Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma

Shashwat Tripathi; Hinda Najem; Corey Dussold; Sebastian Pacheco; Ruochen Du; Moloud Sooreshjani; Lisa Hurley; James P. Chandler; Roger Stupp; Adam M. Sonabend; Craig M. Horbinski; Rimas V. Lukas; Joanne Xiu; Giselle Lopez; Theodore P. Nicolaides; Valerie Brown; Nitin R. Wadhwani; Sandi K. Lam; Charles David James; Ganesh Rao; Maria G. Castro; Amy B. Heimberger; Michael DeCuypere

doi:10.1172/JCI177413

Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma

Shashwat Tripathi, Hinda Najem, Corey Dussold, Sebastian Pacheco, Ruochen Du, Moloud Sooreshjani, Lisa Hurley, James P. Chandler, Roger Stupp, Adam M. Sonabend, Craig M. Horbinski, Rimas V. Lukas, Joanne Xiu, Giselle Lopez, Theodore P. Nicolaides, Valerie Brown, Nitin R. Wadhwani, Sandi K. Lam, Charles David James, Ganesh RaoMaria G. Castro, Amy B. Heimberger^*, Michael DeCuypere

^*Corresponding author for this work

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

Abstract

Despite being the leading cause of cancer-related childhood mortality, pediatric gliomas have been relatively understudied, and the repurposing of immunotherapies has not been successful. Whole-transcriptome sequencing, single-cell sequencing, and sequential multiplex immunofluorescence were used to identify an immunotherapeutic strategy that could be applied to multiple preclinical glioma models. MAPK-driven pediatric gliomas have a higher IFN signature relative to other molecular subgroups. Single-cell sequencing identified an activated and cytotoxic microglia (MG) population designated MG-Act in BRAF-fused, MAPK-activated pilocytic astrocytoma (PA), but not in high-grade gliomas or normal brain. T cell immunoglobulin and mucin domain 3 (TIM3) was expressed on MG-Act and on the myeloid cells lining the tumor vasculature but not normal brain vasculature. TIM3 expression became upregulated on immune cells in the PA microenvironment, and anti-TIM3 reprogrammed ex vivo immune cells from human PAs to a proinflammatory cytotoxic phenotype. In a genetically engineered murine model of MAPK-driven, low-grade gliomas, anti-TIM3 treatment increased median survival over IgG- and anti–PD-1–treated mice. Single-cell RNA-Seq data during the therapeutic window of anti-TIM3 revealed enrichment of the MG-Act population. The therapeutic activity of anti-TIM3 was abrogated in mice on the CX3CR1 MG–KO background. These data support the use of anti-TIM3 in clinical trials of pediatric low-grade, MAPK-driven gliomas.

Original language	English (US)
Article number	e177413
Journal	Journal of Clinical Investigation
Volume	134
Issue number	19
DOIs	https://doi.org/10.1172/JCI177413
State	Published - Oct 2024

Funding

ABH serves on the advisory boards of WCG Oncology and Caris Life Sciences and receives research support from Moleculin, AbbVie, and Alnylam. Lunaphore COMET multiplex immunofluorescence was enabled by a gift from the Stephen M. Coffman trust to the Northwestern Medicine Malnati Brain Tumor Institute of the Lurie Cancer Center. This study was funded by NIH grants CA120813, NS120547, P30CA060553, and P50CA221747; the Remission Alliance, the Charlie Teo Foundation; Sammy\u2019s Superheroes Foundation; Robert Mosky; and the Malnati Brain Tumor Institute. ST was supported in part by National Cancer Institute (NCI), NIH training grant T32 CA009560. The single-cell library preparation and sequencing were done at Northwestern University NUseq facility core. We would like to thank Kaethe Leonard for help processing human samples. Lunaphore COMET multiplex immunofluorescence was enabled by a gift from the Stephen M. Coffman trust to the Northwestern Medicine Malnati Brain Tumor Institute of the Lurie Cancer Center. This study was funded by NIH grants CA120813, NS120547, P30CA060553, and P50CA221747; the Remission Alliance, the Charlie Teo Foundation; Sammy\u2019s Superheroes Foundation; Robert Mosky; and the Malnati Brain Tumor Institute. ST was supported in part by National Cancer Institute (NCI), NIH training grant T32 CA009560. The single-cell library preparation and sequencing were done at North-western University NUseq facility core. We would like to thank Kaethe Leonard for help processing human samples.

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General Medicine

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10.1172/JCI177413

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Tripathi, S., Najem, H., Dussold, C., Pacheco, S., Du, R., Sooreshjani, M., Hurley, L., Chandler, J. P., Stupp, R., Sonabend, A. M., Horbinski, C. M., Lukas, R. V., Xiu, J., Lopez, G., Nicolaides, T. P., Brown, V., Wadhwani, N. R., Lam, S. K., James, C. D., ... DeCuypere, M. (2024). Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma. Journal of Clinical Investigation, 134(19), Article e177413. https://doi.org/10.1172/JCI177413

@article{bba100869c984005874aefeb845039e9,

title = "Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma",

abstract = "Despite being the leading cause of cancer-related childhood mortality, pediatric gliomas have been relatively understudied, and the repurposing of immunotherapies has not been successful. Whole-transcriptome sequencing, single-cell sequencing, and sequential multiplex immunofluorescence were used to identify an immunotherapeutic strategy that could be applied to multiple preclinical glioma models. MAPK-driven pediatric gliomas have a higher IFN signature relative to other molecular subgroups. Single-cell sequencing identified an activated and cytotoxic microglia (MG) population designated MG-Act in BRAF-fused, MAPK-activated pilocytic astrocytoma (PA), but not in high-grade gliomas or normal brain. T cell immunoglobulin and mucin domain 3 (TIM3) was expressed on MG-Act and on the myeloid cells lining the tumor vasculature but not normal brain vasculature. TIM3 expression became upregulated on immune cells in the PA microenvironment, and anti-TIM3 reprogrammed ex vivo immune cells from human PAs to a proinflammatory cytotoxic phenotype. In a genetically engineered murine model of MAPK-driven, low-grade gliomas, anti-TIM3 treatment increased median survival over IgG- and anti–PD-1–treated mice. Single-cell RNA-Seq data during the therapeutic window of anti-TIM3 revealed enrichment of the MG-Act population. The therapeutic activity of anti-TIM3 was abrogated in mice on the CX3CR1 MG–KO background. These data support the use of anti-TIM3 in clinical trials of pediatric low-grade, MAPK-driven gliomas.",

author = "Shashwat Tripathi and Hinda Najem and Corey Dussold and Sebastian Pacheco and Ruochen Du and Moloud Sooreshjani and Lisa Hurley and Chandler, {James P.} and Roger Stupp and Sonabend, {Adam M.} and Horbinski, {Craig M.} and Lukas, {Rimas V.} and Joanne Xiu and Giselle Lopez and Nicolaides, {Theodore P.} and Valerie Brown and Wadhwani, {Nitin R.} and Lam, {Sandi K.} and James, {Charles David} and Ganesh Rao and Castro, {Maria G.} and Heimberger, {Amy B.} and Michael DeCuypere",

note = "Publisher Copyright: {\textcopyright} 2024, Tripathi et al.",

year = "2024",

month = oct,

doi = "10.1172/JCI177413",

language = "English (US)",

volume = "134",

journal = "Journal of Clinical Investigation",

issn = "0021-9738",

publisher = "American Society for Clinical Investigation",

number = "19",

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Tripathi, S, Najem, H, Dussold, C, Pacheco, S, Du, R, Sooreshjani, M, Hurley, L, Chandler, JP , Stupp, R , Sonabend, AM , Horbinski, CM , Lukas, RV, Xiu, J, Lopez, G, Nicolaides, TP, Brown, V, Wadhwani, NR , Lam, SK, James, CD, Rao, G, Castro, MG, Heimberger, AB & DeCuypere, M 2024, 'Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma', Journal of Clinical Investigation, vol. 134, no. 19, e177413. https://doi.org/10.1172/JCI177413

TY - JOUR

T1 - Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma

AU - Tripathi, Shashwat

AU - Najem, Hinda

AU - Dussold, Corey

AU - Pacheco, Sebastian

AU - Du, Ruochen

AU - Sooreshjani, Moloud

AU - Hurley, Lisa

AU - Chandler, James P.

AU - Stupp, Roger

AU - Sonabend, Adam M.

AU - Horbinski, Craig M.

AU - Lukas, Rimas V.

AU - Xiu, Joanne

AU - Lopez, Giselle

AU - Nicolaides, Theodore P.

AU - Brown, Valerie

AU - Wadhwani, Nitin R.

AU - Lam, Sandi K.

AU - James, Charles David

AU - Rao, Ganesh

AU - Castro, Maria G.

AU - Heimberger, Amy B.

AU - DeCuypere, Michael

PY - 2024/10

Y1 - 2024/10

N2 - Despite being the leading cause of cancer-related childhood mortality, pediatric gliomas have been relatively understudied, and the repurposing of immunotherapies has not been successful. Whole-transcriptome sequencing, single-cell sequencing, and sequential multiplex immunofluorescence were used to identify an immunotherapeutic strategy that could be applied to multiple preclinical glioma models. MAPK-driven pediatric gliomas have a higher IFN signature relative to other molecular subgroups. Single-cell sequencing identified an activated and cytotoxic microglia (MG) population designated MG-Act in BRAF-fused, MAPK-activated pilocytic astrocytoma (PA), but not in high-grade gliomas or normal brain. T cell immunoglobulin and mucin domain 3 (TIM3) was expressed on MG-Act and on the myeloid cells lining the tumor vasculature but not normal brain vasculature. TIM3 expression became upregulated on immune cells in the PA microenvironment, and anti-TIM3 reprogrammed ex vivo immune cells from human PAs to a proinflammatory cytotoxic phenotype. In a genetically engineered murine model of MAPK-driven, low-grade gliomas, anti-TIM3 treatment increased median survival over IgG- and anti–PD-1–treated mice. Single-cell RNA-Seq data during the therapeutic window of anti-TIM3 revealed enrichment of the MG-Act population. The therapeutic activity of anti-TIM3 was abrogated in mice on the CX3CR1 MG–KO background. These data support the use of anti-TIM3 in clinical trials of pediatric low-grade, MAPK-driven gliomas.

AB - Despite being the leading cause of cancer-related childhood mortality, pediatric gliomas have been relatively understudied, and the repurposing of immunotherapies has not been successful. Whole-transcriptome sequencing, single-cell sequencing, and sequential multiplex immunofluorescence were used to identify an immunotherapeutic strategy that could be applied to multiple preclinical glioma models. MAPK-driven pediatric gliomas have a higher IFN signature relative to other molecular subgroups. Single-cell sequencing identified an activated and cytotoxic microglia (MG) population designated MG-Act in BRAF-fused, MAPK-activated pilocytic astrocytoma (PA), but not in high-grade gliomas or normal brain. T cell immunoglobulin and mucin domain 3 (TIM3) was expressed on MG-Act and on the myeloid cells lining the tumor vasculature but not normal brain vasculature. TIM3 expression became upregulated on immune cells in the PA microenvironment, and anti-TIM3 reprogrammed ex vivo immune cells from human PAs to a proinflammatory cytotoxic phenotype. In a genetically engineered murine model of MAPK-driven, low-grade gliomas, anti-TIM3 treatment increased median survival over IgG- and anti–PD-1–treated mice. Single-cell RNA-Seq data during the therapeutic window of anti-TIM3 revealed enrichment of the MG-Act population. The therapeutic activity of anti-TIM3 was abrogated in mice on the CX3CR1 MG–KO background. These data support the use of anti-TIM3 in clinical trials of pediatric low-grade, MAPK-driven gliomas.

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DO - 10.1172/JCI177413

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AN - SCOPUS:85205525180

SN - 0021-9738

VL - 134

JO - Journal of Clinical Investigation

JF - Journal of Clinical Investigation

IS - 19

M1 - e177413

ER -

Pediatric glioma immune profiling identifies TIM3 as a therapeutic target in BRAF fusion pilocytic astrocytoma

Abstract

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UN SDGs

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