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Deinococcus frigens is a species of low temperature and drought-tolerating, UV-resistant bacteria from Antarctica. It is Gram-positive, non-motile and coccoid-shaped. Its type strain is AA-692. Individual Deinococcus frigens range in size from 0.9-2.0 μm and colonies appear orange or pink in color. Liquid-grown cells viewed using phase-contrast light microscopy and transmission electron microscopy on agar-coated slides show that isolated D. frigens appear to produce buds. Comparison of the genomes of Deiococcus radiodurans and D. frigens have predicted that no flagellar assembly exists in D. frigens.

Discovery
Deinococcus frigens was discovered in 2004 by Peter Hirsch, a researcher at the Institute for General Microbiology of the Christian-Albrechts-University Kiel, in soil samples gathered from the ice-free McMurdo Dry Valleys of Continental Antarctica. Whether D. frigens can be found in other areas of the Antarctic is currently unknown. The soil sample containing D. frigens was collected from the top 0-4 cm of soil at pH 6.3. To enrich for certain bacteria, the soil sample was added to PYGV medium and incubated at 9°C and pH 8.0. PYGV is a media containing peptone, yeast, and glucose at low concentrations, first used to culture freshwater bacteria that could survive oligotrophic conditions, or low amounts of nutrients. To isolate and cultivate these bacteria, enrichment samples taken at various time intervals were streaked on PYGV plates, where individual colonies could be subcultured onto PYGV slants.

Taxonomy
Deinococcus frigens is an extremophilic, gram-positive cocci bacterium. The Deinococcus genus is generally known for its resistance to very large doses of radiation, and the species D. frigens is no exception. The species designation “frigens” refers to the harsh, cold climate of Antarctica where this microbe is found. It is situated in a small clade of the Deinococcus genus that also includes two other species found in the area: Deinococcus saxicola and Deinococcus marmoris. Using 16s rRNA sequencing as a basis of comparison, D. frigens has been found to have a 97.3% similarity with D. saxicola and a 96.6% similarity to D. marmoris. The closest relative to these three more recently-discovered species is Deinococcus radiopugnans, which has a genome with a 96.1% similarity. The full scientific classification of this species is Kingdom Bacteria, Phylum Deinococcus-Thermus, Class Deinococci, Order Deinococcales, Family Deinococcaceae, Genus Deinococcus, Species D. frigens.

Genome
DNA sequences from six isolates found in the McMurdo Valley were determined by extraction of the genomic DNA, PCR amplification of the 16S rDNA, and analysis of the PCR product sequences. To determine their phylogenetic positions, these isolated sequences were subjected to genetic comparative analysis. Using sequence databases, these six isolates were shown to all be related to the Deinococcus lineage; however, they form three coherent clusters, separate from other Deinococcus species. DNA-DNA similarity data, obtained using the DNA hybridization technique, shows that these three clusters represented three new species of Deinococcus, and were given the names D. frigens, D. saxicola, and D. marmoris. D. frigens has 2,015,889 base pairs in its DNA with a GC-content of 65.5% and 3,987 genes coding for proteins. This high GC-content contributes to the thermal tolerance of this bacteria, and such adaptations have led D. frigens to be dubbed "extremo-tolerant." According to the KEGG database, within its genome, D. fringens contains genes which encode for sulfate reduction, no apparent pathogenicity, and utilizes a two-component chemotaxis system.

Growth Conditions
Deinococcus species such as these are well known for being some of the most resilient bacteria discovered on Earth. Deinococcus frigens is in many ways similar to other microbes of the Deinococcus genus, but with a several adaptations that allow it to live in the extreme environment of the Antarctic- an area characterized by heavy, incessant winds, droughts, and severely cold winters. D. frigens is aerobic to facultatively anaerobic allowing it to survive in topsoil, and it is able to hydrolyze glucose, acetate, and casein for use as carbon sources. Additionally, this species grows at low temperatures, ranging from 1-21°C, which was determined by placing test tubes containing isolates into an aluminum block that produced a range of temperatures from 0-40°C. D. frigens can tolerate growth in up to 10% NaCl and can grow in pH ranging from 3.8-8.7. To determine ideal NaCl concentration and pH levels for growth, isolated samples were placed into several PYGV plates where various amounts of NaCl, ranging from 1-20% weight by volume, and 0.05 g*1-1 phosphate buffer were added respectively. D. frigens is also resistant to UV radiation. By placing samples of D. frigens at various distances, 8-12cm, from a 254nm UV lamp, the bacterial growth under UV conditions could then be measured over 4-20 minute time periods.

Relevance
These extremo-tolerant characteristics make D. frigens a candidate for further study in areas as diverse as cancer, aging, and microbiology in space. Because of their hardy nature and extreme characteristics, Deinococcus species are often used as model organisms for oncological and aging studies. Their ability to combat oxidative stress and the formation of carcinogenic reactive oxygen species may be the vital key in future endeavors for anti aging research and anticancer treatments. The psychrophilic, or thriving in cold temperatures, nature of D. frigens is also of interest to humanity. Psychrophiles’ ability to survive in extremely cold environments may potentially be studied by astrophysicists trying to unlock the key to exploring frozen environments within our solar system. Indeed, the field of "astrobiology” seeks to explore life within the upper atmosphere of Earth. Psychrophiles in the atmosphere have been found living at the very interface between water and ice, and new species, such as Colwellia psychrerythraea have been discovered as a result of this research. Psychrophilic bacteria have also been shown to contain unique lipids and membrane structures which help add stability to the membrane of the cells. In general, microorganisms from the Antarctic are used as model organisms for studying methods and tools of adaptation to extremely cold temperatures.