Gene electrotransfer of proinflammatory chemokines CCL5 and CCL17 as a novel approach of modifying cytokine expression profile in the tumor microenvironment

The effectiveness of immunotherapy highly correlates with the degree and the type of infiltrated immune cells in the tumor tissue. Treatments based on modifying the immune cell infiltrate of the tumor microenvironment are thus gaining momentum. Therefore, the aim of our study was to investigate the effects of gene therapy with two proinflammatory chemokines CCL5 and CCL17 on inflammatory cytokine expression profile and immune cell infiltrate in two murine breast tumor models, 4T1 and E0771, and two murine colon tumor models, CT26 and MC38. In vitro, lipofection of plasmid DNA encoding CCL5 or CCL17 resulted in changes in the cytokine expression profile similar to control plasmid DNA, implying that the main driver of these changes was the entry of foreign DNA into the cell%s cytosol. In vivo, gene electrotransfer resulted in high expression levels of both Ccl5 and Ccl17 transgenes in the 4T1 and CT26 tumor models. Besides a minor increase in the survival of the treated mice, the therapy also resulted in increased expression of Cxcl9 and Ifn%, potent activators of the immune system, in CT26 tumors. However, this was not recapitulated in changes of TME, implying that a further refinement of the dosing schedule is needed

PARP inhibitor olaparib has a potential to increase the effectiveness of electrochemotherapy in BRCA1 mutated breast cancer in mice

Electrochemotherapy (ECT), a local therapy, has different effectiveness among tumor types. In breast can-cer, its effectiveness is lowtherefore, combined therapies are needed. The aim of our study was to com-bine ECT with PARP inhibitor olaparib, which could inhibit the repair of bleomycin or cisplatin inducedDNA damage and potentiate the effectiveness of ECT. The effects of combined therapy were studied inBRCA1mutated (HCC1937) and non-mutated (HCC1143) triple negative breast cancer cell lines.Therapeutic effectiveness was studied in 2D and 3D cell cultures andin vivoon subcutaneousHCC1937 tumor model in mice. The underlying mechanism of combined therapy was determined withthe evaluation ofcH2AX foci. Combined therapy of ECT with bleomycin and olaparib potentiated theeffectiveness of ECT inBRCA1mutated HCC1937, but not in non-mutated HCC1143 cells. The combinedtherapy had a synergistic effect, which was due to the increased number of DNA double strand breaks.Addition of olaparib to ECT with bleomycinin vivoin HCC1937 tumor model had only minimal effect,indicating repetitive olaparib treatment would be needed. This study demonstrates that DNA repar inhibiting drugs, like olaparib, have the potential to increase the effectiveness of ECT with bleomycin

Mutational burden, MHC-I expression and immune infiltration as limiting factors for in situ vaccination by TNF[alfa] and IL-12 gene electrotransfer

In situ vaccination is a promising immunotherapeutic approach, where various local ablative therapies are used to induce an immune response against tumor antigens that are released from the therapy-killed tumor cells. We recently proposed using intratumoral gene electrotransfer for concomitant transfection of a cytotoxic cytokine tumor necrosis factor-% (TNF%) to induce in situ vaccination, and an immunostimulatory cytokine interleukin 12 (IL-12) to boost the primed immune response. Here, our aim was to test the local and systemic effectiveness of the approach in tree syngeneic mouse tumor models and associate it with tumor immune profiles, characterized by tumor mutational burden, immune infiltration and expression of PD-L1 and MHC-I on tumor cells. While none of the tested characteristic proved predictive for local effectiveness, high tumor mutational burden, immune infiltration and MHC-I expression were associated with higher abscopal effectiveness. Hence, we have confirmed that both the abundance and presentation of tumor antigens as well as the absence of immunosuppressive mechanisms are important for effective in situ vaccination. These findings provide important indications for future development of in situ vaccination based treatments, and for the selection of tumor types that will most likely benefit from it