Improving radiotherapy in immunosuppressive microenvironments by targeting complement receptor C5aR1
Callum Beach, David MacLean, Dominika Majorova, Stavros Melemenidis, Dhanya K. Nambiar, Ryan K. Kim, Gabriel N. Valbuena, Silvia Guglietta, Carsten Krieg, Mahnaz Darvish-Damavandi, Tatsuya Suwa, Alistair Easton, Lily V.S. Hillson, Ashley K. McCulloch, Ross K. McMahon, Kathryn Pennel, Joanne Edwards, Sean M. O’Cathail, Campbell S. Roxburgh, Enric Domingo, Eui Jung Moon, Dadi Jiang, Yanyan Jiang, Qingyang Zhang, Albert C. Koong, Trent M. Woodruff, Edward E. Graves, Tim Maughan, Simon J.A. Buczacki, Manuel Stucki, Quynh-Thu Le, Simon J. Leedham, Amato J. Giaccia, Monica M. Olcina
Callum Beach, David MacLean, Dominika Majorova, Stavros Melemenidis, Dhanya K. Nambiar, Ryan K. Kim, Gabriel N. Valbuena, Silvia Guglietta, Carsten Krieg, Mahnaz Darvish-Damavandi, Tatsuya Suwa, Alistair Easton, Lily V.S. Hillson, Ashley K. McCulloch, Ross K. McMahon, Kathryn Pennel, Joanne Edwards, Sean M. O’Cathail, Campbell S. Roxburgh, Enric Domingo, Eui Jung Moon, Dadi Jiang, Yanyan Jiang, Qingyang Zhang, Albert C. Koong, Trent M. Woodruff, Edward E. Graves, Tim Maughan, Simon J.A. Buczacki, Manuel Stucki, Quynh-Thu Le, Simon J. Leedham, Amato J. Giaccia, Monica M. Olcina
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Research Article Cell biology Oncology

Improving radiotherapy in immunosuppressive microenvironments by targeting complement receptor C5aR1

Abstract

An immunosuppressive microenvironment causes poor tumor T cell infiltration and is associated with reduced patient overall survival in colorectal cancer. How to improve treatment responses in these tumors is still a challenge. Using an integrated screening approach to identify cancer-specific vulnerabilities, we identified complement receptor C5aR1 as a druggable target, which when inhibited improved radiotherapy, even in tumors displaying immunosuppressive features and poor CD8+ T cell infiltration. While C5aR1 is well-known for its role in the immune compartment, we found that C5aR1 is also robustly expressed on malignant epithelial cells, highlighting potential tumor cell–specific functions. C5aR1 targeting resulted in increased NF-κB–dependent apoptosis specifically in tumors and not normal tissues, indicating that, in malignant cells, C5aR1 primarily regulated cell fate. Collectively, these data revealed that increased complement gene expression is part of the stress response mounted by irradiated tumors and that targeting C5aR1 could improve radiotherapy, even in tumors displaying immunosuppressive features.

Authors

Callum Beach, David MacLean, Dominika Majorova, Stavros Melemenidis, Dhanya K. Nambiar, Ryan K. Kim, Gabriel N. Valbuena, Silvia Guglietta, Carsten Krieg, Mahnaz Darvish-Damavandi, Tatsuya Suwa, Alistair Easton, Lily V.S. Hillson, Ashley K. McCulloch, Ross K. McMahon, Kathryn Pennel, Joanne Edwards, Sean M. O’Cathail, Campbell S. Roxburgh, Enric Domingo, Eui Jung Moon, Dadi Jiang, Yanyan Jiang, Qingyang Zhang, Albert C. Koong, Trent M. Woodruff, Edward E. Graves, Tim Maughan, Simon J.A. Buczacki, Manuel Stucki, Quynh-Thu Le, Simon J. Leedham, Amato J. Giaccia, Monica M. Olcina

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Figure 7

C5aR1 inhibition can improve radiotherapy in tumors with an immunosuppressive microenvironment.

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C5aR1 inhibition can improve radiotherapy in tumors with an immunosuppre...
(A) Curves show counted viable AKPT organoids vs. RT dose following treatment with vehicle or PMX205. **P < 0.01, Welch’s t test. Data are shown as the mean. Error bars represent standard deviation. (B) Schematic representation of experimental design for CF. Created with BioRender.com. (C) Tumor growth curves for AKPT organoids grown subcutaneously and treated with 0 Gy and vehicle or PMX205. Comparisons were not significant (P = >0.05) by repeated measures 2-way ANOVA (with Geisser-Greanhouse correction). n = 7 mice/group. (D) Tumor growth curves for AKPT organoids grown subcutaneously and treated with 9 Gy and vehicle or PMX205 flanking RT. ****P < 0.0001 by repeated measures 2-way ANOVA (with Geisser-Greanhouse correction); P < 0.05 for day 10, 14, and 17 with Šídák’s comparison test. n = 7 mice/group. (E) Probability of survival for tumor-bearing mice from C and D. ****P < 0.0001, log-rank. n = 7 mice/group. (F) The percentage of apoptotic (TUNEL+) area/hematoxylin+ area in mice from C and D. **P < 0.01, ordinary 1-way ANOVA with Dunnett’s multiple comparisons test. n = 4–8 mice/group. (G) Tumor growth curves for AKPT organoids grown subcutaneously in athymic nude mice and treated with 0 Gy and vehicle or PMX205. Comparisons were not significant (P > 0.05) by repeated measures 2-way ANOVA (with Geisser-Greanhouse correction). n = 7 mice/group. (H) Tumor growth curves for AKPT organoids grown subcutaneously in athymic nude mice and treated with 9 Gy and vehicle or PMX205 flanking RT. ***P < 0.001, repeated measures 2-way ANOVA (with Geisser-Greanhouse correction); ***P < 0.001 for day 24, Šídák’s comparison test. n = 7 mice/group. (I) Probability of survival for mice from G and H. ****P < 0.0001, log-rank. n = 7/group (n = 6 for 0 Gy vehicle). (J) Working model: C5aR1 attenuates RT-induced tumor cell death via increased prosurvival signaling (including NF-κB). Upon C5aR1 blockade, tumor cells undergo increased RT-induced cell death, which is not observed in the intestinal epithelium. Created with BioRender.com.