Mutated and Bacteriophage T4 Nanoparticle Arrayed F1-V Immunogens from Yersinia pestis as Next Generation Plague Vaccines

Pneumonic plague is a highly virulent infectious disease with 100% mortality rate,and its causative organism yersinia pestis poses a serious threat for deliberate use as a bioterror agent. currently,there is no fda approved vaccine against plague. the polymeric bacterial capsular protein f1,a key component of the currently tested bivalent subunit vaccine consisting,in addition,of low calcium response v antigen,has high propensity to aggregate,thus affecting its purification and vaccine efficacy. we used two basic approaches,structure-based immunogen design and phage t4 nanoparticle delivery,to construct new plague vaccines that provided complete protection against pneumonic plague. the nh2-terminal β-strand of f1 was transplanted to the cooh-terminus and the sequence flanking the β-strand was duplicated to eliminate polymerization but to retain the t cell epitopes. the mutated f1 was fused to the v antigen,a key virulence factor that forms the tip of the type three secretion system (t3ss). the f1mut-v protein showed a dramatic switch in solubility,producing a completely soluble monomer. the f1mut-v was then arrayed on phage t4 nanoparticle via the small outer capsid protein,soc. the f1mut-v monomer was robustly immunogenic and the t4-decorated f1mut-v without any adjuvant induced balanced th1 and th2 responses in mice. inclusion of an oligomerization-deficient yscf,another component of the t3ss,showed a slight enhancement in the potency of f1-v vaccine,while deletion of the putative immunomodulatory sequence of the v antigen did not improve the vaccine efficacy. both the soluble (purified f1mut-v mixed with alhydrogel) and t4 decorated f1mut-v (no adjuvant) provided 100% protection to mice and rats against pneumonic plague evoked by high doses of y. pestis co92. these novel platforms might lead to efficacious and easily manufacturable next generation plague vaccines. © 2013 tao et al.