Yeast adds new amino acids to its proteins.With only ram exceptions, every organism constructs proteins from just 20 building blocks called amino acids. Recently, however, researchers modified Escherichia coli Escherichia coli (ĕsh'ərĭk`ēə kō`lī), common bacterium that normally inhabits the intestinal tracts of humans and animals, but can cause infection in other parts of the body, especially the urinary tract. bacteria so that the single-celled organisms also make an alien amino acid and incorporate it into proteins (SN: 1/25/03, p. 53). Now, the same scientists have used genetic engineering techniques to coerce more-complicated organisms into placing unnatural amino acids into proteins. Led by Peter G. Schultz of the Scripps Research Institute in La Jolla La Jolla (lə hoi`yə), on the Pacific Ocean, S Calif., an uninc. district within the confines of San Diego; founded 1869. The beautiful ocean beaches, in particular La Jolla shores and Black's Beach, and sea-washed caves attract visitors and , Calif., the team created yeast cells that add one of five unnatural amino acids to their natural 20-piece construction set. To give the yeast this capability, the researchers altered the cells' biochemical machinery that identifies amino acids and puts them into particular locations within a protein. Unlike the E. coli E. coli: see Escherichia coli. E. coli in full Escherichia coli Species of bacterium that inhabits the stomach and intestines. E. coli can be transmitted by water, milk, food, or flies and other insects. on which the team previously reported, the yeast doesn't manufacture synthetic amino acids itself. Instead, it takes the molecules up from the nutrient mixture in which it's grown. The researchers describe this work on Saccharomyces Saccharomyces: see yeast. cerevisiae in the Aug. 15 Science. The Scripps team suggests that scientists could use this technology to produce proteins with new or enhanced properties. For example, improved drugs might result. The development may also improve the study of protein function in yeast, the scientists report. The unnatural amino acids used by the engineered yeast have various useful properties, says Scripps team member T. Ashton Cropp. For example, when activated by light, two of these amino acids bond proteins together, a function that could prove valuable in studies of protein interactions. Another of the novel amino acids might help researchers using X-ray crystallography studies to elucidate protein structure. "It is another brilliant achievement from the Schultz group," says Jack F. Kirsch kirsch n. A colorless brandy made from the fermented juice of cherries. [French, short for German Kirschwasser; see kirschwasser. of the University of California, Berkeley The University of California, Berkeley is a public research university located in Berkeley, California, United States. Commonly referred to as UC Berkeley, Berkeley and Cal . "The potential applications are endless." "This technology will be very powerful and very useful," agrees Hung-wen (Ben) Liu of the University of Texas at Austin “University of Texas” redirects here. For other system schools, see University of Texas System. The University of Texas at Austin (often referred to as The University of Texas, UT Austin, UT, or Texas . He says he hopes the Scripps team will make the technology available to other scientists or basic biological investigations. The method should also work on organisms even more complex than yeast, says the study's lead author, Jason W. Chin, who is now at the Medical Research Council Laboratory of Molecular Biology The Laboratory of Molecular Biology (or LMB) is a research institute in Cambridge, England, which was at the forefront of the revolution in molecular biology which occurred in the 1950-60s. Since then it remains a major medical research laboratory with a much broader focus. in Cambridge, England. That's because yeast contain protein-building machinery that's similar to that in multicellular organisms, from peas to people. Yeast cells and those of the more complex organisms are classified as eukaryotes because, unlike bacteria, they contain distinct nuclei and organelles. In fact, says Cropp, the team has already begun experiments in which it's trying to get human cells to use unnatural amino acids when making proteins. |
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