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Investigational New Drugs
Published in: Investigational New Drugs 1/2020

Open Access 01-02-2020 | Glioma | PRECLINICAL STUDIES

Emodin induced necroptosis in the glioma cell line U251 via the TNF-α/RIP1/RIP3 pathway

Authors: Jiabin Zhou, Genhua Li, Guangkui Han, Song Feng, Yuhan Liu, Jun Chen, Chen Liu, Lei Zhao, Feng Jin

Published in: Investigational New Drugs | Issue 1/2020

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Summary

Emodin, an anthraquinone compound extracted from rhubarb and other traditional Chinese medicines, has been proven to have a wide range of pharmacological effects, such as anti-inflammatory, antiviral, and antitumor activities. Previous studies have confirmed that emodin has inhibitory effects on various solid tumors, such as osteosarcoma, liver cancer, prostate cancer and glioma. This study aimed to investigate the effects and mechanisms of emodin-induced necroptosis in the glioma cell line U251 by targeting the TNF-α/RIP1/RIP3 signaling pathway. We found that emodin could significantly inhibit U251 cell proliferation, and the viability of U251 cells treated with emodin was reduced in a dose- and time-dependent manner. Flow cytometry assays and Hoechst-PI staining assays showed that emodin induced apoptosis and necroptosis. Real-time PCR and western blot analysis showed that emodin upregulated the levels of TNF-α, RIP1, RIP3 and MLKL. Furthermore, the RIP1 inhibitor Nec-1 and the RIP3 inhibitor GSK872 attenuated the killing effect of emodin on U251 cells. In addition, emodin could increase the levels of TNF-α, RIP1, RIP3 and MLKL in vivo. The results demonstrate that emodin could induce necroptosis in glioma possibly through the activation of the TNF-α/RIP1/RIP3 axis. These studies provide novel insight into the induction of necroptosis by emodin and indicate that emodin might be a potential candidate for treating glioma through the necroptosis pathway.
Literature
1.
Behin A; Hoangxuan K, Carpentier AF, Delattre JY (2012) Primary brain tumours in adults. Lancet 379:1984–1996CrossRef
2.
Seystahl K, Wick W, Weller M (2016) Therapeutic options in recurrent glioblastoma—an update. Crit Rev Oncol Hematol 99:389–408CrossRef
3.
Auffinger B, Spencer D; Pytel P, Ahmed A, Lesniak M (2016) The role of glioma stem cells in chemotherapy resistance and glioblastoma multiforme recurrence. Expert Rev Neurother 15:741CrossRef
4.
Osswald M, Jung E, Sahm F, Solecki G, Venkataramani V, Blaes J, Weil S, Horstmann H, Wiestler B, Syed M (2015) Brain tumour cells interconnect to a functional and resistant network. Nature 528:93–98CrossRef
5.
Cai J, Niu X, Chen Y, Hu Q, Shi G, Wu H, Wang J, Yi J (2008) Emodin-induced generation of reactive oxygen species inhibits RhoA activation to sensitize gastric carcinoma cells to Anoikis. Neoplasia 10:41–51CrossRef
6.
Yu-Ting S, Huei-Ling C, Song-Kun S, Shih-Lan H (2005) Emodin induces apoptosis in human lung adenocarcinoma cells through a reactive oxygen species-dependent mitochondrial signaling pathway. Biochem Pharmacol 70:229–241CrossRef
7.
Iwanowycz S, Wang J, Hodge J, Wang Y, Yu F, Fan D (2016) Emodin inhibits breast Cancer growth by blocking the tumor-promoting feedforward loop between Cancer cells and macrophages. Mol Cancer Ther 15:1931–1942CrossRef
8.
Lee K, Lee M, Cha E, Sul J, Lee J, Kim J, Park J, Kim J (2017) Inhibitory effect of emodin on fatty acid synthase, colon cancer proliferation and apoptosis. Mol Med Rep 15:2163–2173CrossRef
9.
Shrimali D, Shanmugam M, Kumar A, Zhang J, Tan B, Ahn K, Sethi G (2013) Targeted abrogation of diverse signal transduction cascades by emodin for the treatment of inflammatory disorders and cancer. Cancer Lett 341:139–149CrossRef
10.
Xinfang Y, Qipan D, Bode A, Zigang D, Ya C (2013) The role of necroptosis, an alternative form of cell death, in cancer therapy. Expert Rev Anticancer Ther 13:883–893CrossRef
11.
Petrie EJ, Czabotar PE, Murphy JM (2019) The structural basis of Necroptotic cell death signaling. Trends Biochem Sci 44:53–63CrossRef
12.
Jin F, Gao C, Zhao L, Zhang H, Wang H, Shao T, Zhang S, Wei Y, Jiang X, Zhou P (2011) Using CD133 positive U251 glioblastoma stem cells to establish nude mice model of transplanted tumor. Brain Res 1368:82–90CrossRef
13.
Treuting P; Albertson T; Preston B (2010) Apoptosis: A Review of Programmed Cell Death
14.
Galluzzi L, Kepp O, Chan FK, Kroemer G (2017) Necroptosis: mechanisms and relevance to disease. Annual Review of Pathology: Mechanisms of Disease 12:103–130CrossRef
15.
Dixon SJ, Lemberg KM, Lamprecht MR, Skouta R, Zaitsev EM, Gleason CE, Patel DN, Bauer AJ, Cantley AM, Yang WS, Morrison B, Stockwell BR (2012) Ferroptosis: an iron-dependent form of nonapoptotic cell death. Cell 149:1060–1072CrossRef
16.
Shi J, Gao W, Feng S (2016) Pyroptosis: Gasdermin-mediated programmed necrotic cell death. Trends Biochem Sci 42:245CrossRef
17.
Su Z, Yang Z, Xie L, DeWitt J, Chen Y (2016) Cancer therapy in the necroptosis era. Cell Death Differ 23:748–756CrossRef
18.
Moriwaki K, Chan F (2016) Necroptosis-independent signaling by the RIP kinases in inflammation. Cell Mol Life Sci 73:2325–2334CrossRef
19.
Eisele G, Weller M (2013) Targeting apoptosis pathways in glioblastoma. Cancer Lett 332:335–345CrossRef
20.
Groot J, Gilbert M (2007) New molecular targets in malignant gliomas. Curr Opin Neurol 20:712–718CrossRef
21.
Mijatović S, Bramanti A, Nicoletti F, Fagone P, Kaluđerović G, Maksimović-Ivanić D (2018) Naturally occurring compounds in differentiation based therapy of cancer. Biotechnol Adv 35:1622–1632CrossRef
22.
Min L (2013) Targeting apoptosis pathways in cancer by Chinese medicine. Cancer Lett 332:304–312CrossRef
23.
Gu J, Cui CF, Yang L, Wang L, Jiang XH (2019) Emodin inhibits Colon Cancer cell invasion and migration by suppressing epithelial-mesenchymal transition via the Wnt/β-catenin pathway. Oncol Res 27:193–202CrossRef
24.
Tummers B, Green D (2017) Caspase-8: regulating life and death. Immonological Reviews 277:76–89CrossRef
25.
Dondelinger Y, Jouan-Lanhouet S, Divert T, Theatre E, Bertin J, Gough PJ, Giansanti P, Heck AJ, Dejardin E, Vandenabeele P, Bertrand MJ (2015) NF-κB-independent role of IKKα/IKKβ in preventing RIPK1 kinase-dependent apoptotic and Necroptotic cell death during TNF signaling. Mol Cell 60:63–67CrossRef
26.
Fulda S (2016) Regulation of necroptosis signaling and cell death by reactive oxygen species. Biol Chem 397:657–660CrossRef
27.
He S, Huang S, Shen Z (2016) Biomarkers for the detection of necroptosis. Cell Mol Life Sci 73:2177–2181CrossRef
28.
Christofferson D, Yuan J (2010) Necroptosis as an alternative form of programmed cell death. Current Opioion in Cell Biology 22:263–268CrossRef
29.
Jouan-Lanhouet S, Riquet F, Duprez L, Berghe T, Takahashi N, Vandenabeele P (2014) Necroptosis, in vivo detection in experimental disease models. Semin Cell Dev Biol 35:2–13CrossRef
30.
Thapa R, Shoko N; Peirong C, Maki J, Anthony L, Mark A; Rall G; Alexei D, Siddharth B (2013) Interferon-induced RIP1/RIP3-mediated necrosis requires PKR and is licensed by FADD and caspases. Proc Natl Acad Sci U S A 110:E3109–E3118CrossRef
31.
Shergalis A, Bankhead R; Luesakul U; Muangsin N, Neamati N (2019) Current challenges and opportunities in treating glioblastoma. Pharmacol Rev 70:412–445CrossRef
Metadata
Title
Emodin induced necroptosis in the glioma cell line U251 via the TNF-α/RIP1/RIP3 pathway
Authors
Jiabin Zhou
Genhua Li
Guangkui Han
Song Feng
Yuhan Liu
Jun Chen
Chen Liu
Lei Zhao
Feng Jin
Publication date
01-02-2020
Publisher
Springer US
Published in
Investigational New Drugs / Issue 1/2020
Print ISSN: 0167-6997
Electronic ISSN: 1573-0646
DOI
https://doi.org/10.1007/s10637-019-00764-w

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