Innovative approach in Pompe disease therapy: Induction of immune tolerance by antigen-encapsulated red blood cells.

Pompe disease is a glycogen storage disease caused by acid α-glucosidase enzyme deficiency. Currently, the unique treatment is lifelong enzyme replacement therapy ERT with frequent intravenous administration of the recombinant analog alglucosidase-α (AGA), which ultimately generates a sustained humoral response resulting in treatment discontinuation. Our aim is to use the tolerogenic properties of antigen-encapsulated red blood cells (RBCs) to abolish the humoral response against AGA and to restore tolerance to replacement therapy. To demonstrate that our approach could prevent the AGA-induced immune response, mice were intravenously injected three times with AGA encapsulated into RBCs before being sensitized to AGA with several adjuvant molecules. Control animals received injections of free AGA instead of the encapsulated molecule. One-week after treatment with AGA-loaded RBCs, a strong decrease in specific humoral response was observed despite three stimulations with AGA and adjuvant molecules. Furthermore, this specific immunomodulation was maintained for at least two months without affecting the overall immune response. AGA-loaded RBCs represent a promising strategy to induce or restore tolerance in Pompe disease patients who develop hypersensitivity reactions following repeated AGA administrations.

Red blood cells as innovative antigen carrier to induce specific immune tolerance.

The route of administration, the dose of antigen as well as the type of antigen-presenting cells (APCs) targeted are important factors to induce immune tolerance. Despite encouraging results obtained in animal models, intravenous injection of soluble antigen is unsuccessful in human clinical trials on autoimmune disease due to inefficient antigen delivery. To improve antigen delivery, we used mouse red blood cells (RBCs) as antigen vehicles to specifically target APCs which are responsible for removal of senescent RBCs after phagocytosis. In this study, we demonstrated that antigen-delivery by RBCs induced a strong decrease in the humoral response compared with the ovalbumin (OVA) free form in mice. In addition, OVA-loaded RBC treated with [bis(sulphosuccinimidyl)] suberate (BS3), a chemical compound known to enhance RBC phagocytosis, induced an inhibition of antigen-specific T cell responses and an increase in the percentage of regulatory T cells. The state of tolerance induced is long lasting, antigen-specific and sufficiently robust to withstand immunization with antigen mixed with cholera toxin adjuvant. This RBC strategy, which does not abolish the immune system, constitutes an attractive approach for induction of tolerance compared to systemic immunosuppressant therapies already in use.

Tumor growth control using red blood cells as the antigen delivery system and poly(I:C).

The goal of most current vaccines in tumor immunology is to induce an efficient immune response against the tumor cells. The use of red blood cells (RBCs) for the delivery of tumor-associated antigen to antigen-presenting cells is an innovative approach for cancer immunotherapy. The induction of antigen-specific immune responses after administration of antigen-loaded RBCs has been demonstrated previously in mice. In this paper, we show the utility of this delivery system for cancer immunotherapy in 2 tumor mouse models, using the E.G7-OVA and the B16F10 tumor cells. The non-self-antigen, ovalbumin, loaded in RBCs and the self-tumor antigen, tyrosinase-related protein 2, loaded in RBCs were tested in the E.G7-OVA and the B16F10 tumor models, respectively. We showed that not only protein but also peptide could be efficiently entrapped in RBCs by a controlled lysis/resealing process. In both antigen models, the administration of a small quantity of antigen loaded in RBCs combined with polyinosinic-polycytidylic acid induced an antigen-specific T-cell response and the control of tumor growth in mice, whereas the injection of the same quantity of free antigen did not. The intensity of the T-cell response was dependent on the concentrations of antigen entrapped and the treatment performed on the RBC membrane (antibody coating and heat treatment) to improve antigen delivery. In summary, these results support the use of RBCs as an antigen delivery system for a powerful cancer immunotherapy approach.

Sublingual immunization with an HIV subunit vaccine induces antibodies and cytotoxic T cells in the mouse female genital tract.

A vaccine against heterosexual transmission by human immunodeficiency virus (HIV) should generate cytotoxic and antibody responses in the female genital tract and in extra-genital organs. We report that sublingual immunization with HIV-1 gp41 and a reverse transcriptase polypeptide coupled to the cholera toxin B subunit (CTB) induced gp41-specific IgA antibodies and antibody-secreting cells, as well as reverse transcriptase-specific CD8 T cells in the genital mucosa, contrary to intradermal immunization. Conjugation of the reverse transcriptase peptide to CTB favored its cross-presentation by human dendritic cells to a T cell line from an HIV(+) patient. Sublingual vaccination could represent a promising vaccine strategy against heterosexual transmission of HIV-1.

In situ targeting of dendritic cells by antigen-loaded red blood cells: A novel approach to cancer immunotherapy.

Red blood cells (RBCs) were shown to be efficient antigen carriers to target dendritic cells (DCs) and induce cytotoxic T-cell responses. Mouse RBCs were loaded with ovalbumin (RBC-OVA) and injected with Poly (I:C) into mice. Phagocytosis of RBC-OVA by macrophages and DCs was demonstrated to induce OVA-specific CD4(+) and CD8(+) T cell activation. Moreover, these CD8(+) T cells produced IFN-gamma and were able to induce OVA-specific cell lysis. Finally, T-cell response was demonstrated to be dependent on the dose-amount of antigen entrapped and this response could be maintained for up to 30 days.

Female genital tract immunization: evaluation of candidate immunoadjuvants on epithelial cell secretion of CCL20 and dendritic/Langerhans cell maturation.

The female genital tract is an important site for numerous pathogens entry. Local immunization, generating specific mucosal IgA and systemic IgG, represents an interesting alternative immunization pathway. However, such a vaccine strategy needs mucosal adjuvants to obtain the best immune response. Considering that the immunization process is mainly dependent on the capture and on the transport of the antigen by Langerhans cells, we evaluated potential adjuvant molecules by analysing their effects on the CCL20 secretion by endocervical and exocervical/vaginal epithelial cells as well as on dendritic cell and Langerhans cell maturation. We demonstrated that DC-Chol and Zymosan are the most efficient mucosal candidate immunoadjuvants that generate a strong increase of CCL20 secretion by the two epithelial cell lines and the maturation of dendritic and Langerhans cells, respectively.

Characterization of CCL20 secretion by human epithelial vaginal cells: involvement in Langerhans cell precursor attraction.

Mucosa represents the main site of pathogen/cell interactions. The two main types of cells forming the epithelial structure [epithelial cells and Langerhans cells (LC)] coordinate the first defense responses to avoid infection. To evaluate the involvement of epithelial cells in the early steps leading to a specific adaptive immune response, we have studied the interactions between vaginal epithelial and LC through the establishment of a human vaginal epithelial mucosa. We demonstrate that normal human vaginal epithelial cells constitutively secrete the chemokine macrophage inflammatory protein 3alpha/CC chemokine ligand 20 (CCL20), known to recruit LC precursors (LCps) selectively via its cognate CC chemokine receptor 6 (CCR6). This secretion is up-regulated by the proinflammatory cytokine interleukin-1beta through the nuclear factor-kappaB pathway. Similar results were obtained with the human vaginal epithelial cell line SiHa, which displays numerous homologies with normal vaginal cells. The chemotactic activity of the secreted CCL20 was demonstrated by its ability to attract LCp CCR6+. Moreover, the use of neutralizing polyclonal antibodies directed against the CCL20 molecule abolished this migration completely, suggesting that CCL20 is the main attracting factor for LCps, which is produced by the vaginal cells. These data indicate that vaginal epithelial cells play an important role in the immunological defense by attracting immune cells to the site of epithelial/pathogen contact.