Type I IFN is a cytokine family endowed with multiple biological activities. In recent years, type I IFN has been demonstrated to play a crucial role in innate immunity, in dendritic cell maturation/differentiation and in the priming of primary antibody responses, especially when administered i.m. with a purified influenza vaccine. Due to the increasing interest in mucosal vaccination especially for respiratory infections, we investigated two different IFN-adjuvanted immunization protocols against influenza. In the first one, anesthesized C3H/HeN mice were instilled intranasally with 50 microl of a commercially available influenza vaccine containing 5 mg of hemagglutinin (HA) and a partially purified preparation of mouse IFN-alphal. A single intranasal administration of IFN-adjuvanted vaccine resulted in a full protection of 100% of mice against virus challenge while vaccine alone was only partially effective (40%). From the analysis of the specific antibody response emerged that type I IFN induced a significant increase of antibody titers in all the Ig subclasses with particular effect on IgG2a and IgA. To mimic aerosol administration and to limit vaccine delivery strictly to nasal mucosa, a second method of intranasal vaccination was developed in which mice were left awake and their nostrils moistened along the day of treatment (every 10 min) with six mini-doses (8 microl each) of vaccine +/- IFN-I with dose and timing equivalent to previous immunization protocol. This vaccination schedule prevented mice from pulmonary damage and the concomintant use of type I IFN induced an efficient and long lasting both local and systemic immune response. These findings shed new light on the involvement of type I IFN in the early phases of the immune response and open new and practical perspectives in vaccine research.
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