Scientific background: Treatment of malignant melanoma remains a challenge due to its aggressiveness and resistance to treatment. Combining established local ablative therapies with recently discovered immunotherapies is a promising approach for treating malignant melanoma. While electrochemotherapy with cisplatin is already a well-established treatment, oxaliplatin has not yet been tested for use with electrochemotherapy. Based on its similar characteristics to cisplatin, described lesser side-effect and its presumably more pronounced immunomodulatory effect, oxaliplatin is an eligible candidate for electrochemotherapy. Although local effectiveness of electrochemotherapy is up to 80 % of local tumor control, noticeable effects on distant non-treated metastases (abscopal effect) have yet to be described. With the aim to increase the armamentarium of drugs for electrochemotherapy, oxaliplatin was compared to the already well-established electrochemotherapy with cisplatin in murine malignant melanoma B16F10. In addition, we also investigated if peritumoral gene electrotransfer of a plasmid encoding interleukin-12 (IL-12) as an adjuvant immunotherapy enhances the responses seen with electrochemotherapy on a local and systemic level (abscopal effect).
Methods: Murine B16F10 melanoma cells with a high metastatic potential were used. Firstly, we determined the potentiation in the uptake of platinum after applying electric pulses and platinum-based drugs oxaliplatin or cisplatin in vitro. Platinum content in cells and the amount of platinum bound to DNA were measured by inductively coupled plasma mass spectrometry. Using the clonogenic assay we determined the cellular reproductive potential following electroporation with oxaliplatin or cisplatin. We also determined the type of cell death after electroporation with oxaliplatin or cisplatin. More specifically, we determined the amount of cells which died via apoptosis, necrosis or immunogenic cell death. Secondly, in vivo experiments were performed in C57Bl/6 mice. Solid tumors were grown on the right flank of mice after a subcutaneous inoculation of tumor cells. The therapy was performed when tumors reached 3540 mm3 in volume. The antitumor effect of electrochemotherapy was compared to electrochemotherapy with cisplatin. Thereafter, the antitumor effect of the combined treatment consisting of intratumoral electrochemotherapy with cisplatin or oxaliplatin and peritumoral gene electrotransfer of plasmid encoding IL-12 was researched. For gene electrotransfer mice received four intradermal injections of plasmid DNA encoding IL-12 (50 µg) around the tumor. Immediately after low voltage electric pulses (12 pulses, 170 V/cm, 150 ms, 0.4/1.39 Hz) were applied with a multi-electrode array (MEA). Five minutes after gene electrotransfer, oxaliplatin or cisplatin were injected intratumorally and after two minutes electric pulses (8 pulses, 1300 V/cm, 100 µs, 1 Hz) were applied with plate electrodes. The antitumor effectiveness of the combined treatment with multiple repetitions of gene electrotransfer was also tested. A dual flank model mimicking systemic disease was used to determine the systemic antitumor effect of the therapy. It was established by subcutaneous injections of tumor cells on both flanks of mice, 1 x 106 cells on the right and 0.7 x 106 on the left flank. During the treatment, animals were under inhalational anesthesia with isoflurane. Tumor growth was followed by measuring three mutually orthogonal tumor diameters with a Vernier caliper. The right tumor was regarded as a primary tumor and was treated; the left tumor was left untreated. Blood samples were collected for the detection of IL-12 in mice sera and tumor samples were collected for histological analysis. Immunohistochemical analysis was performed to detect necrosis, apoptosis (caspase 3), transgene expression (IL-12) and infiltration of immune cells into tumors (granzyme B, Foxp3).
Results: Electroporation potentiated the cytotoxicity of oxaliplatin in vitro on B16F10 melanoma cells and no differences in cytotoxicity between cisplatin and oxaliplatin were observed. Cytotoxicity correlated with cisplatin or oxaliplatin uptake into cells and drug binding to DNA. Based on in vivo results pertaining to effectiveness and drug uptake in tumors, electrochemotherapy with oxaliplatin is as effective as electrochemotherapy with cisplatin when the dose of oxaliplatin is increased 1.6-fold. Electrochemotherapy induced immunogenic cell death when either oxaliplatin or cisplatin were used, which correlated with a comparable increase in lymphocyte infiltration into tumors after electrochemotherapy with either oxaliplatin or cisplatin. We observed a delay in tumor growth after electrochemotherapy with low doses of oxaliplatin or cisplatin, with no complete responses. We showed that peritumoral gene electrotransfer of plasmid encoding IL-12 potentiated the antitumor effect of electrochemotherapy with oxaliplatin or cisplatin in B16F10 melanoma on a local level. The most pronounced potentiation was with electrochemotherapy using cisplatin, resulting in 38% of complete responses. However, the additional repetitions of gene electrotransfer did not improve the therapeutic effectiveness. Moreover, we also observed an abscopal effect after the combination treatment with electrochemotherapy with cisplatin. Average tumor growth delay of the distant untreated tumors in the latter group was two days. We ascribe the success of this novel therapy to the induction of an immune response on a local and systemic level. Namely, infiltration of granzyme B positive immune cells after the combination therapy with electrochemotherapy with cisplatin was observed in both primary and distant tumors.
Conclusion: We showed that gene electrotransfer of IL-12 potentiates the effect of electrochemotherapy on a local level. Additionally, an abscopal effect was detected after the combination therapy in which cisplatin was used for electrochemotherapy. Our findings highlight the potential clinical use of intratumoral oxaliplatin in electrochemotherapy. Most importantly, the preclinical data will serve as the basis for a clinical phase study application.
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