Your search keyword '"James Bradley Breitmeyer"' showing total 3 results

1. Poxvirus-based active immunotherapy synergizes with CTLA-4 blockade to increase survival in a murine tumor model by improving the magnitude and quality of cytotoxic T cells

Author

James Bradley Breitmeyer, Susan P. Foy, Alex Franzusoff, Stefanie Mandl, Evan Gordon, Ryan Rountree, Tracy dela Cruz, Erica Trent, Alain Delcayre, and Joseph Cote

Subjects

0301 basic medicine, Cancer Research, Lung Neoplasms, Active immunotherapy, medicine.medical_treatment, T cell, Immunology, Vaccinia virus, chemical and pharmacologic phenomena, Anti-CTLA-4, CD8-Positive T-Lymphocytes, Biology, Cancer Vaccines, T-Lymphocytes, Regulatory, Antibodies, 03 medical and health sciences, Cell Line, Tumor, Tumor Microenvironment, medicine, Animals, Humans, Immunology and Allergy, Cytotoxic T cell, CTLA-4 Antigen, Cancer, Mice, Inbred BALB C, Modified Vaccinia Ankara (MVA), Drug Synergism, hemic and immune systems, Neoplasms, Experimental, Immunotherapy, Flow Cytometry, Survival Analysis, Immune checkpoint, Blockade, 030104 developmental biology, medicine.anatomical_structure, Oncology, CTLA-4, Poxvirus, Cytokines, Original Article, Female, Immune checkpoint blockade, CD8, T-Lymphocytes, Cytotoxic

Abstract

The dramatic clinical benefit of immune checkpoint blockade for a fraction of cancer patients suggests the potential for further clinical benefit in a broader cancer patient population by combining immune checkpoint inhibitors with active immunotherapies. The anti-tumor efficacy of MVA-BN-HER2 poxvirus-based active immunotherapy alone or in combination with CTLA-4 checkpoint blockade was investigated in a therapeutic CT26-HER-2 lung metastasis mouse model. MVA-BN-HER2 immunotherapy significantly improved the median overall survival compared to untreated controls or CTLA-4 blockade alone (p

Published

2016

2. 1620O Phase I study of TK216, a novel anti-ETS agent for Ewing sarcoma

Author

Richard F. Riedel, Margaret E. Macy, F.J. Hsu, Paul A. Meyers, Pete Anderson, X. Ianopulos, Jeffrey A. Toretsky, Ravin Ratan, James Bradley Breitmeyer, Lara E. Davis, Joseph A. Ludwig, Najat C. Daw, Noah Federman, and J.A. Muscal

Subjects

Oncology, business.industry, Cancer research, medicine, Hematology, Sarcoma, medicine.disease, business, Phase i study

Published

2020

3. Abstract LB-234: Poxvirus-based active immunotherapy synergizes with PD-1 plus LAG-3 immune checkpoint inhibition to enhance antitumor efficacy in preclinical models

Author

Veronica Xavier, Susan P. Foy, James Bradley Breitmeyer, Ryan Rountree, Evan Gordon, Barbara Sennino, Alex Franzusoff, Stefanie Mandl, Tracy dela Cruz, and Felicia Kemp

Subjects

Cancer Research, Tumor-infiltrating lymphocytes, business.industry, medicine.medical_treatment, T cell, Active immunotherapy, Immunotherapy, Immune checkpoint, Immune system, medicine.anatomical_structure, Oncology, Antigen, Immunology, Medicine, business, Prostvac

Abstract

Treatment with poxvirus-based active immunotherapies shows evidence of robust immune responses against a variety of tumor-associated antigens in preclinical and clinical studies. Poxvirus-based immunotherapies in development include PSA-targeted PROSTVAC, now in Phase 3 clinical development; CV-301 (targeting CEA and MUC-1); as well as MVA-BN-HER2 and MVA-BN-Brachyury (targeting HER-2 and the transcription factor Brachyury, respectively). Evidence of robust and productive anti-tumor efficacy in preclinical models was accompanied by treatment-emergent infiltration of tumors by activated cytotoxic CD8 T cells producing high amounts of IFNγ. Treatment with immune checkpoint inhibitors such as anti-PD-1 antibodies is showing significant clinical benefit by re-activating dormant tumor-specific T cells. Furthermore, preclinical studies have shown further synergistic efficacy by combining PD-1 blockade with inhibition of LAG-3, which acts independently of PD-1 to modulate T cell function. We hypothesized that poxvirus-based active immunotherapy may provide even greater improvements to patient outcome when used in combination with immune checkpoint blockade, by inducing new productive tumor-specific responses. This may be especially important in patients lacking an endogenous T cell response against their tumors. In therapeutic CT26-HER2 solid and metastatic tumor models, mice were administered MVA-BN-HER2 immunotherapy alone or in combination with anti-PD-1 and/or anti-LAG-3 antibodies. Synergistic benefit for anti-tumor efficacy was observed when combining MVA-BN-HER2 immunotherapy with anti-PD-1 alone, while combination with anti-LAG-3 alone had little effect. Notably, a further enhancement occurred when MVA-BN-HER2 immunotherapy was combined with PD-1 and LAG-3 blockade as shown by complete tumor regression in 20/20 mice. Subsequent rejection of HER-2 negative tumors 6 months after the original challenge revealed that immune responses were durable and included antigen spread to additional tumor antigens. Flow cytometric analysis demonstrated that tumor infiltrating lymphocytes (TILs) in untreated tumors were PD-1hi and LAG-3+, a more exhausted phenotype. Poxvirus-based immunotherapy led to the induction of activated TILs characterized by low to mid-levels of PD-1 expression. While PD-1 blockade prevented binding to PD-L1 it also caused an increase in LAG-3 expression on T cells. Together these data provide further rationale for why combination therapy of poxvirus-based immunotherapy with inhibition of PD-1 plus LAG-3 resulted in synergistic efficacy in preclinical tumor models. Overall these data demonstrate that combining complementary immune-based therapies such as poxvirus-based active immunotherapy and PD-1 plus LAG-3 immune checkpoint blockade result in synergistic anti-tumor efficacy. Citation Format: Barbara Sennino, Susan P. Foy, Ryan B. Rountree, Tracy dela Cruz, Evan J. Gordon, Veronica Xavier, Felicia Kemp, Alex Franzusoff, James Breitmeyer, Stefanie J. Mandl. Poxvirus-based active immunotherapy synergizes with PD-1 plus LAG-3 immune checkpoint inhibition to enhance antitumor efficacy in preclinical models. [abstract]. In: Proceedings of the 106th Annual Meeting of the American Association for Cancer Research; 2015 Apr 18-22; Philadelphia, PA. Philadelphia (PA): AACR; Cancer Res 2015;75(15 Suppl):Abstract nr LB-234. doi:10.1158/1538-7445.AM2015-LB-234

Published

2015