Your search keyword '"Perez-Penco, Maria"' showing total 14 results

1. The antitumor activity of TGFβ-specific T cells is dependent on IL-6 signaling

Author

Perez-Penco, Maria, Byrdal, Mikkel, Lara de la Torre, Lucia, Ballester, Marta, Khan, Shawez, Siersbæk, Majken, Lecoq, Inés, Madsen, Cecilie Oelvang, Kjeldsen, Julie Westerlin, Svane, Inge Marie, Hansen, Morten, Donia, Marco, Johansen, Julia Sidenius, Olsen, Lars Rønn, Grøntved, Lars, Chen, Inna Markovna, Arnes, Luis, Holmström, Morten Orebo, and Andersen, Mads Hald

Published

2025

2. Data from Arginase 1–Based Immune Modulatory Vaccines Induce Anticancer Immunity and Synergize with Anti–PD-1 Checkpoint Blockade

Author

Aaboe Jørgensen, Mia, primary, Ugel, Stefano, primary, Linder Hübbe, Mie, primary, Carretta, Marco, primary, Perez-Penco, Maria, primary, Weis-Banke, Stine Emilie, primary, Martinenaite, Evelina, primary, Kopp, Katharina, primary, Chapellier, Marion, primary, Adamo, Annalisa, primary, De Sanctis, Francesco, primary, Frusteri, Cristina, primary, Iezzi, Manuela, primary, Zocca, Mai-Britt, primary, Hargbøll Madsen, Daniel, primary, Wakatsuki Pedersen, Ayako, primary, Bronte, Vincenzo, primary, and Andersen, Mads Hald, primary

Published

2023

3. Supplementary Data from Arginase 1–Based Immune Modulatory Vaccines Induce Anticancer Immunity and Synergize with Anti–PD-1 Checkpoint Blockade

Author

Aaboe Jørgensen, Mia, primary, Ugel, Stefano, primary, Linder Hübbe, Mie, primary, Carretta, Marco, primary, Perez-Penco, Maria, primary, Weis-Banke, Stine Emilie, primary, Martinenaite, Evelina, primary, Kopp, Katharina, primary, Chapellier, Marion, primary, Adamo, Annalisa, primary, De Sanctis, Francesco, primary, Frusteri, Cristina, primary, Iezzi, Manuela, primary, Zocca, Mai-Britt, primary, Hargbøll Madsen, Daniel, primary, Wakatsuki Pedersen, Ayako, primary, Bronte, Vincenzo, primary, and Andersen, Mads Hald, primary

Published

2023

4. TGFβ-derived immune modulatory vaccine: targeting the immunosuppressive and fibrotic tumor microenvironment in a murine model of pancreatic cancer

Author

Perez-Penco, Maria, primary, Weis-Banke, Stine Emilie, additional, Schina, Aimilia, additional, Siersbæk, Majken, additional, Hübbe, Mie Linder, additional, Jørgensen, Mia Aaboe, additional, Lecoq, Inés, additional, Lara de la Torre, Lucia, additional, Bendtsen, Simone Kloch, additional, Martinenaite, Evelina, additional, Holmström, Morten Orebo, additional, Madsen, Daniel Hargbøl, additional, Donia, Marco, additional, Ødum, Niels, additional, Grøntved, Lars, additional, and Andersen, Mads Hald, additional

Published

2022

5. Therapeutic Potential of an Immune-Modulatory Vaccination Targeting Myeloid-Derived Suppressor Cells in Myelodysplastic Syndrome

Author

Bentivegna, Sofia, primary, Holmstrøm, Morten, additional, Balhuizen, Alexander, additional, Almosailleakh, Marwa, additional, Perez-Penco, Maria, additional, Porse, Bo, additional, Andersen, Mads Hald, additional, and Grønbæk, Kirsten, additional

Published

2022

6. Arginase-2-specific cytotoxic T cells specifically recognize functional regulatory T cells

Author

Weis-Banke, Stine Emilie, primary, Lisle, Thomas Landkildehus, additional, Perez-Penco, Maria, additional, Schina, Aimilia, additional, Hübbe, Mie Linder, additional, Siersbæk, Majken, additional, Holmström, Morten Orebo, additional, Jørgensen, Mia Aaboe, additional, Marie Svane, Inge, additional, Met, Özcan, additional, Ødum, Niels, additional, Madsen, Daniel Hargbøl, additional, Donia, Marco, additional, Grøntved, Lars, additional, and Andersen, Mads Hald, additional

Published

2022

7. CCL22-based peptide vaccines induce anti-cancer immunity by modulating tumor microenvironment

Author

Lecoq, Inés, primary, Kopp, Katharina L., additional, Chapellier, Marion, additional, Mantas, Panagiotis, additional, Martinenaite, Evelina, additional, Perez-Penco, Maria, additional, Rønn Olsen, Lars, additional, Zocca, Mai-Britt, additional, Wakatsuki Pedersen, Ayako, additional, and Andersen, Mads Hald, additional

Published

2022

8. Peptide vaccination activating Galectin-3-specific T cells offers a novel means to target Galectin-3-expressing cells in the tumor microenvironment

Author

Bendtsen, Simone Kloch, Perez-Penco, Maria, Hübbe, Mie Linder, Martinenaite, Evelina, Orebo Holmström, Morten, Weis-Banke, Stine Emilie, Grønne Dahlager Jørgensen, Nicolai, Jørgensen, Mia Aaboe, Munir Ahmad, Shamaila, Jensen, Kasper Mølgaard, Friese, Christina, Lundsager, Mia Thorup, Johansen, Astrid Zedlitz, Carretta, Marco, Ødum, Niels, Met, Özcan, Svane, Inge Marie, Madsen, Daniel Hargbøl, Andersen, Mads Hald, Bendtsen, Simone Kloch, Perez-Penco, Maria, Hübbe, Mie Linder, Martinenaite, Evelina, Orebo Holmström, Morten, Weis-Banke, Stine Emilie, Grønne Dahlager Jørgensen, Nicolai, Jørgensen, Mia Aaboe, Munir Ahmad, Shamaila, Jensen, Kasper Mølgaard, Friese, Christina, Lundsager, Mia Thorup, Johansen, Astrid Zedlitz, Carretta, Marco, Ødum, Niels, Met, Özcan, Svane, Inge Marie, Madsen, Daniel Hargbøl, and Andersen, Mads Hald

Abstract

Galectin-3 (Gal3) can be expressed by many cells in the tumor microenvironment (TME), including cancer cells, cancer-associated fibroblasts, tumor-associated macrophages, and regulatory T cells (Tregs). In addition to immunosuppression, Gal3 expression has been connected to malignant cell transformation, tumor progression, and metastasis. In the present study, we found spontaneous T-cell responses against Gal3-derived peptides in PBMCs from both healthy donors and cancer patients. We isolated and expanded these Gal3-specific T cells in vitro and showed that they could directly recognize target cells that expressed Gal3. Finally, therapeutic vaccination with a long Gal3-derived peptide epitope, which induced the expansion of Gal3-specific CD8+ T cells in vivo, showed a significant tumor-growth delay in mice inoculated with EO771.LMB metastatic mammary tumor cells. This was associated with a significantly lower percentage of both Tregs and tumor-infiltrating Gal3+ cells in the non-myeloid CD45+CD11b− compartment and with an alteration of the T-cell memory populations in the spleens of Gal3-vaccinated mice. These results suggest that by activating Gal3-specific T cells by an immune-modulatory vaccination, we can target Gal3-producing cells in the TME, and thereby induce a more immune permissive TME. This indicates that Gal3 could be a novel target for therapeutic cancer vaccines.

Published

2022

9. Therapeutic Potential of an Immune-Modulatory Vaccination Targeting Myeloid-Derived Suppressor Cells in Myelodysplastic Syndrome

Author

Bentivegna, Sofia, Holmstrøm, Morten, Balhuizen, Alexander, Almosailleakh, Marwa, Perez-Penco, Maria, Porse, Bo, Andersen, Mads Hald, Grønbæk, Kirsten, Bentivegna, Sofia, Holmstrøm, Morten, Balhuizen, Alexander, Almosailleakh, Marwa, Perez-Penco, Maria, Porse, Bo, Andersen, Mads Hald, and Grønbæk, Kirsten

Published

2022

10. Peptide vaccination activating Galectin-3-specific T cells offers a novel means to target Galectin-3-expressing cells in the tumor microenvironment

Author

Bendtsen, Simone Kloch, primary, Perez-Penco, Maria, additional, Hübbe, Mie Linder, additional, Martinenaite, Evelina, additional, Orebo Holmström, Morten, additional, Weis-Banke, Stine Emilie, additional, Grønne Dahlager Jørgensen, Nicolai, additional, Jørgensen, Mia Aaboe, additional, Munir Ahmad, Shamaila, additional, Jensen, Kasper Mølgaard, additional, Friese, Christina, additional, Lundsager, Mia Thorup, additional, Johansen, Astrid Zedlitz, additional, Carretta, Marco, additional, Ødum, Niels, additional, Met, Özcan, additional, Svane, Inge Marie, additional, Madsen, Daniel Hargbøl, additional, and Andersen, Mads Hald, additional

Published

2022

11. Arginase 1–Based Immune Modulatory Vaccines Induce Anticancer Immunity and Synergize with Anti–PD-1 Checkpoint Blockade

Author

Aaboe Jørgensen, Mia, primary, Ugel, Stefano, additional, Linder Hübbe, Mie, additional, Carretta, Marco, additional, Perez-Penco, Maria, additional, Weis-Banke, Stine Emilie, additional, Martinenaite, Evelina, additional, Kopp, Katharina, additional, Chapellier, Marion, additional, Adamo, Annalisa, additional, De Sanctis, Francesco, additional, Frusteri, Cristina, additional, Iezzi, Manuela, additional, Zocca, Mai-Britt, additional, Hargbøll Madsen, Daniel, additional, Wakatsuki Pedersen, Ayako, additional, Bronte, Vincenzo, additional, and Andersen, Mads Hald, additional

Published

2021

12. Arginase 1–Based immune modulatory vaccines induce anticancer immunity and synergize with Anti–PD-1 checkpoint blockade

Author

Jørgensen, Mia Aaboe, Ugel, Stefano, Hübbe, Mie Linder, Carretta, Marco, Perez-Penco, Maria, Weis-Banke, Stine Emilie, Martinenaite, Evelina, Kopp, Katharina, Chapellier, Marion, Adamo, Annalisa, de Sanctis, Francesco, Frusteri, Cristina, Iezzi, Manuela, Zocca, Mai Britt, Madsen, Daniel Hargbøll, Pedersen, Ayako Wakatsuki, Bronte, Vincenzo, Andersen, Mads Hald, Jørgensen, Mia Aaboe, Ugel, Stefano, Hübbe, Mie Linder, Carretta, Marco, Perez-Penco, Maria, Weis-Banke, Stine Emilie, Martinenaite, Evelina, Kopp, Katharina, Chapellier, Marion, Adamo, Annalisa, de Sanctis, Francesco, Frusteri, Cristina, Iezzi, Manuela, Zocca, Mai Britt, Madsen, Daniel Hargbøll, Pedersen, Ayako Wakatsuki, Bronte, Vincenzo, and Andersen, Mads Hald

Abstract

Expression of the L-arginine catabolizing enzyme arginase 1 (ARG1) is a central immunosuppressive mechanism mediated by tumor-educated myeloid cells. Increased activity of ARG1 promotes the formation of an immunosuppressive microenvironment and leads to a more aggressive phenotype in many cancers. Intrinsic T-cell immunity against ARG1-derived epitopes in the peripheral blood of cancer patients and healthy subjects has previously been demonstrated. To evaluate the antitumor efficacy of ARG1-derived peptide vaccines as a monotherapy and as a combinational therapy with checkpoint blockade, different in vivo syngeneic mouse tumor models were utilized. To evaluate the antitumor effects, flow cytometry analysis and IHC were performed on tumors, and ELISPOT assays were performed to characterize immune responses. We show that ARG1-targeting therapeutic vaccines were able to activate endogenous antitumor immunity in several in vivo syngeneic mouse tumor models and to modulate the cell composition of the tumor microenvironment without causing any associated side effects or systemic toxicity. ARG1-targeting vaccines in combination with anti–PD-1 also resulted in increased T-cell infiltration, decreased ARG1 expression, reduced suppressive function of tumor-educated myeloid cells, and a shift in the M1/M2 ratio of tumor-infiltrating macrophages. These results indicated that the induced shift toward a more proinflammatory microenvironment by ARG1-targeting immunotherapy favors effective tumor control when combined with anti–PD-1 checkpoint blockade. Our data illustrate the ability of ARG1-based immune modulatory vaccination to elicit antigen-specific immunosurveillance and imply the feasibility of this novel immunotherapeutic approach for clinical translation.

Published

2021

13. Perez Penco, Maria

Author

Perez Penco, Maria and Perez Penco, Maria

Published

2020

14. TGFβ-specific T cells induced by a TGFβ-derived immune modulatory vaccine both directly and indirectly modulate the phenotype of tumor-associated macrophages and fibroblasts.

Author

Perez-Penco M, Lara de la Torre L, Lecoq I, Martinenaite E, and Andersen MH

Subjects

Animals, Mice, T-Lymphocytes, Tumor-Associated Macrophages, Transforming Growth Factor beta, Cell Line, Tumor, Fibroblasts, Phenotype, Tumor Microenvironment, Pancreatic Neoplasms therapy, Pancreatic Neoplasms pathology, Vaccines

Abstract

The tumor microenvironment (TME) of pancreatic cancer is highly immunosuppressive. We recently developed a transforming growth factor (TGF)β-based immune modulatory vaccine that controlled tumor growth in a murine model of pancreatic cancer by targeting immunosuppression and desmoplasia in the TME. We found that treatment with the TGFβ vaccine not only reduced the percentage of M2-like tumor-associated macrophages (TAMs) and cancer-associated fibroblasts (CAFs) in the tumor but polarized CAFs away from the myofibroblast-like phenotype. However, whether the immune modulatory properties of the TGFβ vaccine on TAM and CAF phenotypes are a direct consequence of the recognition and subsequent targeting of these subsets by TGFβ-specific T cells or an indirect consequence of the overall modulation induced within the TME remains unknown. Recognition of M2 macrophages and fibroblast by TGFβ-specific T cells was assessed by ELISpot and flow cytometry. The indirect and direct effects of the TGFβ vaccine on these cell subsets were evaluated by culturing M2 macrophages or fibroblasts with tumor-conditioned media or with T cells isolated from the spleen of mice treated with the TGFβ vaccine or a control vaccine, respectively. Changes in phenotype were assessed by flow cytometry and Bio-Plex multiplex system (Luminex). We found that TGFβ-specific T cells induced by the TGFβ vaccine can recognize M2 macrophages and fibroblasts. Furthermore, we demonstrated that the phenotype of M2 macrophages and CAFs can be directly modulated by TGFβ-specific T cells induced by the TGFβ vaccine, as well as indirectly modulated as a result of the immune-modulatory effects of the vaccine within the TME. TAMs tend to have tumor-promoting functions, harbor an immunosuppressive phenotype and are linked to decreased overall survival in pancreatic cancer when they harbor an M2-like phenotype. In addition, myofibroblast-like CAFs create a stiff extracellular matrix that restricts T cell infiltration, impeding the effectiveness of immune therapies in desmoplastic tumors, such as pancreatic ductal adenocarcinoma. Reducing immunosuppression and immune exclusion in pancreatic tumors by targeting TAMs and CAFs with the TGFβ-based immune modulatory vaccine emerges as an innovative strategy for the generation of a more favorable environment for immune-based therapies, such as immune checkpoint inhibitors., Competing Interests: Competing interests: MHA has developed an invention based on the use of transforming growth factor-β-derived peptides for vaccinations. A patent application directed to the invention is owned by the company IO Biotech ApS and lists MHA as the sole inventor. MHA is advisor and shareholder at IO Biotech. IL and EM are employees at IO Biotech. The additional authors declare no competing financial interests., (© Author(s) (or their employer(s)) 2024. Re-use permitted under CC BY-NC. No commercial re-use. See rights and permissions. Published by BMJ.)

Published

2024