New animation gives information on how viruses spread
How can an influenza virus transfer from animals to humans even though the molecules on which they land at the cell surface are different? To find out, researchers of the University of Twente developed a sensor chip that mimics the cell surface and has an increasing number of binding sites along the way. The virus rolls across the surface until the binding is strong enough. For visualizing and better understanding of the mechanisms involved, the researchers created an animation, together with Dutch veterinary lab Royal GD.
Influenza viruses like H5N8, which is rapidly emerging now, mainly come from wild birds. In many cases, the virus doesn't jump to humans, but of course, there are epidemics and even pandemics caused by a bird flu virus. Zoonosis, transfer from wild animals to humans, is often indirect. Chickens or pigs held in large numbers can accelerate the transfer.
Enough sugars to stick
Still, the sugars on the respective cell surfaces of animals and humans are not the same. It is these sugars to which the protein spikes on the virus surface connect. To find out the characteristics of the binding, the UT researchers developed a method called multivalent affinitiy profiling. They developed a special fluidic chip that has a varying concentration of sugars. A virus could bind only to one sugar molecule, but it will use more to strengthen the bond, encapsulate, and do its damaging work. If there aren't enough sugars nearby, the binding will be unsuccessful—the virus may leave the surface or start rolling along in the direction of the higher concentrations of sugars. This method has now been visualized in an animation for gaining better insight in zoonosis. It is made specifically for understanding influenza A viruses, but also reveals more about corona and other types of viruses.
The animation is bases on years of scientific work by the Molecular Nanofabrication group of Prof Jurriaan Huskens, together with a multidisciplinary team of nanotechnologists, virologists and drug specialists. The most recent publication is "Multivalent Affinity Profiling: direct visualization of the superselective binding of influenza viruses" in ACS Nano.