Gautam N Shenoy1, Christopher J Greene1,2, Maulasri Bhatta3,4, Miren L Baroja5, Jenni L Loyall1, Sathy V Balu-Iyer6, Raymond J Kelleher1, Beatriz M Carreno5, Gerald P Linette5, Leonard D Shultz7, Richard B Bankert1. 1. Department of Microbiology and Immunology at the Jacobs School of Medicine and Biomedical Sciences University at Buffalo Buffalo NY USA. 2. Present address: Hodgson Russ LLP. Buffalo NY USA. 3. Immune Modulatory Therapies, LLC Eden NY USA. 4. Present address: Roswell Park Comprehensive Cancer Center Buffalo NY USA. 5. Center for Cellular Immunotherapies Perelman School of Medicine University of Pennsylvania Philadelphia PA USA. 6. Department of Pharmaceutical Sciences University at Buffalo Buffalo NY USA. 7. The Jackson Laboratory Bar Harbor ME USA.
Abstract
OBJECTIVES: With a rapidly growing list of candidate immune-based cancer therapeutics, there is a critical need to generate highly reliable animal models to preclinically evaluate the efficacy of emerging immune-based therapies, facilitating successful clinical translation. Our aim was to design and validate a novel in vivo model (called Xenomimetic or 'X' mouse) that allows monitoring of the ability of human tumor-specific T cells to suppress tumor growth following their entry into the tumor. METHODS: Tumor xenografts are established rapidly in the greater omentum of globally immunodeficient NOD-scid IL2Rγnull (NSG) mice following an intraperitoneal injection of melanoma target cells expressing tumor neoantigen peptides, as well as green fluorescent protein and/or luciferase. Changes in tumor burden, as well as in the number and phenotype of adoptively transferred patient-derived tumor neoantigen-specific T cells in response to immunotherapy, are measured by imaging to detect fluorescence/luminescence and flow cytometry, respectively. RESULTS: The tumors progress rapidly and disseminate in the mice unless patient-derived tumor-specific T cells are introduced. An initial T cell-mediated tumor arrest is later followed by a tumor escape, which correlates with the upregulation of the checkpoint molecules programmed cell death-1 (PD-1) and lymphocyte-activation gene 3 (LAG3) on T cells. Treatment with immune-based therapies that target these checkpoints, such as anti-PD-1 antibody (nivolumab) or interleukin-12 (IL-12), prevented or delayed the tumor escape. Furthermore, IL-12 treatment suppressed PD-1 and LAG3 upregulation on T cells. CONCLUSION: Together, these results validate the X-mouse model and establish its potential to preclinically evaluate the therapeutic efficacy of immune-based therapies.
OBJECTIVES: With a rapidly growing list of candidate immune-based cancer therapeutics, there is a critical need to generate highly reliable animal models to preclinically evaluate the efficacy of emerging immune-based therapies, facilitating successful clinical translation. Our aim was to design and validate a novel in vivo model (called Xenomimetic or 'X' mouse) that allows monitoring of the ability of human tumor-specific T cells to suppress tumor growth following their entry into the tumor. METHODS: Tumor xenografts are established rapidly in the greater omentum of globally immunodeficient NOD-scid IL2Rγnull (NSG) mice following an intraperitoneal injection of melanoma target cells expressing tumor neoantigen peptides, as well as green fluorescent protein and/or luciferase. Changes in tumor burden, as well as in the number and phenotype of adoptively transferred patient-derived tumor neoantigen-specific T cells in response to immunotherapy, are measured by imaging to detect fluorescence/luminescence and flow cytometry, respectively. RESULTS: The tumors progress rapidly and disseminate in the mice unless patient-derived tumor-specific T cells are introduced. An initial T cell-mediated tumor arrest is later followed by a tumor escape, which correlates with the upregulation of the checkpoint molecules programmed cell death-1 (PD-1) and lymphocyte-activation gene 3 (LAG3) on T cells. Treatment with immune-based therapies that target these checkpoints, such as anti-PD-1 antibody (nivolumab) or interleukin-12 (IL-12), prevented or delayed the tumor escape. Furthermore, IL-12 treatment suppressed PD-1 and LAG3 upregulation on T cells. CONCLUSION: Together, these results validate the X-mouse model and establish its potential to preclinically evaluate the therapeutic efficacy of immune-based therapies.
Authors: Gautam N Shenoy; Jenni Loyall; Charles S Berenson; Raymond J Kelleher; Vandana Iyer; Sathy V Balu-Iyer; Kunle Odunsi; Richard B Bankert Journal: J Immunol Date: 2018-11-16 Impact factor: 5.422
Authors: Beatriz M Carreno; Joel R Garbow; Grant R Kolar; Erin N Jackson; John A Engelbach; Michelle Becker-Hapak; Leonidas N Carayannopoulos; David Piwnica-Worms; Gerald P Linette Journal: Clin Cancer Res Date: 2009-05-15 Impact factor: 12.531
Authors: Michael R Nazareth; Lori Broderick; Michelle R Simpson-Abelson; Raymond J Kelleher; Sandra J Yokota; Richard B Bankert Journal: J Immunol Date: 2007-05-01 Impact factor: 5.422
Authors: J I Johnson; S Decker; D Zaharevitz; L V Rubinstein; J M Venditti; S Schepartz; S Kalyandrug; M Christian; S Arbuck; M Hollingshead; E A Sausville Journal: Br J Cancer Date: 2001-05-18 Impact factor: 7.640
Authors: Till Strowig; Cagan Gurer; Alexander Ploss; Yi-Fang Liu; Frida Arrey; Junji Sashihara; Gloria Koo; Charles M Rice; James W Young; Amy Chadburn; Jeffrey I Cohen; Christian Münz Journal: J Exp Med Date: 2009-06-01 Impact factor: 14.307
Authors: Maulasri Bhatta; Gautam N Shenoy; Jenni L Loyall; Brian D Gray; Meghana Bapardekar; Alexis Conway; Hans Minderman; Raymond J Kelleher; Beatriz M Carreno; Gerald Linette; Leonard D Shultz; Kunle Odunsi; Sathy V Balu-Iyer; Koon Yan Pak; Richard B Bankert Journal: J Immunother Cancer Date: 2021-10 Impact factor: 13.751
Authors: Harinarayanan Janakiraman; Scott A Becker; Alexandra Bradshaw; Mark P Rubinstein; Ernest Ramsay Camp Journal: PLoS One Date: 2022-09-12 Impact factor: 3.752