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2. STEM Education Institutional Change Projects: Examining Enacted Approaches through the Lens of the Four Categories of Change Strategies Model

Author

Feola, S., Lewis, J. E., McAlpin, J. D., Prevost, L. B., Skvoretz, J., Stains, M., Couch, B. A., Earl, B., Ziker, J. P., Lane, A. K., and Shadle, S. E.

Abstract

Enacting STEM education reform is a complex task and there are a variety of approaches that might be selected by change agents. When working on an institutional change project to impact multiple parts of the STEM education system, teams of change agents may select multiple strategies and tactics to enact at one time and over multiple years of a project. However, the literature lacks studies which document and analyze strategies and tactics used by change project teams in a way that can be useful for other change agents. The current study seeks to fill this gap by investigating National Science Foundation-funded change initiatives at three public research universities focused on encouraging the adoption of evidenced-based instructional practices by STEM faculty in order to understand the strategies used within and across projects. Qualitative framework analysis using the lens of the Henderson et al. (Journal of Research in Science Teaching 48(8): 952-984, 2011. https://doi.org/10.1002/tea.20439) Four Categories of Change Strategies Model showed that institutional projects enact a wide range of tactics that span the four strategies represented in the four categories of the model both across institutions and within each institution. The analysis documents a number of change tactics not previously described by the model and offers expanded definitions of the change processes that operate within each category in the context of institutional change projects. This descriptive work advances our understanding of the breadth and depth of actions taken by institutional change initiatives and provides insights into types of variations that might be observed based on different institutional contexts. The current analysis both affirms the value of the original model and identifies expanded ways to think about the four categories within the context of institutional change projects.

Published
2023
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3. Oncolytic ImmunoViroTherapy : A long history of crosstalk between viruses and immune system for cancer treatment

Author

Feola, S., Russo, S., Ylösmäki, E., Cerullo, V., ImmunoViroTherapy Lab, Division of Pharmaceutical Biosciences, Drug Research Program, TRIMM - Translational Immunology Research Program, Digital Precision Cancer Medicine (iCAN), and Divisions of Faculty of Pharmacy

Subjects
T-CELL ENGAGER, HERPES-SIMPLEX-VIRUS, CD40 LIGAND, Oncolytic viruses, cancer immunotherapies, COLONY-STIMULATING FACTOR, Tumor antigens, VACCINIA VIRUS, REPLICATION-COMPETENT, PHASE-I TRIAL, P53 STATUS, 317 Pharmacy, NEWCASTLE-DISEASE VIRUS, ADENOVIRUS ONYX-015, cancer vaccines
Abstract

Cancer Immunotherapy relies on harnessing a patient's immune system to fine-tune specific anti-tumor responses and ultimately eradicate cancer. Among diverse therapeutic approaches, oncolytic viruses (OVs) have emerged as a novel form of cancer immunotherapy. OVs are a naturally occurring or genetically modified class of viruses able to selectively kill cancer cells, leaving healthy cells unharmed; in the last two decades, the role of OVs has been redefined to act beyond their oncolytic activity. Indeed, the immunogenic cancer cell death mediated by OVs induces the release of tumor antigens that in turn induces anti-tumor immunity, allowing OVs to act as in situ therapeutic cancer vaccines. Additionally, OVs can be engineered for intratumoral delivery of immunostimulatory molecules such as tumor antigens or cytokines to further enhance anti-tumor response. Moreover, OVs can be used in combination with other cancer immunotherapeutic approaches such as Immune Checkpoint Inhibitors and CAR-T cells. The current review first defines the three main mechanisms of action (MOA) of OVs currently used in cancer therapy that are: i) Oncolysis, ii) OV-induced cancer-specific immune activation, and iii) Exploiting preexisting anti-viral immunity to enhance cancer therapy. Secondly, we focus on how OVs can induce and/or improve anti-cancer immunity in a specific or unspecific fashion, highlighting the importance of these approaches. Finally, the last part of the review analyses OVs combined with other cancer immunotherapies, revising present and future clinical applications. (c) 2021 Published by Elsevier Inc.

Published
2022

5. Therapeutic cancer vaccination with immunopeptidomics-discovered antigens confers protective antitumor efficacy

Author

Peltonen K., Feola S., Umer H. M., Chiaro J., Mermelekas G., Ylosmaki E., Pesonen S., Branca R. M. M., Lehtio J., Cerullo V., Peltonen, K., Feola, S., Umer, H. M., Chiaro, J., Mermelekas, G., Ylosmaki, E., Pesonen, S., Branca, R. M. M., Lehtio, J., and Cerullo, V.

Subjects
Immunopepti-dome, Breast cancer, Mass spectrometry, Endogenous retroviru, Ligandome, Cancer vaccine, Immunotherapy, Oncolytic vaccine, Tumor antigen
Abstract

Knowledge of clinically targetable tumor antigens is becoming vital for broader design and utility of therapeutic cancer vaccines. This information is obtained reliably by directly interro-gating the MHC-I presented peptide ligands, the immunopeptidome, with state-of-the-art mass spectrometry. Our manuscript describes direct identification of novel tumor antigens for an aggres-sive triple-negative breast cancer model. Immunopeptidome profiling revealed 2481 unique anti-gens, among them a novel ERV antigen originating from an endogenous retrovirus element. The clinical benefit and tumor control potential of the identified tumor antigens and ERV antigen were studied in a preclinical model using two vaccine platforms and therapeutic settings. Prominent control of established tumors was achieved using an oncolytic adenovirus platform designed for flexi-ble and specific tumor targeting, namely PeptiCRAd. Our study presents a pipeline integrating im-munopeptidome analysis-driven antigen discovery with a therapeutic cancer vaccine platform for improved personalized oncolytic immunotherapy.

Published
2021

6. GAMER-Ad: a novel and rapid method for generating recombinant adenoviruses

Author

Hamdan F., Martins B., Feodoroff M., Giannoula Y., Feola S., Fusciello M., Chiaro J., Antignani G., Gronholm M., Ylosmaki E., Cerullo V., Hamdan, F., Martins, B., Feodoroff, M., Giannoula, Y., Feola, S., Fusciello, M., Chiaro, J., Antignani, G., Gronholm, M., Ylosmaki, E., and Cerullo, V.

Subjects
molecular cloning, oncolytic viruses, gene therapy, Gibson Assembly, adenoviruse
Abstract

Oncolytic adenoviruses have become ideal agents in the path toward treating cancer. Such viruses have been engineered to conditionally replicate in malignant cells in which certain signaling pathways have been disrupted. Other than such oncolytic properties, the viruses need to activate the immune system in order to sustain a long-term response. Therefore, oncolytic adenoviruses have been genetically modified to express various immune-stimulatory agents to achieve this. However, genetically modifying adenoviruses is very time consuming and labor intensive with the current available methods. In this paper, we describe a novel method we have called GAMER-Ad to genetically modify adenovirus genomes within 2 days. Our method entails the replacement of the gp19k gene in the E3 region with any given gene of interest (GOI) using Gibson Assembly avoiding the homologous recombination between the shuttle and the parental plasmid. In this manuscript as proof of concept we constructed and characterized three oncolytic adenoviruses expressing CXCL9, CXCL10, and interleukin-15 (IL-15). We demonstrate that our novel method is fast, reliable, and simple compared to other methods. We anticipate that our method will be used in the future to genetically engineer oncolytic but also other adenoviruses used for gene therapy as well.

Published
2021

7. Characterization of a novel OX40 ligand and CD40 ligand-expressing oncolytic adenovirus used in the PeptiCRAd cancer vaccine platform

Author

Ylosmaki E., Ylosmaki L., Fusciello M., Martins B., Ahokas P., Cojoc H., Uoti A., Feola S., Kreutzman A., Ranki T., Karbach J., Viitala T., Priha P., Jager E., Pesonen S., Cerullo V., Ylosmaki, E., Ylosmaki, L., Fusciello, M., Martins, B., Ahokas, P., Cojoc, H., Uoti, A., Feola, S., Kreutzman, A., Ranki, T., Karbach, J., Viitala, T., Priha, P., Jager, E., Pesonen, S., and Cerullo, V.

Subjects
T cell activation, CD40L, oncolytic vaccine, PeptiCRAd, OX40L
Abstract

Ylösmäki et al. develop an oncolytic adenovirus expressing immunostimulatory cytokines OX40L and CD40L. This virus was tested in a peptide-based cancer vaccine platform called PeptiCRAd. Intratumoral administration of PeptiCRAd induced systemic and intratumoral tumor-specific T cell responses, reduced tumor growth, and sensitized tumors to immune checkpoint inhibitor therapy.

Published
2021

8. Viral molecular mimicry influences the antitumor immune response in murine and human melanoma

Author

Chiaro J., Kasanen H. H. E., Whalley T., Capasso C., Gronholm M., Feola S., Peltonen K., Hamdan F., Hernberg M., Makela S., Karhapaa H., Brown P. E., Martins B., Fusciello M., Ylosmaki E. O., Greco D., Kreutzman A. S., Mustjoki S., Szomolay B., Cerullo V., Chiaro, J., Kasanen, H. H. E., Whalley, T., Capasso, C., Gronholm, M., Feola, S., Peltonen, K., Hamdan, F., Hernberg, M., Makela, S., Karhapaa, H., Brown, P. E., Martins, B., Fusciello, M., Ylosmaki, E. O., Greco, D., Kreutzman, A. S., Mustjoki, S., Szomolay, B., and Cerullo, V.

Subjects
Mice, Animal, Cell Line, Tumor, Molecular Mimicry, Immunity, Female, Immunotherapy, Melanoma, Human
Abstract

Molecular mimicry is one of the leading mechanisms by which infectious agents can induce autoimmunity. Whether a similar mechanism triggers an antitumor immune response is unexplored, and the role of antiviral T cells infiltrating the tumor has remained anecdotal. To address these questions, we first developed a bioinformatic tool to identify tumor peptides with high similarity to viral epitopes. Using peptides identified by this tool, we demonstrated that, in mice, preexisting immunity toward specific viral epitopes enhanced the efficacy of cancer immunotherapy via molecular mimicry in different settings. To understand whether this mechanism could partly explain immunotherapy responsiveness in humans, we analyzed a cohort of patients with melanoma undergoing anti-PD1 treatment who had a high IgG titer for cytomegalovirus (CMV). In this cohort of patients, we showed that high levels of CMV-specific antibodies were associated with prolonged progression-free survival and found that, in some cases, peripheral blood mononuclear cells (PBMC) could cross-react with both melanoma and CMV homologous peptides. Finally, T-cell receptor sequencing revealed expansion of the same CD8þ T-cell clones when PBMCs were expanded with tumor or homologous viral peptides. In conclusion, we have demonstrated that preexisting immunity and molecular mimicry could influence the response to immunotherapies. In addition, we have developed a free online tool that can identify tumor antigens and neoantigens highly similar to pathogen antigens to exploit molecular mimicry and cross-reactive T cells in cancer vaccine development.

Published
2021

9. Novel personalized cancer vaccine platform based on Bacillus Calmette-Guèrin

Author

Ylosmaki E., Fusciello M., Martins B., Feola S., Hamdan F., Chiaro J., Ylosmaki L., Vaughan M. J., Viitala T., Kulkarni P. S., Cerullo V., Ylosmaki, E., Fusciello, M., Martins, B., Feola, S., Hamdan, F., Chiaro, J., Ylosmaki, L., Vaughan, M. J., Viitala, T., Kulkarni, P. S., and Cerullo, V.

Subjects
Animal, active, adaptive immunity, immunogenicity, immunity, Disease Models, Animal, Mice, vaccine, Cell Line, Tumor, BCG Vaccine, Female, Immunotherapy, Precision Medicine, cellular, Cancer Vaccine, Human
Abstract

Background Intratumoral BCG therapy, one of the earliest immunotherapies, can lead to infiltration of immune cells into a treated tumor. However, an increase in the number of BCG-induced tumor-specific T cells in the tumor microenvironment could lead to enhanced therapeutic effects. Methods Here, we have developed a novel cancer vaccine platform based on BCG that can broaden BCG-induced immune responses to include tumor antigens. By physically attaching tumor-specific peptides onto the mycobacterial outer membrane, we were able to induce strong systemic and intratumoral T cell-specific immune responses toward the attached tumor antigens. These therapeutic peptides can be efficiently attached to the mycobacterial outer membrane using a poly-lysine sequence N-terminally fused to the tumor-specific peptides. Results Using two mouse models of melanoma and a mouse model of colorectal cancer, we observed that the antitumor immune responses of BCG could be improved by coating the BCG with tumor-specific peptides. In addition, by combining this novel cancer vaccine platform with anti-programmed death 1 (anti-PD-1) immune checkpoint inhibitor (ICI) therapy, the number of responders to anti-PD-1 immunotherapy was markedly increased. Conclusions This study shows that intratumoral BCG immunotherapy can be improved by coating the bacteria with modified tumor-specific peptides. In addition, this improved BCG immunotherapy can be combined with ICI therapy to obtain enhanced tumor growth control. These results warrant clinical testing of this novel cancer vaccine platform.

Published
2021

10. Oncolytic ImmunoViroTherapy: A long history of crosstalk between viruses and immune system for cancer treatment

Author

Feola, S., Russo, S., Ylösmäki, E., and Cerullo, V.

Subjects
Pharmacology, Oncolytic Virotherapy, Oncolytic Viruses, Antigens, Neoplasm, Immune System, Neoplasms, Humans, Pharmacology (medical), Immunotherapy
Abstract

Cancer Immunotherapy relies on harnessing a patient's immune system to fine-tune specific anti-tumor responses and ultimately eradicate cancer. Among diverse therapeutic approaches, oncolytic viruses (OVs) have emerged as a novel form of cancer immunotherapy. OVs are a naturally occurring or genetically modified class of viruses able to selectively kill cancer cells, leaving healthy cells unharmed; in the last two decades, the role of OVs has been redefined to act beyond their oncolytic activity. Indeed, the immunogenic cancer cell death mediated by OVs induces the release of tumor antigens that in turn induces anti-tumor immunity, allowing OVs to act as in situ therapeutic cancer vaccines. Additionally, OVs can be engineered for intratumoral delivery of immunostimulatory molecules such as tumor antigens or cytokines to further enhance anti-tumor response. Moreover, OVs can be used in combination with other cancer immunotherapeutic approaches such as Immune Checkpoint Inhibitors and CAR-T cells. The current review first defines the three main mechanisms of action (MOA) of OVs currently used in cancer therapy that are: i) Oncolysis, ii) OV-induced cancer-specific immune activation, and iii) Exploiting pre-existing anti-viral immunity to enhance cancer therapy. Secondly, we focus on how OVs can induce and/or improve anti-cancer immunity in a specific or unspecific fashion, highlighting the importance of these approaches. Finally, the last part of the review analyses OVs combined with other cancer immunotherapies, revising present and future clinical applications.

Published
2021

13. Landscape-scale patterns of alien plant species on coastal dunes: the case of iceplant in central Italy

Author

CARRANZA M. L, CARBONI M, FEOLA S, ACOSTA, ALICIA TERESA ROSARIO, CARBONI, MARTA, CARRANZA M., L, Carboni, M, Feola, S, Acosta, ALICIA TERESA ROSARIO, and Carboni, Marta

Subjects
Ecology, biology, Between patch boundary, Electivity, Iceplant (Carpobrotus aff. acinaciformis (L.) L. Bolus), Land-cover map, Landscape metrics, Mediterranean coast, Spatial pattern, Propagule pressure, Carpobrotus, Introduced species, Vegetation, Management, Monitoring, Policy and Law, biology.organism_classification, Invasive species, Geography, Habitat, Common spatial pattern, Scale (map), Nature and Landscape Conservation
Abstract

Question: We investigated the spatial pattern of coastal landscapes invaded by iceplant (Carpobrotus aff. acinaciformis) focusing on two questions: (1) Does the spatial structure of iceplant patches differ from that of native natural costal dune cover types?; (2) Is the distribution of iceplant patches related to other cover types? Location: Tyrrhenian coast of Central Italy. Method: On the basis of a detailed land-cover map, we calculated structural metrics for iceplant patches and for each native coastal dune cover category (mean patch size and patch shape index) and compared them by means of anova. To assess the spatial association between iceplant patches and the different cover types, we implemented an electivity analysis which analyses the frequency of common borders. Results: The mapped coastal dune cover types included beaches, dunes and sand plain variants, related to the typical Tyrrhenian coastal dune vegetation zonation. Iceplant-dominated vegetation presented elongated and irregularly shaped patches, which were not significantly different from most of the natural cover types suggesting a natural spread along the territory analysed. Iceplant patches were positively associated with beach, mobile and inter-dune cover types indicating that these habitats are exposed to further alien spread. Iceplant patches were also positively associated with artificial surfaces highlighting this cover type as a possible source of propagule pressure. Conclusions: The proposed landscape approach combining patch-based metrics with edge-based metrics provided a comprehensive description of the invaded coastal landscape. From an applied research perspective, this landscape approach could be useful in identifying the correct management strategies for alien-invaded areas.

Published
2010
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15. Exploiting the Pre-Existing Immunity to Adenoviruses for Cancer Immunotherapy

Author

capasso, (Capasso, C, 1 ), Cristian), Frascaro, (Frascaro, F, 2 ), Federica), Carpi, Sara, (Carpi, S, 3 ), Sara), Tahtinen, (Tahtinen, S, 1 ), Siri), Feola, (Feola, S, 4 ), Sara), Fusciello, (Fusciello, M, 1 ), Manlio), Peltonen, (Peltonen, K, 1 ), Karita), Martins, (Martins, B, 1 ), Beatriz), Sjoberg, (Sjoberg, M, 1 ), Madeleine), Pesonen, (Pesonen, S, 5 ), Sari), Ranki, (Ranki, T, 5 ), Tuuli), Ylosmaki, (Ylosmaki, E, 1 ), Erkko), Cerullo, (Cerullo, V, and Vincenzo

Published
2017

22. Il contenzioso in chirurgia estetica: un caso di mastoplastica additiva

Author

Agostini, S, Eramo, A, Feola, S, Marsella, Lt, and T

Subjects
Cosmetic Breast Augmentation, responsabilità professionale, mastoplastica additiva, mastoplastica additiva, Settore MED/43 - Medicina Legale, professional responsibility, Cosmetic Breast Augmentation, professional responsibility, responsabilità professionale
Published
2010

23. Landscape scale patterns of alien plant species on coastal dunes. The case of iceplant in central Italy

Author

Carranza, Maria Laura, Carboni, M, Feola, S, and Acosta, A. T. R.

Subjects
between patch boundary, Mediterranean coast, between patch boundary, iceplant (Carpobrotus aff. acinaciformis (L.) L. Bolus), electivity, land cover map, landscape metrics, Mediterranean coast, spatial pattern, spatial pattern, landscape metrics, land cover map, iceplant (Carpobrotus aff. acinaciformis (L.) L. Bolus), electivity
Published
2010

36. Karyology and molecular biology

Author

Angelici, M. C., Gramiccia, M., Gradoni, L., Angelici, M. C., Ponzi, M., Birago, C., Battaglia, P. A., Cremisi, F., Vignali, E., Rilji, F., Batistoni, E., Androhico, F., Barsacchi-Pilone, G., Capriglione, T., Olmo, E., Cau, A., Deiana, A. M., Salvadori, S., Laudani, U., Gallent, L., Canovai, R., Esposito, A., Stanyon, H., Gianguzza, M., Dolcemascolo, G., Lunadei, M., Marco, A. del, Valentino, F., Rocchi, A., Manicardi, G. C., Garagna, S., Redi, C. A., Bertolani, R., Zuccotti, M., Miceli, C., La Terza, A., Zhang, S., Orias, E., Motta, C. M., Filosa, S., Feola, S., Fiorentino, S., Anoreuccetti, P., Odierna, G., Cobror, O., Olmo, E., Morescalchi, A., Olmo, E., Odierna, G., Cobror, O., Capriglione, T., Pala, M., Vacca, R. A., Casu, S., Ragghianti, M., Bucci, S., Mancino, G., Lacroix, J. C., Rocchi, A., Lanza, V., Castro, M. di, Rubini, M., Goldoni, D., Lunghi, R., Fontana, F., Salvini, M., Barone, E., Giannessi, M., Nobili, R., Stingo, V., Castaldo, G., Improta, R., Stingo, V., Ciampa, C., and Rocco, L.

Published
1986
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42. Karyology and molecular biology

Author

Angelici, M. C., primary, Gramiccia, M., additional, Gradoni, L., additional, Angelici, M. C., additional, Ponzi, M., additional, Birago, C., additional, Battaglia, P. A., additional, Cremisi, F., additional, Vignali, E., additional, Rilji, F., additional, Batistoni, E., additional, Androhico, F., additional, Barsacchi‐Pilone, G., additional, Capriglione, T., additional, Olmo, E., additional, Cau, A., additional, Deiana, A. M., additional, Salvadori, S., additional, Laudani, U., additional, Gallent, L., additional, Canovai, R., additional, Esposito, A., additional, Stanyon, H., additional, Gianguzza, M., additional, Dolcemascolo, G., additional, Lunadei, M., additional, del Marco, A., additional, Valentino, F., additional, Rocchi, A., additional, Manicardi, G. C., additional, Garagna, S., additional, Redi, C. A., additional, Bertolani, R., additional, Zuccotti, M., additional, Miceli, C., additional, La Terza, A., additional, Zhang, S., additional, Orias, E., additional, Motta, C. M., additional, Filosa, S., additional, Feola, S., additional, Fiorentino, S., additional, Anoreuccetti, P., additional, Odierna, G., additional, Cobror, O., additional, Morescalchi, A., additional, Pala, M., additional, Vacca, R. A., additional, Casu, S., additional, Ragghianti, M., additional, Bucci, S., additional, Mancino, G., additional, Lacroix, J. C., additional, Lanza, V., additional, di Castro, M., additional, Rubini, M., additional, Goldoni, D., additional, Lunghi, R., additional, Fontana, F., additional, Salvini, M., additional, Barone, E., additional, Giannessi, M., additional, Nobili, R., additional, Stingo, V., additional, Castaldo, G., additional, Improta, R., additional, Ciampa, C., additional, and Rocco, L., additional

Published
1986
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43. Artificially cloaked viral nanovaccine for cancer immunotherapy

Author

Flavia Fontana, Harri Alenius, Leena Ylösmäki, Hélder A. Santos, Beatriz Martins, Cristian Capasso, Vincenzo Cerullo, Jouni Hirvonen, Arto Urtti, Otto K. Kari, Firas Hamdan, Manlio Fusciello, Erkko Ylösmäki, Sara Feola, Jacopo Chiaro, Siri Tähtinen, Karita Peltonen, Joseph Ndika, ImmunoViroTherapy Lab, Division of Pharmaceutical Biosciences, Drug Research Program, Digital Precision Cancer Medicine (iCAN), Nanomedicines and Biomedical Engineering, Division of Pharmaceutical Chemistry and Technology, Drug Delivery Unit, Department of Bacteriology and Immunology, Medicum, HUMI - Human Microbiome Research, Drug Delivery, Jouni Hirvonen / Principal Investigator, Helsinki One Health (HOH), Helsinki Institute of Life Science HiLIFE, Fusciello, M., Fontana, F., Tahtinen, S., Capasso, C., Feola, S., Martins, B., Chiaro, J., Peltonen, K., Ylosmaki, L., Ylosmaki, E., Hamdan, F., Kari, O. K., Ndika, J., Alenius, H., Urtti, A., Hirvonen, J. T., Santos, H. A., and Cerullo, V.

Subjects
0301 basic medicine, medicine.medical_treatment, General Physics and Astronomy, Cancer immunotherapy, 02 engineering and technology, Injections, Intralesional, T-CELL THERAPY, Mice, Nanoparticle, oncoimmunology, Neoplasms, NANOPARTICLES, Medicine, lcsh:Science, IN-VIVO, Multidisciplinary, 318 Medical biotechnology, Melanoma, 021001 nanoscience & nanotechnology, SOLID TUMORS, 3. Good health, Oncolytic Viruses, CO-DELIVERY, oncolytic vaccines, Treatment Outcome, 317 Pharmacy, VACCINATION, Female, immunotherapy, 0210 nano-technology, Cancer Vaccine, Human, Science, ANTIGEN, Drug development, Oncolytic Viruse, Cancer Vaccines, GENE-TRANSFER, Article, General Biochemistry, Genetics and Molecular Biology, OVARIAN-CANCER, Adenoviridae, ADENOVIRUS, 03 medical and health sciences, Immune system, Antigen, Antigens, Neoplasm, Cell Line, Tumor, Animals, Humans, oncolytic virus, business.industry, Animal, Cell Membrane, Cancer, General Chemistry, Immunotherapy, medicine.disease, Xenograft Model Antitumor Assays, Oncolytic virus, Disease Models, Animal, 030104 developmental biology, biohybrid nanoparticles, Cancer research, Neoplasm, lcsh:Q, business, Ovarian cancer
Abstract

Virus-based cancer vaccines are nowadays considered an interesting approach in the field of cancer immunotherapy, despite the observation that the majority of the immune responses they elicit are against the virus and not against the tumor. In contrast, targeting tumor associated antigens is effective, however the identification of these antigens remains challenging. Here, we describe ExtraCRAd, a multi-vaccination strategy focused on an oncolytic virus artificially wrapped with tumor cancer membranes carrying tumor antigens. We demonstrate that ExtraCRAd displays increased infectivity and oncolytic effect in vitro and in vivo. We show that this nanoparticle platform controls the growth of aggressive melanoma and lung tumors in vivo both in preventive and therapeutic setting, creating a highly specific anti-cancer immune response. In conclusion, ExtraCRAd might serve as the next generation of personalized cancer vaccines with enhanced features over standard vaccination regimens, representing an alternative way to target cancer., Cancer therapy using oncolytic virus has shown pre-clinical and clinical efficacy. Here, the authors report ExtraCRAd, an oncolytic virus cloaked with tumour cell membrane and report its therapeutic effects in vitro and in vivo in multiple mouse tumour models.

Published
2019
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44. Biohybrid Vaccines for Improved Treatment of Aggressive Melanoma with Checkpoint Inhibitor

Author

Jacopo Chiaro, Hélder A. Santos, Vincenzo Cerullo, Manlio Fusciello, Flavia Fontana, Christianne Groeneveldt, Zehua Liu, Jouni Hirvonen, Ermei Mäkilä, Jarno Salonen, Cristian Capasso, Sara Feola, Nanomedicines and Biomedical Engineering, Division of Pharmaceutical Chemistry and Technology, Drug Research Program, ImmunoViroTherapy Lab, Division of Pharmaceutical Biosciences, Jouni Hirvonen / Principal Investigator, University Management, Helsinki Institute of Life Science HiLIFE, Fontana, F., Fusciello, M., Groeneveldt, C., Capasso, C., Chiaro, J., Feola, S., Liu, Z., Makila, E. M., Salonen, J. J., Hirvonen, J. T., Cerullo, V., and Santos, H. A.

Subjects
BLOCKADE, medicine.medical_treatment, immune checkpoint inhibitor, General Physics and Astronomy, 02 engineering and technology, 01 natural sciences, Mice, Cancer immunotherapy, Tumor Microenvironment, NANOPARTICLES, General Materials Science, nanotechnology, Melanoma, General Engineering, 021001 nanoscience & nanotechnology, 3. Good health, porous silicon, 317 Pharmacy, CANCER-IMMUNOTHERAPY, immunotherapy, 221 Nano-technology, cancer vaccine, 0210 nano-technology, biohybrid, ANTIGEN, microfluidics, Antigen-Presenting Cells, 010402 general chemistry, Cancer Vaccines, DELIVERY, SURFACE-CHEMISTRY, Immune system, Antigens, Neoplasm, Cell Line, Tumor, melanoma, medicine, Animals, Tumor microenvironment, business.industry, Cancer, Immunotherapy, EFFICACY, medicine.disease, 0104 chemical sciences, Mice, Inbred C57BL, ACETALATED DEXTRAN, IMMUNE CELLS, Tumor progression, Cancer research, 1182 Biochemistry, cell and molecular biology, Cancer vaccine, business, cell membrane, TUMOR-CELL VACCINE
Abstract

[Image: see text] Recent approaches in the treatment of cancer focus on involving the immune system to control the tumor growth. The administration of immunotherapies, like checkpoint inhibitors, has shown impressive results in the long term survival of patients. Cancer vaccines are being investigated as further tools to prime tumor-specific immunity. Biomaterials show potential as adjuvants in the formulation of vaccines, and biomimetic elements derived from the membrane of tumor cells may widen the range of antigens contained in the vaccine. Here, we show how mice presenting an aggressive melanoma tumor model treated twice with the complete nanovaccine formulation showed control on the tumor progression, while in a less aggressive model, the animals showed remission and control on the tumor progression, with a modification in the immunological profile of the tumor microenvironment. We also prove that co-administration of the nanovaccine together with a checkpoint inhibitor increases the efficacy of the treatment (87.5% of the animals responding, with 2 remissions) compared to the checkpoint inhibitor alone in the B16.OVA model. Our platform thereby shows potential applications as a cancer nanovaccine in combination with the standard clinical care treatment for melanoma cancers.

Published
2019
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45. Novel oncolytic adenovirus expressing enhanced cross-hybrid IgGA Fc PD-L1 inhibitor activates multiple immune effector populations leading to enhanced tumor killing in vitro, in vivo and with patient-derived tumor organoids

Author

Hamdan, Firas, Ylösmäki, Erkko, Chiaro, Jacopo, Giannoula, Yvonne, Long, Maeve, Fusciello, Manlio, Feola, Sara, Martins, Beatriz, Feodoroff, Michaela, Antignani, Gabriella, Russo, Salvatore, Kari, Otto, Lee, Moon, Järvinen, Petrus, Nisen, Harry, Kreutzman, Anna, Leusen, Jeanette, Mustjoki, Satu, McWilliams, Thomas G., Grönholm, Mikaela, Cerullo, Vincenzo, Hamdan, F., Ylosmaki, E., Chiaro, J., Giannoula, Y., Long, M., Fusciello, M., Feola, S., Martins, B., Feodoroff, M., Antignani, G., Russo, S., Kari, O., Lee, M., Jarvinen, P., Nisen, H., Kreutzman, A., Leusen, J., Mustjoki, S., Mcwilliams, T. G., Gronholm, M., Cerullo, V., Division of Pharmaceutical Biosciences, Drug Research Program, ImmunoViroTherapy Lab, Drug Delivery, TRIMM - Translational Immunology Research Program, STEMM - Stem Cells and Metabolism Research Program, Department of Anatomy, Medicum, Institute for Molecular Medicine Finland, Research Services, Drug Delivery Unit, HUS Abdominal Center, HUSLAB, HUS Comprehensive Cancer Center, Department of Clinical Chemistry and Hematology, Digital Precision Cancer Medicine (iCAN), Research Programs Unit, Faculty of Medicine, and Biosciences

Subjects
Organoid, BLOCKADE, Immune Checkpoint Inhibitor, 3122 Cancers, Oncolytic Viruse, GAMMA-RS, Mice, SCID, Receptors, Fc, THERAPY, Adenoviridae, Mice, Mice, Inbred NOD, Cell Line, Tumor, NEUTROPHILS, Oncolytic Virotherapy, RECEPTOR, Animal, EFFICACY, antibody formation, CANCER, Immunoglobulin A, ANTIBODY, 317 Pharmacy, REPLICATION, T-CELLS, 1182 Biochemistry, cell and molecular biology, Neoplasm, Female, Immunotherapy, Human
Abstract

Background Despite the success of immune checkpoint inhibitors against PD-L1 in the clinic, only a fraction of patients benefit from such therapy. A theoretical strategy to increase efficacy would be to arm such antibodies with Fc-mediated effector mechanisms. However, these effector mechanisms are inhibited or reduced due to toxicity issues since PD-L1 is not confined to the tumor and also expressed on healthy cells. To increase efficacy while minimizing toxicity, we designed an oncolytic adenovirus that secretes a cross-hybrid Fc-fusion peptide against PD-L1 able to elicit effector mechanisms of an IgG1 and also IgA1 consequently activating neutrophils, a population neglected by IgG1, in order to combine multiple effector mechanisms. Methods The cross-hybrid Fc-fusion peptide comprises of an Fc with the constant domains of an IgA1 and IgG1 which is connected to a PD-1 ectodomain via a GGGS linker and was cloned into an oncolytic adenovirus. We demonstrated that the oncolytic adenovirus was able to secrete the cross-hybrid Fc-fusion peptide able to bind to PD-L1 and activate multiple immune components enhancing tumor cytotoxicity in various cancer cell lines, in vivo and ex vivo renal-cell carcinoma patient-derived organoids. Results Using various techniques to measure cytotoxicity, the cross-hybrid Fc-fusion peptide expressed by the oncolytic adenovirus was shown to activate Fc-effector mechanisms of an IgA1 (neutrophil activation) as well as of an IgG1 (natural killer and complement activation). The activation of multiple effector mechanism simultaneously led to significantly increased tumor killing compared with FDA-approved PD-L1 checkpoint inhibitor (Atezolizumab), IgG1-PDL1 and IgA-PDL1 in various in vitro cell lines, in vivo models and ex vivo renal cell carcinoma organoids. Moreover, in vivo data demonstrated that Ad-Cab did not require CD8+ T cells, unlike conventional checkpoint inhibitors, since it was able to activate other effector populations. Conclusion Arming PD-L1 checkpoint inhibitors with Fc-effector mechanisms of both an IgA1 and an IgG1 can increase efficacy while maintaining safety by limiting expression to the tumor using oncolytic adenovirus. The increase in tumor killing is mostly attributed to the activation of multiple effector populations rather than activating a single effector population leading to significantly higher tumor killing.

Published
2021

46. PeptiCHIP : A Microfluidic Platform for Tumor Antigen Landscape Identification

Author

Janne Lehtiö, Antonio Federico, Jacopo Chiaro, Satu Koskela, Gabriella Antignani, Karita Peltonen, Olga L. Gurvich, Cristian Capasso, Erkko Ylösmäki, Jukka Partanen, Tuija Kekarainen, Dario Greco, Salvatore Russo, Masoumeh Eshaghi, Tiina Sikanen, Antti Rannikko, Rui M. M. Branca, Mikaela Grönholm, Markus Haapala, Vincenzo Cerullo, Firas Hamdan, Seppo Ylä-Herttuala, Michaela Feodoroff, Sara Feola, Sari Tähkä, Manlio Fusciello, Beatriz Martins, Vilja Pietiäinen, Tampere University, BioMediTech, ImmunoViroTherapy Lab, Division of Pharmaceutical Biosciences, TRIMM - Translational Immunology Research Program, Drug Research Program, Division of Pharmaceutical Chemistry and Technology, Tiina Sikanen / Chemical Microsystems Lab, Institute for Molecular Medicine Finland, Precision Systems Medicine, Research Program in Systems Oncology, Clinicum, Department of Surgery, Urologian yksikkö, HUS Abdominal Center, Faculty of Pharmacy, Biosciences, Feola, S., Haapala, M., Peltonen, K., Capasso, C., Martins, B., Antignani, G., Federico, A., Pietiainen, V., Chiaro, J., Feodoroff, M., Russo, S., Rannikko, A., Fusciello, M., Koskela, S., Partanen, J., Hamdan, F., Tahka, S. M., Ylosmaki, E., Greco, D., Gronholm, M., Kekarainen, T., Eshaghi, M., Gurvich, O. L., Yla-Herttuala, S., M. Branca R., M., Lehtio, J., Sikanen, T. M., and Cerullo, V.

Subjects
Computer science, 116 Chemical sciences, microfluidic, General Physics and Astronomy, HLA peptide, Tandem mass spectrometry, Ligands, 0302 clinical medicine, General Materials Science, 0303 health sciences, 318 Medical biotechnology, biology, ligandome, HLA peptides, DERIVE, General Engineering, IMMUNOPEPTIDOMICS, PEPTIDES, SELF, Tumor antigen, 3. Good health, Identification (information), 317 Pharmacy, Biotinylation, Peptide, Human, Affinity matrix, Microfluidics, microfluidics, Ligand, Computational biology, Human leukocyte antigen, Major histocompatibility complex, Article, VALIDATION, thiol-enes, 03 medical and health sciences, Antigens, Neoplasm, Humans, 030304 developmental biology, Histocompatibility Antigens Class I, thiol-ene, affinity purification, MASS-SPECTROMETRY, DISCOVERY, thiol−enes, biology.protein, 1182 Biochemistry, cell and molecular biology, 3111 Biomedicine, 030215 immunology
Abstract

Publisher Copyright: © 2021 The Authors. Published by American Chemical Society. Identification of HLA class I ligands from the tumor surface (ligandome or immunopeptidome) is essential for designing T-cell mediated cancer therapeutic approaches. However, the sensitivity of the process for isolating MHC-I restricted tumor-specific peptides has been the major limiting factor for reliable tumor antigen characterization, making clear the need for technical improvement. Here, we describe our work from the fabrication and development of a microfluidic-based chip (PeptiCHIP) and its use to identify and characterize tumor-specific ligands on clinically relevant human samples. Specifically, we assessed the potential of immobilizing a pan-HLA antibody on solid surfaces via well-characterized streptavidin-biotin chemistry, overcoming the limitations of the cross-linking chemistry used to prepare the affinity matrix with the desired antibodies in the immunopeptidomics workflow. Furthermore, to address the restrictions related to the handling and the limited availability of tumor samples, we further developed the concept toward the implementation of a microfluidic through-flow system. Thus, the biotinylated pan-HLA antibody was immobilized on streptavidin-functionalized surfaces, and immune-affinity purification (IP) was carried out on customized microfluidic pillar arrays made of thiol-ene polymer. Compared to the standard methods reported in the field, our methodology reduces the amount of antibody and the time required for peptide isolation. In this work, we carefully examined the specificity and robustness of our customized technology for immunopeptidomics workflows. We tested this platform by immunopurifying HLA-I complexes from 1 × 106 cells both in a widely studied B-cell line and in patients-derived ex vivo cell cultures, instead of 5 × 108 cells as required in the current technology. After the final elution in mild acid, HLA-I-presented peptides were identified by tandem mass spectrometry and further investigated by in vitro methods. These results highlight the potential to exploit microfluidics-based strategies in immunopeptidomics platforms and in personalized immunopeptidome analysis from cells isolated from individual tumor biopsies to design tailored cancer therapeutic vaccines. Moreover, the possibility to integrate multiple identical units on a single chip further improves the throughput and multiplexing of these assays with a view to clinical needs.

Published
2021

47. Tumor Suppressor Role of hsa-miR-193a-3p and -5p in Cutaneous Melanoma

Author

Vincenzo Cerullo, Valentina Citi, Paola Nieri, Sara Feola, Sara Carpi, Filippo M. Santorelli, Antonella Romanini, Stefano Doccini, Alma Martelli, Beatrice Polini, ImmunoViroTherapy Lab, Division of Pharmaceutical Biosciences, Drug Research Program, TRIMM - Translational Immunology Research Program, Digital Precision Cancer Medicine (iCAN), University of Helsinki, Polini, B., Carpi, S., Doccini, S., Citi, V., Martelli, A., Feola, S., Santorelli, F. M., Cerullo, V., Romanini, A., and Nieri, P.

Subjects
Male, Skin Neoplasms, PI3K/AKT PATHWAY, Exosomes, lcsh:Chemistry, 0302 clinical medicine, miR-193a-5p, Medicine, Gene Regulatory Networks, lcsh:QH301-705.5, 3' Untranslated Regions, Melanoma, Spectroscopy, IN-VIVO, MIR-193A-3P, 0303 health sciences, microRNA, NECROSIS, General Medicine, Middle Aged, 3. Good health, Computer Science Applications, Cutaneous melanoma, MicroRNA, MiR-193a-3p, MiR-193a-5p, Tumor suppressor, Gene Expression Regulation, Neoplastic, 030220 oncology & carcinogenesis, Female, Signal Transduction, ERBB RECEPTORS, EXPRESSION, tumor suppressor, Cell Survival, TROY, Down-Regulation, Exosome, Catalysis, Article, Inorganic Chemistry, 03 medical and health sciences, cutaneous melanoma, LUNG-CANCER, Downregulation and upregulation, Cell Line, Tumor, Humans, Viability assay, Physical and Theoretical Chemistry, Molecular Biology, Protein kinase B, neoplasms, PI3K/AKT/mTOR pathway, 030304 developmental biology, Cell Proliferation, Cell growth, business.industry, Organic Chemistry, medicine.disease, body regions, MicroRNAs, lcsh:Biology (General), lcsh:QD1-999, Case-Control Studies, FACTOR RECEPTOR SUPERFAMILY, Cancer research, 1182 Biochemistry, cell and molecular biology, business
Abstract

Background: Remarkable deregulation of several microRNAs (miRNAs) is demonstrated in cutaneous melanoma. hsa-miR-193a-3p is reported to be under-expressed in tissues and in plasma of melanoma patients, but the role of both miR-193a arms in melanoma is not known yet. Methods: After observing the reduced levels of miR-193a arms in plasma exosomes of melanoma patients, the effects of hsa-miR-193a-3p and &ndash, 5p transfection in cutaneous melanoma cell lines are investigated. Results: In melanoma cell lines A375, 501Mel, and MeWo, the ectopic over-expression of miR-193a arms significantly reduced cell viability as well as the expression of genes involved in proliferation (ERBB2, KRAS, PIK3R3, and MTOR) and apoptosis (MCL1 and NUSAP1). These functional features were accompanied by a significant downregulation of Akt and Erk pathways and a strong increase in the apoptotic process. Since in silico databases revealed TROY, an orphan member of the tumor necrosis receptor family, as a potential direct target of miR-193a-5p, this possibility was investigated using the luciferase assay and excluded by our results. Conclusions: Our results underline a relevant role of miR-193a, both -3p and -5p, as tumor suppressors clarifying the intracellular mechanisms involved and suggesting that their ectopic over-expression could represent a novel treatment for cutaneous melanoma patients.

Published
2020

48. Uncovering the Tumor Antigen Landscape: What to Know about the Discovery Process

Author

Beatriz Martins, Vincenzo Cerullo, Jacopo Chiaro, Sara Feola, Feola, S., Chiaro, J., Martins, B., and Cerullo, V.

Subjects
0301 basic medicine, Cancer Research, immunopeptidome, medicine.medical_treatment, Computational biology, Review, Biology, lcsh:RC254-282, Epitope, 03 medical and health sciences, epitope prediction, 0302 clinical medicine, Immune system, Antigen, Cancer immunotherapy, medicine, Cytotoxic T cell, Tumor microenvironment, cancer immunotherapy, Immunotherapy, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Tumor antigen, 3. Good health, 030104 developmental biology, Oncology, tumor antigens, 030220 oncology & carcinogenesis
Abstract

According to the latest available data, cancer is the second leading cause of death, highlighting the need for novel cancer therapeutic approaches. In this context, immunotherapy is emerging as a reliable first-line treatment for many cancers, particularly metastatic melanoma. Indeed, cancer immunotherapy has attracted great interest following the recent clinical approval of antibodies targeting immune checkpoint molecules, such as PD-1, PD-L1, and CTLA-4, that release the brakes of the immune system, thus reviving a field otherwise poorly explored. Cancer immunotherapy mainly relies on the generation and stimulation of cytotoxic CD8 T lymphocytes (CTLs) within the tumor microenvironment (TME), priming T cells and establishing efficient and durable anti-tumor immunity. Therefore, there is a clear need to define and identify immunogenic T cell epitopes to use in therapeutic cancer vaccines. Naturally presented antigens in the human leucocyte antigen-1 (HLA-I) complex on the tumor surface are the main protagonists in evocating a specific anti-tumor CD8+ T cell response. However, the methodologies for their identification have been a major bottleneck for their reliable characterization. Consequently, the field of antigen discovery has yet to improve. The current review is intended to define what are today known as tumor antigens, with a main focus on CTL antigenic peptides. We also review the techniques developed and employed to date for antigen discovery, exploring both the direct elution of HLA-I peptides and the in silico prediction of epitopes. Finally, the last part of the review analyses the future challenges and direction of the antigen discovery field.

Published
2020

49. Oncolytic adenovirus drives specific immune response generated by a poly-epitope pDNA vaccine encoding melanoma neoantigens into the tumor site

Author

Vincenzo Cerullo, Alessandra Lopes, Gaëlle Vandermeulen, Sophie Ligot, Manlio Fusciello, Véronique Préat, Sara Feola, Lopes, A., Feola, S., Ligot, S., Fusciello, M., Vandermeulen, G., Preat, V., Cerullo, V., Division of Pharmaceutical Biosciences, ImmunoViroTherapy Lab, Drug Research Program, University Management, and UCL - SSS/LDRI - Louvain Drug Research Institute

Subjects
0301 basic medicine, Cancer Research, Melanoma, Experimental, THERAPY, ACTIVATION, Epitopes, NATURAL-KILLER-CELLS, 0302 clinical medicine, Vaccines, DNA, Immunology and Allergy, Medicine, INTERLEUKIN-2, Cancer, Oncolytic Virotherapy, Melanoma, Immunogenicity, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Acquired immune system, Combined Modality Therapy, 3. Good health, Oncolytic Viruses, Oncolytic adenoviru, Oncology, Tumor microenvironment, 030220 oncology & carcinogenesis, Molecular Medicine, NK CELLS, Research Article, Plasmids, Melanoma neoantigen, RECRUITMENT, Oncolytic adenovirus, DNA vaccine, 3122 Cancers, Immunology, lcsh:RC254-282, Adenoviridae, DNA vaccination, Melanoma neoantigens, 03 medical and health sciences, Immune system, Antigens, Neoplasm, Cell Line, Tumor, Animals, Pharmacology, IDENTIFICATION, RECEPTOR, business.industry, EFFICACY, medicine.disease, Oncolytic virus, Mice, Inbred C57BL, 030104 developmental biology, Cancer research, business
Abstract

Background DNA vaccines against cancer held great promises due to the generation of a specific and long-lasting immune response. However, when used as a single therapy, they are not able to drive the generated immune response into the tumor, because of the immunosuppressive microenvironment, thus limiting their use in humans. To enhance DNA vaccine efficacy, we combined a new poly-epitope DNA vaccine encoding melanoma tumor associated antigens and B16F1-specific neoantigens with an oncolytic virus administered intratumorally. Methods Genomic analysis were performed to find specific mutations in B16F1 melanoma cells. The antigen gene sequences were designed according to these mutations prior to the insertion in the plasmid vector. Mice were injected with B16F1 tumor cells (n = 7–9) and therapeutically vaccinated 2, 9 and 16 days after the tumor injection. The virus was administered intratumorally at day 10, 12 and 14. Immune cell infiltration analysis and cytokine production were performed by flow cytometry, PCR and ELISPOT in the tumor site and in the spleen of animals, 17 days after the tumor injection. Results The combination of DNA vaccine and oncolytic virus significantly increased the immune activity into the tumor. In particular, the local intratumoral viral therapy increased the NK infiltration, thus increasing the production of different cytokines, chemokines and enzymes involved in the adaptive immune system recruitment and cytotoxic activity. On the other side, the DNA vaccine generated antigen-specific T cells in the spleen, which migrated into the tumor when recalled by the local viral therapy. The complementarity between these strategies explains the dramatic tumor regression observed only in the combination group compared to all the other control groups. Conclusions This study explores the immunological mechanism of the combination between an oncolytic adenovirus and a DNA vaccine against melanoma. It demonstrates that the use of a rational combination therapy involving DNA vaccination could overcome its poor immunogenicity. In this way, it will be possible to exploit the great potential of DNA vaccination, thus allowing a larger use in the clinic. Electronic supplementary material The online version of this article (10.1186/s40425-019-0644-7) contains supplementary material, which is available to authorized users.

Published
2019

50. Oncolytic vaccines increase the response to PD-L1 blockade in immunogenic and poorly immunogenic tumors

Author

Manlio Fusciello, Vincenzo Cerullo, F. Frascaro, Erkko Ylösmäki, Lucio Pastore, Karita Peltonen, Siri Tähtinen, Sara Carpi, M. Medeot, Cristian Capasso, Sara Feola, Beatriz Martins, Feola, S., Capasso, C., Fusciello, Celeste, Martins, B., Tähtinen, S., Medeot, M., Carpi, S., Frascaro, F., Ylosmäki, E., Peltonen, K., Pastore, L., and Cerullo, V.

Subjects
0301 basic medicine, lcsh:Immunologic diseases. Allergy, medicine.medical_treatment, Immunology, oncolytic vaccine, therapeutic antibodies, lcsh:RC254-282, 03 medical and health sciences, Immune system, breast cancer, therapeutic antibodie, PD-L1, medicine, melanoma, Immunology and Allergy, Triple-negative breast cancer, Original Research, biology, cancer epitopes, cancer vaccines, checkpoint inhibitors, immunotherapy, oncolytic vaccines, oncolytic viruses, therapeutic vaccination, Oncology, business.industry, Melanoma, Immunotherapy, medicine.disease, lcsh:Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Immune checkpoint, 3. Good health, Oncolytic virus, 030104 developmental biology, checkpoint inhibitor, oncolytic viruse, Cancer research, biology.protein, Cancer vaccine, cancer epitope, business, lcsh:RC581-607, cancer vaccine
Abstract

Activation of immune checkpoint pathways and limited T- cell infiltration result in immunological escape of tumors. Although immune checkpoint inhibitors are currently approved for several types of cancers, the response rate is often limited by the lack of tumor specific T-cells within the malignant tissue. Therefore, new combinatorial strategies are needed to enhance the clinical benefit of immune checkpoint inhibitors. We have previously developed PeptiCRAd, an oncolytic vaccine platform capable of directing the immune response toward tumor epitopes. In this study, we evaluated whether the platform could be used to increase the response rate to checkpoint inhibitors in both highly immunogenic and poorly immunogenic tumors, such as melanoma and triple negative breast cancer (TNBC). We report here that anti-PD-L1 therapy in combination with PeptiCRAd significantly reduced the growth of melanomas and increased the response rate to checkpoint inhibition. In fact, we registered a higher rate of complete responses among mice treated with the combination. This approach promoted the presence of non-exhausted antigen-specific T-cells within the tumor in comparison to anti-PD-L1 monotherapy. Furthermore, we found that targeting both MHC-I and II restricted tumor epitopes was necessary to decrease the growth of the poorly immunogenic TNBC model 4T1 and that combination with PD-L1 blockade increased the number of responders to checkpoint inhibition. Finally, the described strategy was validated in a translational in vitro model using HLA matched human PBMCs and tumor cell lines. Consistent to our previous results, improved cytotoxicity was observed with combination of PeptiCRAd and anti-PD-L1. These results demonstrate that oncolytic virus based cancer vaccine can significantly improve the response rate to checkpoint blocking antibodies in the context of immunogenic and non-immunogenic tumors.

Published
2018

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