Therapeutic monoclonal antibodies (mAbs) are currently being developed for the treatment of cancer and other diseases. Despite clinical success, widespread application of mAb therapies may be limited by manufacturing capabilities. In this paper, we describe a mAb delivery system that allows continuous production of a full-length antibody at high-concentrations in vivo after gene transfer. The mAb is expressed from a single open reading frame by linking the heavy and light chains with a 2A self-processing peptide derived from the foot-and-mouth disease virus. Using this expression system, we generated a recombinant adeno-associated virus vector encoding the VEGFR2-neutralizing mAb DC101 (rAAV8-DC101). A single dose of rAAV8-DC101 resulted in long-term expression of >1,000 microg/ml of DC101 in mice, demonstrating significant anti-tumor efficacy. This report describes the first feasible gene therapy approach for stable delivery of mAbs at therapeutic levels, which may serve as an attractive alternative to direct injection of mAbs.
Monoclonal antibody (mAb) delivery by gene transfer in vivo may be an attractive alternative to current mAb therapies for applications that require long-term therapy. This article describes a transfer system that allows inducible high-level expression of unmodified mAbs in vivo. A recombinant adeno-associated viral (rAAV) vector is used that comprises an expression cassette consisting of a dimerizer-regulated promoter that drives expression of the antibody heavy and light chains linked by a 2A self-processing peptide and a furin cleavage site. Following intravenous injection of the rAAV vector, serum mAb levels >1 mg/ml were attained by administration of the inducer, rapamycin. Antibody expression could be rapidly shut off by discontinuing treatment with rapamycin. By optimizing the furin cleavage sequence, this system generated native antibody in vivo, decreasing the likelihood of a host immune response to foreign sequences. In summary, this optimized mAb expression system allows regulated high-level expression of native full-length mAbs in vivo and may offer a new opportunity for delivery of therapeutic mAbs in the clinic.
Promising anti-tumor responses have been observed in the clinic using monoclonal antibodies (mAbs) that block immune checkpoints. One concern with these therapeutic agents remains the potential induction of immune breakthrough events (IBEs) resulting from the disruption of T cell homeostasis or the breaking of tolerance to self antigens. As an approach to maintaining anti-tumor responses but decreasing the likelihood of these events, the local expression of a mAb in combination with a GM-CSF-secreting cancer immunotherapy was evaluated. Using anti-cytotoxic T lymphocyte antigen (CTLA)-4 as a model antibody to test this hypothesis, tumor cell lines were generated that expressed the full-length mAb in addition to GM-CSF. Evaluation of these cell lines in two therapeutic tumor models revealed that local, cell-mediated delivery of anti-CTLA-4 from a GM-CSF-secreting tumor cell immunotherapy activated potent anti-tumor responses and prolonged overall survival at significantly lower serum mAb levels in the host. Furthermore, lowering the systemic exposure of the host to the immune modulatory mAb correlated with reduced evidence of systemic autoimmunity. This approach has broad utility for the delivery of mAbs or proteins locally from cellular immunotherapies to minimize IBEs while retaining the potent therapeutic effects of such combination treatments.
Monoclonal antibody (mAb) delivery by gene transfer in vivo may be an attractive alternative to current mAb therapies for applications that require long-term therapy. This article describes a transfer system that allows inducible high-level expression of unmodified mAbs in vivo. A recombinant adeno-associated viral (rAAV) vector is used that comprises an expression cassette consisting of a dimerizer-regulated promoter that drives expression of the antibody heavy and light chains linked by a 2A self-processing peptide and a furin cleavage site. Following intravenous injection of the rAAV vector, serum mAb levels >1 mg/ml were attained by administration of the inducer, rapamycin. Antibody expression could be rapidly shut off by discontinuing treatment with rapamycin. By optimizing the furin cleavage sequence, this system generated native antibody in vivo, decreasing the likelihood of a host immune response to foreign sequences. In summary, this optimized mAb expression system allows regulated high-level expression of native full-length mAbs in vivo and may offer a new opportunity for delivery of therapeutic mAbs in the clinic.
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