Untangling a protein's omega loops.Untangling a protein's omega loops The molecular backbones of globular proteins have an intricates structure. Segments of these chains may be coiled in the form of a helix or folded into parallel strands. The rest is sometimes classified as "random coil random coil A sequence of amino acids that has neither alpha-helical nor beta-sheet structure. Proteins consisting of alpha helixes or beta sheets are reduced to random coils upon denaturing. Compare alpha helixbeta sheet ," but generally, it is neither random nor coiled. Recently, Jacquelyn F. Leszcynski and George D. Rose of Pennsylvania State University's Milton S. Hershey Milton Snavely Hershey (September 13, 1857 – October 13, 1945) was an American businessman and philanthropist. He is famous for founding The Hershey Chocolate Company and the "company town" of Hershey, Pennsylvania. Medical Center in Hershey took a closer look at one group of random-coil segments often loosely described as "loops." Their systematic study reveals that compact loops, shaped like the Greek letter omega ([omega]), are common and may play an important role in the way protein molecules function. Their report appears in the Nov. 14 SCIENCE. For their computer-aided survey of 67 proteins with known structures, the researchers established three criteria for defining omega loops. Such segments contain between 6 and 16 amino acids amino acid (əmē`nō), any one of a class of simple organic compounds containing carbon, hydrogen, oxygen, nitrogen, and in certain cases sulfur. These compounds are the building blocks of proteins. , they have no other regular structure, and the distance across the gap where the loop necks is less than 10 angstroms. Leszczynski and Rose found 270 omega loops, abut To reach; to touch. To touch at the end; be contiguous; join at a border or boundary; terminate on; end at; border on; reach or touch with an end. The term abutting implies a closer proximity than the term adjacent. four per protein molecule. Only six of the msallest proteins studied have no loops. Most of the loops are highly compact because loop side-chain atoms appear to pack tightly within the loop core. Nearly always, the loops sit at the molecule's surface. These surface loops may be involved in processes like antibody binding or molecular recognition, the researchers say. If the loops function as integral units, they could be useful in bioengineering bioengineering Application of engineering principles and equipment to biology and medicine. It includes the development and fabrication of life-support systems for underwater and space exploration, devices for medical treatment (see experiments that involve "clipping (1) Cutting off the outer edges or boundaries of a word, signal or image. In rendering an image, clipping removes any objects or portions thereof that are not visible on screen. See scissoring. See also WCA. and swapping" protein segments. Such swapping processes may have occurred naturally as part of evolutionary change. |
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