CRISPR screens decode cancer cell pathways that trigger γδ T cell detection

Murad R Mamedov; Shane Vedova; Jacob W Freimer; Avinash Das Sahu; Amrita Ramesh; Maya M Arce; Angelo D Meringa; Mineto Ota; Peixin Amy Chen; Kristina Hanspers; Vinh Q Nguyen; Kirsten A Takeshima; Anne C Rios; Jonathan K Pritchard; Jürgen Kuball; Zsolt Sebestyen; Erin J Adams; Alexander Marson

doi:10.1038/s41586-023-06482-x

CRISPR screens decode cancer cell pathways that trigger γδ T cell detection

Murad R Mamedov^*
, Shane Vedova
, Jacob W Freimer
, Avinash Das Sahu
, Amrita Ramesh
, Maya M Arce
, Angelo D Meringa
, Mineto Ota
, Peixin Amy Chen
, Kristina Hanspers
, Vinh Q Nguyen
, Kirsten A Takeshima
, Anne C Rios
, Jonathan K Pritchard
, Jürgen Kuball
, Zsolt Sebestyen
, Erin J Adams
, Alexander Marson^*

^*Corresponding author for this work

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

Abstract

γδ T cells are potent anticancer effectors with the potential to target tumours broadly, independent of patient-specific neoantigens or human leukocyte antigen background 1-5. γδ T cells can sense conserved cell stress signals prevalent in transformed cells 2,3, although the mechanisms behind the targeting of stressed target cells remain poorly characterized. Vγ9Vδ2 T cells-the most abundant subset of human γδ T cells 4-recognize a protein complex containing butyrophilin 2A1 (BTN2A1) and BTN3A1 (refs. 6-8), a widely expressed cell surface protein that is activated by phosphoantigens abundantly produced by tumour cells. Here we combined genome-wide CRISPR screens in target cancer cells to identify pathways that regulate γδ T cell killing and BTN3A cell surface expression. The screens showed previously unappreciated multilayered regulation of BTN3A abundance on the cell surface and triggering of γδ T cells through transcription, post-translational modifications and membrane trafficking. In addition, diverse genetic perturbations and inhibitors disrupting metabolic pathways in the cancer cells, particularly ATP-producing processes, were found to alter BTN3A levels. This induction of both BTN3A and BTN2A1 during metabolic crises is dependent on AMP-activated protein kinase (AMPK). Finally, small-molecule activation of AMPK in a cell line model and in patient-derived tumour organoids led to increased expression of the BTN2A1-BTN3A complex and increased Vγ9Vδ2 T cell receptor-mediated killing. This AMPK-dependent mechanism of metabolic stress-induced ligand upregulation deepens our understanding of γδ T cell stress surveillance and suggests new avenues available to enhance γδ T cell anticancer activity.

Original language	English
Pages (from-to)	188-195
Number of pages	8
Journal	Nature
Volume	621
Issue number	7977
Early online date	30 Aug 2023
DOIs	https://doi.org/10.1038/s41586-023-06482-x
Publication status	Published - 7 Sept 2023

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s41586-023-06482-xFinal published version, 7.38 MBLicence: Taverne

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Mamedov, M. R., Vedova, S., Freimer, J. W., Sahu, A. D., Ramesh, A., Arce, M. M., Meringa, A. D., Ota, M., Chen, P. A., Hanspers, K., Nguyen, V. Q., Takeshima, K. A., Rios, A. C., Pritchard, J. K., Kuball, J., Sebestyen, Z., Adams, E. J., & Marson, A. (2023). CRISPR screens decode cancer cell pathways that trigger γδ T cell detection. Nature, 621(7977), 188-195. https://doi.org/10.1038/s41586-023-06482-x

@article{8a0389f4d99f4fddb97783b21cec10a7,

title = "CRISPR screens decode cancer cell pathways that trigger γδ T cell detection",

abstract = "γδ T cells are potent anticancer effectors with the potential to target tumours broadly, independent of patient-specific neoantigens or human leukocyte antigen background 1-5. γδ T cells can sense conserved cell stress signals prevalent in transformed cells 2,3, although the mechanisms behind the targeting of stressed target cells remain poorly characterized. Vγ9Vδ2 T cells-the most abundant subset of human γδ T cells 4-recognize a protein complex containing butyrophilin 2A1 (BTN2A1) and BTN3A1 (refs. 6-8), a widely expressed cell surface protein that is activated by phosphoantigens abundantly produced by tumour cells. Here we combined genome-wide CRISPR screens in target cancer cells to identify pathways that regulate γδ T cell killing and BTN3A cell surface expression. The screens showed previously unappreciated multilayered regulation of BTN3A abundance on the cell surface and triggering of γδ T cells through transcription, post-translational modifications and membrane trafficking. In addition, diverse genetic perturbations and inhibitors disrupting metabolic pathways in the cancer cells, particularly ATP-producing processes, were found to alter BTN3A levels. This induction of both BTN3A and BTN2A1 during metabolic crises is dependent on AMP-activated protein kinase (AMPK). Finally, small-molecule activation of AMPK in a cell line model and in patient-derived tumour organoids led to increased expression of the BTN2A1-BTN3A complex and increased Vγ9Vδ2 T cell receptor-mediated killing. This AMPK-dependent mechanism of metabolic stress-induced ligand upregulation deepens our understanding of γδ T cell stress surveillance and suggests new avenues available to enhance γδ T cell anticancer activity. ",

author = "Mamedov, \{Murad R\} and Shane Vedova and Freimer, \{Jacob W\} and Sahu, \{Avinash Das\} and Amrita Ramesh and Arce, \{Maya M\} and Meringa, \{Angelo D\} and Mineto Ota and Chen, \{Peixin Amy\} and Kristina Hanspers and Nguyen, \{Vinh Q\} and Takeshima, \{Kirsten A\} and Rios, \{Anne C\} and Pritchard, \{Jonathan K\} and J{\"u}rgen Kuball and Zsolt Sebestyen and Adams, \{Erin J\} and Alexander Marson",

note = "Funding Information: We thank members of the Marson laboratory, I. Jain, S. Dodgson, S. Pyle, T. Tolpa and the Gladstone Flow Cytometry Core for providing valuable input and technical expertise. We also thank B. Gewurz (Harvard Medical School) for sharing Daudi-Cas9 cells. M.R.M. was a Cancer Research Institute (CRI) Irvington Fellow supported by CRI and was supported by the Human Vaccines Project Michelson Prizes for Human Immunology and Vaccine Research funded by the Michelson Medical Research Foundation. J.W.F. was funded by an NIH grant (no. R01HG008140). A.R. was supported by an NIH training grant (no. T32GM007281). M.M.A. is supported by an NSF GRFP grant (no. 2038436). M.O. was supported by Astellas Foundation for Research on Metabolic Disorder, Chugai Foundation for Innovative Drug Discovery Science and Mochida Memorial Foundation for Medicine and Pharmaceutical Research. K.A.T. was supported by the Gladstone PUMAS programme, funded by an NIH grant (no. 5R25HL121037). J.K. and Z.S. were supported by Oncode-PACT and Dutch Cancer Society grant nos. KWF 11393, 12586 and 13043. E.J.A. is funded by an NIH grant (no. R01AI155984). The Marson laboratory has received funds from the CRI Lloyd J. Old STAR grant, The Cancer League, the Innovative Genomics Institute, the Simons Foundation and the Parker Institute for Cancer Immunotherapy. We thank the Hubrecht Organoid Technology for providing patient-derived breast cancer organoids, and J. M. L. Roodhart (Department of Medical Oncology, University Medical Center Utrecht, Utrecht University, Utrecht, the Netherlands) for providing the patient-derived colon cancer organoid. The Gladstone Flow Cytometry Core is supported by the James B. Pendleton Charitable Trust. The schematic in Fig. 3a was adapted from the BioRender {\textquoteleft}Electron Transport Chain{\textquoteright} template. Some of the results shown here are based on data generated by the TCGA Research Network: https://www.cancer.gov/tcga. Funding Information: We thank members of the Marson laboratory, I. Jain, S. Dodgson, S. Pyle, T. Tolpa and the Gladstone Flow Cytometry Core for providing valuable input and technical expertise. We also thank B. Gewurz (Harvard Medical School) for sharing Daudi-Cas9 cells. M.R.M. was a Cancer Research Institute (CRI) Irvington Fellow supported by CRI and was supported by the Human Vaccines Project Michelson Prizes for Human Immunology and Vaccine Research funded by the Michelson Medical Research Foundation. J.W.F. was funded by an NIH grant (no. R01HG008140). A.R. was supported by an NIH training grant (no. T32GM007281). M.M.A. is supported by an NSF GRFP grant (no. 2038436). M.O. was supported by Astellas Foundation for Research on Metabolic Disorder, Chugai Foundation for Innovative Drug Discovery Science and Mochida Memorial Foundation for Medicine and Pharmaceutical Research. K.A.T. was supported by the Gladstone PUMAS programme, funded by an NIH grant (no. 5R25HL121037). J.K. and Z.S. were supported by Oncode-PACT and Dutch Cancer Society grant nos. KWF 11393, 12586 and 13043. E.J.A. is funded by an NIH grant (no. R01AI155984). The Marson laboratory has received funds from the CRI Lloyd J. Old STAR grant, The Cancer League, the Innovative Genomics Institute, the Simons Foundation and the Parker Institute for Cancer Immunotherapy. We thank the Hubrecht Organoid Technology for providing patient-derived breast cancer organoids, and J. M. L. Roodhart (Department of Medical Oncology, University Medical Center Utrecht, Utrecht University, Utrecht, the Netherlands) for providing the patient-derived colon cancer organoid. The Gladstone Flow Cytometry Core is supported by the James B. Pendleton Charitable Trust. The schematic in Fig. 3a was adapted from the BioRender {\textquoteleft}Electron Transport Chain{\textquoteright} template. Some of the results shown here are based on data generated by the TCGA Research Network: https://www.cancer.gov/tcga . Publisher Copyright: {\textcopyright} 2023, The Author(s), under exclusive licence to Springer Nature Limited.",

year = "2023",

month = sep,

day = "7",

doi = "10.1038/s41586-023-06482-x",

language = "English",

volume = "621",

pages = "188--195",

journal = "Nature",

issn = "0028-0836",

publisher = "Nature Research",

number = "7977",

}

Mamedov, MR, Vedova, S, Freimer, JW, Sahu, AD, Ramesh, A, Arce, MM, Meringa, AD, Ota, M, Chen, PA, Hanspers, K, Nguyen, VQ, Takeshima, KA, Rios, AC, Pritchard, JK, Kuball, J , Sebestyen, Z, Adams, EJ & Marson, A 2023, 'CRISPR screens decode cancer cell pathways that trigger γδ T cell detection', Nature, vol. 621, no. 7977, pp. 188-195. https://doi.org/10.1038/s41586-023-06482-x

TY - JOUR

T1 - CRISPR screens decode cancer cell pathways that trigger γδ T cell detection

AU - Mamedov, Murad R

AU - Vedova, Shane

AU - Freimer, Jacob W

AU - Sahu, Avinash Das

AU - Ramesh, Amrita

AU - Arce, Maya M

AU - Meringa, Angelo D

AU - Ota, Mineto

AU - Chen, Peixin Amy

AU - Hanspers, Kristina

AU - Nguyen, Vinh Q

AU - Takeshima, Kirsten A

AU - Rios, Anne C

AU - Pritchard, Jonathan K

AU - Kuball, Jürgen

AU - Sebestyen, Zsolt

AU - Adams, Erin J

AU - Marson, Alexander

N1 - Funding Information: We thank members of the Marson laboratory, I. Jain, S. Dodgson, S. Pyle, T. Tolpa and the Gladstone Flow Cytometry Core for providing valuable input and technical expertise. We also thank B. Gewurz (Harvard Medical School) for sharing Daudi-Cas9 cells. M.R.M. was a Cancer Research Institute (CRI) Irvington Fellow supported by CRI and was supported by the Human Vaccines Project Michelson Prizes for Human Immunology and Vaccine Research funded by the Michelson Medical Research Foundation. J.W.F. was funded by an NIH grant (no. R01HG008140). A.R. was supported by an NIH training grant (no. T32GM007281). M.M.A. is supported by an NSF GRFP grant (no. 2038436). M.O. was supported by Astellas Foundation for Research on Metabolic Disorder, Chugai Foundation for Innovative Drug Discovery Science and Mochida Memorial Foundation for Medicine and Pharmaceutical Research. K.A.T. was supported by the Gladstone PUMAS programme, funded by an NIH grant (no. 5R25HL121037). J.K. and Z.S. were supported by Oncode-PACT and Dutch Cancer Society grant nos. KWF 11393, 12586 and 13043. E.J.A. is funded by an NIH grant (no. R01AI155984). The Marson laboratory has received funds from the CRI Lloyd J. Old STAR grant, The Cancer League, the Innovative Genomics Institute, the Simons Foundation and the Parker Institute for Cancer Immunotherapy. We thank the Hubrecht Organoid Technology for providing patient-derived breast cancer organoids, and J. M. L. Roodhart (Department of Medical Oncology, University Medical Center Utrecht, Utrecht University, Utrecht, the Netherlands) for providing the patient-derived colon cancer organoid. The Gladstone Flow Cytometry Core is supported by the James B. Pendleton Charitable Trust. The schematic in Fig. 3a was adapted from the BioRender ‘Electron Transport Chain’ template. Some of the results shown here are based on data generated by the TCGA Research Network: https://www.cancer.gov/tcga. Funding Information: We thank members of the Marson laboratory, I. Jain, S. Dodgson, S. Pyle, T. Tolpa and the Gladstone Flow Cytometry Core for providing valuable input and technical expertise. We also thank B. Gewurz (Harvard Medical School) for sharing Daudi-Cas9 cells. M.R.M. was a Cancer Research Institute (CRI) Irvington Fellow supported by CRI and was supported by the Human Vaccines Project Michelson Prizes for Human Immunology and Vaccine Research funded by the Michelson Medical Research Foundation. J.W.F. was funded by an NIH grant (no. R01HG008140). A.R. was supported by an NIH training grant (no. T32GM007281). M.M.A. is supported by an NSF GRFP grant (no. 2038436). M.O. was supported by Astellas Foundation for Research on Metabolic Disorder, Chugai Foundation for Innovative Drug Discovery Science and Mochida Memorial Foundation for Medicine and Pharmaceutical Research. K.A.T. was supported by the Gladstone PUMAS programme, funded by an NIH grant (no. 5R25HL121037). J.K. and Z.S. were supported by Oncode-PACT and Dutch Cancer Society grant nos. KWF 11393, 12586 and 13043. E.J.A. is funded by an NIH grant (no. R01AI155984). The Marson laboratory has received funds from the CRI Lloyd J. Old STAR grant, The Cancer League, the Innovative Genomics Institute, the Simons Foundation and the Parker Institute for Cancer Immunotherapy. We thank the Hubrecht Organoid Technology for providing patient-derived breast cancer organoids, and J. M. L. Roodhart (Department of Medical Oncology, University Medical Center Utrecht, Utrecht University, Utrecht, the Netherlands) for providing the patient-derived colon cancer organoid. The Gladstone Flow Cytometry Core is supported by the James B. Pendleton Charitable Trust. The schematic in Fig. 3a was adapted from the BioRender ‘Electron Transport Chain’ template. Some of the results shown here are based on data generated by the TCGA Research Network: https://www.cancer.gov/tcga . Publisher Copyright: © 2023, The Author(s), under exclusive licence to Springer Nature Limited.

PY - 2023/9/7

Y1 - 2023/9/7

N2 - γδ T cells are potent anticancer effectors with the potential to target tumours broadly, independent of patient-specific neoantigens or human leukocyte antigen background 1-5. γδ T cells can sense conserved cell stress signals prevalent in transformed cells 2,3, although the mechanisms behind the targeting of stressed target cells remain poorly characterized. Vγ9Vδ2 T cells-the most abundant subset of human γδ T cells 4-recognize a protein complex containing butyrophilin 2A1 (BTN2A1) and BTN3A1 (refs. 6-8), a widely expressed cell surface protein that is activated by phosphoantigens abundantly produced by tumour cells. Here we combined genome-wide CRISPR screens in target cancer cells to identify pathways that regulate γδ T cell killing and BTN3A cell surface expression. The screens showed previously unappreciated multilayered regulation of BTN3A abundance on the cell surface and triggering of γδ T cells through transcription, post-translational modifications and membrane trafficking. In addition, diverse genetic perturbations and inhibitors disrupting metabolic pathways in the cancer cells, particularly ATP-producing processes, were found to alter BTN3A levels. This induction of both BTN3A and BTN2A1 during metabolic crises is dependent on AMP-activated protein kinase (AMPK). Finally, small-molecule activation of AMPK in a cell line model and in patient-derived tumour organoids led to increased expression of the BTN2A1-BTN3A complex and increased Vγ9Vδ2 T cell receptor-mediated killing. This AMPK-dependent mechanism of metabolic stress-induced ligand upregulation deepens our understanding of γδ T cell stress surveillance and suggests new avenues available to enhance γδ T cell anticancer activity.

AB - γδ T cells are potent anticancer effectors with the potential to target tumours broadly, independent of patient-specific neoantigens or human leukocyte antigen background 1-5. γδ T cells can sense conserved cell stress signals prevalent in transformed cells 2,3, although the mechanisms behind the targeting of stressed target cells remain poorly characterized. Vγ9Vδ2 T cells-the most abundant subset of human γδ T cells 4-recognize a protein complex containing butyrophilin 2A1 (BTN2A1) and BTN3A1 (refs. 6-8), a widely expressed cell surface protein that is activated by phosphoantigens abundantly produced by tumour cells. Here we combined genome-wide CRISPR screens in target cancer cells to identify pathways that regulate γδ T cell killing and BTN3A cell surface expression. The screens showed previously unappreciated multilayered regulation of BTN3A abundance on the cell surface and triggering of γδ T cells through transcription, post-translational modifications and membrane trafficking. In addition, diverse genetic perturbations and inhibitors disrupting metabolic pathways in the cancer cells, particularly ATP-producing processes, were found to alter BTN3A levels. This induction of both BTN3A and BTN2A1 during metabolic crises is dependent on AMP-activated protein kinase (AMPK). Finally, small-molecule activation of AMPK in a cell line model and in patient-derived tumour organoids led to increased expression of the BTN2A1-BTN3A complex and increased Vγ9Vδ2 T cell receptor-mediated killing. This AMPK-dependent mechanism of metabolic stress-induced ligand upregulation deepens our understanding of γδ T cell stress surveillance and suggests new avenues available to enhance γδ T cell anticancer activity.

UR - https://www.scopus.com/pages/publications/85169156595

U2 - 10.1038/s41586-023-06482-x

DO - 10.1038/s41586-023-06482-x

M3 - Article

C2 - 37648854

SN - 0028-0836

VL - 621

SP - 188

EP - 195

JO - Nature

JF - Nature

IS - 7977

ER -

CRISPR screens decode cancer cell pathways that trigger γδ T cell detection

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