Deinococcus radiodurans NEU2011: Difference between revisions

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=='''''<big>Deinococcus Radiodurans</big>'''''==
{{Uncurated}}
=='''''<big>Deinococcus radiodurans</big>'''''==
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[[file:d_radiodurans.jpg|250px|thumb|left|'''Figure 1''':--<i>'''''Deinococcus radiodurans'''''</i><br/>Electron micrograph of the bacterium ''Deinococcus radiodurans''.[http://www.scifun.ed.ac.uk/card/facts.html (1)]]]
[[file:d_radiodurans.jpg|250px|thumb|left|'''Figure 1''':--<i>'''''Deinococcus radiodurans'''''</i><br/>Electron micrograph of the bacterium ''Deinococcus radiodurans''.[http://www.scifun.ed.ac.uk/card/facts.html (1)]]]
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''Deinococcus radiodurans'' is highly resistant against ionizing radiation, ultraviolet radiation, oxidative stress, and desiccation.  Although radiation causes a delay in growth and replication,''D. radiodurans'' can recover rapidly from 15kGy of gamma radiation, a level that is deadly to most life.  ''D. radiodurans'' is 50 times more resistant than ''Escherichia coli'' to ionizing radiation and about 33 times more resistant than ''E. coli''  to ultraviolet radiation.  It is no less susceptible to the damage that radiation causes than other cells, but is however much better at repairing its genome when radiation causes double stranded breaks (DSB).  ''E. coli'' can withstand about 10-15 DSB’s, while ''D. radiodurans'' is able to repair 1,000-2,000 DSB’s.  It is theorized that perhaps ''D. radiodurans'' is able to use the multiple copies of its genomes to find templates for repair when mending DSB’s.  Many people wondered what selective pressure caused ''D. radiodurans'' to develop such extreme resilience to radiation when no such conditions are present on earth.  It is postulated that it was severe dehydration, which can cause similar DNA damage to radiation was the pressure that lead to the evolution of ''D. radiodurans'' [http://mmbr.asm.org/cgi/content/short/65/1/44 (3)].   
''Deinococcus radiodurans'' is highly resistant against ionizing radiation, ultraviolet radiation, oxidative stress, and desiccation.  Although radiation causes a delay in growth and replication, ''D. radiodurans'' can recover rapidly from 15kGy of gamma radiation, a level that is deadly to most life.  ''D. radiodurans'' is 50 times more resistant than ''Escherichia coli'' to ionizing radiation and about 33 times more resistant than ''E. coli''  to ultraviolet radiation.  It is no less susceptible to the damage that radiation causes than other cells, but is however much better at repairing its genome when radiation causes double stranded breaks (DSB).  ''E. coli'' can withstand about 10-15 DSB’s, while ''D. radiodurans'' is able to repair 1,000-2,000 DSB’s.  It is theorized that perhaps ''D. radiodurans'' is able to use the multiple copies of its genomes to find templates for repair when mending DSB’s.  Many people wondered what selective pressure caused ''D. radiodurans'' to develop such extreme resilience to radiation when no such conditions are present on earth.  It is postulated that it was severe dehydration, which can cause similar DNA damage to radiation, was the pressure that lead to the evolution of ''D. radiodurans'' [http://mmbr.asm.org/cgi/content/short/65/1/44 (3)].   
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''D. radiodurans'' has been of fascination to researchers who are eager to understand its amazing DNA repair mechanisms.  It also has been useful as a genetically engineered bacteria.  It has been recombined to be capable of metabolizing toxic toluene and mercury from radioactive waste, as it can survive in the extreme radioactive conditions [http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/ (5)].
''D. radiodurans'' has been of fascination to researchers who are eager to understand its amazing DNA repair mechanisms.  It also has been useful as a genetically engineered bacteria.  It has been recombined to be capable of metabolizing toxic toluene and mercury from radioactive waste, as it can survive in the most extreme radioactive conditions [http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/ (5)].
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[[file:genome.jpg|250px|thumb|right|'''Figure 3''': Genomic map of the bacterium Deinococcus Radiodurans [http://mmbr.asm.org/cgi/content/short/65/1/44 (6)]]]
[[file:genome.jpg|250px|thumb|right|'''Figure 3''': Genomic map of the bacterium Deinococcus Radiodurans [http://mmbr.asm.org/cgi/content/short/65/1/44 (6)]]]


The genome is composed of four circular molecules:  
The genome of this bacteria is composed of four circular molecules:  
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The genome contains 3187 open reading frames (ORFs), with an average size of 937 base pairs (bp), representing 91% of the genome.Analysis of the genome shows that almost 30% of the total number of genes encode proteins with regulatory functions (39 of 140) including: transcription factors, response regulators, and kinases are found on chromosome II and the megaplasmid.[http://mmbr.asm.org/cgi/content/short/65/1/44 (6)]
The genome contains 3187 open reading frames (ORFs), with an average size of 937 base pairs (bp), representing 91% of the genome. Analysis of the genome shows that almost 30% of the total number of genes encode proteins with regulatory functions (39 of 140) including: transcription factors, response regulators, and kinases are found on chromosome II and the megaplasmid.[http://mmbr.asm.org/cgi/content/short/65/1/44 (6)]
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''D.radiodurans'' can be found in a wide variety of habitats. However a lot of them are dependent on water which limits the areas in which they can be found.  They are widely distributed in the soil and can be found in every continent. It has also colonized ground meat and sewage. Many colonies have been isolated from including radiation sterilized surgical tools, filtered air, and elephant waste [http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/Habitat.htm (8).]There ability to withstand extreme environment also makes it easy for them to live in almost every habitant on the planet. They are able to survive in nutrient poor environments and dry places because they have also been isolated from dried food, musical instruments, and room dust [http://www.biology.lsu.edu/webfac/jbattista/publications/downloads/Against_All_Odds.pdf (7).]
''D.radiodurans'' can be found in a wide variety of habitats. However a lot of them are dependent on water which limits the areas in which they can be found.  They are widely distributed in the soil and can be found in every continent. It has also colonized ground meat and sewage. Many colonies have been isolated from many different settings including radiation sterilized surgical tools, filtered air, and elephant waste [http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/Habitat.htm (8).]Their ability to withstand extreme environment also makes it easy for them to live in almost every habitant on the planet. They are also able to survive in nutrient poor environments and dry places since they have also been isolated from dried food, musical instruments, and room dust [http://www.biology.lsu.edu/webfac/jbattista/publications/downloads/Against_All_Odds.pdf (7).]
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''D. radiodurans'': Getting a Better Fix on DNA Repair by Robert Longtin focuses on the role of D. radiodurans in the treatment of cancer. The article describes the research being done to use the bacterial DNA repair system in helping to fix DNA damage present on cancer cells because D. radiodurans has been found to have a DNA repair mechanism that can fix up to 250 times more DNA breaks than E.Coli can fix[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).] While this seems very promising, no in vivo research has been performed yet and some researchers claim that the bacteria might not be as useful as the theory suggests because “the most meaningful biologic information is not DNA structure, it is protein structure”[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).]  The article also concludes by putting an emphasis on the lack of funding from the National Institute of Health compared to other agencies such as the Department of Energy, NASA, the National Science Foundation, and the Department of Defense which all have interest in using the bacteria for different purposes such as its potential to absorb and degrade toxic matter in high-radiation environments.[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).]
''D. radiodurans'': Getting a Better Fix on DNA Repair by Robert Longtin focuses on the role of ''D. radiodurans'' in the treatment of cancer. The article describes the research being done to use the bacterial DNA repair system in helping to fix DNA damage present on cancer cells because ''D. radiodurans'' has been found to have a DNA repair mechanism that can fix up to 250 times more DNA breaks than ''E.Coli'' can fix[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).] While this seems very promising, no in vivo research has been performed yet and some researchers claim that the bacteria might not be as useful as the theory suggests because “the most meaningful biologic information is not DNA structure, it is protein structure”[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).]  The article also concludes by putting an emphasis on the lack of funding from the National Institute of Health compared to other agencies such as the Department of Energy, NASA, the National Science Foundation, and the Department of Defense which all have interest in using the bacteria for different purposes such as its potential to absorb and degrade toxic matter in high-radiation environments.[http://jnci.oxfordjournals.org/content/95/17/1270.full (10).]
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==='''''Article 2'''''===
==='''''D. radiodurans and UV radiation'''''===


[[file:ARTICLE 1.JPG|250px|thumb|right|'''Figure 5''': '''Study Results'''<br/> The effect of bacteria Dienococcus radiphilus lipid extract on LDL oxidation induced by copper ion ('''A''') or the free radical generator AAPH ('''B''') [http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).]]]
[[file:ARTICLE 1.JPG|250px|thumb|right|'''Figure 5''': '''Study Results'''<br/> The effect of bacteria Dienococcus radiphilus lipid extract on LDL oxidation induced by copper ion ('''A''') or the free radical generator AAPH ('''B''') [http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).]]]
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In an experiment by Xiaosong Chang et al., Involvment of recF in 254 nm, Ultraviolet Radiation Resistance in Deinococcus Radiodurans and Escherichia coli it was shown that rec F is a crucial gene to the RecFOR pathway.  The RecFOR pathway is essential to the repair of single stranded gaps after DNA damage involving several Rec proteins.  This experiment manipulated recF individually to gain an understanding of its significance in Deinococcus Radiodurans UV resistance, so a  recF mutant of D. radiodurans was constructed.  The researchers were also interested in if UV resistance could be increased in E. coli if D. radiodurans recF was transformed into E. coli BL21.  Deinococcus Radiodurans, RecF mutant strain, E. coli-recF, and E. coli were cultured and then were exposed to UV-C irradiation treatment at 254nm.  At 2 hour time intervals a sample was taken that was plated and incubated from which survival analysis was conducted [http://cat.inist.fr/?aModele=afficheN&cpsidt=23241474 (11)].   
In an experiment by Xiaosong Chang et al., Involvment of recF in 254 nm, Ultraviolet Radiation Resistance in ''Deinococcus radiodurans'' and ''Escherichia coli'' it was shown that rec F is a crucial gene to the RecFOR pathway.  The RecFOR pathway is essential to the repair of single stranded gaps after DNA damage involving several Rec proteins.  This experiment manipulated recF individually to gain an understanding of its significance in ''Deinococcus radiodurans'' UV resistance, so a  recF mutant of ''D. radiodurans'' was constructed.  The researchers were also interested in if UV resistance could be increased in ''E. coli'' if ''D. radiodurans'' recF was transformed into ''E. coli'' BL21.  ''Deinococcus radiodurans'', RecF mutant strain, ''E. coli''-recF, and ''E. coli'' were cultured and then were exposed to UV-C irradiation treatment at 254nm.  At 2 hour time intervals a sample was taken that was plated and incubated from which survival analysis was conducted [http://cat.inist.fr/?aModele=afficheN&cpsidt=23241474 (11)].   


A statistically significant difference between RecF mutant, and D. radiodurans, as the RecF mutant had a lesser coping ability to UV radiation.  The E. coli-recF showed a 2.5 fold increase in survival to UV radiation compared to the non-recombinant E.coli.  This shows that recF has an important role in UV resistance, and D. radiodurans recF is more UV resistant that that of E.coli  recF [http://cat.inist.fr/?aModele=afficheN&cpsidt=23241474 (11)].
A statistically significant difference was observed between RecF mutant and ''D. radiodurans'' recF , as the RecF mutant had a lesser coping ability to UV radiation.  The ''E. coli''-recF showed a 2.5 fold increase in survival to UV radiation compared to the non-recombinant ''E.coli''.  This shows that recF has an important role in UV resistance and ''D. radiodurans'' recF is more UV resistant that that of ''E.coli'' recF [http://cat.inist.fr/?aModele=afficheN&cpsidt=23241474 (11)].
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==='''''Potential Clinical Relevance'''''===
 
==='''''Article 3'''''===




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A sister specie in the same genus called ''Dienococcus radiophilus'' is also studied for its benefits in cardiovascular disease. The antioxidative effect of the bacteria ''D. radiophilus'' against LDL lipid peroxidation by A. Lavy, Y. Neeman, and B. Fuhrman was a paper describing the research done to explore the benefit of ''Dienococcus radiophilus'' in reducing the development of atherosclerosis. The atherosclerosis plaque formation is a process by which macrophages get deposited in blood vessels and starts accumulating low density lipoprotein (LDL), or what is known as “bad cholesterol”, until a complete atherosclerosis plaque is formed[http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).] The prevention of the formation of these plaques is important because if the plaque occludes the blood vessel or bursts it could lead to some serious cardiovascular problems leading to death in many cases. Lavy et al investigated the use of D. radiophilus in inhibiting the oxidative modification of LDL and therefore reducing atherosclerosis plaque formation. Thiobarbituric acid reactive substances (TBARS) and of lipid peroxides were used to measure LDL oxidation in control samples versus samples with bacterial extracts when induced by copper ions and the free radical generator AAPH. As shown in figure 5, the bacterial extract showed significant decrease in LDL oxidation. This suggest that ''D. radiophilus'' could have a role is decreasing the formation of atherosclerosis plaques. Since this was an in vitro study, further studies needs to be done to confirm this benefit an equivalent in vivo benefit [http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).]
A sister specie in the same genus called ''Dienococcus radiophilus'' is also studied for its benefits in cardiovascular disease. The antioxidative effect of the bacteria ''D. radiophilus'' against LDL lipid peroxidation by A. Lavy, Y. Neeman, and B. Fuhrman was a paper describing the research done to explore the benefit of ''Dienococcus radiophilus'' in reducing the development of atherosclerosis. The atherosclerosis plaque formation is a process by which macrophages get deposited in blood vessels and starts accumulating low density lipoprotein (LDL), or what is known as “bad cholesterol”, until a complete atherosclerosis plaque is formed[http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).] The prevention of the formation of these plaques is important because if the plaque occludes the blood vessel or bursts it could lead to some serious cardiovascular problems leading to death in many cases. Lavy et al investigated the use of ''D. radiophilus'' in inhibiting the oxidative modification of LDL and therefore reducing atherosclerosis plaque formation. Thiobarbituric acid reactive substances (TBARS) and of lipid peroxides were used to measure LDL oxidation in control samples versus samples with bacterial extracts when induced by copper ions and the free radical generator AAPH. As shown in figure 5, the bacterial extract showed significant decrease in LDL oxidation. This suggest that ''D. radiophilus'' could have a role is decreasing the formation of atherosclerosis plaques. Since this was an in vitro study, further studies needs to be done to confirm this benefit an equivalent in vivo benefit [http://www.ncbi.nlm.nih.gov/pubmed/15278372 (12).]
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Latest revision as of 18:22, 15 April 2011

This student page has not been curated.

Deinococcus radiodurans


Figure 1:--Deinococcus radiodurans
Electron micrograph of the bacterium Deinococcus radiodurans.(1)
















Classifications

Figure 2: Deinococcus radiodurans Taxonomy.(2)


Higher Taxa (2)


  • Kingdom: Bacteria


  • Phylum: Deinococcus-Thermus


  • Order: Deinococcales


  • Family: Deinococcaaceae


  • Genus: Deinococcus


  • Species: Radiodurans


Description and Significance


Deinococcus radiodurans is a spherical bacteria 1-2 μm in diameter that tends to form tetrads and is well known for being extremely resistant to radiation (3). It is red in color and non-motile as well as nonsporulating, as shown in figure 1 (4). It is found in many places worldwide, from soil, elephant dung, and granite in Antarticas dry valleys (5). It was first isolated in 1956 when canned meat was found spoiled even though it had been exposed to radiation (3).

Another unique feature of D. radiodurans is that it has multiple copies of its genome. During the exponential growth phase, D. radiodurans will have 8-10 copies of its genome. During the stationary growth phase it will still have 4 copies of its genome, which consists of 2 chromosomes, 1 megaplasmid, and 1 plasmind (3). The taxonomy as well as the complete genome of Deinococcus radiodurans are shown in figures 2 and 3.

Deinococcus radiodurans is highly resistant against ionizing radiation, ultraviolet radiation, oxidative stress, and desiccation. Although radiation causes a delay in growth and replication, D. radiodurans can recover rapidly from 15kGy of gamma radiation, a level that is deadly to most life. D. radiodurans is 50 times more resistant than Escherichia coli to ionizing radiation and about 33 times more resistant than E. coli to ultraviolet radiation. It is no less susceptible to the damage that radiation causes than other cells, but is however much better at repairing its genome when radiation causes double stranded breaks (DSB). E. coli can withstand about 10-15 DSB’s, while D. radiodurans is able to repair 1,000-2,000 DSB’s. It is theorized that perhaps D. radiodurans is able to use the multiple copies of its genomes to find templates for repair when mending DSB’s. Many people wondered what selective pressure caused D. radiodurans to develop such extreme resilience to radiation when no such conditions are present on earth. It is postulated that it was severe dehydration, which can cause similar DNA damage to radiation, was the pressure that lead to the evolution of D. radiodurans (3).

D. radiodurans has been of fascination to researchers who are eager to understand its amazing DNA repair mechanisms. It also has been useful as a genetically engineered bacteria. It has been recombined to be capable of metabolizing toxic toluene and mercury from radioactive waste, as it can survive in the most extreme radioactive conditions (5).

Genome Structure

Figure 3: Genomic map of the bacterium Deinococcus Radiodurans (6)

The genome of this bacteria is composed of four circular molecules:


    - Chromosome I = 2,648,638 base pairs 
    - Chromosome II = 412,348 base pairs
    - A megaplasmid = 177,466 base pairs 
    - A plasmid = 45,704 base pairs



The genome contains 3187 open reading frames (ORFs), with an average size of 937 base pairs (bp), representing 91% of the genome. Analysis of the genome shows that almost 30% of the total number of genes encode proteins with regulatory functions (39 of 140) including: transcription factors, response regulators, and kinases are found on chromosome II and the megaplasmid.(6)



Cell Structure and Metabolism


D. radiodurans is an obligate gram positive aerobe that is chemoorganotrophic. (7) This bacterium however has been recombined in order for it to be able to metabolize various radioactive toxic waste, such as toluene and mercury. It is cocci shape bacterium that stains gram positive although it’s cell structure more closely resembles that of a gram negative cell. It has an outer and an inner membrane and a thicker peptidoglycan layer that is 14-20nm thick. On top of the peptidoglycan layer there is another layer that is broken up into many small compartments. (3)

Ecology


D.radiodurans can be found in a wide variety of habitats. However a lot of them are dependent on water which limits the areas in which they can be found. They are widely distributed in the soil and can be found in every continent. It has also colonized ground meat and sewage. Many colonies have been isolated from many different settings including radiation sterilized surgical tools, filtered air, and elephant waste (8).Their ability to withstand extreme environment also makes it easy for them to live in almost every habitant on the planet. They are also able to survive in nutrient poor environments and dry places since they have also been isolated from dried food, musical instruments, and room dust (7).

Pathology


Currently, Deinococcus radiodurans is not proven to be a pathogenic organism. Most studies on Deinococcus radiodurans provide hope for it to be used in research as an agent that can be genetically altered to serve an important role in getting rid of toxins(9).

Current Research

Figure 4: Radio fluorescence imaging of Deinoccocus Radiodurans (10).


The famous saying “What doesn’t kill you makes you stronger” by Frederich Nietzsche might apply to our bacteria. Many researchers are taking advantage of the fact that Dienococcus radiophilus is not found to be pathogenic to humans and are trying to use its radiation characteristics, as shown in figure 4, for the benefit of our species. Some examples of the ongoing research will be summarized below.


D. radiodurans and DNA repair system


D. radiodurans: Getting a Better Fix on DNA Repair by Robert Longtin focuses on the role of D. radiodurans in the treatment of cancer. The article describes the research being done to use the bacterial DNA repair system in helping to fix DNA damage present on cancer cells because D. radiodurans has been found to have a DNA repair mechanism that can fix up to 250 times more DNA breaks than E.Coli can fix(10). While this seems very promising, no in vivo research has been performed yet and some researchers claim that the bacteria might not be as useful as the theory suggests because “the most meaningful biologic information is not DNA structure, it is protein structure”(10). The article also concludes by putting an emphasis on the lack of funding from the National Institute of Health compared to other agencies such as the Department of Energy, NASA, the National Science Foundation, and the Department of Defense which all have interest in using the bacteria for different purposes such as its potential to absorb and degrade toxic matter in high-radiation environments.(10).

D. radiodurans and UV radiation

Figure 5: Study Results
The effect of bacteria Dienococcus radiphilus lipid extract on LDL oxidation induced by copper ion (A) or the free radical generator AAPH (B) (12).


In an experiment by Xiaosong Chang et al., Involvment of recF in 254 nm, Ultraviolet Radiation Resistance in Deinococcus radiodurans and Escherichia coli it was shown that rec F is a crucial gene to the RecFOR pathway. The RecFOR pathway is essential to the repair of single stranded gaps after DNA damage involving several Rec proteins. This experiment manipulated recF individually to gain an understanding of its significance in Deinococcus radiodurans UV resistance, so a recF mutant of D. radiodurans was constructed. The researchers were also interested in if UV resistance could be increased in E. coli if D. radiodurans recF was transformed into E. coli BL21. Deinococcus radiodurans, RecF mutant strain, E. coli-recF, and E. coli were cultured and then were exposed to UV-C irradiation treatment at 254nm. At 2 hour time intervals a sample was taken that was plated and incubated from which survival analysis was conducted (11).

A statistically significant difference was observed between RecF mutant and D. radiodurans recF , as the RecF mutant had a lesser coping ability to UV radiation. The E. coli-recF showed a 2.5 fold increase in survival to UV radiation compared to the non-recombinant E.coli. This shows that recF has an important role in UV resistance and D. radiodurans recF is more UV resistant that that of E.coli recF (11).

Potential Clinical Relevance


A sister specie in the same genus called Dienococcus radiophilus is also studied for its benefits in cardiovascular disease. The antioxidative effect of the bacteria D. radiophilus against LDL lipid peroxidation by A. Lavy, Y. Neeman, and B. Fuhrman was a paper describing the research done to explore the benefit of Dienococcus radiophilus in reducing the development of atherosclerosis. The atherosclerosis plaque formation is a process by which macrophages get deposited in blood vessels and starts accumulating low density lipoprotein (LDL), or what is known as “bad cholesterol”, until a complete atherosclerosis plaque is formed(12). The prevention of the formation of these plaques is important because if the plaque occludes the blood vessel or bursts it could lead to some serious cardiovascular problems leading to death in many cases. Lavy et al investigated the use of D. radiophilus in inhibiting the oxidative modification of LDL and therefore reducing atherosclerosis plaque formation. Thiobarbituric acid reactive substances (TBARS) and of lipid peroxides were used to measure LDL oxidation in control samples versus samples with bacterial extracts when induced by copper ions and the free radical generator AAPH. As shown in figure 5, the bacterial extract showed significant decrease in LDL oxidation. This suggest that D. radiophilus could have a role is decreasing the formation of atherosclerosis plaques. Since this was an in vitro study, further studies needs to be done to confirm this benefit an equivalent in vivo benefit (12).

Cool Factor

Figure 6:--Strong Bacteria Cartoon (16)




D. radiodurans is known as the world’s strongest bacteria. It is capable of surviving in high radiation. “The bacterium D. radiodurans, the present gold-medalist of radiation resistance, is widely considered an extremophile par excellence” (13). Many scientists have been studying their ability to survive in condition such as “5 megarads of γ-irradiation and up to 1,000 J of UV irradiation/m2 without mutation” (14). The results that were found are that they are able to survive in such conditions due to two genes that were found: sig1 and sig2. These two genes are mutants and a D. radiodurans bacterium that contains the sig 1 gene is capable of living in even more severe environments. Since it can survive in such harsh environments it has become a good candidate for radioactive waste cleanup. They have been use for the complete degradation of toluene in sites where there is contamination (15). Not only that they are able to repair their damage in only an hour which is a short amount of time. Unlike most other bacteria that have only one DNA it has four to ten DNA. According to data this specific bacteria is known as one of the oldest life forms on earth originating about 2 billion years ago. One of the theories that scientists have is that it is originally from outer of space but this was prove to be wrong.




References

  1. http://www.scifun.ed.ac.uk/card/facts.html
  2. http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/Phylogeny.htm
  3. Makarova K, Minton K, et al. Genome of the Extremely Radiation-Resistant Bacterium Deinococcus radiodurans Viewed from the Perspective of Comparative Genomics. Microbiology and Molecular Biology Reviews. March 2001. Volume 65. p. 44-79.
  4. White O, Eisen JA, Heidelberg JF, Hickey EK, et al. Genome sequence of the radioresistant bacterium Deinococcus radiodurans R1. Science. November; 1999. 19;286 (5444) : 1571-7.
  5. <http://bioweb.uwlax.edu/bio203/s2008/arnold_meag/>. "RamblingSoul." BioWeb Home. Web. 31 Mar. 2011.
  6. Kira S. Makarova,1,2 L. Aravind,2 Yuri I. Wolf,2 Roman L. Tatusov,2Kenneth W. Minton,1 Eugene V. Koonin,2 and Michael J. Daly1,* Genome of the Extremely Radiation-Resistant Bacterium Deinococcus radiodurans Viewed from the Perspective of Comparative Genomics. Microbiology and Molecular Biology Reviews, March 2001, p. 44-79, Vol. 65.
  7. Battista JR. Against all odds: the survival strategies of Deinococcus radiodurans. Annu Rev Microbiol. 1997;51:203-24. Review. PubMed PMID: 9343349.
  8. Brim, H. "Deinococcus Radiodurans Engineered for Complete Toluene Degradation Facilitates Cr(VI) Reduction." Microbiology 152.8 (2006): 2469-477.
  9. Guide: DN. Gilbers,RC. Moellering, GM. Eliopoulos, HF. Chambers, MS Saag, editors. The stanford guide to antimicrobial therapy 2010. January 2010, 40th Edition. Antimicrobial Therapt, Inc. VA, United States.
  10. Longtin. Deinoccocus Radiodurans: Getting a Better Fix on DNA Repair. Oxford University Press (2003). JNCI Natl Cancer Inst, Volume 95: Issue 17: 1270-1271.
  11. Chang, Xiaosong, et al. "Involvement of Recf in 254 Nm Ultraviolet Radiation Resistance in Deinococcus Radiodurans and Escherichia Coli." Current Microbiology 61.5 (2010): 458-64.
  12. Lavy, Y. Neeman, B. Fuhrman. The antioxidative effect of the bacteria Dienococcus Radiophilus against LDL lipid peroxidation. Eur J Nutr (2005) 44 : 281–284.
  13. http://www.nsf.gov/news/frontiers_archive/10-96/10bugs.jsp
  14. Rothschild, Lynn. "Life in Extreme Environments." Nature 409 (2001): 1092-101.
  15. Schmid, A. K., and M. E. Lidstrom. "Involvement of Two Putative Alternative Sigma Factors in Stress Response of the Radioresistant Bacterium Deinococcus Radiodurans." Journal of Bacteriology 184.22 (2002): 6182-189.
  16. http://www.salmonellablog.com/2005/07/