Your search keyword '"Abigail L. Toren"' showing total 3 results

1. Combined Dusp4 and p53 loss with Dbf4 amplification drives tumorigenesis via cell cycle restriction and replication stress escape in breast cancer

Author

Ann Hanna, Mellissa J. Nixon, M. Valeria Estrada, Violeta Sanchez, Quanhu Sheng, Susan R. Opalenik, Abigail L. Toren, Joshua Bauer, Phillip Owens, Frank M. Mason, Rebecca S. Cook, Melinda E. Sanders, Carlos L. Arteaga, and Justin M. Balko

Subjects

Breast cancer, Oncogenesis, Dusp4, Replication stress, p53, Dbf4, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, RC254-282

Abstract

Abstract Aim Deregulated signaling pathways are a hallmark feature of oncogenesis and driver of tumor progression. Dual specificity protein phosphatase 4 (DUSP4) is a critical negative regulator of the mitogen-activated protein kinase (MAPK) pathway and is often deleted or epigenetically silenced in tumors. DUSP4 alterations lead to hyperactivation of MAPK signaling in many cancers, including breast cancer, which often harbor mutations in cell cycle checkpoint genes, particularly in TP53. Methods Using a genetically engineered mouse model, we generated mammary-specific Dusp4-deleted primary epithelial cells to investigate the necessary conditions in which DUSP4 loss may drive breast cancer oncogenesis. Results We found that Dusp4 loss alone is insufficient in mediating tumorigenesis, but alternatively converges with loss in Trp53 and MYC amplification to induce tumorigenesis primarily through chromosome 5 amplification, which specifically upregulates Dbf4, a cell cycle gene that promotes cellular replication by mediating cell cycle checkpoint escape. Conclusions This study identifies a novel mechanism for breast tumorigenesis implicating Dusp4 loss and p53 mutations in cellular acquisition of Dbf4 upregulation as a driver of cellular replication and cell cycle checkpoint escape.

Published

2022

2. Combined Dusp4 and p53 loss with Dbf4 amplification drives tumorigenesis via cell cycle restriction and replication stress escape in breast cancer

Author

Ann Hanna, Mellissa J. Nixon, M. Valeria Estrada, Violeta Sanchez, Quanhu Sheng, Susan R. Opalenik, Abigail L. Toren, Joshua Bauer, Phillip Owens, Frank M. Mason, Rebecca S. Cook, Melinda E. Sanders, Carlos L. Arteaga, and Justin M. Balko

Subjects

Mice, Cell Transformation, Neoplastic, Cell Cycle, Animals, Dual-Specificity Phosphatases, Mitogen-Activated Protein Kinase Phosphatases, Cell Cycle Proteins, Tumor Suppressor Protein p53, Signal Transduction

Abstract

Aim Deregulated signaling pathways are a hallmark feature of oncogenesis and driver of tumor progression. Dual specificity protein phosphatase 4 (DUSP4) is a critical negative regulator of the mitogen-activated protein kinase (MAPK) pathway and is often deleted or epigenetically silenced in tumors. DUSP4 alterations lead to hyperactivation of MAPK signaling in many cancers, including breast cancer, which often harbor mutations in cell cycle checkpoint genes, particularly in TP53. Methods Using a genetically engineered mouse model, we generated mammary-specific Dusp4-deleted primary epithelial cells to investigate the necessary conditions in which DUSP4 loss may drive breast cancer oncogenesis. Results We found that Dusp4 loss alone is insufficient in mediating tumorigenesis, but alternatively converges with loss in Trp53 and MYC amplification to induce tumorigenesis primarily through chromosome 5 amplification, which specifically upregulates Dbf4, a cell cycle gene that promotes cellular replication by mediating cell cycle checkpoint escape. Conclusions This study identifies a novel mechanism for breast tumorigenesis implicating Dusp4 loss and p53 mutations in cellular acquisition of Dbf4 upregulation as a driver of cellular replication and cell cycle checkpoint escape.

Published

2021

3. T cells specific for α-myosin drive immunotherapy-related myocarditis

Author

Margaret L. Axelrod, Wouter C. Meijers, Elles M. Screever, Juan Qin, Mary Grace Carroll, Xiaopeng Sun, Elie Tannous, Yueli Zhang, Ayaka Sugiura, Brandie C. Taylor, Ann Hanna, Shaoyi Zhang, Kaushik Amancherla, Warren Tai, Jordan J. Wright, Spencer C. Wei, Susan R. Opalenik, Abigail L. Toren, Jeffrey C. Rathmell, P. Brent Ferrell, Elizabeth J. Phillips, Simon Mallal, Douglas B. Johnson, James P. Allison, Javid J. Moslehi, Justin M. Balko, and Cardiology

Subjects

Multidisciplinary, General Science & Technology, Inflammatory and immune system, CD8-Positive T-Lymphocytes, Cardiovascular, Autoantigens, Ventricular Myosins, Mice, Myocarditis, Heart Disease, Animals, 2.1 Biological and endogenous factors, CTLA-4 Antigen, Immunotherapy, Aetiology

Abstract

Immune-related adverse events, particularly severe toxicities such as myocarditis, are major challenges to the utility of immune checkpoint inhibitors (ICIs) in anticancer therapy1. The pathogenesis of ICI-associated myocarditis (ICI-MC) is poorly understood. Pdcd1–/–Ctla4+/– mice recapitulate clinicopathological features of ICI-MC, including myocardial T cell infiltration2. Here, using single-cell RNA and T cell receptor (TCR) sequencing of cardiac immune infiltrates from Pdcd1–/–Ctla4+/– mice, we identify clonal effector CD8+ T cells as the dominant cell population. Treatment with anti-CD8-depleting, but not anti-CD4-depleting, antibodies improved the survival of Pdcd1–/–Ctla4+/– mice. Adoptive transfer of immune cells from mice with myocarditis induced fatal myocarditis in recipients, which required CD8+ T cells. The cardiac-specific protein α-myosin, which is absent from the thymus3,4, was identified as the cognate antigen source for three major histocompatibility complex class I-restricted TCRs derived from mice with fulminant myocarditis. Peripheral blood T cells from three patients with ICI-MC were expanded by α-myosin peptides. Moreover, these α-myosin-expanded T cells shared TCR clonotypes with diseased heart and skeletal muscle, which indicates that α-myosin may be a clinically important autoantigen in ICI-MC. These studies underscore the crucial role for cytotoxic CD8+ T cells, identify a candidate autoantigen in ICI-MC and yield new insights into the pathogenesis of ICI toxicity.

Published

2022