Several functions have been proposed for prions during the past couple of decades, but none has survived close scrutiny. "The first mouse with knocked-out prion genes was made back in 1991," says Adriano Aguzzi at the University Hospital of Zurich in Switzerland, who led the new work. "We leapt on it, and studied it in every way we could think of — but never managed to find any obvious sign that lack of the prion was causing it harm." In fact, at first glance, lack of prions seemed like a good thing because it made mice immune to prion infection. But four years ago, Aguzzi started to think again about a generally overlooked 1999 paper by researchers in Japan that suggested the lack of prion protein caused the degeneration and demyelination of nerves outside the brain. He decided to undertake a thorough and systematic analysis of prions' effects on such peripheral nerves. Together with his colleagues, he studied four different strains of mice lacking the gene for the prion PrPC. In every mouse they tested, regardless of strain, they found early evidence of myelin damage just six weeks after birth. By the age of two months, the nerves were extensively demyelinated, and the mice had become more sensitive to pain.
"Because there is no myelin damage at birth, we assumed prions are needed to maintain the quality of the myelin sheath, which diminishes throughout life," says Aguzzi. Accordingly, when the researchers re-introduced prion proteins specifically into nerves, the demyelination did not occur. Curiously, however, only variants of prion proteins susceptible to cleavage by enzymes were effective. But no variant of prion protein was able to prevent demyelination when introduced specifically into the Schwann cells that surround and support peripheral nerve cells. "This surprised us," says Aguzzi, "since Schwann cells actually do the job of manufacturing fresh myelin." Aguzzi concludes that when nerves' sheathes are suffering wear and tear, the nerves enzymatically cleave their prion proteins, releasing fragments that travel to Schwann cells, where they signal activation of myelin repair. He also has a hunch, supported by preliminary data, that prion proteins will turn out to play the same part in supporting myelination in the brain. "So it is going to be interesting to see if prions play any role in demyelinating diseases that stem from the brain," he says. "Treatment of CJD targets prion proteins, which are assumed to be doing the damage," says Mead. "But if CJD did indeed turn out to be caused by absence of prions, then we would have to rethink this therapeutic approach."
Nature
February 23, 2010
Original web page at Nature
