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Literature DB >> 32265228

Verteporfin Inhibits PD-L1 through Autophagy and the STAT1-IRF1-TRIM28 Signaling Axis, Exerting Antitumor Efficacy.

Jiyong Liang¹, Lulu Wang², Chao Wang^3,4, Jianfeng Shen², Bojin Su³, Anantha L Marisetty⁵, Dexing Fang⁵, Cynthia Kassab⁵, Kang Jin Jeong³, Wei Zhao³, Yiling Lu³, Abhinav K Jain⁶, Zhicheng Zhou³, Han Liang⁷, Shao-Cong Sun⁸, Changming Lu⁹, Zhi-Xiang Xu¹⁰, Qinghua Yu³, Shan Shao³, XiaoHua Chen³, Meng Gao³, Francois X Claret³, Zhiyong Ding³, Jian Chen¹¹, Pingsheng Chen¹², Michelle C Barton⁶, Guang Peng², Gordon B Mills¹³, Amy B Heimberger¹⁴.

Abstract

Programmed cell death 1 ligand 1 (PD-L1) is a key driver of tumor-mediated immune suppression, and targeting it with antibodies can induce therapeutic responses. Given the costs and associated toxicity of PD-L1 blockade, alternative therapeutic strategies are needed. Using reverse-phase protein arrays to assess drugs in use or likely to enter trials, we performed a candidate drug screen for inhibitors of PD-L1 expression and identified verteporfin as a possible small-molecule inhibitor. Verteporfin suppressed basal and IFN-induced PD-L1 expression in vitro and in vivo through Golgi-related autophagy and disruption of the STAT1-IRF1-TRIM28 signaling cascade, but did not affect the proinflammatory CIITA-MHC II cascade. Within the tumor microenvironment, verteporfin inhibited PD-L1 expression, which associated with enhanced T-lymphocyte infiltration. Inhibition of chromatin-associated enzyme PARP1 induced PD-L1 expression in high endothelial venules (HEV) in tumors and, when combined with verteporfin, enhanced therapeutic efficacy. Thus, verteporfin effectively targets PD-L1 through transcriptional and posttranslational mechanisms, representing an alternative therapeutic strategy for targeting PD-L1. ©2020 American Association for Cancer Research.

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Year: 2020 PMID： 32265228 PMCID： PMC8204534 DOI： 10.1158/2326-6066.CIR-19-0159

Source DB: PubMed Journal: Cancer Immunol Res ISSN： 2326-6066 Impact factor: 11.151

48 in total

1. PD-L1 mediated the differentiation of tumor-infiltrating CD19⁺ B lymphocytes and T cells in Invasive breast cancer.

Authors: Honggeng Guan; Yang Lan; Yuqiu Wan; Qin Wang; Cheng Wang; Longjiang Xu; Yongjing Chen; Wenting Liu; Xueguang Zhang; Yecheng Li; Yongping Gu; Zemin Wang; Fang Xie
Journal: Oncoimmunology Date: 2015-08-12 Impact factor: 8.110

2. The BioPlex Network: A Systematic Exploration of the Human Interactome.

Authors: Edward L Huttlin; Lily Ting; Raphael J Bruckner; Fana Gebreab; Melanie P Gygi; John Szpyt; Stanley Tam; Gabriela Zarraga; Greg Colby; Kurt Baltier; Rui Dong; Virginia Guarani; Laura Pontano Vaites; Alban Ordureau; Ramin Rad; Brian K Erickson; Martin Wühr; Joel Chick; Bo Zhai; Deepak Kolippakkam; Julian Mintseris; Robert A Obar; Tim Harris; Spyros Artavanis-Tsakonas; Mathew E Sowa; Pietro De Camilli; Joao A Paulo; J Wade Harper; Steven P Gygi
Journal: Cell Date: 2015-07-16 Impact factor: 41.582

3. Atezolizumab versus docetaxel in patients with previously treated non-small-cell lung cancer (OAK): a phase 3, open-label, multicentre randomised controlled trial.

Authors: Achim Rittmeyer; Fabrice Barlesi; Daniel Waterkamp; Keunchil Park; Fortunato Ciardiello; Joachim von Pawel; Shirish M Gadgeel; Toyoaki Hida; Dariusz M Kowalski; Manuel Cobo Dols; Diego L Cortinovis; Joseph Leach; Jonathan Polikoff; Carlos Barrios; Fairooz Kabbinavar; Osvaldo Arén Frontera; Filippo De Marinis; Hande Turna; Jong-Seok Lee; Marcus Ballinger; Marcin Kowanetz; Pei He; Daniel S Chen; Alan Sandler; David R Gandara
Journal: Lancet Date: 2016-12-13 Impact factor: 79.321

4. Structurally similar but functionally distinct factors, IRF-1 and IRF-2, bind to the same regulatory elements of IFN and IFN-inducible genes.

Authors: H Harada; T Fujita; M Miyamoto; Y Kimura; M Maruyama; A Furia; T Miyata; T Taniguchi
Journal: Cell Date: 1989-08-25 Impact factor: 41.582

5. CTLA-4 Blockade Synergizes Therapeutically with PARP Inhibition in BRCA1-Deficient Ovarian Cancer.

Authors: Tomoe Higuchi; Dallas B Flies; Nicole A Marjon; Gina Mantia-Smaldone; Lukas Ronner; Phyllis A Gimotty; Sarah F Adams
Journal: Cancer Immunol Res Date: 2015-07-02 Impact factor: 11.151

6. Chromatin to Clinic: The Molecular Rationale for PARP1 Inhibitor Function.

Authors: Felix Y Feng; Johann S de Bono; Mark A Rubin; Karen E Knudsen
Journal: Mol Cell Date: 2015-06-18 Impact factor: 17.970

7. Noncleavable poly(ADP-ribose) polymerase-1 regulates the inflammation response in mice.

Authors: Virginie Pétrilli; Zdenko Herceg; Paul O Hassa; Nimesh S A Patel; Rosanna Di Paola; Ulrich Cortes; Laura Dugo; Helder-Mota Filipe; Christoph Thiemermann; Michael O Hottiger; Salvatore Cuzzocrea; Zhao-Qi Wang
Journal: J Clin Invest Date: 2004-10 Impact factor: 14.808

8. Targeted disruption of IRF-1 or IRF-2 results in abnormal type I IFN gene induction and aberrant lymphocyte development.

Authors: T Matsuyama; T Kimura; M Kitagawa; K Pfeffer; T Kawakami; N Watanabe; T M Kündig; R Amakawa; K Kishihara; A Wakeham
Journal: Cell Date: 1993-10-08 Impact factor: 41.582

9. Presence of high-endothelial venules correlates with a favorable immune microenvironment in oral squamous cell carcinoma.

Authors: Anna Maria Wirsing; Ida Korsnes Ervik; Marit Seppola; Lars Uhlin-Hansen; Sonja Eriksson Steigen; Elin Hadler-Olsen
Journal: Mod Pathol Date: 2018-02-07 Impact factor: 7.842

10. Glycosylation and stabilization of programmed death ligand-1 suppresses T-cell activity.

Authors: Chia-Wei Li; Seung-Oe Lim; Weiya Xia; Heng-Huan Lee; Li-Chuan Chan; Chu-Wei Kuo; Kay-Hooi Khoo; Shih-Shin Chang; Jong-Ho Cha; Taewan Kim; Jennifer L Hsu; Yun Wu; Jung-Mao Hsu; Hirohito Yamaguchi; Qingqing Ding; Yan Wang; Jun Yao; Cheng-Chung Lee; Hsing-Ju Wu; Aysegul A Sahin; James P Allison; Dihua Yu; Gabriel N Hortobagyi; Mien-Chie Hung
Journal: Nat Commun Date: 2016-08-30 Impact factor: 14.919

23 in total

Review 1. Programmed death ligand 1 signals in cancer cells.

Authors: Anand V R Kornepati; Ratna K Vadlamudi; Tyler J Curiel
Journal: Nat Rev Cancer Date: 2022-01-14 Impact factor: 60.716

Review 2. Mechanisms regulating PD-L1 expression in cancers and associated opportunities for novel small-molecule therapeutics.

Authors: Hirohito Yamaguchi; Jung-Mao Hsu; Wen-Hao Yang; Mien-Chie Hung
Journal: Nat Rev Clin Oncol Date: 2022-02-07 Impact factor: 66.675

3. FOXO3-dependent suppression of PD-L1 promotes anticancer immune responses via activation of natural killer cells.

Authors: Young Min Chung; Wen Bin Tsai; Pragya P Khan; Jessica Ma; Jonathan S Berek; James W Larrick; Mickey C-T Hu
Journal: Am J Cancer Res Date: 2022-03-15 Impact factor: 6.166

4. Upregulation of PD-L1 in Senescence and Aging.

Authors: Angelique Onorati; Aaron P Havas; Brian Lin; Jayaraj Rajagopal; Payel Sen; Peter D Adams; Zhixun Dou
Journal: Mol Cell Biol Date: 2022-09-26 Impact factor: 5.069

5. YAP Inhibition by Verteporfin Causes Downregulation of Desmosomal Genes and Proteins Leading to the Disintegration of Intercellular Junctions.

Authors: Yunying Huang; Usama Sharif Ahmad; Ambreen Rehman; Jutamas Uttagomol; Hong Wan
Journal: Life (Basel) Date: 2022-05-26

6. Interferon regulatory factor 1(IRF-1) activates anti-tumor immunity via CXCL10/CXCR3 axis in hepatocellular carcinoma (HCC).

Authors: Yihe Yan; Leting Zheng; Qiang Du; Hamza Yazdani; Kun Dong; Yarong Guo; David A Geller
Journal: Cancer Lett Date: 2021-03-06 Impact factor: 9.756

Review 10. Spatial and Temporal Changes in PD-L1 Expression in Cancer: The Role of Genetic Drivers, Tumor Microenvironment and Resistance to Therapy.

Authors: Elena Shklovskaya; Helen Rizos
Journal: Int J Mol Sci Date: 2020-09-27 Impact factor: 5.923