If the key to winning battles is knowing both your enemy and yourself, then scientists are now well on their way toward becoming the Sun Tzus of medicine by taking a giant step toward a priceless advantage – the ability to see the soldiers in action on the battlefield.
A novel microfluidics platform allowed viewing of structural details of rotavirus double-layered particles; the 3-D graphic of the virus, in purple, was reconstructed from data gathered by the new technique. Credit: Virginia Tech
Investigators at the Virginia Tech Carilion Research Institute have invented a way to directly image biological structures at their most fundamental level and in their natural habitats. The technique is a major advancement toward the ultimate goal of imaging biological processes in action at the atomic level.
"It's sort of like the difference between seeing Han Solo frozen in carbonite and watching him walk around blasting stormtroopers," said Deborah Kelly, an assistant professor at the VTC Research Institute and a lead author on the paper describing the first successful test of the new technique. "Seeing viruses, for example, in action in their natural environment is invaluable."
The technique involves taking two silicon-nitride microchips with windows etched in their centers and pressing them together until only a 150-nanometer space between them remains. The researchers then fill this pocket with a liquid resembling the natural environment of the biological structure to be imaged, creating a microfluidic chamber.
Then, because free-floating structures yield images with poor resolution, the researchers coat the microchip's interior surface with a layer of natural biological tethers, such as antibodies, which naturally grab onto a virus and hold it in place.
In a recent study in Lab on a Chip, Kelly joined Sarah McDonald, also an assistant professor at the VTC Research Institute, to prove that the technique works.
McDonald provided a pure sample of rotavirus double-layered particles for the study.
"What's missing in the field of structural biology right now is dynamics – how things move in time," said McDonald. "Debbie is developing technologies to bridge that gap, because that's clearly the next big breakthrough that structural biology needs."
Rotavirus is the most common cause of severe diarrhea among infants and children. By the age of 5, nearly every child in the world has been infected at least once. And although the disease tends to be easily managed in the developed world, in developing countries rotavirus kills more than 450,000 children a year.
At the second step in the pathogen's life cycle, rotavirus sheds its outer layer, which allows it to enter a cell, and becomes what is called a double-layered particle. Once its second layer is exposed, the virus is ready to begin using the cell's own infrastructure to produce more viruses. It was the viral structure at this stage that the researchers imaged in the new study.
Kelly and McDonald coated the interior window of the microchip with antibodies to the virus. The antibodies, in turn, latched onto the rotaviruses that were injected into the microfluidic chamber and held them in place. The researchers then used a transmission electron microscope to image the prepared slide.
The technique worked perfectly.
The experiment gave results that resembled those achieved using traditional freezing methods to prepare rotavirus for electron microscopy, proving that the new technique can deliver accurate results.
"It's the first time scientists have imaged anything on this scale in liquid," said Kelly.
The next step is to continue to develop the technique with an eye toward imaging biological structures dynamically in action.
Specifically, McDonald is looking to understand how rotavirus assembles, so as to better know and develop tools to combat this particular enemy of children's health.
The researchers said their ongoing collaboration is an example of the cross-disciplinary work that is becoming a hallmark of the VTC Research Institute.
"It's an ideal collaboration because Sarah provides a phenomenal model system by which we can develop new technologies to move the field of microstructural biology forward," said Kelly.
"It's very win-win," McDonald added. "While the virus is a great tool for Debbie to develop her techniques, her technology is critical for allowing me to understand how this deadly virus assembles and changes dynamically over time."