Epigenetic strategies to boost CAR T cell therapy

被引:43
作者
Akbari, Behnia [1 ]
Ghahri-Saremi, Navid [1 ]
Soltantoyeh, Tahereh [1 ]
Hadjati, Jamshid [1 ]
Ghassemi, Saba [2 ]
Mirzaei, Hamid Reza [1 ]
机构
[1] Univ Tehran Med Sci, Sch Med, Dept Med Immunol, Tehran 1417613151, Iran
[2] Univ Penn, Ctr Cellular Immunotherapies, Perelman Sch Med, Philadelphia, PA 19104 USA
来源
MOLECULAR THERAPY | 2021年 / 29卷 / 09期
关键词
CHIMERIC ANTIGEN RECEPTOR; HISTONE DEACETYLASE INHIBITORS; NOVO DNA METHYLATION; GENE-EXPRESSION; INTRACHROMOSOMAL INTERACTIONS; DIFFERENTIAL EXPRESSION; REGULATES EFFECTOR; VIRUS-INFECTION; UP-REGULATION; CANCER CELLS;
D O I
10.1016/j.ymthe.2021.08.003
中图分类号
Q81 [生物工程学(生物技术)]; Q93 [微生物学];
学科分类号
071005 ; 0836 ; 090102 ; 100705 ;
摘要
Chimeric antigen receptor (CAR) T cell therapy has led to a paradigm shift in cancer immunotherapy, but still several obstacles limit CAR T cell efficacy in cancers. Advances in high throughput technologies revealed new insights into the role that epigenetic reprogramming plays in T cells. Mechanistic studies as well as comprehensive epigenome maps revealed an important role for epigenetic remodeling in T cell differentiation. These modifications shape the overall immune response through alterations in T cell phenotype and function. Here, we outline how epigenetic modifications in CAR T cells can overcome barriers limiting CAR T cell effectiveness, particularly in immunosuppressive tumor microenvironments. We also offer our perspective on how selected epigenetic modifications can boost CAR T cells to ultimately improve the efficacy of CAR T cell therapy.
引用
收藏
页码:2640 / 2659
页数:20
相关论文
共 224 条
[1]   Human memory CD8 T cell effector potential is epigenetically preserved during in vivo homeostasis [J].
Abdelsamed, Hossam A. ;
Moustaki, Ardiana ;
Fan, Yiping ;
Dogra, Pranay ;
Ghoneim, Hazem E. ;
Zebley, Caitlin C. ;
Triplett, Brandon M. ;
Sekaly, Rafick-Pierre ;
Youngblood, Ben .
JOURNAL OF EXPERIMENTAL MEDICINE, 2017, 214 (06) :1593-1606
[2]   Differentiation of Pathogenic Th17 Cells Is Negatively Regulated by Let-7 MicroRNAs in a Mouse Model of Multiple Sclerosis [J].
Angelou, Constance C. ;
Wells, Alexandria C. ;
Vijayaraghavan, Jyothi ;
Dougan, Carey E. ;
Lawlor, Rebecca ;
Iverson, Elizabeth ;
Lazarevic, Vanja ;
Kimura, Motoko Y. ;
Peyton, Shelly R. ;
Minter, Lisa M. ;
Osborne, Barbara A. ;
Pobezinskaya, Elena L. ;
Pobezinsky, Leonid A. .
FRONTIERS IN IMMUNOLOGY, 2020, 10
[3]   Histone acetylation facilitates rapid and robust memory CD8 T cell response through differential expression of effector molecules (eomesodermin and its targets: perforin and granzyme B) [J].
Araki, Yasuto ;
Fann, Monchou ;
Wersto, Robert ;
Weng, Nan-ping .
JOURNAL OF IMMUNOLOGY, 2008, 180 (12) :8102-8108
[4]   Next-Generation Manufacturing Protocols Enriching TSCMCAR T Cells Can Overcome Disease-Specific T Cell Defects in Cancer Patients [J].
Arcangeli, Silvia ;
Falcone, Laura ;
Camisa, Barbara ;
De Girardi, Federica ;
Biondi, Marta ;
Giglio, Fabio ;
Ciceri, Fabio ;
Bonini, Chiara ;
Bondanza, Attilio ;
Casucci, Monica .
FRONTIERS IN IMMUNOLOGY, 2020, 11
[5]   Enhancement of the in vivo persistence and antitumor efficacy of CD19 chimeric antigen receptor T cells through the delivery of modified TERT mRNA [J].
Bai, Yun ;
Kan, Shifeng ;
Zhou, Shixin ;
Wang, Yuting ;
Xu, Jun ;
Cooke, John P. ;
Wen, Jinhua ;
Deng, Hongkui .
CELL DISCOVERY, 2015, 1
[6]   Targeted and genome-scale strategies reveal gene-body methylation signatures in human cells [J].
Ball, Madeleine P. ;
Li, Jin Billy ;
Gao, Yuan ;
Lee, Je-Hyuk ;
LeProust, Emily M. ;
Park, In-Hyun ;
Xie, Bin ;
Daley, George Q. ;
Church, George M. .
NATURE BIOTECHNOLOGY, 2009, 27 (04) :361-368
[7]   Revving the CAR-Combination strategies to enhance CAR T cell effectiveness [J].
Bansal, Rajat ;
Reshef, Ran .
BLOOD REVIEWS, 2021, 45
[8]   Developmental Relationships of Four Exhausted CD8+ T Cell Subsets Reveals Underlying Transcriptional and Epigenetic Landscape Control Mechanisms [J].
Beltra, Jean-Christophe ;
Manne, Sasikanth ;
Abdel-Hakeem, Mohamed S. ;
Kurachi, Makoto ;
Giles, Josephine R. ;
Chen, Zeyu ;
Casella, Valentina ;
Ngiow, Shin Foong ;
Khan, Omar ;
Huang, Yinghui Jane ;
Yan, Patrick ;
Nzingha, Kito ;
Xu, Wei ;
Amaravadi, Ravi K. ;
Xu, Xiaowei ;
Karakousis, Giorgos C. ;
Mitchell, Tara C. ;
Schuchter, Lynn M. ;
Huang, Alexander C. ;
Wherry, E. John .
IMMUNITY, 2020, 52 (05) :825-+
[9]   A mammalian microRNA cluster controls DNA methylation and telomere recombination via Rbl2-dependent regulation of DNA methyltransferases [J].
Benetti, Roberta ;
Gonzalo, Susana ;
Jaco, Isabel ;
Munoz, Purificacion ;
Gonzalez, Susana ;
Schoeftner, Stefan ;
Murchison, Elizabeth ;
Andl, Thomas ;
Chen, Taiping ;
Klatt, Peter ;
Li, En ;
Serrano, Manuel ;
Millar, Sarah ;
Hannon, Gregory ;
Blasco, Maria A. .
NATURE STRUCTURAL & MOLECULAR BIOLOGY, 2008, 15 (03) :268-279
[10]   Lactate-mediated epigenetic reprogramming regulates formation of human pancreatic cancer-associated fibroblasts [J].
Bhagat, Tushar D. ;
Von Ahrens, Dagny ;
Dawlaty, Meelad ;
Zou, Yiyu ;
Baddour, Joelle ;
Achreja, Abhinav ;
Zhao, Hongyun ;
Yang, Lifeng ;
Patel, Brijesh ;
Kwak, Changsoo ;
Choudhary, Gaurav S. ;
Gordon-Mitchell, Shanisha ;
Aluri, Srinivas ;
Bhattacharyya, Sanchari ;
Sahu, Srabani ;
Bhagat, Prafulla ;
Yu, Yiting ;
Bartenstein, Matthias ;
Giricz, Orsi ;
Suzuki, Masako ;
Sohal, Davendra ;
Gupta, Sonal ;
Guerrero, Paola A. ;
Batra, Surinder ;
Goggins, Michael ;
Steidl, Ulrich ;
Greally, John ;
Agarwal, Beamon ;
Pradhan, Kith ;
Banerjee, Debabrata ;
Nagrath, Deepak ;
Maitra, Anirban ;
Verma, Amit .
ELIFE, 2019, 8
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