In mice, injection of messenger RNA (mRNA) coding for tumor-associated antigens can induce antitumor immune responses and therefore offers a broadly applicable immunotherapy approach. We injected intradermally protamine-stabilized mRNAs coding for Melan-A, Tyrosinase, gp100, Mage-A1, Mage-A3, and Survivin in 21 metastatic melanoma patients. In 10 patients keyhole limpet hemocyanin (KLH) was added to the vaccine. Granulocyte macrophage colony-stimulating factor was applied as an adjuvant. Endpoints were toxicity and immune responses. No adverse events more than grade II have been observed. During treatment the frequency of Foxp3+/CD4+ regulatory T cells was significantly decreased upon mRNA vaccination in peripheral blood of the patients in the KLH arm, whereas myeloid suppressor cells (CD11b+HLA-DR lo monocytes) were reduced in the patients not receiving KLH. A reproducible increase of vaccine-directed T cells was observed in 2 of 4 immunologically evaluable patients. One of 7 patients with measurable disease showed a complete response. In conclusion, we show here that direct injection of protamine-protected mRNA is feasible and safe. The significant influence of the treatment on the frequency of immunosuppressive cells, the increase of vaccine-directed T cells upon treatment in a subset of patients together with the demonstration of a complete clinical response encourage further clinical investigation of the protamine-mRNA vaccine.
Vaccination against tumor antigens has been shown to be a safe and efficacious prophylactic and therapeutic antitumor treatment in many animal models. Clinical studies in humans indicate that specific immunotherapy can also result in clinical benefits. The active pharmaceutical ingredient in such vaccines can be DNA, RNA, protein, or peptide and can be administered naked, encapsulated, or after delivery in vitro into cells that are then adoptively transferred. One of the easiest, most versatile and theoretically safest technologies relies on the direct injection of naked messenger RNA (mRNA) that code for tumor antigens. We and others have shown in mice that intradermal application of naked mRNA results in protein expression and the development of an immune response. We used this protocol to vaccinate 15 melanoma patients. For each patient a growing metastasis was removed, total RNA was extracted, reverse-transcribed, amplified, and cloned. Libraries of cDNA were transcribed to produce unlimited amounts of copy mRNA. Autologous preparations were applied intradermally in combination with granulocyte macrophage colony-stimulating factor as adjuvant. We demonstrate here that such treatment is feasible and safe (phase 1 criteria). Furthermore, an increase in antitumor humoral immune response was seen in some patients. However, a demonstration of clinical effectiveness of direct injection of copy mRNA for antitumor immunotherapy was not shown in this study and must be evaluated in subsequent trials.
The development of new treatments in the post-genomic era requires methods for safe delivery of foreign genetic information in vivo. As a transient, natural and controllable alternative to recombinant viruses or plasmid DNA (pDNA), purified or in vitro transcribed messenger RNA (mRNA) can be used for the expression of any therapeutic protein in vitro and in vivo. As it has been shown previously, the simple injection of naked mRNA results in local uptake and expression. We show here that this process, in the skin, can greatly be modulated according to the injection solution composition and blocked by an excess of competing nucleic acids or a drug affecting cytosolic mobility. Different cell types at the site of injection can take up the foreign nucleic acid molecules and the protein translated from this is detected for no more than a few days. To test this gene transfer method in humans, we produced in vitro transcribed mRNA under good manufacturing practice (GMP) conditions in a dedicated facility. After injection into the human dermis, we could document the translation of the exogenous mRNA. Our results pave the way toward the use of mRNA as a vehicle for transient gene delivery in humans.
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