Effective depletion of regulatory T cells allows the recruitment of mesothelin-specific CD8 T cells to the antitumor immune response against a mesothelin-expressing mouse pancreatic adenocarcinoma.

Vaccine-induced CD8(+) T-cell responses can eradicate developing tumors in vivo in mouse models. Translating these successes into approved treatments for cancer patients has been challenging, since many of these models lack expression of clinically proven/relevant tumor antigens. We have shown that mesothelin is a clinically relevant CD8(+) T-cell target in human pancreas cancer, which is also highly conserved among species. Here, we utilize the murine mesothelin-expressing pancreatic tumor model (Panc02) to identify the immune-relevant mesothelin-derived peptides and study interventions that enhance the antitumor response. We first screened overlapping peptides of the entire murine mesothelin protein to identify two new CD8(+) mesothelin-restricted epitopes. These peptides were then evaluated for recognition by vaccine-induced T cells from mice treated with vaccine in sequence with low-dose cyclophosphamide (CY) and an anti-CD25 IL-2Ralpha monoclonal antibody (PC61). These treatments are both known to deplete subpopulations of T regulatory cells (Tregs). Our findings demonstrate that combined Treg-depleting therapies synergize to enhance vaccine efficacy. Furthermore, our data supports mesothelin as a relevant antigen in murine and clinical models and the use of Panc02 as a clinically relevant murine model of pancreatic cancer for evaluating antigen-targeted immunotherapies in immune-tolerant hosts.

Production and characterization of a monoclonal antibody against Niemann Pick type C protein.

Niemann Pick type C is a severe, incurable disease caused, in the majority of cases, by mutations in the Niemann Pick type C protein 1 (NPC1). The pathology and biochemical changes associated with the disease have been extensively studied. However, the function of the protein is still unknown, and recent studies challenge the established concept that a defect in cholesterol and sphingolipids transport is the primary cause of this human lipidosis. Clearly defining the mechanisms by which defects in this protein lead to the disease phenotype will require further studies on the structure and function of this protein. Therefore, the development of a well-characterized monoclonal antibody (MAb) against this protein to facilitate such studies is an important goal. Here, we describe the production and characterization of such a MAb. The antibody is demonstrated to be highly specific and species cross-reactive. Function studies show that the antibody induces the NPC1 disease phenotype in cells, making it highly likely that the antibody blocks function of the NPC1 protein.

HIV-1 p55Gag encoded in the lysosome-associated membrane protein-1 as a DNA plasmid vaccine chimera is highly expressed, traffics to the major histocompatibility class II compartment, and elicits enhanced immune responses.

Several genetic vaccines encoding antigen chimeras containing the lysosome-associated membrane protein (LAMP) translocon, transmembrane, and cytoplasmic domain sequences have elicited strong mouse antigen-specific immune responses. The increased immune response is attributed to trafficking of the antigen chimera to the major histocompatibility class II (MHC II) compartment where LAMP is colocalized with MHC II. In this report, we describe a new form of an HIV-1 p55gag DNA vaccine, with the gag sequence incorporated into the complete LAMP cDNA sequence. Gag encoded with the translocon, transmembrane and cytoplasmic lysosomal membrane targeting sequences of LAMP, without the luminal domain, was poorly expressed, did not traffic to lysosomes or MHC II compartments of transfected cells, and elicited a limited immune response from DNA immunized mice. In contrast, addition of the LAMP luminal domain sequence to the construct resulted in a high level of expression of the LAMP/Gag protein chimera in transfected cells that was further increased by including the inverted terminal repeat sequences of the adeno-associated virus to the plasmid vector. This LAMP/Gag chimera with the complete LAMP protein colocalized with endogenous MHC II of transfected cells and elicited strong cellular and humoral immune responses of immunized mice as compared with the response to DNA-encoding native Gag, with a 10-fold increase in CD4+ responses, a 4- to 5-fold increase in CD8+ T-cell responses, and antibody titers of >100,000. These results reveal novel roles of the LAMP luminal domain as a determinant of Gag protein expression, lysosomal trafficking, and possibly of the immune response to Gag.

Dengue 2 PreM-E/LAMP chimera targeted to the MHC class II compartment elicits long-lasting neutralizing antibodies.

A dengue 2 plasmid DNA vaccine (pD2) expressing the pre-membrane and envelope proteins (preM-E) was modified by replacing the dengue transmembrane and cytoplasmic sequences with those of the mouse lysosome-associated membrane protein (pD2/LAMP). Immunofluorescence and confocal microscopy of human 293, NIH 3T3, and macrophage IC21 cell lines transfected with pD2/LAMP showed that the preM-E/LAMP protein chimera was present in vesicles containing endogenous LAMP and major histocompatability complex class II (MHC II), in contrast to the non-vesicular localization of native preM-E protein lacking the LAMP targeting sequence. Mice immunized with pD2 showed an antigen-specific immunoglobulin response but the neutralizing antibodies titers (plaque reduction neutralization test, PRNT(50)) elicited by the native protein were minimal. In contrast, vaccination with pD2/LAMP resulted in PRNT(50) of 270, 320 and 160 at approximately 1, 3 and 8 months after two immunizations with 50 microg DNA, and approached 100% neutralization at 1:20 dilution. Additional immunization with pD2/LAMP, after 8 months, increased the neutralizing antibody titers to >640. Comparable neutralizing antibody responses were induced by two vector backbones, pVR1012 and pVax-1, at 5 and 50 microg of DNA. The neutralizing responses to the pD2/LAMP chimera were greatly superior to those elicited by pD2 in all conditions. These results underscore the importance of MHC class II presentation of DNA-encoded dengue-virus envelope protein for production of neutralizing antibodies.