Deinococcus radiodurans

Deinococcus radiodurans
A tetrad of D. radiodurans
Scientific classification Edit this classification
Domain: Bacteria
Phylum: Deinococcota
Class: Deinococci
Order: Deinococcales
Family: Deinococcaceae
Genus: Deinococcus
Species:
D. radiodurans
Binomial name
Deinococcus radiodurans
Brooks & Murray, 1981

Deinococcus radiodurans is a bacterium, an extremophile and one of the most radiation-resistant organisms known. It can survive cold, dehydration, vacuum, and acid, and therefore is known as a polyextremophile. The Guinness Book Of World Records listed it in January 1998[1] as the world's most radiation-resistant bacterium or lifeform.[2] However the archaea Thermococcus gammatolerans is actually the most resistant organism to radiation.

Name and classification

The name Deinococcus radiodurans derives from the Ancient Greek δεινός (deinos) and κόκκος (kokkos) meaning "terrible grain/berry" and the Latin radius and durare, meaning "radiation surviving". The species was formerly called Micrococcus radiodurans. As a consequence of its hardiness, it has been nicknamed “Conan the Bacterium”, in reference to Conan the Barbarian.[3]

Initially, it was placed in the genus Micrococcus. After evaluation of ribosomal RNA sequences and other evidence, it was placed in its own genus Deinococcus, which is closely related to the genus, Thermus.[4]

Deinococcus is one genus of three in the order Deinococcales. D. radiodurans is the type species of this genus, and the best studied member. All known members of the genus are radioresistant: D. proteolyticus, D. radiopugnans, D. radiophilus, D. grandis, D. indicus, D. frigens, D. saxicola, D. marmoris, D. deserti,[5] D. geothermalis, and D. murrayi; the latter two are also thermophilic.[6]

History

D. radiodurans was discovered in 1956 by Arthur Anderson at the Oregon Agricultural Experiment Station in Corvallis, Oregon.[7] Experiments were being performed to determine whether canned food could be sterilized using high doses of gamma radiation. A tin of meat was exposed to a dose of radiation that was thought to kill all known forms of life, but the meat subsequently spoiled, and D. radiodurans was isolated.[1]

The complete DNA sequence of D. radiodurans was published in 1999 by The Institute for Genomic Research. A detailed annotation and analysis of the genome appeared in 2001.[4] The sequenced strain was ATCC BAA-816.

Deinococcus radiodurans has a unique quality in which it can repair both single- and double-stranded DNA. When damage is apparent to the cell, it brings the damaged DNA into a compartmental ring-like structure where the DNA is repaired, and then is able to fuse the nucleoids from the outside of the compartment with the damaged DNA.[8]

In August 2020, scientists reported that bacteria from Earth, particularly Deinococcus radiodurans bacteria, were found to survive for three years in outer space, based on studies conducted on the International Space Station (ISS). These findings support the notion of panspermia, the hypothesis that life exists throughout the Universe, distributed in various ways, including space dust, meteoroids, asteroids, comets, planetoids, or contaminated spacecraft.[9][10]

Description

D. radiodurans is a rather large, spherical bacterium, with a diameter of 1.5 to 3.5 μm.[11] Four cells normally stick together, forming a tetrad. The bacteria are easily cultured and do not appear to cause disease.[4] Under controlled growth conditions, cells of dimer, tetramer, and even multimer morphologies can be obtained.[11] Colonies are smooth, convex, and pink to red in color. The cells stain Gram positive, although its cell envelope is unusual and is reminiscent of the cell walls of Gram negative bacteria.[12]

Deinococcus radiodurans does not form endospores and is nonmotile. It is an obligate aerobic chemoorganoheterotroph, i.e., it uses oxygen to derive energy from organic compounds in its environment. It is often found in habitats rich in organic materials, such as sewage, meat, feces, or, soil, but has also been isolated from medical instruments, room dust, textiles, and dried foods.[12]

It is extremely resistant to ionizing radiation, ultraviolet light, desiccation, and oxidizing and electrophilic agents.[13]

PCR assays and Fluorescent in Situ Hybridization (FISH) techniques can be used to test for D. radiodurans in nature.[citation needed]

Its genome consists of two circular chromosomes, one 2.65 million base pairs long and the other 412,000 base pairs long, as well as a megaplasmid of 177,000 base pairs and a plasmid of 46,000 base pairs. It has approximately 3,195 genes. In its stationary phase, each bacterial cell contains four copies of this genome; when rapidly multiplying, each bacterium contains 8-10 copies of the genome.[citation needed]

Ionizing-radiation resistance

Deinococcus radiodurans is capable of withstanding an acute dose of 5,000 grays (Gy), or 500,000 rad, of ionizing radiation with almost no loss of viability, and an acute dose of 15,000 Gy with 37% viability.[14][15][16] A dose of 5,000 Gy is estimated to introduce several hundred double-strand breaks (DSBs) into the organism's DNA (~0.005 DSB/Gy/Mbp (haploid genome)). For comparison, a chest X-ray or Apollo mission involves about 1 mGy, 5 Gy can kill a human, 200–800 Gy will kill E. coli, and more than 4,000 Gy will kill the radiation-resistant tardigrade.[citation needed]

Several bacteria of comparable radioresistance are known, including some species of the genus Chroococcidiopsis (phylum cyanobacteria) and some species of Rubrobacter (phylum Actinomycetota); among the archaea, the species Thermococcus gammatolerans shows comparable radioresistance.[6] Deinococcus radiodurans also has a unique ability to repair damaged DNA. It isolates the damaged segments in controlled areas and repairs them. These bacteria can also repair many small fragments from an entire chromosome.[8]

Mechanisms of ionizing-radiation resistance

Deinococcus accomplishes its resistance to radiation by having multiple copies of its genome and rapid DNA repair mechanisms. It usually repairs breaks in its chromosomes within 12–24 hours by a 2-step process. First, D. radiodurans reconnects some chromosome fragments by a process called single-stranded annealing. In the second step, multiple proteins mend double-strand breaks through homologous recombination. This process does not introduce any more mutations than a normal round of replication would. Theoretically, Deinococcus should have little or even no mutation accumulation.[citation needed]

Scanning electron microscopy analysis has shown that DNA in D. radiodurans is organized into tightly packed toroids, which may facilitate DNA repair.[17]

A team of Croatian and French researchers led by Miroslav Radman have bombarded D. radiodurans to study the mechanism of DNA repair. At least two copies of the genome, with random DNA breaks, can form DNA fragments through annealing. Partially overlapping fragments are then used for synthesis of homologous regions through a moving D-loop that can continue extension until the fragments find complementary partner strands. In the final step, there is crossover by means of RecA-dependent homologous recombination.[18]

Deinococcus radiodurans is capable of genetic transformation, a process by which DNA derived from one cell can be taken up by another cell and integrated into the recipient genome by homologous recombination.[19] When DNA damages (e.g. pyrimidine dimers) are introduced into donor DNA by UV irradiation, the recipient cells efficiently repair the damages in the transforming DNA, as they do in cellular DNA, when the cells themselves are irradiated.

Michael Daly has suggested the bacterium uses manganese complexes as antioxidants to protect itself against radiation damage.[20] In 2007 his team showed that high intracellular levels of manganese(II) in D. radiodurans protect proteins from being oxidized by radiation, and they proposed the idea that "protein, rather than DNA, is the principal target of the biological action of [ionizing radiation] in sensitive bacteria, and extreme resistance in Mn-accumulating bacteria is based on protein protection".[21] In 2016, Massimiliano Peana et al. reported a spectroscopic study through NMR, EPR, and ESI-MS techniques on the Mn(II) interaction with two peptides, DP1 (DEHGTAVMLK) and DP2 (THMVLAKGED), whose amino acid composition was selected to include the majority of the most prevalent amino acids present in a Deinococcus radiodurans bacterium cell-free extract that contains components capable of conferring extreme resistance to ionizing radiation.[22] In 2018, M. Peana and C. Chasapis reported by a combined approach of bioinformatic strategies based on structural data and annotation, the Mn(II)-binding proteins encoded by the genome of DR and proposed a model for Manganese interaction with DR proteome network involved in ROS response and defense. [23]

A team of Russian and American scientists proposed that the radioresistance of D. radiodurans had a Martian origin. They suggested that evolution of the microorganism could have taken place on the Martian surface until it was delivered to Earth on a meteorite.[24] However, apart from its resistance to radiation, Deinococcus is genetically and biochemically very similar to other terrestrial life forms, arguing against an extraterrestrial origin not common to them.

In 2009, nitric oxide was reported to play an important role in the bacteria's recovery from radiation exposure: the gas is required for division and proliferation after DNA damage has been repaired. A gene was described that increases nitric oxide production after UV radiation, and in the absence of this gene, the bacteria were still able to repair DNA damage, but would not grow.[25]

Evolution of ionizing-radiation resistance

A persistent question regarding D. radiodurans is how such a high degree of radioresistance could evolve. Natural background radiation levels are very low—in most places, on the order of 0.4 mGy per year, and the highest known background radiation, near Ramsar, Iran, is only 260 mGy per year. With naturally occurring background radiation levels so low, organisms evolving mechanisms specifically to ward off the effects of high radiation are unlikely. In the distant geological past, higher background radiation existed both due to more primordial radionuclides not yet having decayed and due to effects of things like the natural nuclear fission reactors at Oklo, Gabon, which were active some 1.7 billion years ago. However, even if adaptations to such conditions did evolve during that time, genetic drift would almost certainly have eliminated them if they provided no (other) evolutionary benefit.[citation needed]

Valerie Mattimore of Louisiana State University has suggested the radioresistance of D. radiodurans is simply a side effect of a mechanism for dealing with prolonged cellular desiccation (dryness). To support this hypothesis, she performed an experiment in which she demonstrated that mutant strains of D. radiodurans that are highly susceptible to damage from ionizing radiation are also highly susceptible to damage from prolonged desiccation, while the wild-type strain is resistant to both. It was also shown that desiccation induces double-stranded DNA breaks with patterns similar to extreme ionizing radiation.[26] In addition to DNA repair, D. radiodurans use LEA proteins (Late Embryogenesis Abundant proteins)[27] expression to protect against desiccation.[28]

In this context, also the robust S-layer of D. radiodurans through its main protein complex, the S-layer Deinoxanthin Binding Complex (SDBC), strongly contributes to its extreme radioresistance. In fact, this S-layer acts as a shield against electromagnetic stress, as in the case of ionizing radiation exposure, but also stabilizes the cell wall against possible consequent high temperatures and desiccation.[29][30]

Applications

Deinococcus radiodurans as a model system for studying the cell cycle

Deinococcus radiodurans has been shown to have a great potential to be used in different fields of investigation. Not only has D. radiodurans been genetically modified for bioremediation applications, but also it has been discovered that it could perform a major role in biomedical research and in nanotechnology.

Bioremediation refers to any process that uses microorganisms, fungi, plants, or the enzymes derived from them, to return an environment altered by contaminants to its natural condition. Large areas of soils, sediments, and groundwater are contaminated with radionuclides, heavy metals, and toxic solvents. There are microorganisms that are able to decontaminate soils with heavy metals by immobilizing them, but in the case of nuclear waste, ionizing radiation limits the amount of microorganisms that can be useful. In this sense, D. radiodurans, due to its characteristics, can be used for the treatment of nuclear energy waste. Deinococcus radiodurans has been genetically engineered to consume and digest solvents and heavy metals in these radioactive environments. The mercuric reductase gene has been cloned from Escherichia coli into Deinococcus to detoxify the ionic mercury residue frequently found in radioactive waste generated from nuclear weapons manufacture.[31] Those researchers developed a strain of Deinococcus that could detoxify both mercury and toluene in mixed radioactive wastes. Moreover, a gene encoding a non-specific acid phosphatase from Salmonella enterica, serovar Typhi,[32] and the alkaline phosphatase gene from Sphingomonas[33] have been introduced in strains of D. radiodurans for the bioprecipitation of uranium in acid and alkaline solutions, respectively.

In the biomedical field, Deinococcus radiodurans could be used as a model to study the processes that lead to aging and cancer. The main causes of these physiological changes are related to the damage in DNA, RNA, and proteins resulting from oxidative stress, the weakening of antioxidant defense, and the inability of repair mechanisms to deal with the damage originated by reactive oxygen species, also known as ROS. To this extent, D. radiodurans mechanisms of protection against oxidative damage and of DNA reparation could be the starting points in research aimed to develop medical procedures to prevent aging and cancer.[34] Some lines of investigation are focused on the application of D. radiodurans antioxidant systems in human cells to prevent ROS damaging and the study of the development of resistance to radiation in tumoral cells.[35]

A nanotechnological application of D. radiodurans in the synthesis of silver[36] and gold[37] nanoparticles has also been described. Whereas chemical and physical methods to produce these nanoparticles are expensive and generate a huge amount of pollutants, biosynthetic processes represent an ecofriendly and cheaper alternative. The importance of these nanoparticles relies on their medical applications as they have been demonstrated to exhibit activity against pathogenic bacteria, antifouling effects, and cytotoxicity to tumoral cells.

Moreover, there are other uncommon applications of Deinococcus radiodurans. The Craig Venter Institute has used a system derived from the rapid DNA repair mechanisms of D. radiodurans to assemble synthetic DNA fragments into chromosomes, with the ultimate goal of producing a synthetic organism they call Mycoplasma laboratorium.[38] In 2003, U.S. scientists demonstrated D. radiodurans could be used as a means of information storage that might survive a nuclear catastrophe. They translated the song "It's a Small World" into a series of DNA segments 150 base pairs long, inserted these into the bacteria, and were able to retrieve them without errors 100 bacterial generations later.[39]

Clues for future search of extremophile microbial life on Mars

When cultured and exposed to ionizing radiations in liquid media, Deinococcus radiodurans could survive up to 25 kGy.[40] Horne et al. (2022) have studied the effects of desiccation and freezing on the microbial survivability to ionizing radiations considering the feasibility studies to return Martian subsurface soil samples for microbial characterization and for determining the most favorable landing sites of a future robotic exploration mission.[41] They found that the desiccated and frozen cells could resist to a 5.6 higher radiation dose: up to 140 kGy. They calculated that this could correspond to a theoretical survival time of 280 million years at a depth of 33 feet (10 m) below the Mars surface. However, this time scale is too short to allow microbial survival at a depth accessible to a rover equipped with a drilling system below the Martian surface when compared to the moment when liquid water disappeared from the Martian surface (2 – 2.5 billion years ago). Nevertheless, Horne et al. (2022) consider the hypothesis that meteorite impacts could have dispersed Martian soil and heated locally the subsurface during the geological history of Mars, heating sporadically from time to time the local environment, melting the frozen ice and giving perhaps a chance to a hypothetical distant Martian extremophile resembling its terrestrial cousin Deinococcus radiodurans to grow again for short moment before to rapidly become again frozen and dormant for millions of years. So, for returning subsurface soil samples from Mars for microbial characterization with a potentially "successful" mission like the European Rosalind Franklin rover, it would be necessary to target a relatively young impact crater to increase the chances of discovering dormant extremophile micro-organisms surviving in the dry and frozen Martian subsurface environment relatively protected from the lethal ionizing radiations.[40]

See also

References

  1. ^ a b "Most radiation-resistant lifeform". Guinness World Records. Archived from the original on June 23, 2015. The red-coloured bacterium Deinococcus radiodurans can resist 1.5 million rads of gamma radiation, about 3,000 times the amount that would kill a human. The bacteria was first isolated from cans of meat that were subjected to supposedly sterilising doses of radiation in the megarad range.
  2. ^ DeWeerdt, Sarah E. (July 5, 2002). "The World's Toughest Bacterium". Genome News Network. The Center for the Advancement of Genomics. Archived from the original on May 6, 2003. Deinococcus radiodurans is listed in the Guinness Book of World Records as "the world's toughest bacterium."
  3. ^ Huyghe, Patrick (July–August 1998). "Conan the Bacterium" (PDF). The Sciences. 38 (4): 16–19. doi:10.1002/j.2326-1951.1998.tb03393.x. Archived from the original (PDF) on 2011-09-27. Retrieved 2009-10-14.
  4. ^ a b c Makarova, K S; L Aravind; Y I Wolf; R L Tatusov; K W Minton; E V Koonin; M J Daly (March 2001). "Genome of the extremely radiation-resistant bacterium Deinococcus radiodurans viewed from the perspective of comparative genomics". Microbiology and Molecular Biology Reviews. 65 (1): 44–79. doi:10.1128/MMBR.65.1.44-79.2001. PMC 99018. PMID 11238985.
  5. ^ de Groot A, Chapon V, Servant P, Christen R, Saux MF, Sommer S, Heulin T (November 2005). "Deinococcus deserti sp. nov., a gamma-radiation-tolerant bacterium isolated from the Sahara Desert". Int J Syst Evol Microbiol. 55 (Pt 6): 2441–2446. doi:10.1099/ijs.0.63717-0. PMID 16280508.
  6. ^ a b Cox, Michael M; John R Battista (November 2005). "Deinococcus radiodurans – the consummate survivor" (PDF). Nature Reviews. Microbiology. 3 (11): 882–892. doi:10.1038/nrmicro1264. PMID 16261171. S2CID 20680425. Archived from the original (PDF) on 2011-10-08. Retrieved 2008-02-01.
  7. ^ Anderson, A W; H C Nordan; R F Cain; G Parrish; D Duggan (1956). "Studies on a radio-resistant micrococcus. I. Isolation, morphology, cultural characteristics, and resistance to gamma radiation". Food Technol. 10 (1): 575–577.
  8. ^ a b Madigan, Michael T.; Martinko, John M.; Dunlap, Paul V.; Clark, D.P. (2009). Brock Biology of Microorganisms (Twelfth ed.). San Francisco: Benjamin Cummings Pearson. p. 481. ISBN 978-0-13-232460-1. OCLC 173163469.
  9. ^
  10. ^ Strickland, Ashley (26 August 2020). "Bacteria from Earth can survive in space and could endure the trip to Mars, according to new study". CNN News. Retrieved 26 August 2020.
  11. ^ a b Jena, Sidhartha S.; Joshi, Hiren M.; Sabareesh, K.P.V.; Tata, B.V.R.; Rao, T.S. (2006). "Dynamics of Deinococcus radiodurans under Controlled Growth Conditions". Biophysical Journal. 91 (7): 2699–2707. Bibcode:2006BpJ....91.2699J. doi:10.1529/biophysj.106.086520. PMC 1562370. PMID 16829564.
  12. ^ a b Battista, J R (1997). "Against all odds: the survival strategies of Deinococcus radiodurans" (PDF). Annual Review of Microbiology. 51: 203–224. doi:10.1146/annurev.micro.51.1.203. PMID 9343349. Archived from the original (PDF) on 2011-11-05. Retrieved 2008-02-01.
  13. ^ Slade, D; Radman, M (2011). "Oxidative stress resistance in Deinococcus radiodurans". Microbiol Mol Biol Rev. 75 (1): 133–191. doi:10.1128/MMBR.00015-10. PMC 3063356. PMID 21372322.
  14. ^ Moseley BE, Mattingly A (1971). "Repair of irradiated transforming deoxyribonu- cleic acid in wild type and a radiation- sensitive mutant of Micrococcus radiodu- rans". J. Bacteriol. 105 (3): 976–983. doi:10.1128/JB.105.3.976-983.1971. PMC 248526. PMID 4929286.
  15. ^ Murray, Robert G. E. (1992). "204: The Family Deinococcaceae". In Balows, Albert; Trüper, Hans G.; Dworkin, Martin; Harder, Wim; Schleifer, Karl-Heinz (eds.). The Prokaryotes: A Handbook on the Biology of Bacteria. Vol. 4 (2nd ed.). New York: Springer-Verlag. pp. 3732–3744. doi:10.1007/978-1-4757-2191-1_42. ISBN 978-1-4757-2193-5.
  16. ^ Ito H, Watanabe H, Takeshia M, Iizuka H (1983). "Isolation and identification of radiation-resistant cocci belonging to the genus Deinococcus from sewage sludges and animal feeds". Agricultural and Biological Chemistry. 47 (6): 1239–1247. doi:10.1271/bbb1961.47.1239.
  17. ^ Levin-Zaidman S, Englander J, Shimoni E, Sharma AK, Minton KW, Minsky A (2003). "Ringlike structure of the Deinococcus radiodurans genome: a key to radioresistance?". Science. 299 (5604): 254–256. Bibcode:2003Sci...299..254L. doi:10.1126/science.1077865. PMID 12522252. S2CID 38378087.
  18. ^ Zahradka K, Slade D, Bailone A, Sommer S, Averbeck D, Petranovic M, Lindner AB, Radman M (2006). "Reassembly of shattered chromosomes in Deinococcus radiodurans". Nature. 443 (7111): 569–573. Bibcode:2006Natur.443..569Z. doi:10.1038/nature05160. PMID 17006450. S2CID 4412830.
  19. ^ Moseley, BE; Setlow, JK (1968). "Transformation in Micrococcus radiodurans and the ultraviolet sensitivity of its transforming DNA". Proc Natl Acad Sci U S A. 61 (1): 176–183. Bibcode:1968PNAS...61..176M. doi:10.1073/pnas.61.1.176. PMC 285920. PMID 5303325.
  20. ^ Pearson, Helen (30 September 2004). "Secret of radiation-proof bugs proposed" (PDF). news@nature.com. Archived from the original (PDF) on 2006-01-04. Retrieved 2006-06-19.
  21. ^ Daly, Michael J.; Elena K. Gaidamakova; Vera Y. Matrosova; Alexander Vasilenko; Min Zhai; Richard D. Leapman; Barry Lai; Bruce Ravel; Shu-Mei W. Li; Kenneth M. Kemner; James K. Fredrickson (2007-04-01). "Protein Oxidation Implicated as the Primary Determinant of Bacterial Radioresistance". PLOS Biology. 5 (4): e92 EP. doi:10.1371/journal.pbio.0050092. PMC 1828145. PMID 17373858.
  22. ^ Peana M, Medici S, Pangburn HA, Lamkin TJ, Ostrowska M, Gumienna-Kontecka E, Zoroddu MA (2016). "Manganese binding to antioxidant peptides involved in extreme radiation resistance in Deinococcus radiodurans". Journal of Inorganic Biochemistry. 164: 49–58. doi:10.1016/j.jinorgbio.2016.08.012. PMID 27637368.
  23. ^ Peana M, Chasapis CT, Simula G, Medici S, Zoroddu MA (2018). "A Model for Manganese interaction with Deinococcus radiodurans proteome network involved in ROS response and defense". Journal of Trace Elements in Medicine and Biology. 50: 465–473. doi:10.1016/j.jtemb.2018.02.001. PMID 29449107. S2CID 46779191.
  24. ^ Pavlov AK, Kalinin VL, Konstantinov AN, Shelegedin VN, Pavlov AA (2006). "Was Earth ever infected by martian biota? Clues from radioresistant bacteria" (PDF). Astrobiology. 6 (6): 911–918. Bibcode:2006AsBio...6..911P. CiteSeerX 10.1.1.491.6308. doi:10.1089/ast.2006.6.911. PMID 17155889. Archived from the original (PDF) on 2008-12-17. Retrieved 2008-02-01.
  25. ^ Krishna Ramanujan (October 19, 2009). "Research reveals key to world's toughest organism". Physorg.com.
  26. ^ Mattimore V, Battista JR (1 February 1996). "Radioresistance of Deinococcus radiodurans: functions necessary to survive ionizing radiation are also necessary to survive prolonged desiccation". Journal of Bacteriology. 178 (3): 633–637. doi:10.1128/jb.178.3.633-637.1996. PMC 177705. PMID 8550493.
  27. ^ Goyal K, Walton LJ, Tunnacliffe A (2005). "LEA proteins prevent protein aggregation due to water stress". Biochemical Journal. 388 (Pt 1): 151–157. doi:10.1042/BJ20041931. PMC 1186703. PMID 15631617.
  28. ^ Battista JR, Park MJ, McLemore AE (2001). "Inactivation of two homologues of proteins presumed to be involved in the desiccation tolerance of plants sensitizes Deinococcus radiodurans R1 to desiccation". Cryobiology. 43 (2): 133–139. doi:10.1006/cryo.2001.2357. PMID 11846468.
  29. ^ Farci D, Slavov C, Tramontano E, Piano D (2016). "The S-layer Protein DR_2577 Binds Deinoxanthin and under Desiccation Conditions Protects against UV-Radiation in Deinococcus radiodurans". Frontiers in Microbiology. 7: 155. doi:10.3389/fmicb.2016.00155. PMC 4754619. PMID 26909071.
  30. ^ Farci D, Slavov C, Piano D (2018). "Coexisting properties of thermostability and ultraviolet radiation resistance in the main S-layer complex of Deinococcus radiodurans". Photochem Photobiol Sci. 17 (1): 81–88. Bibcode:2018PcPbS..17...81F. doi:10.1039/c7pp00240h. PMID 29218340. S2CID 4343655.
  31. ^ Brim H, McFarlan SC, Fredrickson JK, Minton KW, Zhai M, Wackett LP, Daly MJ (2000). "Engineering Deinococcus radiodurans for metal remediation in radioactive mixed waste environments" (PDF). Nature Biotechnology. 18 (1): 85–90. doi:10.1038/71986. PMID 10625398. S2CID 28531. Archived from the original (PDF) on 2015-04-02. Retrieved 2013-02-07.
  32. ^ Appukuttan, Deepti; Rao, Amara Sambasiva; Apte, Shree Kumar (December 2006). "Engineering of Deinococcus radiodurans R1 for Bioprecipitation of Uranium from Dilute Nuclear Waste". Applied and Environmental Microbiology. 72 (12): 7873–7878. Bibcode:2006ApEnM..72.7873A. doi:10.1128/AEM.01362-06. PMC 1694275. PMID 17056698.
  33. ^ Kulkarni, Sayali; Ballal, Anand; Apte, Shree Kumar (15 November 2013). "Bioprecipitation of uranium from alkaline waste solutions using recombinant Deinococcus radiodurans". Journal of Hazardous Materials. 262: 853–861. doi:10.1016/j.jhazmat.2013.09.057. PMID 24140537.
  34. ^ Slade, Dea; Radman, Miroslav (2011). "Oxidative Stress Resistance in Deinococcus radiodurans". Microbiology and Molecular Biology Reviews. 75 (1): 133–191. doi:10.1128/MMBR.00015-10. PMC 3063356. PMID 21372322.
  35. ^ Rew, D. A (1 August 2003). "Deinococcus radiodurans". European Journal of Surgical Oncology (EJSO). 29 (6): 557–558. doi:10.1016/S0748-7983(03)00080-5. PMID 12875865.
  36. ^ Kulkarni, Rasika R; Shaiwale, Nayana S; Deobagkar, Dileep N; Deobagkar, Deepti D (29 January 2015). "Synthesis and extracellular accumulation of silver nanoparticles by employing radiation-resistant Deinococcus radiodurans, their characterization, and determination of bioactivity". International Journal of Nanomedicine. 10: 963–974. doi:10.2147/IJN.S72888. PMC 4321572. PMID 25673991.
  37. ^ Li, Jiulong; Li, Qinghao; Ma, Xiaoqiong; Tian, Bing; Li, Tao; Yu, Jiangliu; Dai, Shang; Weng, Yulan; Hua, Yuejin (9 November 2016). "Biosynthesis of gold nanoparticles by the extreme bacterium Deinococcus radiodurans and an evaluation of their antibacterial properties". International Journal of Nanomedicine. 11: 5931–5944. doi:10.2147/IJN.S119618. PMC 5108609. PMID 27877039.
  38. ^ Craig Venter's TED talk (February 2005) mentions D. radiodurans as the ultimate genome assembly machine
  39. ^ McDowell, Natasha (2003-01-08). "Data stored in multiplying bacteria". New Scientist. Retrieved 2011-04-01.
  40. ^ a b Cooper, Keith (25 October 2022). "Extremophiles on Mars could survive for hundreds of millions of years". Space.com. Retrieved 28 October 2022.
  41. ^ Horne, William H.; Volpe, Robert P.; Korza, George; DePratti, Sarah; Conze, Isabel H.; Shuryak, Igor; Grebenc, Tine; Matrosova, Vera Y.; Gaidamakova, Elena K.; Tkavc, Rok; Sharma, Ajay; Gostinčar, Cene; Gunde-Cimerman, Nina; Hoffman, Brian M.; Setlow, Peter; Daly, Michael J. (25 October 2022). "Effects of Desiccation and Freezing on Microbial Ionizing Radiation Survivability: Considerations for Mars Sample Return". Astrobiology. 22 (11): 1337–1350. Bibcode:2022AsBio..22.1337H. doi:10.1089/ast.2022.0065. eISSN 1557-8070. ISSN 1531-1074. PMC 9618380. PMID 36282180.

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