Sensitization by intratracheally injected dendritic cells is independent of antigen presentation by host antigen-presenting cells

Adoptive transfer of antigen-pulsed dendritic cells ( DC) in the airways of mice has been used as a model system for eosinophilic airway inflammation, which allows studying the DC-specific contribution of genes of interest or reagents to induced inflammation by genetically modifying DC or exposure of DC to compounds prior to injection in the airways. Antigen transfer and CD4(+) T cell priming by endogenous antigen-presenting cells (APCs) may interfere with the correct interpretation of the data obtained in this model, however. We therefore examined antigen transfer and indirect CD4(+) T cell priming by host APCs in this model system. Transfer of antigen between injected DC and host cells appeared to be minimal but could not be totally excluded. However, only direct antigen presentation by injected DC resulted in robust CD4(+) T cell priming and eosinophilic airway inflammation. Thus, this adoptive transfer model is well suited to study the role of DC in eosinophilic airway inflammation. J. Leukoc. Biol. 85: 64-70; 2009

Facilitated antigen uptake and timed exposure to TLR ligands dictate the antigen-presenting potential of plasmacytoid DCs

Subsets of antigen-presenting cDCs have a differential capacity to present exogenous and endogenous protein antigens to CD4(+) and/or CD8(+) T lymphocytes, depending on expression of antigen-uptake receptors, processing machinery, and microbial instruction. pDCs are also capable of antigen presentation, but the conditions under which they do this have not been systematically addressed. Highly purified cDCs and pDCs were exposed to exogenous, soluble OVA peptide or whole protein. Alternatively, they were made to express cytoplasmic or endosomal OVA by retroviral transduction or by infection with influenza virus containing OVA epitopes. Like cDCs, pDCs expressed the MHC I processing machinery and could present endogenous or cross-present exogenous OVA to CD8(+) T cells, provided they had been stimulated by CpG motif TLR9 ligands or by influenza. Unlike cDCs, the cross-priming activity of pDCs was enhanced, not decreased, by simultaneous TLR stimulation. Processing and presentation of exogenous OVA to CD4(+) T cells required TLR9 ligation prior to antigen encounter and addition of OVA-specific Igs. These stimuli up-regulated critical MHC II processing machinery and enhanced routing to acidic endosomal organelles in a Fc gamma RII-dependent manner. Endogenous antigen was not presented to CD4(+) T cells when expressed in the cytoplasm of pDCs by retrovirus or contained in influenza, unless an Ii-chain-derived endosomal routing signal was present. Thus, timing of TLR ligation and facilitated antigen uptake dictate the potential of pDCs to present endogenous or exogenous antigen by influencing endosomal traffic and antigen-processing machinery

Facilitated antigen uptake and timed exposure to TLR ligands dictate the antigen-presenting potential of plasmacytoid DCs

Subsets of antigen-presenting cDCs have a differential capacity to present exogenous and endogenous protein antigens to CD4(+) and/or CD8(+) T lymphocytes, depending on expression of antigen-uptake receptors, processing machinery, and microbial instruction. pDCs are also capable of antigen presentation, but the conditions under which they do this have not been systematically addressed. Highly purified cDCs and pDCs were exposed to exogenous, soluble OVA peptide or whole protein. Alternatively, they were made to express cytoplasmic or endosomal OVA by retroviral transduction or by infection with influenza virus containing OVA epitopes. Like cDCs, pDCs expressed the MHC I processing machinery and could present endogenous or cross-present exogenous OVA to CD8(+) T cells, provided they had been stimulated by CpG motif TLR9 ligands or by influenza. Unlike cDCs, the cross-priming activity of pDCs was enhanced, not decreased, by simultaneous TLR stimulation. Processing and presentation of exogenous OVA to CD4(+) T cells required TLR9 ligation prior to antigen encounter and addition of OVA-specific Igs. These stimuli up-regulated critical MHC II processing machinery and enhanced routing to acidic endosomal organelles in a Fc gamma RII-dependent manner. Endogenous antigen was not presented to CD4(+) T cells when expressed in the cytoplasm of pDCs by retrovirus or contained in influenza, unless an Ii-chain-derived endosomal routing signal was present. Thus, timing of TLR ligation and facilitated antigen uptake dictate the potential of pDCs to present endogenous or exogenous antigen by influencing endosomal traffic and antigen-processing machinery. J. Leukoc. Biol. 90: 1177-1190; 2011

Antigen capsid-display on human adenovirus 35 via pIX fusion is a potent vaccine platform.

Durable protection against complex pathogens is likely to require immunity that comprises both humoral and cellular responses. While heterologous prime-boost regimens based on recombinant, replication-incompetent Adenoviral vectors (AdV) and adjuvanted protein have been able to induce high levels of concomitant humoral and cellular responses, complex manufacturing and handling in the field may limit their success. To combine the benefits of genetic and protein-based vaccination within one vaccine construct and to facilitate their use, we generated Human Adenovirus 35 (HAdV35) vectors genetically encoding a model antigen based on the Plasmodium falciparum (P. falciparum) circumsporozoite (CS) protein and displaying a truncated version of the same antigen (CSshort) via protein IX on the capsid, with or without a flexible glycine-linker and/or a 45Å-spacer. The four tested pIX-antigen display variants were efficiently incorporated and presented on the HAdV35 capsid irrespective of whether a transgene was encoded or not. Transgene-expression and producibility of the display-/expression vectors were not impeded by the pIX-display. In mice, the pIX-modified vectors induced strong humoral antigen-specific immunity that increased with the inclusion of the linker-/spacer molecules, exceeded the responses induced by the genetic, transgene-expressing HAdV35 vector, and surpassed recombinant protein in potency. In addition, the pIX- display/expression vectors elicited high antigen-specific cellular immune responses that matched those of the genetic HAdV35 vector expressing CS. pIX-modified display-/expression HAdV vectors may therefore be a valuable technology for the development of vaccines against complex pathogens, especially in resource-limited settings

Restrained expansion of the recall germinal center response as biomarker of protection for influenza vaccination in mice.

Correlates of protection (CoP) are invaluable for iterative vaccine design studies, especially in pursuit of complex vaccines such as a universal influenza vaccine (UFV) where a single antigen is optimized to elicit broad protection against many viral antigenic variants. Since broadly protective antibodies against influenza virus often exhibit mutational evidence of prolonged diversification, we studied germinal center (GC) kinetics in hemagglutinin (HA) immunized mice. Here we report that as early as 4 days after secondary immunization, the expansion of HA-specific GC B cells inversely correlated to protection against influenza virus challenge, induced by the antigen. In contrast, follicular T helper (TFH) cells did not expand differently after boost vaccination, suggestive of a B-cell intrinsic difference in activation and differentiation inferred by protective antigen properties. Importantly, differences in antigen dose only affected GC B-cell frequencies after primary immunization. The absence of accompanying differences in total anti-HA or epitope-specific antibody levels induced by vaccines of different efficacy suggests that the GC B-cell response upon revaccination represents an early and unique marker of protection that may significantly accelerate the pre-clinical phase of vaccine development