BROWN (US) — How do prion proteins—the infectious agents in Mad Cow disease—become transmissible? A new study suggests size—not number— determines their efficiency in spreading.
“The dogma in the field was that the misfolding of the protein is sufficient to cause disease, and the clinical course of the infection depended on the amplification of the misfolded protein,” says Tricia Serio, associate professor of molecular biology, cell biology and biochemistry at Brown University.
“But over the years in mammals it has become clear that the abundance of misfolded protein is not a good predictor of disease progression. The question is, What else has to happen for you to get the clinical pathology?”
Cells make prion proteins naturally, although biologists do not understand what their normal role is in mammals. When those proteins misfold in cells, they assemble into structures called aggregates, but other proteins, known as chaperones, attempt to break down the aggregates.
The rates at which this assembly and disassembly occurs are determined by the shape or conformation that the prion protein has adopted.
“Different conformations of the same prion protein can dramatically alter the spread of pathology and the incubation time of prion diseases,” Serio says. “We wanted to learn how.”
By combining experiments in yeast cells with mathematical models, researchers found that what affects a prions’ ability to transmit from cell to cell is the size of the structures into which they assemble, Serio says. They report their findings in the journal Science.
If the aggregates become too large, they lose their transmissibility among cells. Prion aggregates that remain small are transmitted with greater efficiency.
“In this paper we changed the transmissibility just by shifting the size,” Serio says. “We could change it in either direction.”
The proof was plain to see. Postdoctoral researcher Aaron Derdowski monitored differently sized prion aggregates as they moved among cells under the microscope and could see that smaller ones fared better than larger ones. He also kept track of the spread of different prion structures through a genetic analysis of affected cell populations.
In concert with the experimental work, Suzanne Sindi, a postdoctoral researcher with a joint appointment in molecular biology, cell biology and biochemistry and the Center for Computational Molecular Biology, modeled how cells make and spread prion aggregates, providing a novel simulation of the process that she ran on a computing cluster.
The model that best replicated experimental observations was the one in which aggregate size, rather than abundance, was the key factor.
Implications for disease
Serio says the insights the team has gained in yeast may better explain what others have observed in mammals as well.
“Previously it was not clear why you would have those outcomes,” she says.
Ultimately the findings could inform future strategies for developing a treatment for prion infection. If researchers unaware of the importance of aggregate size developed a therapy to hinder prion aggregate formation, they might inadvertently make things worse by producing smaller aggregates, Serio notes.
“A more effective strategy might be to control the size of the aggregates,” she adds, “rather than their presence or absence.”
The findings may also relate to other neurodegenerative diseases that depend on misfolding proteins, such as Alzheimer’s disease or Parkinson’s disease, Serio says.
The National Institutes of Health funded the work.
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