Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy

Tina Cascone; Jodi A. McKenzie; Rina M. Mbofung; Simone Punt; Zhe Wang; Chunyu Xu; Leila J. Williams; Zhiqiang Wang; Christopher A. Bristow; Alessandro Carugo; Michael D. Peoples; Lerong Li; Tatiana Karpinets; Lu Huang; Shruti Malu; Caitlin Creasy; Sara E. Leahey; Jiong Chen; Yuan Chen; Helen Pelicano; Chantale Bernatchez; Y. N.Vashisht Gopal; Timothy P. Heffernan; Jianhua Hu; Jing Wang; Rodabe N. Amaria; Levi A. Garraway; Peng Huang; Peiying Yang; Ignacio I. Wistuba; Scott E. Woodman; Jason Roszik; R. Eric Davis; Michael A. Davies; John V. Heymach; Patrick Hwu; Weiyi Peng

doi:10.1016/j.cmet.2018.02.024

Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy

Tina Cascone, Jodi A. McKenzie, Rina M. Mbofung, Simone Punt, Zhe Wang, Chunyu Xu, Leila J. Williams, Zhiqiang Wang, Christopher A. Bristow, Alessandro Carugo, Michael D. Peoples, Lerong Li, Tatiana Karpinets, Lu Huang, Shruti Malu, Caitlin Creasy, Sara E. Leahey, Jiong Chen, Yuan Chen, Helen PelicanoChantale Bernatchez, Y. N.Vashisht Gopal, Timothy P. Heffernan, Jianhua Hu, Jing Wang, Rodabe N. Amaria, Levi A. Garraway, Peng Huang, Peiying Yang, Ignacio I. Wistuba, Scott E. Woodman, Jason Roszik, R. Eric Davis, Michael A. Davies, John V. Heymach, Patrick Hwu, Weiyi Peng

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Abstract

Adoptive T cell therapy (ACT) produces durable responses in some cancer patients; however, most tumors are refractory to ACT and the molecular mechanisms underlying resistance are unclear. Using two independent approaches, we identified tumor glycolysis as a pathway associated with immune resistance in melanoma. Glycolysis-related genes were upregulated in melanoma and lung cancer patient samples poorly infiltrated by T cells. Overexpression of glycolysis-related molecules impaired T cell killing of tumor cells, whereas inhibition of glycolysis enhanced T cell-mediated antitumor immunity in vitro and in vivo. Moreover, glycolysis-related gene expression was higher in melanoma tissues from ACT-refractory patients, and tumor cells derived from these patients exhibited higher glycolytic activity. We identified reduced levels of IRF1 and CXCL10 immunostimulatory molecules in highly glycolytic melanoma cells. Our findings demonstrate that tumor glycolysis is associated with the efficacy of ACT and identify the glycolysis pathway as a candidate target for combinatorial therapeutic intervention. Cascone et al. identify tumor glycolysis to be associated with immune resistance to adoptive T cell therapy (ACT). In ACT-treated patients, increased tumor glycolytic activity is associated with lower therapeutic response, highlighting the therapeutic potential of combining glycolysis inhibition with ACT in cancer patients.

Original language	English (US)
Pages (from-to)	977-987.e4
Journal	Cell Metabolism
Volume	27
Issue number	5
DOIs	https://doi.org/10.1016/j.cmet.2018.02.024
State	Published - May 1 2018

Keywords

adoptive T cell therapy
cancer immunotherapy
glycolysis
immune resistance
melanoma
non-small cell lung cancer
tumor metabolism reprogramming

ASJC Scopus subject areas

Physiology
Molecular Biology
Cell Biology

MD Anderson CCSG core facilities

Bioinformatics Shared Resource
Functional Proteomics Reverse Phase Protein Array Core

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10.1016/j.cmet.2018.02.024

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Cascone, T., McKenzie, J. A., Mbofung, R. M., Punt, S., Wang, Z., Xu, C., Williams, L. J., Wang, Z., Bristow, C. A., Carugo, A., Peoples, M. D., Li, L., Karpinets, T., Huang, L., Malu, S., Creasy, C., Leahey, S. E., Chen, J., Chen, Y., ... Peng, W. (2018). Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy. Cell Metabolism, 27(5), 977-987.e4. https://doi.org/10.1016/j.cmet.2018.02.024

Cascone, T, McKenzie, JA, Mbofung, RM, Punt, S, Wang, Z, Xu, C, Williams, LJ, Wang, Z, Bristow, CA, Carugo, A, Peoples, MD, Li, L, Karpinets, T, Huang, L, Malu, S, Creasy, C, Leahey, SE, Chen, J, Chen, Y, Pelicano, H, Bernatchez, C, Gopal, YNV, Heffernan, TP, Hu, J, Wang, J, Amaria, RN, Garraway, LA, Huang, P, Yang, P , Wistuba, II , Woodman, SE , Roszik, J , Davis, RE , Davies, MA , Heymach, JV, Hwu, P & Peng, W 2018, 'Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy', Cell Metabolism, vol. 27, no. 5, pp. 977-987.e4. https://doi.org/10.1016/j.cmet.2018.02.024

@article{21800ab2e5e04ceb8342c19ae19bac92,

title = "Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy",

abstract = "Adoptive T cell therapy (ACT) produces durable responses in some cancer patients; however, most tumors are refractory to ACT and the molecular mechanisms underlying resistance are unclear. Using two independent approaches, we identified tumor glycolysis as a pathway associated with immune resistance in melanoma. Glycolysis-related genes were upregulated in melanoma and lung cancer patient samples poorly infiltrated by T cells. Overexpression of glycolysis-related molecules impaired T cell killing of tumor cells, whereas inhibition of glycolysis enhanced T cell-mediated antitumor immunity in vitro and in vivo. Moreover, glycolysis-related gene expression was higher in melanoma tissues from ACT-refractory patients, and tumor cells derived from these patients exhibited higher glycolytic activity. We identified reduced levels of IRF1 and CXCL10 immunostimulatory molecules in highly glycolytic melanoma cells. Our findings demonstrate that tumor glycolysis is associated with the efficacy of ACT and identify the glycolysis pathway as a candidate target for combinatorial therapeutic intervention. Cascone et al. identify tumor glycolysis to be associated with immune resistance to adoptive T cell therapy (ACT). In ACT-treated patients, increased tumor glycolytic activity is associated with lower therapeutic response, highlighting the therapeutic potential of combining glycolysis inhibition with ACT in cancer patients.",

keywords = "adoptive T cell therapy, cancer immunotherapy, glycolysis, immune resistance, melanoma, non-small cell lung cancer, tumor metabolism reprogramming",

author = "Tina Cascone and McKenzie, {Jodi A.} and Mbofung, {Rina M.} and Simone Punt and Zhe Wang and Chunyu Xu and Williams, {Leila J.} and Zhiqiang Wang and Bristow, {Christopher A.} and Alessandro Carugo and Peoples, {Michael D.} and Lerong Li and Tatiana Karpinets and Lu Huang and Shruti Malu and Caitlin Creasy and Leahey, {Sara E.} and Jiong Chen and Yuan Chen and Helen Pelicano and Chantale Bernatchez and Gopal, {Y. N.Vashisht} and Heffernan, {Timothy P.} and Jianhua Hu and Jing Wang and Amaria, {Rodabe N.} and Garraway, {Levi A.} and Peng Huang and Peiying Yang and Wistuba, {Ignacio I.} and Woodman, {Scott E.} and Jason Roszik and Davis, {R. Eric} and Davies, {Michael A.} and Heymach, {John V.} and Patrick Hwu and Weiyi Peng",

note = "Publisher Copyright: {\textcopyright} 2018 Elsevier Inc.",

year = "2018",

month = may,

day = "1",

doi = "10.1016/j.cmet.2018.02.024",

language = "English (US)",

volume = "27",

pages = "977--987.e4",

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T1 - Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy

AU - Cascone, Tina

AU - McKenzie, Jodi A.

AU - Mbofung, Rina M.

AU - Punt, Simone

AU - Wang, Zhe

AU - Xu, Chunyu

AU - Williams, Leila J.

AU - Wang, Zhiqiang

AU - Bristow, Christopher A.

AU - Carugo, Alessandro

AU - Peoples, Michael D.

AU - Li, Lerong

AU - Karpinets, Tatiana

AU - Huang, Lu

AU - Malu, Shruti

AU - Creasy, Caitlin

AU - Leahey, Sara E.

AU - Chen, Jiong

AU - Chen, Yuan

AU - Pelicano, Helen

AU - Bernatchez, Chantale

AU - Gopal, Y. N.Vashisht

AU - Heffernan, Timothy P.

AU - Hu, Jianhua

AU - Wang, Jing

AU - Amaria, Rodabe N.

AU - Garraway, Levi A.

AU - Huang, Peng

AU - Yang, Peiying

AU - Wistuba, Ignacio I.

AU - Woodman, Scott E.

AU - Roszik, Jason

AU - Davis, R. Eric

AU - Davies, Michael A.

AU - Heymach, John V.

AU - Hwu, Patrick

AU - Peng, Weiyi

PY - 2018/5/1

Y1 - 2018/5/1

N2 - Adoptive T cell therapy (ACT) produces durable responses in some cancer patients; however, most tumors are refractory to ACT and the molecular mechanisms underlying resistance are unclear. Using two independent approaches, we identified tumor glycolysis as a pathway associated with immune resistance in melanoma. Glycolysis-related genes were upregulated in melanoma and lung cancer patient samples poorly infiltrated by T cells. Overexpression of glycolysis-related molecules impaired T cell killing of tumor cells, whereas inhibition of glycolysis enhanced T cell-mediated antitumor immunity in vitro and in vivo. Moreover, glycolysis-related gene expression was higher in melanoma tissues from ACT-refractory patients, and tumor cells derived from these patients exhibited higher glycolytic activity. We identified reduced levels of IRF1 and CXCL10 immunostimulatory molecules in highly glycolytic melanoma cells. Our findings demonstrate that tumor glycolysis is associated with the efficacy of ACT and identify the glycolysis pathway as a candidate target for combinatorial therapeutic intervention. Cascone et al. identify tumor glycolysis to be associated with immune resistance to adoptive T cell therapy (ACT). In ACT-treated patients, increased tumor glycolytic activity is associated with lower therapeutic response, highlighting the therapeutic potential of combining glycolysis inhibition with ACT in cancer patients.

AB - Adoptive T cell therapy (ACT) produces durable responses in some cancer patients; however, most tumors are refractory to ACT and the molecular mechanisms underlying resistance are unclear. Using two independent approaches, we identified tumor glycolysis as a pathway associated with immune resistance in melanoma. Glycolysis-related genes were upregulated in melanoma and lung cancer patient samples poorly infiltrated by T cells. Overexpression of glycolysis-related molecules impaired T cell killing of tumor cells, whereas inhibition of glycolysis enhanced T cell-mediated antitumor immunity in vitro and in vivo. Moreover, glycolysis-related gene expression was higher in melanoma tissues from ACT-refractory patients, and tumor cells derived from these patients exhibited higher glycolytic activity. We identified reduced levels of IRF1 and CXCL10 immunostimulatory molecules in highly glycolytic melanoma cells. Our findings demonstrate that tumor glycolysis is associated with the efficacy of ACT and identify the glycolysis pathway as a candidate target for combinatorial therapeutic intervention. Cascone et al. identify tumor glycolysis to be associated with immune resistance to adoptive T cell therapy (ACT). In ACT-treated patients, increased tumor glycolytic activity is associated with lower therapeutic response, highlighting the therapeutic potential of combining glycolysis inhibition with ACT in cancer patients.

KW - adoptive T cell therapy

KW - cancer immunotherapy

KW - glycolysis

KW - immune resistance

KW - melanoma

KW - non-small cell lung cancer

KW - tumor metabolism reprogramming

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AN - SCOPUS:85044123871

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SP - 977-987.e4

JO - Cell Metabolism

JF - Cell Metabolism

IS - 5

ER -

Increased Tumor Glycolysis Characterizes Immune Resistance to Adoptive T Cell Therapy

Abstract

Keywords

ASJC Scopus subject areas

MD Anderson CCSG core facilities

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