New Antibiotics Take Poke at Bacteria.Imagine a roll of LifeSavers. Now, mentally shrink that stack of candy rings to a few nanometers in length, making it smaller than a cell. That image offers a sense of the unusual structure behind a potential new class of antibiotics developed by M. Reza Ghadiri M. Reza Ghadiri (born in Iran) is an Iranian (persian) chemist and a world expert on nano scale sciences. Ghadiri holds a Ph.D. degree in chemistry (1987) from the University of Wisconsin-Madison. He is currently a Prof of chemistry at The Scripps Research Institute. 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., and his colleagues. In the July 26 NATURE, the investigators report that their nanotubes swiftly kill a wide range of bacteria in both test tubes and animals. The structures helped mice stave off normally lethal bacteria that are resistant to a traditional antibiotic, the Scripps researchers found. At the structural heart of the drugs are rings, called cyclic peptides, that are composed of either six or eight amino acids. Under the proper conditions, such as within bacterial membranes, these rings assemble into hollow tubes. The tubes punch holes in the membranes, quickly killing the microbes. The tube-forming rings, dubbed nanobiotics, combine the natural and the unnatural, says Ghadiri. Every amino acid can come in two forms, one the mirror image of the other. The left-handed, or L, version occurs naturally, but scientists can synthesize the right-handed, or D, counterpart. By alternating D and L amino acids, Ghadiri's team synthesized short strings of amino acids that form into stable rings, which, in turn, can interlock A device that prohibits an action from taking place. with each other into stacks. "It's a very clever structure that advances the field significantly," says Tomas Ganz of the University of California, Los Angeles UCLA comprises the College of Letters and Science (the primary undergraduate college), seven professional schools, and five professional Health Science schools. Since 2001, UCLA has enrolled over 33,000 total students, and that number is steadily rising. , who studies antimicrobial peptides Antimicrobial peptides (also called host defence peptides) are an evolutionarily conserved component of the innate immune response and are found among all classes of life. . The choice of amino acids determines the conditions in which the rings stick together. By using positively charged Adj. 1. positively charged - having a positive charge; "protons are positive" electropositive, positive charged - of a particle or body or system; having a net amount of positive or negative electric charge; "charged particles"; "a charged battery" amino acids, Ghadiri's team made the nanotubes assemble only in the negatively charged Adj. 1. negatively charged - having a negative charge; "electrons are negative" electronegative, negative charged - of a particle or body or system; having a net amount of positive or negative electric charge; "charged particles"; "a charged battery" membranes of bacteria. Within the neutral membranes of mammalian cells, no assembly should occur. In test-tube experiments, Ghadiri's team found that nanobiotics can kill a variety of disease-causing bacteria while leaving red blood cells Red blood cells Cells that carry hemoglobin (the molecule that transports oxygen) and help remove wastes from tissues throughout the body. Mentioned in: Bone Marrow Transplantation red blood cells unharmed. Without obvious side effects Side effects Effects of a proposed project on other parts of the firm. , the nanotubes protected animals infected with an antibiotic-resistant strain of Staphylococcus aureus Staphylococcus au·re·us n. A bacterium that causes furunculosis, pyemia, osteomyelitis, suppuration of wounds, and food poisoning. Staphylococcus aureus Staphylococcus pyogenes . Each year, such bacteria infect more than 2 million hospital patients in the United States. Ghadiri suggests that membrane-destroying drugs, such as his nanobiotics, may be more difficult for bacteria to defeat than current antibiotics. Those drugs typically target a specific molecule within bacteria. Microbes eventually develop resistance by altering the shape of the targeted molecule or by somehow keeping the drugs away from it. "Our hope is that this class [of antibiotics] would have a longer longevity," says Ghadiri. "The bacteria have to do more to become resistant." What's more, he adds, by changing amino acids in the peptide rings, scientists can create countless variations on the nanobiotics and further delay resistance. Although his team so far has used only injections to administer the peptides, Ghadiri is optimistic that the compounds can be delivered in pills. At this point, however, Ghadiri says he and his colleagues have done about as much as they can to establish the promise of their peptides. Ganz agrees, adding that to become drugs, the compounds need testing and development far beyond the means of a single research team. "We'd be delighted to work with the pharmaceutical or biotech industry," says Ghadiri. "These are relatively small molecules that can be synthesized very easily, very quickly, and on large scales." If the bacteria-thwarting nanotubes ever do make it to pharmacy shelves, they'll seem like LifeSavers in more ways than one. |
|
||||||||||||||||||||
Printer friendly
Cite/link
Email
Feedback
Reader Opinion