Freeze! Insect proteins halt ice growth.In cold climates, cars often need an infusion of antifreeze antifreeze, substance added to a solvent to lower its freezing point. The solution formed is called an antifreeze mixture. Antifreeze is typically added to water in the cooling system of an internal-combustion engine so that it may be cooled below the freezing point to survive the winter. Many fish, insects, and plants are no different, but they produce their own protection--proteins that prevent their insides from turning to ice. Scientists have studied fish antifreeze since the 1960s, but now researchers from Queen's University in Kingston, Ontario, have isolated and analyzed antifreeze proteins from insects. Virginia K. Walker, Peter L. Davies, and their colleagues collected the proteins from the spruce budworm, which is a moth larva, and from the common mealworm mealworm see alphitobius diaperinus. yellow mealworm see tenebrio molitor. , a pest that feeds on grain. The budworm bud·worm n. A larva of several tortricid moths, especially the spruce budworm, that devours plant buds. protein is up to 30 times more potent than fish proteins, and the mealworm, protein is up to 100 times stronger, the group reports in the September Nature Biotechnology and the Aug. 21 Nature respectively. "These are some of the most active antifreezes we have encountered so far," says Choy L. Hew, a biochemist at the University of Toronto Research at the University of Toronto has been responsible for the world's first electronic heart pacemaker, artificial larynx, single-lung transplant, nerve transplant, artificial pancreas, chemical laser, G-suit, the first practical electron microscope, the first cloning of T-cells, who studies fish antifreeze proteins. Collecting enough protein from larvae was quite a feat, he adds. If put in frozen foods, fish antifreeze proteins could help prevent ice from recrystallizing, as it does, for example, in ice cream left in the freezer too long. Scientists are also exploring the use of antifreeze proteins in preserving organs and tissues for transplants (SN: 3/21/92, p. 189). The greater potency of the insect proteins suggests that they could be used in lower concentrations, says Laurie A. Graham, a coauthor of the Nature study. Unlike conventional antifreezes, such as the ethylene glycol commonly used in cars, the proteins create a phenomenon called thermal hysteresis: They lower the freezing point of water below 0 [degrees] C without changing the temperature at which ice melts as it is heated. The insect proteins lower the freezing point a maximum of 5.5 [degrees] C. No one knows exactly how the insect antifreeze proteins work, but they seem to bind to to contract; as, to bind one's self to a wife s>. See also: Bind the surface of tiny ice crystals and inhibit their growth, Graham says (SN: 11/26/86, p. 330). The proteins contain many repeated sequences of the amino acids serine, threonine threonine (thrē`ənēn), organic compound, one of the 22 α-amino acids commonly found in animal proteins. Only the l-stereoisomer appears in mammalian protein. , glycine glycine (glī`sēn), organic compound, one of the 20 amino acids commonly found in animal proteins. Glycine is the only one of these amino acids that is not optically active, i.e. , and cysteine cysteine (sĭs`tēn), organic compound, one of the 20 amino acids commonly found in animal proteins. Only the l-stereoisomer participates in the biosynthesis of mammalian protein. . The arrangement of these hydrophilic hydrophilic /hy·dro·phil·ic/ (-fil´ik) readily absorbing moisture; hygroscopic; having strongly polar groups that readily interact with water. hy·dro·phil·ic adj. , or water-loving, amino acids may match well the arrangement of water molecules in ice. Determining the three-dimensional structure of the proteins will provide more clues to how they work, says Hew. "We have solved the structure for fish antifreeze, so we know how it binds to ice, but it doesn't mean that the insect ones will bind in the same manner." The Queen's University group does know that the insect proteins affect the growth of ice crystals differently than fish proteins do, says Daniel Doucet, a coauthor of the Nature Biotechnology study. Ice crystals grown in the presence of the fish protein form pointy spicules with sharp edges. Grown with the budworm protein, however, the ice crystals look like smooth, hexagonal disks, which would cause less damage to cells preserved with antifreeze, he suggests. |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion