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Cancer Immunology Research
Cancer Immunology Research
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Table of Contents

What We're Reading

  • What We're Reading
    A Sampling of Highlights from the Literature
    Cancer Immunol Res July 1 2020 8 (7) 843-843;

Priority Briefs

  • Priority Briefs
    Tumor Fusion Burden as a Hallmark of Immune Infiltration in Prostate Cancer
    Marie-Claire Wagle, Joseph Castillo, Shrividhya Srinivasan, Thomas Holcomb, Kobe C. Yuen, Edward E. Kadel, Sanjeev Mariathasan, Daniel L. Halligan, Adrian R. Carr, Max Bylesjo, Paul R. McAdam, Sarah Lynagh, Koen M. Marien, Mark Kockx, Yannick Waumans, Shih-Min A. Huang, Mark R. Lackner and Zineb Mounir
    Cancer Immunol Res July 1 2020 8 (7) 844-850; DOI:10.1158/2326-6066.CIR-19-0568

    Despite the link of tumor mutational burden with response to immunotherapy, it is not universal across tumor types. In prostate cancer, the burden of tumor gene fusions positively correlates with antitumor immunity, inversely correlating with tumor mutational burden.

  • Priority Briefs
    Demographic Factors Associated with Toxicity in Patients Treated with Anti–Programmed Cell Death-1 Therapy
    Kaustav P. Shah, Haocan Song, Fei Ye, Javid J. Moslehi, Justin M. Balko, Joe-Elie Salem and Douglas B. Johnson
    Cancer Immunol Res July 1 2020 8 (7) 851-855; DOI:10.1158/2326-6066.CIR-19-0986

    Immune-related adverse events (irAEs), and the resulting length of hospitalization and mortality rate, are age specific in patients with melanoma treated with immunotherapy. These differences could be due to specific irAEs that occur in different age groups.

Research Articles

  • Research Articles
    Vaccination against Nonmutated Neoantigens Induced in Recurrent and Future Tumors
    Greta Garrido, Brett Schrand, Agata Levay, Ailem Rabasa, Anthony Ferrantella, Diane M. Da Silva, Francesca D'Eramo, Koen A. Marijt, Zhuoran Zhang, Deukwoo Kwon, Marcin Kortylewski, W. Martin Kast, Vikas Dudeja, Thorbald van Hall and Eli Gilboa
    Cancer Immunol Res July 1 2020 8 (7) 856-868; DOI:10.1158/2326-6066.CIR-20-0020

    A vaccination approach is presented. This strategy overcomes the main limitation of focusing on tumor mutation–derived neoantigens by vaccinating against neoantigens that are experimentally induced in tumor cells.

  • Research Articles
    Dual Relief of T-lymphocyte Proliferation and Effector Function Underlies Response to PD-1 Blockade in Epithelial Malignancies
    Camille-Charlotte Balança, Clara-Maria Scarlata, Marie Michelas, Christel Devaud, Victor Sarradin, Camille Franchet, Carlos Martinez Gomez, Carlos Gomez-Roca, Marie Tosolini, Diana Heaugwane, Françoise Lauzéral-Vizcaino, Lucile Mir-Mesnier, Virginie Féliu, Carine Valle, Frédéric Pont, Gwénaël Ferron, Laurence Gladieff, Stéphanie Motton, Yann Tanguy Le Gac, Agnès Dupret-Bories, Jérôme Sarini, Benjamin Vairel, Claire Illac, Aurore Siegfried-Vergnon, Eliane Mery, Jean-Jacques Fournié, Sébastien Vergez, Jean-Pierre Delord, Philippe Rochaix, Alejandra Martinez and Maha Ayyoub
    Cancer Immunol Res July 1 2020 8 (7) 869-882; DOI:10.1158/2326-6066.CIR-19-0855

    Tumor-infiltrating CD8+ T cells from patients with three cancer types exhibit a memory phenotype, a sequential pattern of immune checkpoint expression with additional CD39 expression, and CD28 loss. These cells' effector potential can be unleashed with anti–PD-1.

  • Research Articles
    SHP-2 and PD-L1 Inhibition Combined with Radiotherapy Enhances Systemic Antitumor Effects in an Anti–PD-1–Resistant Model of Non–Small Cell Lung Cancer
    Dawei Chen, Hampartsoum B. Barsoumian, Liangpeng Yang, Ahmed I. Younes, Vivek Verma, Yun Hu, Hari Menon, Mark Wasley, Fatemeh Masropour, Sara Mosaffa, Tugce Ozgen, Katherine Klein, Maria Angelica Cortez and James W. Welsh
    Cancer Immunol Res July 1 2020 8 (7) 883-894; DOI:10.1158/2326-6066.CIR-19-0744

    A triple-therapy combination leads to repolarization of M2 tumor-associated macrophages (TAMs) to M1 TAMs. As a result, this combination therapy elicits robust antitumor responses against primary NSCLC tumors and can also boost antitumor abscopal responses.

  • Research Articles | AuthorChoice
    Characterization of BAY 1905254, an Immune Checkpoint Inhibitor Targeting the Immunoglobulin-Like Domain Containing Receptor 2 (ILDR2)
    Julia Huetter, Uwe Gritzan, Ilona Gutcher, Wolf-Dietrich Doecke, Merlin V. Luetke-Eversloh, Sven Golfier, Helge G. Roider, Anna-Lena Frisk, John Hunter, Andrew Pow, Andrew Drake, Zurit Levine, Ofer Levy, Meir Azulay, Inbal Barbiro, Gady Cojocaru, Ilan Vaknin, Bertolt Kreft and Lars Roese
    Cancer Immunol Res July 1 2020 8 (7) 895-911; DOI:10.1158/2326-6066.CIR-19-0321

    ILDR2 is an immune checkpoint expressed by certain stromal lymph node cells called fibroblastic reticular cells. ILDR2 negatively interferes with T-cell activity, and its inhibition by the antibody BAY 1905254 is beneficial in preclinical models.

  • Research Articles
    CD226hiCD8+ T Cells Are a Prerequisite for Anti-TIGIT Immunotherapy
    Hyung-seung Jin, Minkyung Ko, Da-som Choi, June Hyuck Kim, Dong-hee Lee, Seong-Ho Kang, Inki Kim, Hee Jin Lee, Eun Kyung Choi, Kyu-pyo Kim, Changhoon Yoo and Yoon Park
    Cancer Immunol Res July 1 2020 8 (7) 912-925; DOI:10.1158/2326-6066.CIR-19-0877

    A subset of CD8+ T cells highly express CD226. The efficacy of anti-TIGIT therapy is more profound on high CD226 expressors rather than low. TIGIT blockade activity depends on CD226 phosphorylation, which predicts the outcome of anti-TIGIT therapy.

  • Research Articles
    Genetic Ablation of HLA Class I, Class II, and the T-cell Receptor Enables Allogeneic T Cells to Be Used for Adoptive T-cell Therapy
    Yuki Kagoya, Tingxi Guo, Brian Yeung, Kayoko Saso, Mark Anczurowski, Chung-Hsi Wang, Kenji Murata, Kenji Sugata, Hiroshi Saijo, Yukiko Matsunaga, Yota Ohashi, Marcus O. Butler and Naoto Hirano
    Cancer Immunol Res July 1 2020 8 (7) 926-936; DOI:10.1158/2326-6066.CIR-18-0508

    Antitumor T-cell grafts with HLA class I, HLA class II, and TCR molecules concurrently ablated evade allogeneic T-cell responses. These cells can be used as a universal T-cell source for adoptive cancer immunotherapy.

  • Research Articles
    Long Noncoding RNAs Control the Modulation of Immune Checkpoint Molecules in Cancer
    Shouping Xu, Qin Wang, Yujuan Kang, Jiena Liu, Yanling Yin, Lei Liu, Hao Wu, Siwei Li, Shiyao Sui, Meiying Shen, Wei Zheng and Da Pang
    Cancer Immunol Res July 1 2020 8 (7) 937-951; DOI:10.1158/2326-6066.CIR-19-0696

    Long noncoding RNAs (lncRNAs) could potentially regulate immune checkpoint molecules. The lncRNAs HCP5 and MIAT are upregulated when prognosis is poor. They drive PD-L1 expression and inhibit the efficacy of immune checkpoint blockade.

  • Research Articles | AuthorChoice
    Verteporfin Inhibits PD-L1 through Autophagy and the STAT1–IRF1–TRIM28 Signaling Axis, Exerting Antitumor Efficacy
    Jiyong Liang, Lulu Wang, Chao Wang, Jianfeng Shen, Bojin Su, Anantha L. Marisetty, Dexing Fang, Cynthia Kassab, Kang Jin Jeong, Wei Zhao, Yiling Lu, Abhinav K. Jain, Zhicheng Zhou, Han Liang, Shao-Cong Sun, Changming Lu, Zhi-Xiang Xu, Qinghua Yu, Shan Shao, XiaoHua Chen, Meng Gao, Francois X. Claret, Zhiyong Ding, Jian Chen, Pingsheng Chen, Michelle C. Barton, Guang Peng, Gordon B. Mills and Amy B. Heimberger
    Cancer Immunol Res July 1 2020 8 (7) 952-965; DOI:10.1158/2326-6066.CIR-19-0159

    Antibody blockade of PD-L1 is associated with toxicities, thus new targeting strategies are needed. Verteporfin suppresses PD-L1 expression via Golgi-related autophagy and disruption of STAT1–IRF1–TRIM28 signaling.

  • Research Articles
    Transfer of MicroRNA via Macrophage-Derived Extracellular Vesicles Promotes Proneural-to-Mesenchymal Transition in Glioma Stem Cells
    Zongpu Zhang, Jianye Xu, Zihang Chen, Huizhi Wang, Hao Xue, Chunlei Yang, Qindong Guo, Yanhua Qi, Xiaofan Guo, Mingyu Qian, Shaobo Wang, Wei Qiu, Xiao Gao, Rongrong Zhao, Xing Guo and Gang Li
    Cancer Immunol Res July 1 2020 8 (7) 966-981; DOI:10.1158/2326-6066.CIR-19-0759

    The progression of glioblastoma is marked by a proneural-to-mesenchymal transition (PMT) and is associated with radiation resistance. PMT is triggered by the release of microRNA-filled small extracellular vesicles from tumor-associated macrophages that target CHD7 in glioma stem cells.

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Cancer Immunology Research: 8 (7)
July 2020
Volume 8, Issue 7
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