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22-09-2022 | Cytostatic Therapy | Original Article

Inhibition of PP2A by LB100 sensitizes bladder cancer cells to chemotherapy by inducing p21 degradation

Authors: Song Gao, Liping Shan, Mo Zhang, Yan Wang, Xi Zhan, Yalei Yin, Zhonghao Jiang, Xinyi Tao, Xinyu Li, Mingliang Ye, Yang Liu

Published in: Cellular Oncology | Issue 6/2022

Abstract

Purpose

Bladder carcinoma (BLCA) is the most common urinary tract malignancy and exhibits a poor response to chemotherapy. Protein phosphatase 2A (PP2A) is a serine/threonine phosphatase involved in a wide variety of regulatory cellular processes, including apoptosis and the DNA-damage response (DDR). LB100, a small molecule inhibitor of PP2A, has been shown to act as a chemo-sensitizer in multiple types of cancer. However, the anti-tumor effect and mode of action of LB100 in BLCA have yet to be identified.

Methods

In vitro and in vivo experiments were performed to assess the anti-tumor effect of LB100 alone or in combination with gemcitabine. Mass spectrometry (MS)-based phosphoproteomics analysis was used to identify the downstream substrates of PP2A and to explore the mechanism underlying LB100-induced DNA damage and apoptosis. In addition, we established a chemo-resistant BLCA cell line (RT-112-R) by prolonged drug exposure and determined the effect of LB100 in enhancing genotoxicity in BLCA cell lines and xenograft mouse models.

Results

We found that LB100 is sufficient to induce an anti-tumor response in BLCA cells by inducing DNA damage and apoptosis both in vitro and in vivo. Furthermore, we found that PP2A potentially dephosphorylates p-p21-ser130 to stabilize p21. Inhibition of PP2A by LB100 increased the level of p-p21-ser130, subsequently leading to a reduction in p21 level in a dose-dependent manner. In addition, we found that treatment of LB100 abrogated the G1/S cell cycle checkpoint, resulting in increased phosphorylation of γH2AX in BLCA cells. Moreover, LB100 enhanced genotoxicity in chemo-resistant BLCA cells by inducing DNA damage and apoptosis in vitro and in vivo.

Conclusion

Our findings indicate that PP2A may serve as a potential therapeutic target in BLCA through regulating p21 stability.

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S. Antoni, J. Ferlay, I. Soerjomataram, A. Znaor, A. Jemal, F. Bray, Bladder Cancer incidence and mortality: A global overview and recent trends. Eur. Urol. 71(1), 96–108 (2017)CrossRef

A.T. Lenis, P.M. Lec, K. Chamie, M.D. Mshs, Bladder Cancer: A review. Jama 324(19), 1980–1991 (2020)CrossRef

R.D. Dubey, A. Saneja, P.K. Gupta, P.N. Gupta, Recent advances in drug delivery strategies for improved therapeutic efficacy of gemcitabine. Eur. J. Pharm. Sci. 93, 147–162 (2016)CrossRef

A.M. Kamat, N.M. Hahn, J.A. Efstathiou, S.P. Lerner, P.U. Malmström, W. Choi, C.C. Guo, Y. Lotan, W. Kassouf, Bladder cancer. Lancet 388(10061), 2796–2810 (2016)CrossRef

D.M. Jiang, S. Gupta, A. Kitchlu, A. Meraz-Munoz, S.A. North, N.S. Alimohamed, N. Blais, S.S. Sridhar, Defining cisplatin eligibility in patients with muscle-invasive bladder cancer. Nat. Rev. Urol. 18(2), 104–114 (2021)CrossRef

A. Volpe, M. Racioppi, D. D'Agostino, E. Cappa, A. Filianoti, P.F. Bassi, Mitomycin C for the treatment of bladder cancer. Minerva Urol. Nefrol. 62(2), 133–144 (2010)

C. Alifrangis, U. McGovern, A. Freeman, T. Powles, M. Linch, Molecular and histopathology directed therapy for advanced bladder cancer. Nat. Rev. Urol. 16(8), 465–483 (2019)CrossRef

J.J. Coen, P. Zhang, P.J. Saylor, C.T. Lee, C.L. Wu, W. Parker, T. Lautenschlaeger, A.L. Zietman, J.A. Efstathiou, A.B. Jani, et al., Bladder preservation with twice-a-day radiation plus fluorouracil/cisplatin or once daily radiation plus gemcitabine for muscle-invasive bladder Cancer: NRG/RTOG 0712-a randomized phase II trial. J. Clin. Oncol. 37(1), 44–51 (2019)CrossRef

E.M. Messing, C.M. Tangen, S.P. Lerner, D.M. Sahasrabudhe, T.M. Koppie, D.P. Wood Jr., P.C. Mack, R.S. Svatek, C.P. Evans, K.S. Hafez, et al., Effect of Intravesical instillation of gemcitabine vs saline immediately following resection of suspected low-grade non-muscle-invasive bladder Cancer on tumor recurrence: SWOG S0337 randomized clinical trial. Jama 319(18), 1880–1888 (2018)CrossRef

10.

C.N. Sternberg, J. Bellmunt, G. Sonpavde, A.O. Siefker-Radtke, W.M. Stadler, D.F. Bajorin, R. Dreicer, D.J. George, M.I. Milowsky, D. Theodorescu, et al., ICUD-EAU international consultation on bladder Cancer 2012: Chemotherapy for urothelial carcinoma-neoadjuvant and adjuvant settings. Eur. Urol. 63(1), 58–66 (2013)CrossRef

11.

P. Pattarawat, T. Hong, S. Wallace, Y. Hu, R. Donnell, T.H. Wang, C.L. Tsai, J. Wang, H.R. Wang, Compensatory combination of romidepsin with gemcitabine and cisplatin to effectively and safely control urothelial carcinoma. Br. J. Cancer 123(2), 226–239 (2020)CrossRef

12.

G.J. DeCastro, W. Sui, J.S. Pak, S.M. Lee, D. Holder, M.M. Kates, R.K. Virk, C.G. Drake, C.B. Anderson, B. James, et al., A phase I trial of Intravesical Cabazitaxel, gemcitabine and cisplatin for the treatment of nonmuscle invasive bacillus Calmette-Guérin unresponsive or recurrent/relapsing urothelial carcinoma of the bladder. J. Urol. 204(2), 247–253 (2020)CrossRef

13.

K.S. Hanna, Updates and novel treatments in urothelial carcinoma. J. Oncol. Pharm. Pract. 25(3), 648–656 (2019)CrossRef

14.

D. Perrotti, P. Neviani, Protein phosphatase 2A: A target for anticancer therapy. Lancet Oncol. 14(6), e229–e238 (2013)CrossRef

15.

A.R. Clark, M. Ohlmeyer, Protein phosphatase 2A as a therapeutic target in inflammation and neurodegeneration. Pharmacol. Ther. 201, 181–201 (2019)CrossRef

16.

K.L. Huang, D. Jee, C.B. Stein, N.D. Elrod, T. Henriques, L.G. Mascibroda, D. Baillat, W.K. Russell, K. Adelman, E.J. Wagner, Integrator recruits protein phosphatase 2A to prevent pause release and facilitate transcription termination. Mol. Cell 80(2), 345–358.e349 (2020)CrossRef

17.

R. Baskaran, B.K. Velmurugan, Protein phosphatase 2A as therapeutic targets in various disease models. Life Sci. 210, 40–46 (2018)CrossRef

18.

Y. Tang, G. Fang, F. Guo, H. Zhang, X. Chen, L. An, M. Chen, L. Zhou, W. Wang, T. Ye, et al., Selective inhibition of STRN3-containing PP2A phosphatase restores hippo tumor-suppressor activity in gastric Cancer. Cancer Cell 38(1), 115–128.e119 (2020)CrossRef

19.

S. Mazhar, S.E. Taylor, J. Sangodkar, G. Narla, Targeting PP2A in cancer: Combination therapies. Biochim. Biophys. Acta, Mol. Cell Res. 1866(1), 51–63 (2019)CrossRef

20.

S. Hao, H. Song, W. Zhang, A. Seldomridge, J. Jung, A.J. Giles, M.K. Hutchinson, X. Cao, N. Colwell, A. Lita, et al., Protein phosphatase 2A inhibition enhances radiation sensitivity and reduces tumor growth in chordoma. Neuro-Oncology 20(6), 799–809 (2018)CrossRef

21.

E. Ferrari, C. Bruhn, M. Peretti, C. Cassani, W.V. Carotenuto, M. Elgendy, G. Shubassi, C. Lucca, R. Bermejo, M. Varasi, et al., PP2A controls genome integrity by integrating nutrient-sensing and metabolic pathways with the DNA damage response. Mol. Cell 67(2), 266–281.e264 (2017)CrossRef

22.

M.H. Uddin, J.M. Pimentel, M. Chatterjee, J.E. Allen, Z. Zhuang, G.S. Wu, Targeting PP2A inhibits the growth of triple-negative breast cancer cells. Cell Cycle 19(5), 592–600 (2020)CrossRef

23.

V. Chung, A.S. Mansfield, F. Braiteh, D. Richards, H. Durivage, R.S. Ungerleider, F. Johnson, J.S. Kovach, Safety, tolerability, and preliminary activity of LB-100, an inhibitor of protein phosphatase 2A, in patients with relapsed solid tumors: An open-label, dose escalation, first-in-human, Phase I Trial. Clin. Cancer Res. 23(13), 3277–3284 (2017)CrossRef

24.

L. Zhao, Z. Liu, X. Deng, J. Wang, L. Sun, L. Fan, Y. Zhang, Polyphyllin VII induces mitochondrial apoptosis by regulating the PP2A/AKT/DRP1 signaling axis in human ovarian cancer. Oncol. Rep. 45(2), 513–522 (2021)CrossRef

25.

S.J. Humphrey, S.B. Azimifar, M. Mann, High-throughput phosphoproteomics reveals in vivo insulin signaling dynamics. Nat. Biotechnol. 33(9), 990–995 (2015)CrossRef

26.

H. Zhou, M. Ye, J. Dong, E. Corradini, A. Cristobal, A.J. Heck, H. Zou, S. Mohammed, Robust phosphoproteome enrichment using monodisperse microsphere-based immobilized titanium (IV) ion affinity chromatography. Nat. Protoc. 8(3), 461–480 (2013)CrossRef

27.

M. Gerić, G. Gajski, V. Garaj-Vrhovac, γ-H2AX as a biomarker for DNA double-strand breaks in ecotoxicology. Ecotoxicol. Environ. Saf. 105, 13–21 (2014)CrossRef

28.

G.Y. Kim, S.E. Mercer, D.Z. Ewton, Z. Yan, K. Jin, E. Friedman, The stress-activated protein kinases p38 alpha and JNK1 stabilize p21(Cip1) by phosphorylation. J. Biol. Chem. 277(33), 29792–29802 (2002)CrossRef

29.

H. Jiang, B. Wang, F. Zhang, Y. Qian, C.C. Chuang, M. Ying, Y. Wang, L. Zuo, The expression and clinical outcome of pCHK2-Thr68 and pCDC25C-Ser216 in breast Cancer. Int. J. Mol. Sci. 17(11) (2016)

30.

Y. Yi, N. Park, J. Park, Y. Seong, Y. Hong, Doxycycline potentiates the anti-proliferation effects of gemcitabine in pancreatic cancer cells. Am. J. Cancer Res. 11(7), 3515–3536 (2021)

31.

A.G. Georgakilas, O.A. Martin, W.M. Bonner, p21: A two-faced genome Guardian. Trends Mol. Med. 23(4), 310–319 (2017)CrossRef

32.

Y. Makinwa, B.M. Cartwright, P.R. Musich, Z. Li, H. Biswas, Y. Zou, PP2A regulates phosphorylation-dependent isomerization of cytoplasmic and mitochondrial-associated ATR by Pin1 in DNA damage responses. Front. Cell. Dev. Biol. 8, 813 (2020)CrossRef

33.

M.A. Pagano, E. Tibaldi, P. Molino, F. Frezzato, V. Trimarco, M. Facco, G. Zagotto, G. Ribaudo, L. Leanza, R. Peruzzo, et al., Mitochondrial apoptosis is induced by Alkoxy phenyl-1-propanone derivatives through PP2A-mediated dephosphorylation of bad and Foxo3A in CLL. Leukemia 33(5), 1148–1160 (2019)CrossRef

34.

Y. Xiong, L. Ju, L. Yuan, L. Chen, G. Wang, H. Xu, T. Peng, Y. Luo, Y. Xiao, X. Wang, KNSTRN promotes tumorigenesis and gemcitabine resistance by activating AKT in bladder cancer. Oncogene 40(9), 1595–1608 (2021)CrossRef

35.

B. Li, D. Xie, H. Zhang, Long non-coding RNA GHET1 contributes to chemotherapeutic resistance to gemcitabine in bladder cancer. Cancer Chemother. Pharmacol. 84(1), 187–194 (2019)CrossRef

36.

A. Kikuchi, T. Suzuki, T. Nakazawa, M. Iizuka, A. Nakayama, T. Ozawa, M. Kameda, N. Shindoh, T. Terasaka, M. Hirano, et al., ASP5878, a selective FGFR inhibitor, to treat FGFR3-dependent urothelial cancer with or without chemoresistance. Cancer Sci. 108(2), 236–242 (2017)CrossRef

37.

Y. Liu, D.J. Kwiatkowski, Combined CDKN1A/TP53 mutation in bladder cancer is a therapeutic target. Mol. Cancer Ther. 14(1), 174–182 (2015)CrossRef

38.

N. Wlodarchak, Y. Xing, PP2A as a master regulator of the cell cycle. Crit. Rev. Biochem. Mol. Biol. 51(3), 162–184 (2016)CrossRef

39.

T. Mirzapoiazova, G. Xiao, B. Mambetsariev, M.W. Nasser, E. Miaou, S.S. Singhal, S. Srivastava, I. Mambetsariev, M.S. Nelson, A. Nam, et al., Protein phosphatase 2A as a therapeutic target in small cell lung Cancer. Mol. Cancer Ther. 20(10), 1820–1835 (2021)CrossRef

40.

C. Zhang, C.S. Hong, X. Hu, C. Yang, H. Wang, D. Zhu, S. Moon, P. Dmitriev, J. Lu, J. Chiang, et al., Inhibition of protein phosphatase 2A with the small molecule LB100 overcomes cell cycle arrest in osteosarcoma after cisplatin treatment. Cell Cycle 14(13), 2100–2108 (2015)CrossRef

41.

J.N.L. da Silva, A.D. Ranzi, C.T. Carvalho, T.V. Scheide, Y.T.M. Strey, T.M. Graziottin, C.G. Bica, Cell cycle markers in the evaluation of bladder Cancer. Pathol. Oncol. Res. 26(1), 175–181 (2020)CrossRef

42.

T. Koie, C. Ohyama, H. Yamamoto, A. Imai, S. Hatakeyama, T. Yoneyama, Y. Hashimoto, T. Yoneyama, Y. Tobisawa, Differences in the recurrence pattern after neoadjuvant chemotherapy compared to surgery alone in patients with muscle-invasive bladder cancer. Med. Oncol. 32(1), 421 (2015)CrossRef

43.

A. Abugomaa, M. Elbadawy, H. Yamawaki, T. Usui, K. Sasaki, Emerging roles of Cancer stem cells in bladder Cancer progression, tumorigenesis, and resistance to chemotherapy: A potential therapeutic target for bladder Cancer. Cells 9(1) (2020)

44.

F. Aljabery, I. Shabo, O. Gimm, S. Jahnson, H. Olsson, The expression profile of p14, p53 and p21 in tumour cells is associated with disease-specific survival and the outcome of postoperative chemotherapy treatment in muscle-invasive bladder cancer. Urol. Oncol. 36(12), 530.e537–530.e518 (2018)CrossRef

45.

A.M. Santos, H. Sousa, C. Portela, D. Pereira, D. Pinto, R. Catarino, C. Rodrigues, A.P. Araújo, C. Lopes, R. Medeiros, TP53 and P21 polymorphisms: Response to cisplatinum/paclitaxel-based chemotherapy in ovarian cancer. Biochem. Biophys. Res. Commun. 340(1), 256–262 (2006)CrossRef

46.

J. Sjöström, C. Blomqvist, P. Heikkilä, K.V. Boguslawski, A. Räisänen-Sokolowski, N.O. Bengtsson, I. Mjaaland, P. Malmström, B. Ostenstadt, J. Bergh, et al., Predictive value of p53, mdm-2, p21, and mib-1 for chemotherapy response in advanced breast cancer. Clin. Cancer Res. 6(8), 3103–3110 (2000)

47.

C.C. Liu, S.P. Lin, H.S. Hsu, S.H. Yang, C.H. Lin, M.H. Yang, M.C. Hung, S.C. Hung, Suspension survival mediated by PP2A-STAT3-col XVII determines tumour initiation and metastasis in cancer stem cells. Nat. Commun. 7, 11798 (2016)CrossRef

48.

R. Liu, L. Wang, G. Chen, H. Katoh, C. Chen, Y. Liu, P. Zheng, FOXP3 up-regulates p21 expression by site-specific inhibition of histone deacetylase 2/histone deacetylase 4 association to the locus. Cancer Res. 69(6), 2252–2259 (2009)CrossRef

49.

S.M. Post, A. Quintás-Cardama, T. Terzian, C. Smith, C.M. Eischen, G. Lozano, p53-dependent senescence delays emu-myc-induced B-cell lymphomagenesis. Oncogene 29(9), 1260–1269 (2010)CrossRef

Title: Inhibition of PP2A by LB100 sensitizes bladder cancer cells to chemotherapy by inducing p21 degradation
Authors: Song Gao
Liping Shan
Mo Zhang
Yan Wang
Xi Zhan
Yalei Yin
Zhonghao Jiang
Xinyi Tao
Xinyu Li
Mingliang Ye
Yang Liu
Publication date: 22-09-2022
Publisher: Springer Netherlands
Keywords: Cytostatic Therapy
Bladder Carcinoma
Bladder Carcinoma
Published in: Cellular Oncology / Issue 6/2022
Print ISSN: 2211-3428
Electronic ISSN: 2211-3436
DOI: https://doi.org/10.1007/s13402-022-00710-8

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