Isolation of Fully Human Antagonistic RON Antibodies Showing Efficient Block of Downstream Signaling and Cell Migration.

RON belongs to the c-MET family of receptor tyrosine kinases. As its well-known family member MET, RON and its ligand macrophage-stimulating protein have been implicated in the progression and metastasis of tumors and have been shown to be overexpressed in cancer. We generated and tested a large number of human monoclonal antibodies (mAbs) against human RON. Our screening yielded three high-affinity antibodies that efficiently block ligand-dependent intracellular AKT and MAPK signaling. This effect correlates with the strong reduction of ligand-activated migration of T47D breast cancer cell line. By cross-competition experiments, we showed that the antagonistic antibodies fall into three distinct epitope regions of the RON extracellular Sema domain. Notably, no inhibition of tumor growth was observed in different epithelial tumor xenografts in nude mice with any of the antibodies. These results suggest that distinct properties beside ligand antagonism are required for anti-RON mAbs to exert antitumor effects in vivo.

ErbB2 genetic cancer vaccine in nonhuman primates: relevance of single nucleotide polymorphisms.

Aberrant Her2/neu expression is associated with the development of epithelial-derived human carcinomas and for this reason it is considered a good target for immunologic intervention. To define methods to circumvent immunologic tolerance and to elicit immunity against the Her2/neu tumor-associated antigen in a suitable animal model, we have isolated the cDNA encoding the rhesus monkey homolog of human Her2/neu (RhErbB2) to construct DNA plasmids and adenoviral vectors for the development of a cancer vaccine against this protein. To further increase the immunogenic potency of these vectors, a synthetic codon-optimized RhErbB2 cDNA (RhErbB2OPT) was constructed and characterized. Genetic vaccination of rhesus monkeys was effective in inducing a response against RhErbB2 in immunized animals; importantly, the elicited immunity was associated with natural RhErbB2 polymorphisms, thus distinguishing responses against "self " and "nonself " epitopes. In particular, the postpriming response recognized mainly nonself epitopes whereas the boosted response cross-reacted with self epitopes. Our findings are particularly relevant in the investigation of the impact of TAA polymorphisms on the efficacy of a cancer vaccine strategy.

Modulation of the immune response induced by gene electrotransfer of a hepatitis C virus DNA vaccine in nonhuman primates.

Induction of multispecific, functional CD4+ and CD8+ T cells is the immunological hallmark of acute self-limiting hepatitis C virus (HCV) infection in humans. In the present study, we showed that gene electrotransfer (GET) of a novel candidate DNA vaccine encoding an optimized version of the nonstructural region of HCV (from NS3 to NS5B) induced substantially more potent, broad, and long-lasting CD4+ and CD8+ cellular immunity than naked DNA injection in mice and in rhesus macaques as measured by a combination of assays, including IFN-gamma ELISPOT, intracellular cytokine staining, and cytotoxic T cell assays. A protocol based on three injections of DNA with GET induced a substantially higher CD4+ T cell response than an adenovirus 6-based viral vector encoding the same Ag. To better evaluate the immunological potency and probability of success of this vaccine, we have immunized two chimpanzees and have compared vaccine-induced cell-mediated immunity to that measured in acute self-limiting infection in humans. GET of the candidate HCV vaccine led to vigorous, multispecific IFN-gamma+CD8+ and CD4+ T lymphocyte responses in chimpanzees, which were comparable to those measured in five individuals that cleared spontaneously HCV infection. These data support the hypothesis that T cell responses elicited by the present strategy could be beneficial in prophylactic vaccine approaches against HCV.

Construction of an rtTA2(s)-m2/tts(kid)-based transcription regulatory switch that displays no basal activity, good inducibility, and high responsiveness to doxycycline in mice and non-human primates.

The tetracycline (Tc)-dependent system in its "on" version (rtTA system) displays a baseline activity in the uninduced state, severely limiting its potential applicability in human gene therapy. So far, two different strategies to circumvent this limitation have been described. On one side, co-expression of the tetracycline regulated repressor tTS(kid) has proved capable of substantially reducing the baseline activity of rtTA. On the other, novel versions of the activator, namely rtTA2(s)-S2 and rtTA2(s)-M2, with a lower basal activity have been engineered. We have combined these two approaches by co-expressing TS(kid) with the novel transactivators. Bicistronic vectors were constructed that co-express TS(kid) with rtTA, rtTA2(s)-S2, or rtTA2(s) M2, through an internal ribosome entry site (plasmids IRES-A, IRES-S2, and IRES-M2, respectively). IRES-M2 proved to be the most effective construct EX VIVO: it displayed a negligible basal activity, > 1000 fold inducibility, and high responsiveness to doxycycline (Dox). Upon delivery as plasmid DNA in mouse muscles, IRES-M2 facilitated 1000-fold induction of serum alkaline phosphatase (SEAP) gene expression and long-term, stringent, and strictly Dox-dose-dependent regulation of erythropoietin (Epo) gene expression. Tight regulation of the gene encoding SEAP was demonstrated also in non-human primates. Notably, the system was induced in animals by Dox-dosing regimens comparable to those used in humans.