Inhibition of proliferation of a hepatoma cell line by fucoxanthin in relation to cell cycle arrest and enhanced gap junctional intercellular communication

Background: Amygdalin (Vitamin B-17) is a naturally occurring vitamin found in the seeds of the fruits of Prunus Rosacea family including apricot, bitter almond, cherry, and peach. Objective: The purpose of this study was to examine the effect of amygdalin with and without zinc on hepatocellular carcinoma (HepG2) cell line. Methods: MTT assay was used to evaluate the cytotoxicity of amygdalin without zinc, amygdalin + 20μmol zinc, and amygdalin + 800μmol zinc on HepG2 cell lines. The cell cycle distribution assay was determined by flow cytometry. Apoptosis was confirmed by Annexin V-FITC/PI staining assay. Moreover, the pathway of apoptosis was determined by the percentage of change in the mean levels of P53, Bcl2, Bax, cytochrome c, and caspase-3. Results: Amygdalin without zinc showed strong anti-HepG2 activity. Furthermore, HepG2 cell lines treatment with amygdalin + 20μmol zinc and amygdalin + 800μmol zinc showed a highly significant apoptotic effect than the effect of amygdalin without zinc. Amygdalin treatment induced cell cycle arrest at G2/M and increased the levels of P53, Bax, cytochrome c, and caspase-3 significantly, while it decreased the level of anti-apoptotic Bcl2. Conclusion: Amygdalin is a natural anti-cancer agent, which can be used for the treatment of hepatocellular carcinoma. It promotes apoptosis via the intrinsic cell death pathway (the mitochondria-initiated pathway) and cell cycle arrest at G/M. The potency of amygdalin in HepG2 treatment increased significantly by the addition of zinc.

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High-intensity Raf signal causes cell cycle arrest mediated by p21Cip1.

Molecular and Cellular Biology ◽

10.1128/mcb.17.9.5588 ◽

1997 ◽

Vol 17 (9) ◽

pp. 5588-5597 ◽

Cited By ~ 323

Author(s):

A Sewing ◽

B Wiseman ◽

A C Lloyd ◽

H Land

Keyword(s):

Cell Cycle ◽

Dna Synthesis ◽

Cell Cycle Arrest ◽

Expression Patterns ◽

Cellular Responses ◽

Specific Cell ◽

Cyclin D ◽

Inhibition Of Proliferation ◽

Cycle Arrest ◽

Signal Specificity

Activated Raf has been linked to such opposing cellular responses as the induction of DNA synthesis and the inhibition of proliferation. However, it remains unclear how such a switch in signal specificity is regulated. We have addressed this question with a regulatable Raf-androgen receptor fusion protein in murine fibroblasts. We show that Raf can cause a G1-specific cell cycle arrest through induction of p21Cip1. This in turn leads to inhibition of cyclin D- and cyclin E-dependent kinases and an accumulation of hypophosphorylated Rb. Importantly, this behavior can be observed only in response to a strong Raf signal. In contrast, moderate Raf activity induces DNA synthesis and is sufficient to induce cyclin D expression. Therefore, Raf signal specificity can be determined by modulation of signal strength presumably through the induction of distinct protein expression patterns. Similar to induction of Raf, a strong induction of activated Ras via a tetracycline-dependent promoter also causes inhibition of proliferation and p21Cip1 induction at high expression levels. Thus, p21Cip1 plays a key role in determining cellular responses to Ras and Raf signalling. As predicted by this finding we show that Ras and loss of p21 cooperate to confer a proliferative advantage to mouse embryo fibroblasts.

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Monochloramine suppresses the proliferation of colorectal cancer cell line Caco-2 by both apoptosis and G2/M cell cycle arrest

Cell Biochemistry and Function ◽

10.1002/cbf.2992 ◽

2013 ◽

Vol 32 (2) ◽

pp. 188-193 ◽

Cited By ~ 1

Author(s):

Tetsuya Kohda ◽

Satoru Sakuma ◽

Muneyuki Abe ◽

Yohko Fujimoto

Keyword(s):

Colorectal Cancer ◽

Cell Cycle ◽

Cell Cycle Arrest ◽

Cell Line ◽

Cancer Cell ◽

Cancer Cell Line ◽

Colorectal Cancer Cell ◽

Colorectal Cancer Cell Line ◽

M Cell ◽

Cycle Arrest

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Experimental Application of High-content Screening in Evaluating the Induction of Cell-cycle Arrest and Apoptosis on Human Liver Cancer Cell Line Hep-G2

VNU Journal of Science Medical and Pharmaceutical Sciences ◽

10.25073/2588-1132/vnumps.4248 ◽

2020 ◽

Vol 36 (4) ◽

Author(s):

Do Huu Nghi ◽

Vo Thi Ngoc Hao ◽

Nguyen Thi Hong Nhung

Keyword(s):

Cell Cycle ◽

Cell Cycle Arrest ◽

Cell Line ◽

Human Liver ◽

Cancer Cell Line ◽

Liver Cancer Cell ◽

Hep G2 ◽

Cycle Arrest ◽

Human Liver Cancer Cell ◽

Human Liver Cancer

This study discusses the results of the experimental application of high-content screening (HCS) techniques in evaluating the induction of cell-cycle arrest and apoptosis on human liver cancer cell line, Hep-G2. Accordingly, the bisbenzimide-stained cells (Hoechst 33342; 350 to 500 nM) were analyzed by using an Olympus scanˆR HCS-system to determine the cell-cycle phases (G1, S, and G2/M) and apoptosis as well. As a result, the cell-cycle arrest could be indicated by an increase in G2/M population of Hep-G2 cells after 24h exposure to zerumbone (Zer4; 9 µg/mL) and a similar observation could be made for paclitaxel (Pac; 4 µg/mL) as a reference substance. Keywords Apoptosis, cell-cycle arrest, high-content screening, human liver cancer cell line Hep-G2. References [1] D. Hanahan, R.A. Weinberg, Hallmarks of cancer: the next generation, Cell 144 (2011) 646–674.[2] M. Malumbres, M. Barbacid, Cell cycle, CDKs and cancer: a changing paradigm, Nat. Rev. Cancer 9 (2009) 153–166.[3] S. Diermeier-Daucher, et al., Cell type specific applicability of 5-ethynyl-2'-deoxyuridine (EdU) for dynamic proliferation assessment in flow cytometry, Cytometry A 75 (2009) 535-546.[4] J. Essers, et al., Nuclear dynamics of PCNA in DNA replication and repair, Mol. Cell Biol 25 (2005) 9350- 9359. [5] V. Roukos, et al., Dynamic recruitment of licensing factor Cdt1 to sites of DNA damage. J. Cell Sci. 124 (2011) 422-434.[6] M. Hesse, et al., Direct visualization of cell division using high-resolution imaging of M-phase of the cell cycle, Nat. Commun 3 (2012) 1076. doi: 10.1038/ncomms2089.[7] P. Cappella, F. Gasparri, M. Pulici, J. Moll, A novel method based on click chemistry, which overcomes limitations of cell cycle analysis by classical determination of BrdU incorporation, allowing multiplex antibody staining, Cytometry A 73 (2008) 626–636. [8] S. Diermeier-Daucher, et al., Cell type specific applicability of 5-ethynyl-2’-deoxyundine (EdU) for dynamic proliferation assessment in flow cytometry, Cytometry A 75 (2009) 535–546.[9] T. Yokochi, D.M. Gilbert, Replication labeling with halogenated thymidine analogs, Curr. Protoc. Cell Biol, 35 (2007) 22.10.1–22.10.14. [10] T.J. McGarry, M.W. Kirschner, Geminin, an inhibitor of DNA replication, is degraded during mitosis, Cell 93 (1998) 1043–1053. [11] H. Nishitani, S. Taraviras, Z. Lygerou, T. Nishimoto, The human licensing factor for DNA replication Cdt1 accumulates in G1 and is destabilized after initiation of S-phase. J. Biol. Chem 276 (2001) 44905–44911.[12] J. Pines, T. Hunter, Human cyclin A is adenovirus E1A-associated protein p60 and behaves differently from cyclin B, Nature 346 (1990) 760–763. [13] A. Stathopoulou, et al., Cdt1 is differentially targeted for degradation by anticancer chemotherapeutic drugs. PLoS ONE 7, e34621 (2012). [14] M. Hesse, A. Raulf, G.A. Pilz, C. Haberlandt, A.M. Klein, R. Jabs, H. Zaehres, C.J. Fügemann, K. Zimmermann, J. Trebicka, A. Welz, A. Pfeifer, W. Röll, M.I. Kotlikoff, C. Steinhäuser, M. Götz, H.R. Schöler, B.K. Fleischmann, Direct visualization of cell division using high-resolution imaging of M-phase of the cell cycle, Nat. Commun 3 (2012): 1076.[15] D.A. Ridenour, M.C. McKinney, C.M. Bailey, P.M. Kulesa, CycleTrak: a novel system for the semiautomated analysis of cell cycle dynamics. Dev. Biol 365 (2012) 189–195. [16] A. Roukos, et al., Cell cycle staging of individual cells by fluorescence microscopy, Nat. Protoc 10 (2015) 334-348.[17] E. Harlow, D. Lane, Fixing attached cells in paraformaldehyde, CSH Protoc 3 (2006) doi: 10.1101/pdb.prot4294.[18] G. Mazzini, M. Danova, Fluorochromes for DNA staining and quantitation, Method. Mol. Biol 1560 (2017) 239-259.[19] A. Gottfried, E. Weinhold, Sequence-specific covalent labelling of DNA, Biochem. Soc. Trans 39 (2011) 623-628.[20] J. Bucevičius, G. Lukinavičius, R. Gerasimaitė, The use of Hoechst dyes for DNA staining and beyond, Chemosensor 6 (2018) 1-18.[21] V. Kumar, A.K. Abbas, J.C. Aster, Robbins and Cotran Pathologic Basis of Disease, Ninth ed., Elsevier/Saunders, Philadelphia (2015).[22] N.A. Jensen et al., Establishment of a high content assay for the identification and characterisation of bioactivities in crude bacterial extracts that interfere with the eukaryotic cell cycle, J. Biotechnol 140 (2009) 124-134.[23] H.S. Rahman, et al., Zerumbone induces G2/M cell cycle arrest and apoptosis via mitochondrial pathway in Jurkat cell line, Nat. Prod. Commun 9 (2014) 1237-1242.[24] S.I. Abdelwahab, et al., Zerumbone inhibits interleukin-6 and induces apoptosis and cell cycle arrest in ovarian and cervical cancer cells, Intern. Immunopharm 12 (2012) 594-602.[25] M. Xian, et al., Zerumbone, A bioactive sesquiterpene, induces G2/M cell cycle arrest and apoptosis in leukemia cells via a Fas- and mitochondria-mediated pathway, Cancer Sci 98 (2007) 118-126.[26] A. Sehrawat, et al., Zerumbone causes Bax-and Bak-mediated apoptosis in human breast cancer cells and inhibits orthotopic xenograft growth in vivo, Breast Cancer Res. Treat. 136 (2012) 429-441.[27] Y.Z. Zhou, et al., Zerumbone induces G1 cell cycle arrest and apoptosis in cervical carcinoma cells, Int. J. Clin. Exp. Med. 10 (2017) 6640-6647.

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