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

Single Nucleotide Polymorphisms Of The Gjb2 And Gjb6 Genes Are Associated With Autosomal Recessive Nonsyndromic Hearing Loss.

Single nucleotide polymorphisms (SNPs) are important markers in many studies that link DNA sequence variations to phenotypic changes; such studies are expected to advance the understanding of human physiology and elucidate the molecular basis of diseases. The DFNB1 locus, which contains the GJB2 and GJB6 genes, plays a key role in nonsyndromic hearing loss. Previous studies have identified important mutations in this locus, but the contribution of SNPs in the genes has not yet been much investigated. The aim of this study was to investigate the association of nine polymorphisms located within the DFNB1 locus with the occurrence of autosomal recessive nonsyndromic hearing loss (ARNSHL). The SNPs rs3751385 (C/T), rs7994748 (C/T), rs7329857 (C/T), rs7987302 (G/A), rs7322538 (G/A), rs9315400 (C/T), rs877098 (C/T), rs945369 (A/C), and rs7333214 (T/G) were genotyped in 122 deaf patients and 132 healthy controls using allele-specific PCR. There were statistically significant differences between patients and controls, in terms of allelic frequencies in the SNPs rs3751385, rs7994748, rs7329857, rs7987302, rs945369, and rs7333214 (P < 0.05). No significant differences between the two groups were observed for rs7322538, rs9315400, and rs877098. Our results suggest that SNPs present in the GJB2 and GJB6 genes may have an influence on ARNSHL in humans.201531872

Single nucleotide polymorphisms of the GJB2 and GJB6 genes are associated with autosomal recessive nonsyndromic hearing loss

Single nucleotide polymorphisms (SNPs) are important markers in many studies that link DNA sequence variations to phenotypic changes; such studies are expected to advance the understanding of human physiology and elucidate the molecular basis of diseases. The DFNB1 locus, which contains the GJB2 and GJB6 genes, plays a key role in nonsyndromic hearing loss. Previous studies have identified important mutations in this locus, but the contribution of SNPs in the genes has not yet been much investigated. The aim of this study was to investigate the association of nine polymorphisms located within the DFNB1 locus with the occurrence of autosomal recessive nonsyndromic hearing loss (ARNSHL). The SNPs rs3751385 (C/T), rs7994748 (C/T), rs7329857 (C/T), rs7987302 (G/A), rs7322538 (G/A), rs9315400 (C/T), rs877098 (C/T), rs945369 (A/C), and rs7333214 (T/G) were genotyped in 122 deaf patients and 132 healthy controls using allele-specific PCR. There were statistically significant differences between patients and controls, in terms of allelic frequencies in the SNPs rs3751385, rs7994748, rs7329857, rs7987302, rs945369, and rs7333214 (P < 0.05). No significant differences between the two groups were observed for rs7322538, rs9315400, and rs877098. Our results suggest that SNPs present in the GJB2 and GJB6 genes may have an influence on ARNSHL in humans2015CONSELHO NACIONAL DE DESENVOLVIMENTO CIENTÍFICO E TECNOLÓGICO - CNPQFundacao Herminio Ometto/FH

Investigation of the antitumor immune response induced by B16F10 cells treated with the p19Arf and Interferon-beta combination in a murine prophylatic model of melanoma vaccine

Dados recentes do nosso laboratório demonstram que somente a co-transdução, não a tradução individual, com vetores adenovirais portadores de Interferon-beta (IFN?) (citocina imuno modulatória) e p19Arf (parceira funcional da proteína supressora de tumor p53) resulta na morte celular massiva do melanoma murino B16F10. A capacidade desse tratamento combinado de induzir uma resposta imune antitumoral ainda não foi avaliada. Dessa maneira, o objetivo do presente trabalho foi investigar se células B16F0 tratadas por essa combinação são capazes de induzir uma resposta imune antitumoral em um modelo de vacinação profilático de melanoma. Para isso, essas células foram co-transduzidas com os vetores AdPGp19 e AdPGIFN? e 48 horas depois, inoculadas como agente vacinal no flanco esquerdo (sítio da vacina) de camundongos C57BL/6 imunocompetentes. Sete dias após a última vacinação, esses animais foram desafiados com células B16F10 naïve no flanco direito (sítio do desafio). A progressão tumoral do desafio foi significativamente reduzida, mesmo quando o desafio tumoral foi feito 73 dias após da vacinação. Porém, como os animais imunizados desenvolveram tumores no sítio da vacina, condições para o uso dessas células tratadas foram avaliadas, revelando que: o número de células e de aplicações usadas durante a vacinação tem influência no aparecimento desse tumores, e que apenas com o tratamento combinado os camundongos permanecem livres de tumor. A influência do sistema imune para este resultado foi revelada após protocolo de imunussupressão. Em seguida, o papel da p19Arf e do IFN? na proteção antitumoral da combinação foi estudado. In vitro, os efeitos antitumorais da combinação parecem ser mais influentes da reposição de p19Arf do que da expressão de IFN?, mas já in vivo, na presença do sistema imune, foram mais dependentes do IFN?. Com a combinação estes efeitos mostraram-se mais pronunciados, induzindo uma proteção antitumoral e maior sobrevida aos animais vacinados. Estes resultados indicam que a combinação p19Arf e IFN? pode ser aplicada como um agente imunoterápico e sugerem que a associação entre morte celular e imuno estimulação pode beneficiar o tratamento contra o câncerPreviously, we have shown in a mouse melanoma model of in situ gene therapy that co-transduction, but not individual application, with adenovirus vectors expressing the Interferon-beta (IFN?) (immune modulatory cytokine) and p19Arf (functional partner of the p53 tumor suppressor) transgenes results in massive cell death and reduced tumor progression. However, the capability of this combined treatment to stimulate an antitumor immune response has not been evaluated. Therefore, the aim of this work was to investigate, trough a prophylactic vaccine model, if B16F10 cells treated by the p19Arf and IFN? combination could induce such immune response. To do so, these cells were co-transduced by the AdPGp19 e AdPGIFN? adenoviral vectors and 48 hours after, inoculated as a vaccine agent in the left flank (vaccine site) of immune competent C57BL/6 mice. Seven days after the last vaccine, a tumor challenge was done with naïve B16F10 cells in the right flank (challenge site). Tumor progression was markedly reduced, even when challenge was done 73 days after the vaccination. However, since these animals developed tumors where the vaccine was applied, more appropriate conditions for the use of these treated cells were pursued, thus revealing that: the number of cells and inoculations can dictate tumor development, and also, that only with the combined treatment was tumor formation abolished. The influence of the immune system for this result was revelead by performing an immune supression protocol. Next, the roles of p19Arf and of IFN? were studied. In vitro, the antitumor effects were stronger upon the introduction of p19Arf than IFN?, but in vivo, in the presence of the immune system, the effects were more IFN? dependent. In fact, these effects were more pronouced with the combined treatment, inducing protection against tumor formation and progression and increasing survival in the vaccinated animals. Taken together, these results demonstrate the application of cells treated by the p19Arf e IFN? combination as an effective vaccine agent and also indicates that the association between cell death and immune stimulation may benefit the treatment of cance

Remediation of the p53/Arf and Interferon-beta pathways as a cancer immunotherapy strategy: a gene transfer approach

As células tumorais prosperam como consequência da capacidade de resistir aos mecanismos de morte celular e de evasão da vigilância imunológica. Nós propomos que, em cânceres que possuem o supressor de tumor p53 selvagem, a remediação de ambas dessas defesas pode ser promovida pela transferência genica combinada de vetores adenovirais portadores dos transgenes de p19Arf (proteína supressora de tumor, parceira funcional de p53) e de interferon-beta (IFNbeta, citocina imunomoduladora). De fato, em resultados anteriores, notamos que a transdução combinada (p19Arf/IFNbeta), mas não os tratamentos individuais, em células de melanoma murino B16F10 resulta em aumento massivo de morte celular. Porém a capacidade destas células em processo de morte de desencadear imunidade antitumoral não foi analisada. Nesta tese e em estudos complementares, buscamos investigar os mecanismos moleculares de morte celular envolvidos na resposta imune estimulada por p19Arf/IFNbeta e explorar sua aplicação como imunoterapia do câncer. Inicialmente, em modelo de vacinação profilática, revelamos que o tratamento combinado em células B16F10 promove a expressão de IL-15, ULBP1, dos receptores de morte FAS/APO1 e KILLER/DR5, assim como uma resposta de células natural killer que rejeitam estas células tratadas quando inoculadas em camundongos imunocompetentes singênicos. Após desafio tumoral no flanco oposto, a progressão desses tumores foi fortemente reduzida devido ao engajamento de linfócitos T CD4+ e CD8+, que apresentaram produção aumentada das citocinas IFN-? e TNF-alfa e medeiam proteção antitumoral de longo prazo. Em seguida, explorando um contexto de imunização diferente, a transferência de gênica in situ foi realizada em carcinoma heterotópico de pulmão e exibiu proteção significativa contra um desafio tumoral secundário, apenas quando o tumor primário foi tratado com p19Arf/IFNbeta. Análise de transcriptoma destes tumores indicou uma assinatura quimiotáxica de neutrófilos e linfócitos T CD8+ através das quimiocinas CCL3, CXCL3 e da IL-1beta. Em apoio destas observações, análises mecanicistas in vitro revelaram que células tratadas com p19Arf/IFNbeta ativam programas apoptóticos de p53 e antivirais de IFNbeta, enquanto sucumbem a um processo de morte por necroptose que também libera moléculas de morte celular imunogênica (MCI), calreticulina, ATP e HMGB1. No entanto, procurando potencializar ainda mais o benefício terapêutico dos nossos vetores, exploramos sua associação com o quimioterápico imunogênico doxorrubicina (Dox), que também é indutor de MCI. E nesta associação, percebemos que a Dox aumenta não apenas os níveis de morte celular, mas também a imunogenicidade das células tratadas, proporcionando em um modelo de vacina terapêutica, um controle tumoral superior em camundongos que já portavam antes da vacinação tumores B16F10 ou MCA205. Além disso, a associação in situ destas terapias restaurou a eficácia de uma dose sub-terapêutica de Dox, que em contraste com sua dose terapêutica, não prejudica a função cardíaca. Finalmente, também exploramos a associação com o bloqueio dos pontos de controle imunológicos PD-1 ou CTLA-4, que no modelo de vacina terapêutica, sua associação induziu maior rejeição completa de tumores B16F10. Em conclusão, aqui apresentamos evidências sobre a capacidade da combinação p19Arf/IFNbeta de induzir morte celular e estimulação imunológica. E ressaltamos seu potencial como uma estratégia de imunoterapia do câncerCancer cells thrive as a consequence of resisting cell death mechanisms and escaping from immune surveillance. We propose that, in cancers that harbor the wild-type tumor suppressor p53, remediation of both of these defenses can be achieved by harnessing the adenoviral vector mediated gene transfer of p19Arf (tumor suppressor protein, p53 functional partner) together with interferon-beta (IFNbeta, immunomodulatory cytokine). Indeed, in our initial observations, it was noticed that combined-transduction (p19Arf/IFNbeta), but not the individual treatments, of B16F10 mouse melanoma cells results in massive cell death levels. Yet, the capability of these dying cells to unleash antitumor immunity was not investigated. Here in this thesis and in complementary studies, we sought to investigate the molecular mechanisms of cell death involved in the p19Arf/IFNbeta immune stimulation and explore its potential as a mediator of cancer immunotherapy. First, in a prophylactic B16F10 vaccine model, we revealed that the dual treatment led to the up-regulation of IL-15, ULBP1, FAS/APO1 and KILLER/DR5 death receptors, plus a natural killer cell response that completely rejects treated cells when inoculated in syngeneic immunocompetent mice. Whereas, upon a contralateral tumor challenge, progression was strongly reduced by engaging both CD4+ and CD8+ T cells, which displayed augmented production of IFN-? and TNF-alpha cytokines and provided long term antitumor protection. Next, exploring different immunization context, in situ gene transfer in a heterotopic lung carcinoma exhibited significant protection against a secondary tumor challenge only when the primary tumor was treated with p19Arf/IFNbeta. Transcriptome analysis of these treated tumors indicated a chemotaxic signature of neutrophils and CD8+ T cells with the involvement of CCL3, CXCL3 chemokines and IL-1beta. Moreover, in support of this evidence, mechanistic in vitro studies revealed that p19Arf/IFNbeta treated cells reactivate p53 apoptotic and IFNbeta antiviral programs, while succumbing to a necroptosis cell death processes that also releases immunogenic cell death (ICD) molecules, calreticulin, ATP and HMGB1. Yet, aiming to potentiate therapeutic benefit of our vectors, we explored their association with doxorubicin (Dox) immunogenic chemotherapy, which is also an inducer of ICD. And in this setting, this association with Dox enhances not only cell death levels but also immunogenicity of treated cells, providing superior tumor control in a therapeutic vaccine model, where mice were already bearing B16F10 tumors or MCA205 sarcomas before vaccination. Moreover, associated use of these therapies in situ rescued efficacy of a sub-therapeutic dose of Dox, which in contrast to its therapeutic dose, does not impair cardiac function. Finally, we also evaluated the association with PD-1 or CTLA-4 checkpoint blockade immunotherapy, which in the therapeutic vaccine model induced full tumor rejection in a greater number of mice. In sum, here we provide compelling evidence for the ability of the p19Arf/IFNbeta combined gene transfer to promote cell death and immunogenic stimuli and underscored its potential to be applied as a cancer immunotherapy strateg

Remediation of the p53/Arf and Interferon-beta pathways as a cancer immunotherapy strategy: a gene transfer approach

As células tumorais prosperam como consequência da capacidade de resistir aos mecanismos de morte celular e de evasão da vigilância imunológica. Nós propomos que, em cânceres que possuem o supressor de tumor p53 selvagem, a remediação de ambas dessas defesas pode ser promovida pela transferência genica combinada de vetores adenovirais portadores dos transgenes de p19Arf (proteína supressora de tumor, parceira funcional de p53) e de interferon-beta (IFNbeta, citocina imunomoduladora). De fato, em resultados anteriores, notamos que a transdução combinada (p19Arf/IFNbeta), mas não os tratamentos individuais, em células de melanoma murino B16F10 resulta em aumento massivo de morte celular. Porém a capacidade destas células em processo de morte de desencadear imunidade antitumoral não foi analisada. Nesta tese e em estudos complementares, buscamos investigar os mecanismos moleculares de morte celular envolvidos na resposta imune estimulada por p19Arf/IFNbeta e explorar sua aplicação como imunoterapia do câncer. Inicialmente, em modelo de vacinação profilática, revelamos que o tratamento combinado em células B16F10 promove a expressão de IL-15, ULBP1, dos receptores de morte FAS/APO1 e KILLER/DR5, assim como uma resposta de células natural killer que rejeitam estas células tratadas quando inoculadas em camundongos imunocompetentes singênicos. Após desafio tumoral no flanco oposto, a progressão desses tumores foi fortemente reduzida devido ao engajamento de linfócitos T CD4+ e CD8+, que apresentaram produção aumentada das citocinas IFN-? e TNF-alfa e medeiam proteção antitumoral de longo prazo. Em seguida, explorando um contexto de imunização diferente, a transferência de gênica in situ foi realizada em carcinoma heterotópico de pulmão e exibiu proteção significativa contra um desafio tumoral secundário, apenas quando o tumor primário foi tratado com p19Arf/IFNbeta. Análise de transcriptoma destes tumores indicou uma assinatura quimiotáxica de neutrófilos e linfócitos T CD8+ através das quimiocinas CCL3, CXCL3 e da IL-1beta. Em apoio destas observações, análises mecanicistas in vitro revelaram que células tratadas com p19Arf/IFNbeta ativam programas apoptóticos de p53 e antivirais de IFNbeta, enquanto sucumbem a um processo de morte por necroptose que também libera moléculas de morte celular imunogênica (MCI), calreticulina, ATP e HMGB1. No entanto, procurando potencializar ainda mais o benefício terapêutico dos nossos vetores, exploramos sua associação com o quimioterápico imunogênico doxorrubicina (Dox), que também é indutor de MCI. E nesta associação, percebemos que a Dox aumenta não apenas os níveis de morte celular, mas também a imunogenicidade das células tratadas, proporcionando em um modelo de vacina terapêutica, um controle tumoral superior em camundongos que já portavam antes da vacinação tumores B16F10 ou MCA205. Além disso, a associação in situ destas terapias restaurou a eficácia de uma dose sub-terapêutica de Dox, que em contraste com sua dose terapêutica, não prejudica a função cardíaca. Finalmente, também exploramos a associação com o bloqueio dos pontos de controle imunológicos PD-1 ou CTLA-4, que no modelo de vacina terapêutica, sua associação induziu maior rejeição completa de tumores B16F10. Em conclusão, aqui apresentamos evidências sobre a capacidade da combinação p19Arf/IFNbeta de induzir morte celular e estimulação imunológica. E ressaltamos seu potencial como uma estratégia de imunoterapia do câncerCancer cells thrive as a consequence of resisting cell death mechanisms and escaping from immune surveillance. We propose that, in cancers that harbor the wild-type tumor suppressor p53, remediation of both of these defenses can be achieved by harnessing the adenoviral vector mediated gene transfer of p19Arf (tumor suppressor protein, p53 functional partner) together with interferon-beta (IFNbeta, immunomodulatory cytokine). Indeed, in our initial observations, it was noticed that combined-transduction (p19Arf/IFNbeta), but not the individual treatments, of B16F10 mouse melanoma cells results in massive cell death levels. Yet, the capability of these dying cells to unleash antitumor immunity was not investigated. Here in this thesis and in complementary studies, we sought to investigate the molecular mechanisms of cell death involved in the p19Arf/IFNbeta immune stimulation and explore its potential as a mediator of cancer immunotherapy. First, in a prophylactic B16F10 vaccine model, we revealed that the dual treatment led to the up-regulation of IL-15, ULBP1, FAS/APO1 and KILLER/DR5 death receptors, plus a natural killer cell response that completely rejects treated cells when inoculated in syngeneic immunocompetent mice. Whereas, upon a contralateral tumor challenge, progression was strongly reduced by engaging both CD4+ and CD8+ T cells, which displayed augmented production of IFN-? and TNF-alpha cytokines and provided long term antitumor protection. Next, exploring different immunization context, in situ gene transfer in a heterotopic lung carcinoma exhibited significant protection against a secondary tumor challenge only when the primary tumor was treated with p19Arf/IFNbeta. Transcriptome analysis of these treated tumors indicated a chemotaxic signature of neutrophils and CD8+ T cells with the involvement of CCL3, CXCL3 chemokines and IL-1beta. Moreover, in support of this evidence, mechanistic in vitro studies revealed that p19Arf/IFNbeta treated cells reactivate p53 apoptotic and IFNbeta antiviral programs, while succumbing to a necroptosis cell death processes that also releases immunogenic cell death (ICD) molecules, calreticulin, ATP and HMGB1. Yet, aiming to potentiate therapeutic benefit of our vectors, we explored their association with doxorubicin (Dox) immunogenic chemotherapy, which is also an inducer of ICD. And in this setting, this association with Dox enhances not only cell death levels but also immunogenicity of treated cells, providing superior tumor control in a therapeutic vaccine model, where mice were already bearing B16F10 tumors or MCA205 sarcomas before vaccination. Moreover, associated use of these therapies in situ rescued efficacy of a sub-therapeutic dose of Dox, which in contrast to its therapeutic dose, does not impair cardiac function. Finally, we also evaluated the association with PD-1 or CTLA-4 checkpoint blockade immunotherapy, which in the therapeutic vaccine model induced full tumor rejection in a greater number of mice. In sum, here we provide compelling evidence for the ability of the p19Arf/IFNbeta combined gene transfer to promote cell death and immunogenic stimuli and underscored its potential to be applied as a cancer immunotherapy strateg

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