Immune landscape of a genetically engineered murine model of glioma compared with human glioma

Daniel B. Zamler; Takashi Shingu; Laura M. Kahn; Kristin Huntoon; Cynthia Kassab; Martina Ott; Katarzyna Tomczak; Jintan Liu; Yating Li; Ivy Lai; Rocio Zorilla-Veloz; Cassian Yee; Kunal Rai; Betty Y.S. Kim; Stephanie S. Watowich; Amy B Heimberger; Giulio F. Draetta; Jian Hu

doi:10.1172/jci.insight.148990

Immune landscape of a genetically engineered murine model of glioma compared with human glioma

Daniel B. Zamler, Takashi Shingu, Laura M. Kahn, Kristin Huntoon, Cynthia Kassab, Martina Ott, Katarzyna Tomczak, Jintan Liu, Yating Li, Ivy Lai, Rocio Zorilla-Veloz, Cassian Yee, Kunal Rai, Betty Y.S. Kim, Stephanie S. Watowich, Amy B Heimberger, Giulio F. Draetta, Jian Hu

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

Novel therapeutic strategies targeting glioblastoma (GBM) often fail in the clinic, partly because preclinical models in which hypotheses are being tested do not recapitulate human disease. To address this challenge, we took advantage of our previously developed spontaneous Qk/Trp53/Pten (QPP) triple-knockout model of human GBM, comparing the immune microenvironment of QPP mice with that of patient-derived tumors to determine whether this model provides opportunity for gaining insights into tumor physiopathology and preclinical evaluation of therapeutic agents. Immune profiling analyses and single-cell sequencing of implanted and spontaneous tumors from QPP mice and from patients with glioma revealed intratumoral immune components that were predominantly myeloid cells (e.g., monocytes, macrophages, and microglia), with minor populations of T, B, and NK cells. When comparing spontaneous and implanted mouse samples, we found more neutrophils and T and NK cells in the implanted model. Neutrophils and T and NK cells were increased in abundance in samples derived from human high-grade glioma compared with those derived from low-grade glioma. Overall, our data demonstrate that our implanted and spontaneous QPP models recapitulate the immunosuppressive myeloid-dominant nature of the tumor microenvironment of human gliomas. Our model provides a suitable tool for investigating the complex immune compartment of gliomas.

Original language	English (US)
Journal	JCI Insight
Volume	7
Issue number	12
DOIs	https://doi.org/10.1172/jci.insight.148990
State	Published - Jun 22 2022

ASJC Scopus subject areas

General Medicine

MD Anderson CCSG core facilities

Research Animal Support Facility
Tissue Biospecimen and Pathology Resource
Genetically Engineered Mouse Facility
Flow Cytometry and Cellular Imaging Facility

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10.1172/jci.insight.148990

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Zamler, D. B., Shingu, T., Kahn, L. M., Huntoon, K., Kassab, C., Ott, M., Tomczak, K., Liu, J., Li, Y., Lai, I., Zorilla-Veloz, R., Yee, C., Rai, K., Kim, B. Y. S., Watowich, S. S., Heimberger, A. B., Draetta, G. F., & Hu, J. (2022). Immune landscape of a genetically engineered murine model of glioma compared with human glioma. JCI Insight, 7(12). https://doi.org/10.1172/jci.insight.148990

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title = "Immune landscape of a genetically engineered murine model of glioma compared with human glioma",

abstract = "Novel therapeutic strategies targeting glioblastoma (GBM) often fail in the clinic, partly because preclinical models in which hypotheses are being tested do not recapitulate human disease. To address this challenge, we took advantage of our previously developed spontaneous Qk/Trp53/Pten (QPP) triple-knockout model of human GBM, comparing the immune microenvironment of QPP mice with that of patient-derived tumors to determine whether this model provides opportunity for gaining insights into tumor physiopathology and preclinical evaluation of therapeutic agents. Immune profiling analyses and single-cell sequencing of implanted and spontaneous tumors from QPP mice and from patients with glioma revealed intratumoral immune components that were predominantly myeloid cells (e.g., monocytes, macrophages, and microglia), with minor populations of T, B, and NK cells. When comparing spontaneous and implanted mouse samples, we found more neutrophils and T and NK cells in the implanted model. Neutrophils and T and NK cells were increased in abundance in samples derived from human high-grade glioma compared with those derived from low-grade glioma. Overall, our data demonstrate that our implanted and spontaneous QPP models recapitulate the immunosuppressive myeloid-dominant nature of the tumor microenvironment of human gliomas. Our model provides a suitable tool for investigating the complex immune compartment of gliomas.",

author = "Zamler, {Daniel B.} and Takashi Shingu and Kahn, {Laura M.} and Kristin Huntoon and Cynthia Kassab and Martina Ott and Katarzyna Tomczak and Jintan Liu and Yating Li and Ivy Lai and Rocio Zorilla-Veloz and Cassian Yee and Kunal Rai and Kim, {Betty Y.S.} and Watowich, {Stephanie S.} and Heimberger, {Amy B} and Draetta, {Giulio F.} and Jian Hu",

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year = "2022",

month = jun,

day = "22",

doi = "10.1172/jci.insight.148990",

language = "English (US)",

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AU - Zamler, Daniel B.

AU - Shingu, Takashi

AU - Kahn, Laura M.

AU - Huntoon, Kristin

AU - Kassab, Cynthia

AU - Ott, Martina

AU - Tomczak, Katarzyna

AU - Liu, Jintan

AU - Li, Yating

AU - Lai, Ivy

AU - Zorilla-Veloz, Rocio

AU - Yee, Cassian

AU - Rai, Kunal

AU - Kim, Betty Y.S.

AU - Watowich, Stephanie S.

AU - Heimberger, Amy B

AU - Draetta, Giulio F.

AU - Hu, Jian

PY - 2022/6/22

Y1 - 2022/6/22

N2 - Novel therapeutic strategies targeting glioblastoma (GBM) often fail in the clinic, partly because preclinical models in which hypotheses are being tested do not recapitulate human disease. To address this challenge, we took advantage of our previously developed spontaneous Qk/Trp53/Pten (QPP) triple-knockout model of human GBM, comparing the immune microenvironment of QPP mice with that of patient-derived tumors to determine whether this model provides opportunity for gaining insights into tumor physiopathology and preclinical evaluation of therapeutic agents. Immune profiling analyses and single-cell sequencing of implanted and spontaneous tumors from QPP mice and from patients with glioma revealed intratumoral immune components that were predominantly myeloid cells (e.g., monocytes, macrophages, and microglia), with minor populations of T, B, and NK cells. When comparing spontaneous and implanted mouse samples, we found more neutrophils and T and NK cells in the implanted model. Neutrophils and T and NK cells were increased in abundance in samples derived from human high-grade glioma compared with those derived from low-grade glioma. Overall, our data demonstrate that our implanted and spontaneous QPP models recapitulate the immunosuppressive myeloid-dominant nature of the tumor microenvironment of human gliomas. Our model provides a suitable tool for investigating the complex immune compartment of gliomas.

AB - Novel therapeutic strategies targeting glioblastoma (GBM) often fail in the clinic, partly because preclinical models in which hypotheses are being tested do not recapitulate human disease. To address this challenge, we took advantage of our previously developed spontaneous Qk/Trp53/Pten (QPP) triple-knockout model of human GBM, comparing the immune microenvironment of QPP mice with that of patient-derived tumors to determine whether this model provides opportunity for gaining insights into tumor physiopathology and preclinical evaluation of therapeutic agents. Immune profiling analyses and single-cell sequencing of implanted and spontaneous tumors from QPP mice and from patients with glioma revealed intratumoral immune components that were predominantly myeloid cells (e.g., monocytes, macrophages, and microglia), with minor populations of T, B, and NK cells. When comparing spontaneous and implanted mouse samples, we found more neutrophils and T and NK cells in the implanted model. Neutrophils and T and NK cells were increased in abundance in samples derived from human high-grade glioma compared with those derived from low-grade glioma. Overall, our data demonstrate that our implanted and spontaneous QPP models recapitulate the immunosuppressive myeloid-dominant nature of the tumor microenvironment of human gliomas. Our model provides a suitable tool for investigating the complex immune compartment of gliomas.

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Immune landscape of a genetically engineered murine model of glioma compared with human glioma

Abstract

ASJC Scopus subject areas

MD Anderson CCSG core facilities

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