The Antarctic midge (a sort of small fly) is the largest fully terrestrial animal on the continent of Antarctica. At 7-8 mm long, it may not seem as impressive as an elephant, or even a house cat, but as an endemic resident of the Antarctic peninsula, it has to live in conditions that would kill most other "big game".
The midge is flightless, which probably helps it stay put during the high winds that can buffet the area. It can withstand being frozen, and nearly complete dehydration (just add water and it pops back).
Their lifespan is about two years - all but the last ten days are spent as a juvenile. Those last ten days are important, though. In that time they must find a mate and have eggs laid for the next generation.
Molecular Biology and Genetics
Barcode data: Belgica antarctica
No available public DNA sequences.
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Statistics of barcoding coverage: Belgica antarctica
Public Records: 69
Specimens with Barcodes: 69
Species With Barcodes: 1
Belgica antarctica, the Antarctic midge, is a species of flightless midge, endemic to the continent of Antarctica. At 2–6 mm (0.079–0.236 in) long, it is the largest purely terrestrial animal on the continent, as well as its only insect.  It also has the smallest known insect genome as of 2014, with only 99 million base pairs of nucleotides (and about 13,500 genes).
The flightlessness of B. antarctica may be an adaptation to prevent wind from blowing it into inhospitable sites. It can survive the freezing of its body fluids and has a lifespan of two years; with the two growing seasons, it is able to accumulate the energy needed to reproduce. With its deep purplish black coloration it is able to absorb heat to survive. It is also able to tolerate large changes in salinity and pH and can survive without oxygen for 2–4 weeks.
Tolerance to extreme conditions
B. antarctica can survive freezing, but despite air temperatures reaching as low as -40°C, it dies below temperatures of -15°C. This is less than other cold-adapted insects. The reason for this comparatively low freezing tolerance is due to thermal buffering: just burrowing at a depth of 1 cm, temperature is stable between 0 and -2°C for 10 months out of 12, and it seldom goes lower than -7°C all year round. Ice and snow cover also helps keeping the temperature stable. Freezing tolerance is enhanced by cold hardening.
To adapt to the cold temperatures, B.antarctica accumulates trehalose, glucose, and erythritol. These compounds help the insect survive freezing by reducing the amount of ice that forms within the body. They also stabilize proteins and membranes, binding to them by means of hydrogen bonds. Heat shock proteins also help the tolerance to both high and low temperatures.
B.antarctica not only tolerates, but also requires a freezing climate to survive: exposure of larvae to mild temperatures as +10°C is enough to kill them within a week. Exposure to temperatures of +30°C kills individuals in a few hours. It can, however, resist partial desiccation, surviving the loss of up to 70% of body water.
B. antarctica spends most of its two-year lifecycle in four larval stages. Overwintering may occur in any instar. Terrestrial algae, particularly Prasiola crispa, moss, organic detritus, and microorganisms provide the food for the larval stage. The adults emerge in the spring and summer and live no more than 10 days; females mate in their first day of life and a few days later release eggs. Mating occurs in large groups of males, analogous to swarms of winged midges.
- Usher, Michael B.; Edwards, Marion (1984). "A dipteran from south of the Antarctic Circle: Belgica antarctica (Chironomidae) with a description of its larva". Biological Journal of the Linnean Society 23 (1): 19–31. doi:10.1111/j.1095-8312.1984.tb00803.x.
- Luke Sandro & Juanita Constible. "Antarctic Bestiary — Terrestrial Animals". Laboratory for Ecophysiological Cryobiology, Miami University. Archived from the original on 23 December 2008. Retrieved December 9, 2008.
- Kelley, Joanna L.; Peyton, Justin T.; Fiston-Lavier, Anna-Sophie; Teets, Nicholas M.; Yee, Muh-Ching; Johnston, J. Spencer; Bustamante, Carlos D.; Lee, Richard E.; Denlinger, David L. (2014). "Compact genome of the Antarctic midge is likely an adaptation to an extreme environment". Nature Communications 5. doi:10.1038/ncomms5611. ISSN 2041-1723.
- "Antarctic midge has smallest insect genome". BBC. 2014-08-12. Retrieved 2014-08-12.
- Lee, R. E.; Elnitsky, M. A.; Rinehart, J. P.; Hayward, S. A.; Sandro, L. H.; Denlinger, D. L. (2006). "Rapid cold-hardening increases the freezing tolerance of the Antarctic midge Belgica antarctica". Journal of Experimental Biology 209 (3): 399–406. doi:10.1242/jeb.02001. PMID 16424090.
- Robert Michaud, M.; Benoit, J. B.; Lopez-Martinez, G.; Elnitsky, M. A.; Lee, R. E.; Denlinger, D. L. (2008). "Metabolomics reveals unique and shared metabolic changes in response to heat shock, freezing and desiccation in the Antarctic midge, Belgica antarctica". Journal of Insect Physiology 54 (4): 645–655. doi:10.1016/j.jinsphys.2008.01.003. PMID 18313070.
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