Abstract
The envelope of the influenza virus undergoes extensive structural change during the viral life cycle. However, it is unknown how lipid and protein components of the viral envelope contribute to its mechanical properties. Using atomic force microscopy, here we show that the lipid envelope of spherical influenza virions is ∼10 times softer (∼0.05 nanonewton nm(-1)) than a viral protein-capsid coat and sustains deformations of one-third of the virion's diameter. Compared with phosphatidylcholine liposomes, it is twice as stiff, due to membrane-attached protein components. We found that virus indentation resulted in a biphasic force-indentation response. We propose that the first phase, including a stepwise reduction in stiffness at ∼10-nm indentation and ∼100 piconewtons of force, is due to mobilization of membrane proteins by the indenting atomic force microscope tip, consistent with the glycoprotein ectodomains protruding ∼13 nm from the bilayer surface. This phase was obliterated for bromelain-treated virions with the ectodomains removed. Following pH 5 treatment, virions were as soft as pure liposomes, consistent with reinforcing proteins detaching from the lipid bilayer. We propose that the soft, pH-dependent mechanical properties of the envelope are critical for the pH-regulated life cycle and support the persistence of the virus inside and outside the host.
Highlights
The lipid and protein contributions to the mechanical properties of the influenza viral envelope are unknown
Using atomic force microscopy, here we show that the lipid envelope of spherical influenza virions is ϳ10 times softer (ϳ0.05 nanonewton nm؊1) than a viral protein-capsid coat and sustains deformations of one-third of the virion’s diameter
Cryo-electron microscopy (EM) and Atomic Force Microscopy of Influenza Virions— To ensure that we did not irreversibly deform or damage our samples during imaging and subsequent force mapping using atomic force spectroscopy, we compared the AFM-determined height of our virus preparation with the diameter of the same preparations measured using cryo-EM (Fig. 1)
Summary
The lipid and protein contributions to the mechanical properties of the influenza viral envelope are unknown. The envelope of the influenza virus undergoes extensive structural change during the viral life cycle It is unknown how lipid and protein components of the viral envelope contribute to its mechanical properties. We propose that the first phase, including a stepwise reduction in stiffness at ϳ10-nm indentation and ϳ100 piconewtons of force, is due to mobilization of membrane proteins by the indenting atomic force microscope tip, consistent with the glycoprotein ectodomains protruding ϳ13 nm from the bilayer surface. This phase was obliterated for bromelain-treated virions with the ectodomains removed. Our data revealed that influenza virions are about 10 times softer than virus particles enclosed by a protein capsid shell, such as DNA-bacteriophage and cowpea chlorotic mottle virus [23, 24], or enveloped viruses with a submembranous capsid, such as herpes simplex, HIV, or murine leukemia virus particles [25,26,27]
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