Abstract
Possible mechanisms that lead to inactivation of feline calicivirus (FCV) by cold atmospheric-pressure plasma (CAP) generated in 99% argon-1% O2 admixture were studied. We evaluated the impact of CAP exposure on the FCV viral capsid protein and RNA employing several cultural, molecular, proteomic and morphologic characteristics techniques. In the case of long exposure (2 min) to CAP, the reactive species of CAP strongly oxidized the major domains of the viral capsid protein (VP1) leading to disintegration of a majority of viral capsids. In the case of short exposure (15 s), some of the virus particles retained their capsid structure undamaged but failed to infect the host cells in vitro. In the latter virus particles, CAP exposure led to the oxidation of specific amino acids located in functional peptide residues in the P2 subdomain of the protrusion (P) domain, the dimeric interface region of VP1 dimers, and the movable hinge region linking the S and P domains. These regions of the capsid are known to play an essential role in the attachment and entry of the virus to the host cell. These observations suggest that the oxidative effect of CAP species inactivates the virus by hindering virus attachment and entry into the host cell. Furthermore, we found that the oxidative impact of plasma species led to oxidation and damage of viral RNA once it becomes unpacked due to capsid destruction. The latter effect most likely plays a secondary role in virus inactivation since the intact FCV genome is infectious even after damage to the capsid.
Highlights
Cold atmospheric-pressure gaseous plasma (CAP) is one of the most promising non-thermal technologies that has gained attention recently due to its strong bactericidal activity [1,2,3,4,5,6,7]
In a previous investigation [16], we reported strong in vitro virucidal activity (> 6 log10 TCID50/0.1 ml) against feline calicivirus (FCV) by 15s exposure of virus suspension to the effluent of a radio frequency (RF)driven CAP jet with gas flow of 99% argon and 1% oxygen operated in an open-air environment
We placed a sterile 96-well microtiter plate below the plasma jet at 11.25 mm exposure distance
Summary
Cold atmospheric-pressure gaseous plasma (CAP) is one of the most promising non-thermal technologies that has gained attention recently due to its strong bactericidal activity [1,2,3,4,5,6,7].
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