Oxidation of virus proteins during UV(254) and singlet oxygen mediated inactivation.

Despite the widespread use of UV(254) irradiation and solar disinfection for water treatment, little is known about the photochemical pathways that lead to virus inactivation by these treatments. The goal of this study was to identify reactions that occur in virus capsid proteins upon treatment by UV(254) irradiation and (1)O(2), an important oxidant involved in sunlight-mediated disinfection. Bacteriophage MS2 was inactivated via UV(254) irradiation and exposure to (1)O(2) in buffered water, and their capsid proteins were then analyzed with MALDI-TOF-TOF and ESI-TOF before and after digestion with protease enzymes. The results demonstrate that chemical modifications occur in the MS2 major capsid protein with both treatments. One oxidation event was detected following (1)O(2) treatment in an amino acid residue located on the capsid outer surface. UV(254) treatment caused three chemical reactions in the capsid proteins, two of which were oxidation reactions with residues on the capsid outer surface. A site-specific cleavage also occurred with UV(254) irradiation at a protein chain location on the inside face of the capsid shell. We attribute this UV(254) induced protein scission, which is nearly unprecedented in the literature, to a close association between the affected residues and viral RNA, an efficient UV(254) absorber. These results suggest that viral protein oxidation by UV(254) and (1)O(2) may play a role in virus inactivation and that viral inactivation may be tracked with mass spectrometric measurements.