Schistosomiasis is a parasitic disease affecting over 200 million people every year in tropical regions of the world. Drug treatment and other existing control measures are costly and have failed to eliminate the incidence of infection, morbidity and mortality due to Schistosoma mansoni infection. Vaccination of susceptible individuals using recombinant vaccines encoding key S. mansoni antigens may be the most effective and least expensive means of controlling schistosomiasis. A candidate vaccine antigen is p80, the large subunit of the S. mansoni protease, calpain. In our vaccine studies, we have employed both the wild-type p80 and a mutant p80 (mut p80) in which an active site amino acid was genetically altered to create a less proteolytically-active enzyme. Two vaccine delivery approaches were implemented using p80 or mut p80 as vaccine antigen: recombinant vaccinia virus (RVV) inoculation and DNA immunization via the Accell gene gun (GG) delivery system. RVV's expressing p80 and mut p80 were generated and tested for recombinant protein expression in vitro. These RVV's were tested for protective capacity in mouse challenge studies. Neither subcutaneous nor intranasal vaccinations with RVV-p80 or RVV-mut p80 were capable of significantly reducing the mean worm burdens of vaccinated mice. A GG-RVV combination immunization regime using WRG-vectors encoding p80 and mut p80 for GG priming and the RVV's for boosting prior to S. mansoni challenge infection was performed and no significant protection was obtained over two repeated studies. However, duplicate challenge studies involving GG immunization of mice with WRG-vectors encoding p80 or mut p80 revealed that 3 inoculations of mice with WRG-full5' mut p80 (containing the full 5' untranslated region of mut p80) provided 60% protection which was statistically significant (p < 0.05). These preliminary in vivo studies demonstrate the potential for further study of the protection afforded by gene gun-delivered WRG-full5' mut p80 into subsequently-challenged mice. Such studies may pave the way to effective vaccination of humans using WRG DNA vectors expressing a schistosomal calcium-activated neutral protease.