Pyrodictium: Difference between revisions

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{{Biorealm Genus}}
'''NCBI:<br />[http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=38568 Taxonomy]<br /> Genome '''
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[[Image:767.jpg|thumb|300px|right|''Pyrodictium occultum''. Image from [http://202.114.65.51/fzjx/wsw/newindex/tuku/MYPER/A05.HTM Site For Microbes.]]]
[[Image:767.jpg|thumb|300px|right|''Pyrodictium occultum''. Image from Reinhardt Rachel, [http://202.114.65.51/fzjx/wsw/newindex/tuku/MYPER/A05.HTM Site For Microbes.]]]


==Classification==
==Classification==
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''Pyrodictium abyssi, P. brockii, P. occultum''
''Pyrodictium abyssi, P. brockii, P. occultum''
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'''NCBI: [http://www.ncbi.nlm.nih.gov/Taxonomy/Browser/wwwtax.cgi?id=38568 Taxonomy] Genome'''
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==Description and Significance==
==Description and Significance==


''Pyrodictium'' is a genera of submarine hyperthrmophilic archaea whose optimal growth temperature ranges from approximately 80<sup>o</sup>C-105<sup>o</sup>C. They have a unique cell structure involving a network of cannulae and flat, disk-shaped cells. ''Pyrodictium'' are found in the porous walls of deep-sea vents where the temperatures inside get as high as 300<sup>o</sup>-400<sup>o</sup>C, while the outside marine environment is typically 3<sup>o</sup>C. ''Pyrodictium'' is apparently able to adapt morphologically to this type of hot-cold habitat.
''Pyrodictium'' is a genera of submarine hyperthermophilic archaea whose optimal growth temperature ranges from approximately 80<sup>o</sup>C-105<sup>o</sup>C. They have a unique cell structure involving a network of cannulae and flat, disk-shaped cells. ''Pyrodictium'' are found in the porous walls of deep-sea vents where the temperatures inside get as high as 300<sup>o</sup>-400<sup>o</sup>C, while the outside marine environment is typically 3<sup>o</sup>C. ''Pyrodictium'' is apparently able to adapt morphologically to this type of hot-cold habitat.


==Genome Structure==
==Genome Structure==
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==Cell Structure and Metabolism==
==Cell Structure and Metabolism==


[[Image:pyrodictium.jpg|thumb|300px|right|''Pyrodictium'''s disks and cannulae. Image from [http://tolweb.org/tree?group=Crenarchaeota&contgroup=Archaea#titlefigcaption Tree of Life.]]]
[[Image:pyrodictium.jpg|thumb|300px|right|''Pyrodictium'''s disks and cannulae. Image from Reinhardt Rachel, [http://tolweb.org/tree?group=Crenarchaeota&contgroup=Archaea#titlefigcaption Tree of Life.]]]
''Pyrodictium'' cells have been studied by scientists in part because they are a model of thermal stability. The cells' structure is a flat, irregular disk, 0.3 - 2.5 microns in diameter and up to .3 microns in width. The cells grow in unique flake-like shapes held together by a network of hollow cannulae (tubules). The cannulae branch out and connect with other cells, greatly extending their range. While the exact reason for this morphology is unknown, it is likely that the range of motion provided by the cannulae allow the cells to move freely when by the thermal energy from the extreme heat of the organisms's environment. The large size range of the cells may allow ''Pyrodictium'' to inhabit a variety of pores in the deep-sea vent walls.
''Pyrodictium'' cells have been studied by scientists in part because they are a model of thermal stability. The cells' structure is a flat, irregular disk, 0.3 - 2.5 microns in diameter and up to .3 microns in width. The cells grow in unique flake-like shapes held together by a network of hollow cannulae (tubules). The cannulae branch out and connect with other cells, greatly extending their range. While the exact reason for this morphology is unknown, it is likely that the range of motion provided by the cannulae allow the cells to move freely when by the thermal energy from the extreme heat of the organisms's environment. The large size range of the cells may allow ''Pyrodictium'' to inhabit a variety of pores in the deep-sea vent walls.


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Members of ''Pyrodictium'' are located in deep-sea hydrothermal vents, first discovered in 1979. Their ecological significance remains a mystery because of the difficulty in collecting samples which may yield data on the abundance and diversity of these extremophiles.  
Members of ''Pyrodictium'' are located in deep-sea hydrothermal vents, first discovered in 1979. Their ecological significance remains a mystery because of the difficulty in collecting samples which may yield data on the abundance and diversity of these extremophiles.  
[[Image:blksmokr.jpg|thumb|300px|right|A Black Smoker hydrothermal vent, habitat typical of ''Pyrodictium.'' Image from [http://www.biosbcc.net/ocean/marinesci/04benthon/dsvents.htm NOAA.]]]
[[Image:blksmokr.jpg|thumb|200px|right|A Black Smoker hydrothermal vent, habitat typical of ''Pyrodictium.'' Image from [http://www.biosbcc.net/ocean/marinesci/04benthon/dsvents.htm NOAA.]]]


==References==
==References==

Latest revision as of 07:21, 17 February 2017

This is a curated page. Report corrections to Microbewiki.

A Microbial Biorealm page on the genus Pyrodictium

Pyrodictium occultum. Image from Reinhardt Rachel, Site For Microbes.

Classification

Higher order taxa:

Archaea, Crenarchaeota, Thermoprotei, Desulfurococcales, Pyrodictiaceae

Species:

Pyrodictium abyssi, P. brockii, P. occultum

NCBI: Taxonomy Genome

Description and Significance

Pyrodictium is a genera of submarine hyperthermophilic archaea whose optimal growth temperature ranges from approximately 80oC-105oC. They have a unique cell structure involving a network of cannulae and flat, disk-shaped cells. Pyrodictium are found in the porous walls of deep-sea vents where the temperatures inside get as high as 300o-400oC, while the outside marine environment is typically 3oC. Pyrodictium is apparently able to adapt morphologically to this type of hot-cold habitat.

Genome Structure

Much research has been done on the genetics of Pyrodictium in order to understand its ability to survive and even thrive in such extreme temperatures. The thermal stability of Pyrodictum occultum's isolate tRNA has been analyzed, indicating that modifications in the nucleosides allow the organism to withstand temperatures well over 100o C.

Cell Structure and Metabolism

Pyrodictium's disks and cannulae. Image from Reinhardt Rachel, Tree of Life.

Pyrodictium cells have been studied by scientists in part because they are a model of thermal stability. The cells' structure is a flat, irregular disk, 0.3 - 2.5 microns in diameter and up to .3 microns in width. The cells grow in unique flake-like shapes held together by a network of hollow cannulae (tubules). The cannulae branch out and connect with other cells, greatly extending their range. While the exact reason for this morphology is unknown, it is likely that the range of motion provided by the cannulae allow the cells to move freely when by the thermal energy from the extreme heat of the organisms's environment. The large size range of the cells may allow Pyrodictium to inhabit a variety of pores in the deep-sea vent walls.

Ecology

Members of Pyrodictium are located in deep-sea hydrothermal vents, first discovered in 1979. Their ecological significance remains a mystery because of the difficulty in collecting samples which may yield data on the abundance and diversity of these extremophiles.

A Black Smoker hydrothermal vent, habitat typical of Pyrodictium. Image from NOAA.

References

Barns, Sue et al. Crenarchaeota. Tree of Life Web Project. 1997.

Euzeby, J.P. Genus Pyrodictium. LPSN. Updated May 14, 2005.

Pihl, T.D. et al. Hydrogen-oxidizing electron transport components in the hyperthermophilic archaebacterium Pyrodictium brockii. Journal of Bacteriology vol 174(1). January 1992. 137-143.

Stetter, Karl O. Smallest Cell Sizes Within Hyperthermophilic Archaea. National Academy of Sciences.

Takai, Ken et al. Distribution of Archaea in a Black Smoker Chimney Structure. Applied and Environmental Microbiology vol 67(8) August 2001. 3618-3629.

Ushida, C. et al. Structural feature of the initiator tRNA gene from Pyrodictium occultum and the thermal stability of its gene product tRNA. Abstract. Biochemie vol 78(10) 1996. 847-855.