The band III ligand dipyridamole protects human RBCs during photodynamic treatment while extracellular virus inactivation is not affected.

BACKGROUND: Recently, the potential usefulness of dipyridamole (DIP) in protecting RBCs against the harmful side effects of photodynamic sterilization was demonstrated. In the present study, the use of DIP for selective protection of RBCs was investigated under conditions more relevant for blood bank practice. STUDY DESIGN AND METHODS: WBC-reduced RBC suspensions (30% Hct) were treated with 1,9-dimethylmethylene blue and red light, and the influence of the inclusion of DIP on photohemolysis was assessed as a function of sensitizer concentration, light dose, and storage time. Furthermore, the possible interference of DIP with inactivation of extracellular virus by use of a panel of different viruses (HIV-1, pseudorabies virus [PRV], bovine viral diarrhea virus [BVDV], VSV, encephalomyocarditis, and canine parvovirus) was investigated. RESULTS: In WBC-reduced RBC suspensions (30% Hct), DIP exerted a clear protective effect against photohemolysis. Part of this protection was achieved with concentrations near the dissociation constant for band III binding. Importantly, efficiency of inactivation of extracellular HIV-1, PRV, BVDV, and VSV was not significantly impaired by the inclusion of DIP. Phototreatment conditions, resulting in a 4 to 5 log inactivation of extracellular HIV-1 and PRV, resulted in a high level of hemolysis after 28 days of storage. This long-term hemolysis could be decreased, but not completely prevented, by the inclusion of DIP. CONCLUSION: Photohemolysis in RBC concentrates can be reduced substantially by the application of DIP, while the efficacy of inactivation of HIV-1 and other viruses remains unchanged.

Inactivated recombinant plant virus protects dogs from a lethal challenge with canine parvovirus.

A vaccine based upon a recombinant plant virus (CPMV-PARVO1), displaying a peptide derived from the VP2 capsid protein of canine parvovirus (CPV), has previously been described. To date, studies with the vaccine have utilized viable plant chimaeric particles (CVPs). In this study, CPMV-PARVO1 was inactivated by UV treatment to remove the possibility of replication of the recombinant plant virus in a plant host after manufacture of the vaccine. We show that the inactivated CVP is able to protect dogs from a lethal challenge with CPV following parenteral immunization with the vaccine. Dogs immunized with the inactivated CPMV-PARVO1 in adjuvant displayed no clinical signs of disease and shedding of CPV in faeces was limited following CPV challenge. All immunized dogs elicited high titres of peptide-specific antibody, which neutralized CPV in vitro. Levels of protection, virus shedding and VP2-specific antibody were comparable to those seen in dogs immunized with the same VP2- peptide coupled to keyhole limpet hemocyanin (KLH). Since plant virus-derived vaccines have the potential for cost-effective manufacture and are not known to replicate in mammalian cells, they represent a viable alternative to current replicating vaccine vectors for development of both human and veterinary vaccines.

Virus inactivation in superoxide dismutase preparations by ultraviolet light irradiation.

Viral inactivation in superoxide dismutase (SOD) derived from human red cells was carried out by ultraviolet light C (UVC) irradiation. With 400 J/m2 UVC irradiation, the titer of canine parvovirus (CPV, a nonenveloped virus), M13 bacteriophage (M13, a nonenveloped phage) and vesicular stomatitis virus (VSV, an enveloped virus), which were spiked into SOD solution, were reduced by > 4.6 log10 (detection limit), 7.0 log10 and 6.2 log10, respectively. The SOD activity was maintained and the band pattern of SOD on an electrophoresis gel was not changed even by 1000 J/m2 UVC irradiation. These results indicate that UVC irradiation is a promising method for the inactivation of both enveloped and nonenveloped viruses in SOD preparations while maintaining its activity.

Photoinactivation of virus infectivity by hypocrellin A.

We investigated the photoinactivation of virus infectivity by hypocrellin A and its mechanism. The titers of vesicular stomatitis virus (VSV) and human immunodeficiency virus type 1 (HIV-1), both of which are enveloped viruses, were reduced upon illumination with hypocrellin A in a concentration-dependent manner, whereas canine parvovirus, a nonenveloped virus, was not killed. The removal of oxygen or addition of sodium azide or beta-carotene both inhibited VSV inactivation. Mannitol and superoxide dismutase had no effect on VSV inactivation. These results indicate that singlet oxygen was involved in the process of VSV inactivation. Of the three major VSV membrane proteins, peripheral membrane protein M was most damaged by the hypocrellin A phototreatment.