blas ID, Prades M, Alonso de Diego M, Ardanaz N, Muniesa A (2014). "Desarrollo de una aplicación informática para aprender clínica y producción equina jugando al Trivial" (PDF). Revista complutense de ciencias veterinarias. 8 (1): 45. doi:10.5209/rev_RCCV.2014.v8.n1.44301.
  12. ^ a b Brock, Christina M.; Bañó-Polo, Manuel; Garcia-Murria, Maria J.; Mingarro, Ismael; Esteve-Gasent, Maria (2017). "Characterization of the inner membrane protein BB0173 from Borrelia burgdorferi". BMC Microbiology. 17 (1): 219. doi:10.1186/s12866-017-1127-y. PMC 5700661. PMID 29166863.
  13. ^ Schönheit, P.; Schäfer, T. (January 1995). "Metabolism of hyperthermophiles". World Journal of Microbiology & Biotechnology. 11 (1): 26–57. doi:10.1007/bf00339135. ISSN 0959-3993. PMID 24414410. S2CID 21904448.
  14. ^ Sakuraba, Haruhiko; Goda, Shuichiro; Ohshima, Toshihisa (2004). "Unique sugar metabolism and novel enzymes of hyperthermophilic archaea". The Chemical Record. 3 (5): 281–7. doi:10.1002/tcr.10066. ISSN 1527-8999. PMID 14762828.
  15. ^ Bar-Even, Arren; Flamholz, Avi; Noor, Elad; Milo, Ron (2012-05-17). "Rethinking glycolysis: on the biochemical logic of metabolic pathways". Nature Chemical Biology. 8 (6): 509–517. doi:10.1038/nchembio.971. ISSN 1552-4450. PMID 22596202.
  16. ^ Schwartz, Michael H.; Pan, Tao (2015-12-10). "Temperature dependent mistranslation in a hyperthermophile adapts proteins to lower temperatures". Nucleic Acids Research. 44 (1): 294–303. doi:10.1093/nar/gkv1379. PMC 4705672. PMID 26657639.
  17. ^ a b Grogan DW (2015). "Understanding DNA Repair in Hyperthermophilic Archaea: Persistent Gaps and Other Reasons to Focus on the Fork". Archaea. 2015: 942605. doi:10.1155/2015/942605. PMC 4471258. PMID 26146487.

Further reading

edit
  NODES
Association 1
Note 1