Photo courtesy of University of VirginiaA hugely destructive plant virus so flexible that it has resisted efforts to describe its form since before World War II has finally surrendered its secrets. The discovery of what makes the bendy bug so malleable will revolutionize the efforts to stop such flexible plant viruses – and the billions in crop loss they cause every year – and may even lead to a new vehicle for delivering vaccines in humans.
Yet Egelman has done just that, revealing the shape and form of the bamboo mosaic virus with the assistance of U.Va.’s mighty Titan Krios microscope, buried beneath Fontaine Research Park. The discovery lets scientists examine just how the viruses can maintain their integrity as they bend and flex. Such filamentous viruses are responsible for more than half the viral crop damage throughout the world.
Efforts to stop the viruses have been undermined by a lack of understanding of their elusive design. The viruses are far too small to be seen with a traditional light microscope and so flexible that they have resisted efforts to create high-quality models of them via crystallography, the use of X-rays to determine structure at the atomic level.
But the bamboo mosaic virus could not escape the scrutiny of the Titan Krios electron microscope, a machine so sensitive that it is buried underground, encased within tons of concrete, to prevent even the smallest of vibrations from disrupting its work.
(This is a second victory for Egelman and the Titan in quick succession: Earlier this year, Egelman, of the Department of Biochemistry and Molecular Genetics, attracted national attention after he used the microscope to reveal the form of a bizarre virus that can live in nearly boiling acid.)
Now that the bamboo mosaic virus has been described, researchers can examine its structure to determine how best to stop it and others like it. And they may even be able to harness the virus to stop other diseases. Because the bamboo mosaic virus is harmless to humans, scientists may be to saddle it up to deliver vaccines in people.
“We eat these every day, large quantities of them. Things like cucumbers and potatoes have these viruses, so we have overwhelming amounts of evidence they’re not toxic. This means they can be used for platforms for vaccines, precisely because they’re nontoxic,” Egelman said. “But all this work has been hampered because no one has known the structure of them. Knowing the structure is the prerequisite to being able to manipulate them and design new features.”
The discovery earned the cover of the scientific journal Nature Structural & Molecular Biology. The authors of the article detailing the findings were Frank DiMaio of the University of Washington in Seattle; Chun-Chieh Chen of Taiwan; Xiong Yu of U.Va.; Brandon Frenz of the University of Washington; Yau-Heiu Hsu of Taiwan; Na-Sheng Lin of Taiwan; and Egelman.
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