Presentation of lipopeptide by dendritic cells induces anti-tumor responses via an endocytosis-independent pathway in vivo.

Cross-presentation by DCs is the major mechanism by which exogenous antigens activate CTLs. However, the mechanisms of entry and presentation of vaccine peptides by DCs remain unclear. In this study, we determined that the mechanisms of antigen presentation differed between nonlipidated and monopalmitoylated peptide antigens. We found that a nonlipidated long peptide could be taken up by DCs and that the peptide could be colocalized with early endosomes. The uptake of nonlipidated peptides by DCs was inhibited at low temperatures or by the depolymerization of actin filaments or microtubules. In contrast, lipidated peptides were internalized by DCs at low temperatures, and internalization was not inhibited when actin filaments or microtubules were depolymerized. Moreover, lipidated peptide, but not nonlipidated peptide, was internalized by nonphagocytic Jurkat cells. The endosomal/lysosomal and proteasomal degradation pathways were necessary for nonlipidated presentation leading to the activation of CD8(+) T cells, but the proteasomal degradation pathway alone was sufficient to process lipidated peptides for MHC class I presentation. We further found that lipidated peptides could enhance peptide-specific T cell responses in vitro and in vivo and induced stronger antitumor responses than nonlipidated peptides. Taken together, our results demonstrate that DCs present lipidated peptides through an endocytosis-independent pathway to promote strong anti-tumor effects in vivo.

Emulsified nanoparticles containing inactivated influenza virus and CpG oligodeoxynucleotides critically influences the host immune responses in mice.

BACKGROUND: Antigen sparing and cross-protective immunity are regarded as crucial in pandemic influenza vaccine development. Both targets can be achieved by adjuvantation strategy to elicit a robust and broadened immune response. We assessed the immunogenicity of an inactivated H5N1 whole-virion vaccine (A/Vietnam/1194/2004 NIBRG-14, clade 1) formulated with emulsified nanoparticles and investigated whether it can induce cross-clade protecting immunity. METHODOLOGY/PRINCIPAL FINDINGS: After formulation with PELC, a proprietary water-in-oil-in-water nanoemulsion comprising of bioresorbable polymer/Span(R)85/squalene, inactivated virus was intramuscularly administered to mice in either one-dose or two-dose schedule. We found that the antigen-specific serum antibody responses elicited after two doses of non-adjuvanted vaccine were lower than those observed after a single dose of adjuvanted vaccine, PELC and the conventional alum adjuvant as well. Moreover, 5 microg HA of PELC-formulated inactivated virus were capable of inducing higher antibodies than those obtained from alum-adjuvanted vaccine. In single-dose study, we found that encapsulating inactivated virus into emulsified PELC nanoparticles could induce better antibody responses than those formulated with PELC-adsorbed vaccine. However, the potency was rather reduced when the inactivated virus and CpG (an immunostimulatory oligodeoxynucleotide containing unmethylated cytosine-guanosine motifs) were co-encapsulated within the emulsion. Finally, the mice who received PELC/CpG(adsorption)-vaccine could easily and quickly reach 100% of seroprotection against a homologous virus strain and effective cross-protection against a heterologous virus strain (A/Whooper swan/Mongolia/244/2005, clade 2.2). CONCLUSIONS/SIGNIFICANCE: Encapsulating inactivated H5N1 influenza virus and CpG into emulsified nanoparticles critically influences the humoral responses against pandemic influenza. These results demonstrated that the use of PELC could be as antigen-sparing in preparation for a potential shortage of prophylactic vaccines against local infectious diseases, in particular pandemic influenza. Moreover, the cross-clade neutralizing antibody responses data verify the potential of such adjuvanted H5N1 candidate vaccine as an effective tool in pre-pandemic preparedness.