Perspectives for cancer immunotherapy mediated by p19Arf plus interferon-beta gene transfer

While cancer immunotherapy has gained much deserved attention in recent years, many areas regarding the optimization of such modalities remain unexplored, including the development of novel approaches and the strategic combination of therapies that target multiple aspects of the cancer-immunity cycle. Our own work involves the use of gene transfer technology to promote cell death and immune stimulation. Such immunogenic cell death, mediated by the combined transfer of the alternate reading frame (p14ARF in humans and p19Arf in mice) and the interferon-b cDNA in our case, was shown to promote an antitumor immune response in mouse models of melanoma and lung carcinoma. With these encouraging results, we are now setting out on the road toward translational and preclinical development of our novel immunotherapeutic approach. Here, we outline the perspectives and challenges that we face, including the use of human tumor and immune cells to verify the response seen in mouse models and the incorporation of clinically relevant models, such as patient-derived xenografts and spontaneous tumors in animals. In addition, we seek to combine our immunotherapeutic approach with other treatments, such as chemotherapy or checkpoint blockade, with the goal of reducing dosage and increasing efficacy. The success of any translational research requires the cooperation of a multidisciplinary team of professionals involved in laboratory and clinical research, a relationship that is fostered at the Cancer Institute of Sao Paulo

Gene-based Interventions for Cancer Immunotherapy

Immunotherapy of cancer has deservedly gained much attention in the past few years and is likely to continue to advance and become a fundamental cancer treatment. While vaccines, chimeric antigen receptor (CAR) T cells and checkpoint blockade have received the lion’s share of the attention, an important direct role for gene transfer as an immunotherapy is emerging. For example, oncolytic viruses induce immunogenic cell death, thus liberating both antigens and the signals that are necessary for the activation of antigen-presenting cells, ensuring stimulation of an adaptive response. In another example, transfer of prodrug converting enzymes, such as the herpes simplex virus-thymidine kinase (HSV-tk) gene or the cytosine deaminase gene, has been shown to promote an immune response, thus functioning as immunotherapies. Alternatively, our own work involves the use of nonreplicating viral vectors for the simultaneous delivery of gene combinations that promote both cell death and an immune response. In fact, our gene transfer approach has been applied as a vaccine, immunotherapy or in situ gene therapy, resulting in immunogenic cell death and the induction of a protective immune response. Here, we highlight the development of these approaches both in terms of technical advances and clinical experience

Establishment of canine melanoma cell lines and transduction with improved adenoviral vectors

NTRODUÇÃO: O melanoma é um câncer de alta mortalidade tanto na medicina quanto na veterinária, devido à baixa resposta às terapias utilizadas e à capacidade de evolução metastática da doença. Avanços no campo da oncologia têm mostrado que os agentes que têm como alvo componentes do sistema imunológico, bem como as terapias molecularmente dirigidas, são muito promissores no tratamento do melanoma. Nosso grupo tem desenvolvido vetores virais para a transferência gênica de fatores antitumorais. O aprimoramento no vetor adenoviral inclui a inserção do tripeptídeo RGD, que permite um amplo tropismo de transdução, e o uso de um promotor responsivo a p53 para controlar expressão do gene terapêutico. Visto que o melanoma canino pode ser um modelo experimental por se tratar de um câncer de ocorrência espontânea e de comportamento biológico semelhante ao melanoma humano, procuramos testar nossa abordagem, que chamamos AdRGD-PG, neste modelo. MÉTODOS: Para isso foram estabelecidas linhagens celulares de melanoma canino para a determinação da capacidade de transdução pelos vetores adenovirais. Em seguida foi realizado o sequenciamento dos exons 4 - 8 do gene TP53 e a avaliação da expressão de genes da via de TP53 induzidos por doxorrubicina e Nutlin-3. RESULTADOS: As quatro linhagens de melanoma canino estabelecidas possuem capacidade tumorigênica e de serem transduzidas pelos vetores adenovirais. Não foram identificadas alterações na sequência do TP53 na região avaliada e a doxorrubicina promoveu aumento da expressão dos transgenes dirigidos pelo promotor PG e a ativação de genes da via de TP53. CONCLUSÕES: A funcionalidade desta plataforma adenoviral aprimorada abre oportunidades para estudos da transferência gênica, incluindo da combinação p19ARF/IFN-beta, nas linhagens estabelecidas. Com o sucesso destas análises, teremos um importante modelo experimental a ser utilizado no desenvolvimento de novas terapias para o melanomaINTRODUCTION: Melanoma is a cancer of high mortality both in human and veterinary medicine due to the poor response to therapies and the metastatic evolution of the disease. Advances in the field of oncology have shown that agents that target immune system components, as well as molecularly targeted therapies, are very promising for the treatment of melanoma. Our group has developed viral vectors for gene transfer of antitumor factors. The improvement in the adenoviral vector includes the insertion of the RGD tripeptide, which allows a broad transduction tropism, and the use of a p53 responsive promoter to control therapeutic gene expression. Canine melanoma may be considered as an experimental model since it is a spontaneous cancer with biological behavior similar to human melanoma, thus we aim to test our approach, which we call AdRGD-PG, in this model. METHODS: For this purpose, canine melanoma cell lines were established before determining the transduction capacity of adenoviral vectors. Next, sequencing of exons 4-8 of the TP53 gene and evaluation of the expression of genes in the TP53 pathway upon induction with doxorubicin and Nutlin-3 were performed. RESULTS: The four established canine melanoma lines have tumorigenic capacity and are transduced by the adenoviral vectors. No changes were identified in the TP53 sequence in the assessed region and doxorubicin promoted increased expression of the transgenes directed by the PG promoter as well as activation of the TP53 pathway genes. CONCLUSIONS: The functionality of this improved adenoviral platform opens up opportunities for gene transfer studies, including the p19ARF / IFN-beta combination, in the established cell lines. With the success of these analyses, we have an important experimental model to be used in the development of new therapies for melanom

Perspectives for cancer immunotherapy mediated by p19Arf plus interferon-beta gene transfer

While cancer immunotherapy has gained much deserved attention in recent years, many areas regarding the optimization of such modalities remain unexplored, including the development of novel approaches and the strategic combination of therapies that target multiple aspects of the cancer-immunity cycle. Our own work involves the use of gene transfer technology to promote cell death and immune stimulation. Such immunogenic cell death, mediated by the combined transfer of the alternate reading frame (p14ARF in humans and p19Arf in mice) and the interferon-β cDNA in our case, was shown to promote an antitumor immune response in mouse models of melanoma and lung carcinoma. With these encouraging results, we are now setting out on the road toward translational and preclinical development of our novel immunotherapeutic approach. Here, we outline the perspectives and challenges that we face, including the use of human tumor and immune cells to verify the response seen in mouse models and the incorporation of clinically relevant models, such as patient-derived xenografts and spontaneous tumors in animals. In addition, we seek to combine our immunotherapeutic approach with other treatments, such as chemotherapy or checkpoint blockade, with the goal of reducing dosage and increasing efficacy. The success of any translational research requires the cooperation of a multidisciplinary team of professionals involved in laboratory and clinical research, a relationship that is fostered at the Cancer Institute of Sao Paulo