Citations to this article
Citation Information: JCI Insight. 2017;2(12):e93411. https://doi.org/10.1172/jci.insight.93411.
Abstract
Cancer cells can inhibit effector T cells (Teff) through both immunomodulatory receptors and the impact of cancer metabolism on the tumor microenvironment. Indeed, Teff require high rates of glucose metabolism, and consumption of essential nutrients or generation of waste products by tumor cells may impede essential T cell metabolic pathways. Clear cell renal cell carcinoma (ccRCC) is characterized by loss of the tumor suppressor von Hippel-Lindau (VHL) and altered cancer cell metabolism. Here, we assessed how ccRCC influences the metabolism and activation of primary patient ccRCC tumor infiltrating lymphocytes (TIL). CD8 TIL were abundant in ccRCC, but they were phenotypically distinct and both functionally and metabolically impaired. ccRCC CD8 TIL were unable to efficiently uptake glucose or perform glycolysis and had small, fragmented mitochondria that were hyperpolarized and generated large amounts of ROS. Elevated ROS was associated with downregulated mitochondrial SOD2. CD8 T cells with hyperpolarized mitochondria were also visible in the blood of ccRCC patients. Importantly, provision of pyruvate to bypass glycolytic defects or scavengers to neutralize mitochondrial ROS could partially restore TIL activation. Thus, strategies to improve metabolic function of ccRCC CD8 TIL may promote the immune response to ccRCC.
Authors
Peter J. Siska, Kathryn E. Beckermann, Frank M. Mason, Gabriela Andrejeva, Allison R. Greenplate, Adam B. Sendor, Yun-Chen J. Chiang, Armando L. Corona, Lelisa F. Gemta, Benjamin G. Vincent, Richard C. Wang, Bumki Kim, Jiyong Hong, Chiu-lan Chen, Timothy N. Bullock, Jonathan M. Irish, W. Kimryn Rathmell, Jeffrey C. Rathmell
Total citations by year
Citations to this article in year 2025 (9)
| Title and authors | Publication | Year |
|---|---|---|
|
Tumor metabolic regulators: key drivers of metabolic reprogramming and the promising targets in cancer therapy
Huang K, Han Y, Chen Y, Shen H, Zeng S, Cai C |
Molecular Cancer | 2025 |
|
Metabolic Signaling in the Tumor Microenvironment
Clay R, Li K, Jin L |
Cancers | 2025 |
|
Integrated RNA sequencing analysis and machine learning identifies a metabolism-related prognostic signature in clear cell renal cell carcinoma
Liu Y, Yan Z, Liu C, Yang R, Zheng Q, Jian J, Wang M, Wang L, Weng X, Chen Z, Liu X |
Scientific Reports | 2025 |
|
Glut3 overexpression improves environmental glucose uptake and antitumor efficacy of CAR-T cells in solid tumors
Hu W, Li F, Liang Y, Liu S, Wang S, Shen C, Zhao Y, Wang H, Zhang Y |
Journal for Immunotherapy of Cancer | 2025 |
|
La dolce vita: fueling chimeric antigen receptor (CAR) T cells with Glut1 to improve therapeutic efficacy
Slattery K, Finlay DK, Darcy PK |
Immunometabolism (Cobham, Surrey) | 2025 |
|
Immune evasion through mitochondrial transfer in the tumour microenvironment
Ikeda H, Kawase K, Nishi T, Watanabe T, Takenaga K, Inozume T, Ishino T, Aki S, Lin J, Kawashima S, Nagasaki J, Ueda Y, Suzuki S, Makinoshima H, Itami M, Nakamura Y, Tatsumi Y, Suenaga Y, Morinaga T, Honobe-Tabuchi A, Ohnuma T, Kawamura T, Umeda Y, Nakamura Y, Kiniwa Y, Ichihara E, Hayashi H, Ikeda JI, Hanazawa T, Toyooka S, Mano H, Suzuki T, Osawa T, Kawazu M, Togashi Y |
Nature | 2025 |
|
Progressive natural killer cell dysfunction in advanced-stage clear-cell renal cell carcinoma and association with clinical outcomes
Xu W, Birch G, Meliki A, Moritz V, Bharadwaj M, Schindler NR, Labaki C, Saliby RM, Dinh K, Horst JT, Sun M, Kashima S, Hugaboom M, Dighe A, Machaalani M, Lee GS, Hurwitz M, McGregor BA, Hirsch MS, Shukla SA, McDermott DF, Signoretti S, Romee R, Choueiri TK, Braun DA |
ESMO Open | 2025 |
|
Lipid Metabolism in Breast Cancer: From Basic Research to Clinical Application
Huang X, Liu B, Shen S |
Cancers | 2025 |
|
Regulatory T Cell Metabolism: A Promising Therapeutic Target for Cancer Treatment?
Kim J, Li J, Wei J, Lim SA |
Immune Network | 2025 |
