Thermus aquaticus: Difference between revisions

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Thermus aquaticus
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Scientific classification
Kingdom: Eubacteria Genus: Thermus Species: aquaticus

Description and significance

Thermus aquaticus was isolated in 1969 by Brocks and Freeze of University of Indiana. It is a gram negative bacteria both motile (presence of a flagellum) or immotile. Comparisons between structures of T. aquaticus and E. coli have shown many similarities linking them to a common ancestor. YT-1 gene extracted from T. aquaticus is structurally similar to RecA from E. coli homologue and comaparisons between Klentaq1, a large fragment of Taq DNA polymerase and the Klenow fragment of E Coli DNA polymerase reveal identical C-termini and very similar N-termini. Discovery of this species of thermophiles primarily came as a surprise to researchers and very soon proved to be an extremely important tool in many fields of sciences including biology, microbiology, genetics, diagnostics, clinical laboratories, forensic and environmental sciences, hereditary studies and paternity testing. The importance of this discovery comes from the high thermostability of the T. aquaticus proteins. The taq polymerase plays an extremely important role in the polymerase chain reaction (PCR). PCR is a process by which one or a few stretches of DNA is amplified using thermal cycling introduced by Kary Mullis in 1984 winning him the Noble Prize in 1993. The enzymes found in the T. aquaticus are able to withstand the heat in the denaturing of the newly formed DNA so strands can seperate and act as templates for the next cycle of PCR. Taq polymerase, with an optimum activity at 72-80 degrees Celsius and a half life of 9 minutes at 97.5 degrees Celsius, can replicate 9000 base pairs in less than 10 seconds, and has replaced DNA polymerase from E. coli and presently still plays an extremely important role in gaining insight into realm of biotechnology. Thermus Aquaticus has not been associated with any known pathology.

Genome structure

T. aquaticus contains pillus like structures used in conjugation. Twelve genes in 3 loci were found to encode preplin-like proteins essential for natural transfomation. It has a double stranded circular DNA chromosome with a length of 2,338,193 nt., with a replicon type WGS, (Master Wgs), no pseudogenes, 53 structural RNA's, 1982 protein-coding sequences, and a pTT27 plasmid.

Cell structure and metabolism

Thermus Aquaticus not only can function at high temperatures but they thrive at elevated temperatures. Optimum growth is seen between 60 and 75°C (could go as low as 35°C to as high as 85°C). The optimal pH ranges from 7.5 to 8.0 generally, but some strains grow between pH 5.1 and 9.5. This organism is a chemotroph using carbohydrates, amino acids, caboxylic acids and peptides for growth. Monosaccharides are generally used for carbons sources but sucrose, maltose (Icelandic stains) and even some fewer strains use glucose. There is also a variance in the proteins isolated from different strains; elastin, fibrin and casein. Not all strains can hydrolize all substrates. Membranes of these proteins are remarkably temperature stable and the heat stability of the enzymes and protein-synthesis systems allow them to function efficiently at high tempratures. Many factors contribute to the stability of the proteins:

1) Highly organized hydrophobic interiors 2) More hydrogen bonds and presence of other non-covalent bonds strengthen the protein structures. 3) Larger quantities of amino acids like proline make peptide chains less flexible. 4) Protein folding is aided and stabilized by special chaperone proteins. 5) Some evidence indicates that DNA is stabilized by specialized histone-like proteins. 6) Their membrane lipids tend to be more saturated and more branched and possess higher molecular weight resulting in a higher melting point and in turn more thermostability.

Ecology

T. aquaticus was first isolated in the Great Fountain region of Yellowstone National Park from neutral and alkaline springs in 1969 by Brocks and Freeze. This discovery disproved the previous beliefs that bacteria could not function properly at higher temperatures. After this discovery, some strains of T. aquaticus were discovered in hot springs in Iceland and hydrothermal vents in other parts of the world. T. aquaticus is sometimes found living in conjuction with other organisms such as cyanobacteria and obtain some of the energy for their growth and metabolism from the neighboring bacterias' photosynthesis.

Application to Biotechnology

Enzymes derived from T. aquaticus have had an incredibly important role in facilitating many aspects of biotechnology correlated with DNA amplification. They enable researchers to study proteins and enzymes under conditions not possible before. This is all due to the thermostability of the proteins and their ability to function at even higher rates at high temperatures. Some of the isolated enzymes and their roles in facilitating applications in biotechnology are as follows:

1) Adolase- a thermostable enzyme (enzyme that functions well at high temperature. 2) RNA polymerase- first polymerase isolated from Taq in1974. 3) Restriction Endonucleases 4) DNA polymerase- isolated in 1976, could be isolated in purer form and later discovered to be used in PCR, for amplifying short segments of DNA (before the discovery of the Taq DNA, enzymes needed to be added after each cycle of denaturing of DNA, but with the use of the Taq DNA polymerase it was not necessary anymore.) One single copy of genomic sequence can be amplified by a factor of more than 10 million(One ng of DNA template up to 35 kb could be amplified from a target DNA molecule present only once in a sample of 105 cells) with high base pair fidelity and the PCR product used as primers for maximum yield. The specificity , sensitivity , yield and length of product could be amplified. This enzyme was soon cloned, sequenced, and produced in mass quantities for commercial sale. 5) Other enzymes with high optimal temperatures allowing researchers to study them in extreme conditions are:DNA ligase, alkaline phosphatase, NADH oxidase, isocitrase, dehydrogenase, amylomaltase and fructose1,6-bisphosphate-dependent L-lactate dehydrogenase.

Besides the revolutionary changes in PCR, ligase chain reaction (LCR), which uses T. aquaticus ligase, can amplify genetic sequences of stretches of DNA that posses a desired sequence million or more times within hours. It can amplify and screen in a single step and screen for mutations simultaneously. LCR is useful in testing for hereditary diseases, revealing hidden infections and distinguishing between drug resistant and drug sensitive strains of viruses and bacteria.

Current Research

Recent studies have emphasized the role of disulfide bonds in stabilizing the structure of intracellular proteins of Thermus Aquaticus among some other thermophiles. Previously the popular belief was disulfide bonds are only present in extracellular proteins where they stabilize folded proteins against harsh conditions and are rarely found in the cytosol. The specific protein which seems to be responsible for the formation of intracellular disulfide bonds seems to be protein disulfide oxidoreductase (PDO), which functions as a cytoplasmic PDI. It has been suggested that eukaryotic PDI, found in the endoplasmic reticulum where it catalyzes isomerization of protein disulfide bonds, has evolved from a protein similar to thermophilic PDO. More research needs to be done on this subject.

Besides thermophiles, elevated intracellular disulfide bonding has been seen in other extremophiles including; halophiles, alkylophiles, acidophiles, and radiation-tolerant organisms. This discovery supports the role of intracellular disulfide bonds in stabilizing proteins in all types of extreme conditions. This study sheds some light on different methods used by organisms to stabilize their proteins to adapt to "exotic" environments.

Controversy: After isolation of Thermus Aquaticus, samples of it were deposited in the American Type Cultures Collection (ATCC), a public repository. Other scientists had access to them and were able to do more research. By the 1980's, it became obvious that the potential for commercializing the enzymes from this species would prove to be very high and profitable. Hoffman La Roche, a Swiss-based pharmaceutical company, patented the Taq DNA polymerase enzyme and the National Parks system was not receiving any of the profits, even though the organism was discovered at a national park. The National Park Service called this "the great Taq ripoff". Since then, researchers in the national parks are required to sign an agreement of benefit sharing so a portion of the profits would be returned to the parks. Meanwhile, a fight for patent rights of the Taq polymerase is still going on. The European Patent office revoked Hoffman La Roche's patent claiming Taq Polymerase is naturally occurring and finding this enzyme was not a "novel invention". While La Roche is appealing this decision, a Russian scientist named Stanislav Gorodetsky is claiming he and his research group were first to isolate the enzyme and they should somehow be involved in the profit sharing.

References

Barnes,W.M. PCR amplification of up to 35 kb DNA with high fidelity and high yield from bacteriophage templates-proceedings of the National Academy of Sciences of the United States of America v.91(March 15,1994)p.2216-20

Weiss, R. Hot prospect for new gene amplifier-Science v.254(November 29,1991)p.1292-3

Saiki, R.K.,et.al., Primer directed enzymatic amplification of DNA with a thermostable DNA polymerase. Science v.239 (January 29,1988)p.487-91.

<http://microbewiki.kenyon.edu/index.php/Thermus> The Genomics of Disulfide Bonding and Protein Stabilization in Thermophiles Beeby M, O'Connor BD, Ryttersgaard C, Boutz DR, Perry LJ, et al. PLoS Biology Vol. 3, No. 9, e309 doi:10.1371/journal.pbio.0030309

http://vnweb.hwwilsonweb.com.central.ezproxy.cuny.edu:2048/hww/jumpstart.jhtml?recid=0bc05f7a67b1790e5a5ef5947c67438bfc25e16bccc605e90e92bd260529e1f39f0fba67f43a661c&fmt=C

Dalton, R. Patent ruling could cut PCR enzyme prices. Nature v. 411 no. 6838 (June 7 2001) p. 622

Dickson, D. European patent for PCR enzyme clouded by Russian claim. Nature v. 364 (July 1 1993) p. 2