Acidic hot springs: Difference between revisions
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===<b>Temperature</b>=== | ===<b>Temperature</b>=== | ||
Hot springs vary in temperature, some are at a temperature comfortable enough to be used as a sort of hot tub for both humans and animals while other reach temperatures of up to 100 °C (212 °F)<sup>4</sup>. The fact | Hot springs vary in temperature, some are at a temperature comfortable enough to be used as a sort of hot tub for both humans and animals while other reach temperatures of up to 100 °C (212 °F)<sup>4</sup>. The temperatures reached in hot springs is enough to kill many microbes. In fact, heat is frequently used as a method of sterilization<sup>. | ||
==Microbial Communities== | ==Microbial Communities== | ||
Microbes found in acidic hot springs are typically thermoacidophilic archaea and bacteria. However, viruses that infect archaea have also been discovered in some acidic hot spring<sup>2</sup>. | Microbes found in acidic hot springs are typically thermoacidophilic archaea and bacteria. However, viruses that infect archaea have also been discovered in some acidic hot spring<sup>2</sup>. | ||
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===<b>Archaea</b>=== | ===<b>Archaea</b>=== | ||
The microbes most commonly found in acidic hot springs come from the domain archaea. They are | The microbes most commonly found in acidic hot springs come from the domain archaea. They are able to survive in some of the most extreme environments on the planet<sup>7</sup>. The archaea that oxidize sulfur belong to the order <i>Sulfolobales</i><sup>8</sup>. Some specific examples of those archaea that have been found in acidic hot springs are [[Sulfolobus]] and [[Sulfurisphaera]]. | ||
===<b>Bacteria</b>=== | ===<b>Bacteria</b>=== | ||
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4. [http://www.husafell.is/ensku_sidurnar/e_nagrenni/e_deildartunguhver/e_deildartunguhver.htm “Deildartunguhver”. Ferðaþjónustan Húsafelli.] | 4. [http://www.husafell.is/ensku_sidurnar/e_nagrenni/e_deildartunguhver/e_deildartunguhver.htm “Deildartunguhver”. Ferðaþjónustan Húsafelli.] | ||
7. [http://www.ucmp.berkeley.edu/archaea/archaea.html Speer, Brian. “Introduction to the Archaea: Life’s extremists...” Univeristy of California Museum of Paleontology. 2001.] | 7. [http://www.ucmp.berkeley.edu/archaea/archaea.html Speer, Brian. “Introduction to the Archaea: Life’s extremists...” Univeristy of California Museum of Paleontology. 2001.] | ||
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10. [http://www.ncbi.nlm.nih.gov/pubmed/11064246 Akiyama H., Yamasaki O., Tada J., Kubota K., Arata J. 2000. “Microbial effects of acidic hot-spring water of Satphylococcus aureus strains isolated from atopic dermatitis patients”. Journal of Dermatological Science 24:112-118.] | 10. [http://www.ncbi.nlm.nih.gov/pubmed/11064246 Akiyama H., Yamasaki O., Tada J., Kubota K., Arata J. 2000. “Microbial effects of acidic hot-spring water of Satphylococcus aureus strains isolated from atopic dermatitis patients”. Journal of Dermatological Science 24:112-118.] | ||
11. [http://www.jstor.org/pss/3515515 Jones B., Renaut R.W., Rosen M.R. 2000 “Stromatolites Forming in Acidic Hot-Spring Waters, North Island, New Zealand”. Palaios. 15:450.] | 11. [http://www.jstor.org/pss/3515515 Jones B., Renaut R.W., Rosen M.R. 2000. “Stromatolites Forming in Acidic Hot-Spring Waters, North Island, New Zealand”. Palaios. 15:450.] | ||
12. [http://docs.google.com/viewer?a=v&q=cache:-Wt3FNAmxZEJ:www.bio.sdsu.edu/faculty/kelley/19.pdf+acidic+hot+springs&hl=en&gl=us&pid=bl&srcid=ADGEESh3IYG7XE-o9D0rJwAURAGl26cgtzcM9F8PPJ1Fic5_pFGLFIO1eBIf-bGKcevFSrzdJXL7gqg4gA3OOFz-8OZsTcvoBFBmxC6DJ_zQSuA45H3YvCZYJGUb5R5m9LgLpJY3gvRu&sig=AHIEtbR1PzB8jn_YmTC-4_IcWDD8ntCe7Q Ellis D.G., Weiss Bizzoco R.L., Maezato Y., Baggett J.N., Kelley S.T. 2005. “Microscopic examination of acidic hot springs of Waiotapu, North Island, New Zealand”. New Zealand Journal of Marine and Freshwater Research. 39:1001-1011.] | 12. [http://docs.google.com/viewer?a=v&q=cache:-Wt3FNAmxZEJ:www.bio.sdsu.edu/faculty/kelley/19.pdf+acidic+hot+springs&hl=en&gl=us&pid=bl&srcid=ADGEESh3IYG7XE-o9D0rJwAURAGl26cgtzcM9F8PPJ1Fic5_pFGLFIO1eBIf-bGKcevFSrzdJXL7gqg4gA3OOFz-8OZsTcvoBFBmxC6DJ_zQSuA45H3YvCZYJGUb5R5m9LgLpJY3gvRu&sig=AHIEtbR1PzB8jn_YmTC-4_IcWDD8ntCe7Q Ellis D.G., Weiss Bizzoco R.L., Maezato Y., Baggett J.N., Kelley S.T. 2005. “Microscopic examination of acidic hot springs of Waiotapu, North Island, New Zealand”. New Zealand Journal of Marine and Freshwater Research. 39:1001-1011.] | ||
13. [http://www.textbookofbacteriology.net/control.html Todar, Kenneth. 2011. "Control of Microbial Growth". Online Textbook of Bacterialogy.] | |||
Edited by Maureen Barr, a student of Angela Kent at the University of Illinois at Urbana-Champaign. | Edited by Maureen Barr, a student of Angela Kent at the University of Illinois at Urbana-Champaign. | ||
<!-- Do not edit or remove this line -->[[Category:Pages edited by students of Angela Kent at the University of Illinois at Urbana-Champaign]] | <!-- Do not edit or remove this line -->[[Category:Pages edited by students of Angela Kent at the University of Illinois at Urbana-Champaign]] |
Revision as of 22:21, 21 April 2011
Introduction:
Hot springs can be found all around the world and while there are many specific definitions, they can be generally be described as any spring that is heated geothermally1. Not only are these environment considered extreme in terms of temperature, but they can also be very extreme in regard to pH. This may seem like a habitat that is unfit for life, but there are many microbes that are able to utilize acidic hot springs in order to survive.
Physical environment
As mentioned before, acidic hot springs are a very extreme environment, home to thermophilic and acidophilic microbes. Thermophile means attraction to heat, so thermophilic microbes prosper in very high temperatures. Acidophile means attraction to acids, therefore acidophilic microbes need an acidic environment.
Acidity
On a pH scale of 1 to 14, 1 being the most acidic and 14 being the most basic, hot springs can reach pH as low as 1.5, like in Pozzuoli, Italy2. In most springs, the acidity is the result of sulfide being oxidized by microbes3.
Temperature
Hot springs vary in temperature, some are at a temperature comfortable enough to be used as a sort of hot tub for both humans and animals while other reach temperatures of up to 100 °C (212 °F)4. The temperatures reached in hot springs is enough to kill many microbes. In fact, heat is frequently used as a method of sterilization.
Microbial Communities
Microbes found in acidic hot springs are typically thermoacidophilic archaea and bacteria. However, viruses that infect archaea have also been discovered in some acidic hot spring2.
Viruses
There are many new virus families that have been discovered in hot springs, some of these are Fuselloviridae, Lipothrixviridae, Rudiviridae, Guttaviridae, and Globuloviridae. These viruses all have unique morphologies and genomic qualities that have yet to be observed outside of the hot springs, and therefore were assigned to new families. One of these viruses, called Acidianus bottle-shaped virus, uses it’s shape to funnel it’s double stranded DNA into the archaeal genus Acidianus. While it is not clear what the exact virus-host relationship is in this example further studies are being conducted. This study strongly supports the idea that there are many morphologically different viruses that we have yet to discover, and that many may be surviving in extreme environments2.
Archaea
The microbes most commonly found in acidic hot springs come from the domain archaea. They are able to survive in some of the most extreme environments on the planet7. The archaea that oxidize sulfur belong to the order Sulfolobales8. Some specific examples of those archaea that have been found in acidic hot springs are Sulfolobus and Sulfurisphaera.
Bacteria
Sulfur can be oxidized by some bacteria that can be defined as either aerobic lithotrophs or anaerobic phototrophs8. One particular genus of bacteria that is known to oxidize sulfur to sulfuric acid is Thiobacillus.
Microbial processes
Sulfur is an element that is frequently found in hot springs; it is dissolved into the springs through the surrounding rocks and soil3. The most important microbial process that occurs in hot springs is the oxidation of sulfur, producing sulfuric acid.
Oxidation
When an element is oxidized, this means that it is losing electrons9. These electrons can then be used by the microbe to generate ATP, which is the energy that allows cells to grow and reproduce.
Current Research
One recent study was investigating potential antimicrobial effects of acidic hot spring water on the species Staphylococcus aureus. These strains of S. Aureus were collected from patients with atopic dermatitis, more commonly known by the name eczema. The results showed significant decreases in the amount of S. Aureus cells that were able to survive in the acidic hot spring water. The conclusions reached was that some of the present ions and the low pH conditions allowed the water to act as a bactericidal agent10. In New Zealand, stromatolites were found developing in several acidic hot springs. Small spicular, columnar and blade-shaped stromatolites are something frequently found in hot springs and geysers, however, they are most commonly found in neutral and alkaline springs. Recently stromatolites have been discovered forming in the acid-sulfate springs of Lake Rotokawa. When the mineral structure and biota found in these stromatolites was compared to those of neutral and alkaline waters there were many differences. This analysis can help us better describe ancient thermal deposits based on their mineralogy11. More research done in a different area of New Zealand found microbes other than Sulfolobus in the acidic hot springs of Waiotapu for the first time. Some rod shaped, spherical and filamentous cells were observed in addition to Sulfolobus spheres. However, the attempts to culture the microbes were unsuccessful. Several analyses of the microbes determined a few known species and several unknown bacteria in the pools12.
References
1. 2009. “Hot Spring”. Encarta World English Dictionary. Microsoft Corportation.
3. Treiman, Allan. “Sulphur Springs”. Lunar and Planetary Institute. 2003.
4. “Deildartunguhver”. Ferðaþjónustan Húsafelli.
9. “Oxidation and Reduction”. The Bodner Group: Purdue Department of Chemistry.
13. Todar, Kenneth. 2011. "Control of Microbial Growth". Online Textbook of Bacterialogy.
Edited by Maureen Barr, a student of Angela Kent at the University of Illinois at Urbana-Champaign.