Water expands when it freezes. Anyone who has ever left a can of pop or bottle of water in the freezer too long has witnessed this first hand. The water in living cells will do the same. Instead of exploding the ice crystals in cells bust out of the cells causing massive cellular damage (frost bite). So how do plants and animals survive sub-freezing temperatures? If you are warm blooded (like us humans) you use your mitochondria to produce energy (and heat) from the food you eat, but what if you are an insect?
Insects exposed to subzero temperatures can adapt to the extreme climate to survive freezing temperatures, but until now, antifreeze molecules had not been isolated from freeze-tolerant animals. The NSF-supported study, published in the November 24 issue of Proceedings of the National Academy of Sciences, describes a brand new type of antifreeze molecule isolated from a freeze-tolerant Alaskan beetle by Kent Walters and colleagues at the University of Notre Dame.
Interestingly, the antifreeze molecule described by the research team differs from previously described factors in that it is not a protein, but a combination of saccharides and fatty acids, which are other types of biomolecules. What does that mean? Size is one big difference. The exact size of this particular molecule is unknown, but the fact that it is small could prove beneficial. The chemical composition of the molecule could prove amenable to commercial production because small chains of sugars can be readily synthesized in the laboratory, making them cheaper and easier to manufacture than biologically assembled molecules.
Antifreeze molecules are present in many organisms including fish, insects, plants, fungi and bacteria. “The most active known antifreeze proteins had been described in freeze-avoiding insects, allowing certain insects to survive temperatures below -60 C (-76 F)” said Walters. However, this is the first reported isolation of antifreeze from a freeze-tolerant insect (those able to survive freezing).
One reason is that the antifreeze molecules are not always present. Dropping temperatures serve as a signal that the insects respond to by activating a host of adaptive responses including expression of antifreeze molecules. Researchers can artificially stimulate this response by conditioning the insects before they perform experiments.
Ever read a scifi story about people who freeze themselves for the long journey between the stars? These small beetles may hold the secret to that future. Current methods used to cryopreserve tissues result in low viability after thaw, in part because existing solutes must be used at concentrations that are often toxic to cells or tissues. Basically the current methods use nasty chemicals to avoid the damage done from freezing, that are deadly to the flesh being frozen. Out of the pan into the fire so to speak, if the pan and fire where really really cold. Because the new antifreeze molecule exhibits activity at relatively low concentrations in insects, it is possible researchers may be able to use them at low concentrations in the lab too.
According to Walters, “Potential applications for this new class of antifreeze molecules are abundant. In terms of cryopreservation, we may be able to increase viability and enhance survivorship of cells and tissues from other organisms under freezing conditions.”