Mammalian ear cells can regenerate.The cells responsible for hearing in mammals The class Mammalia (the Mammals) is divided into two subclasses based on reproductive techniques: egg laying mammals (the Monotremes); and mammals which give live birth. The latter subclass is divided into two infraclasses: pouched mammals (the marsupials); and the placental mammals. are capable of regeneration, a study indicates. The surprising finding could lead to new treatments for hearing loss, say researchers. In birds and other vertebrates, inner-ear sensory, cells called hair cells Hair cells Sensory receptors in the inner ear that transform sound vibrations into messages that travel to the brain. Mentioned in: Cochlear Implants quickly re-grow after they're damaged or destroyed. The regeneration takes place when cells that support each hair cell divide to produce a new hair cell and a new supporting cell. However, researchers have long considered mammalian mammalian emanating from or pertaining to mammals. hair cells irreplaceable. No study had ever shown that mature supporting cells in mammals could divide, much less differentiate into new hair cells (SN.5/20/06, p. 311). Trying a new tactic, Andrew Groves
Dr. Andrew Stephen Grove (born 1936-09-02) is a Hungarian-American businessman. He participated in the founding of Intel and was key to the company's success. of the House Ear Institute in Los Angeles Los Angeles (lôs ăn`jələs, lŏs, ăn`jəlēz'), city (1990 pop. 3,485,398), seat of Los Angeles co., S Calif.; inc. 1850. and his colleagues isolated supporting cells from the inner ears of newborn newborn /new·born/ (noo´born?) 1. recently born. 2. newborn infant. new·born adj. Very recently born. n. A neonate. mice and put them in culture dishes. Within days, Groves' team noticed that about half the cells were dividing, and a significant portion of the new cells were growing into hair cells. Genetic tests showed that the dividing cells had switched off a gene known asp27, but the gene remained on in the nondividers. When the researchers performed the same experiment with cells taken from 2-week-old mice, they found that only about 2 percent of the supporting cells divided. This suggests that p27 becomes more firmly switched on with age, they report in June 22 Nature. However, when Groves and his colleagues tried the experiment with 2-week-old mice genetically, engineered to lack p27, about 10 per cent of the cells multiplied. If researchers could come up with a way to turn off p27 in the ear, they might induce hair cell growth in people who have lost these cells, says Groves. |
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