Stilbene Compounds Inhibit Tumor Growth by the Induction of Cellular Senescence and the Inhibition of Telomerase Activity
Abstract
:1. Introduction
2. Senescence in Cancer Cells and Its Mechanisms
2.1. Characteristics of Senescence
2.2. Effector Signaling Pathways Involved in Senescence
2.3. Senescence in Cancer Cells
3. Senescence Is a Novel Target for Anticancer Therapy
3.1. Telomerase Inhibition by Chemotherapeutic Drugs
3.2. DNA Damage Triggered Senescence
3.3. Permanent Cell Cycle Arrest by Cell Cycle Regulators
3.4. Mitotic Inhibition-Induced Senescence
3.5. The Latest Therapy-Induced Senescence (TIS) Strategies for Cancer Cells
4. Targeting of Telomerase as an Attractive Anticancer Strategy
4.1. Inhibition of Telomerase Components in Cancer Therapy
4.2. Inhibition of Telomere Extension by Anticancer Drugs
4.3. Inhibition of Telomerase Complex-Related Proteins Could Be a Promising Anticancer Strategy
5. Anticancer Effects of Stilbene Compounds Are Mediated by the Targeting of Telomerase and Cellular Senescence
5.1. Classification of Stilbene Compounds and Their Anticancer Mechanisms
5.2. Anticancer Mechanisms of RSV, RSV Derivatibes, or Combined Therapy by Targeting to Telomerase and Cellular Senescence
5.3. Anticancer Mechanisms of PT Are Mediated by the Targeting of Telomerase and Cellular Senescence
6. Conclusion and Perspectives
Author Contributions
Funding
Conflicts of Interest
Abbreviations
ATM | ataxia-telangiectasia mutated |
ATR | ATM- and Rad3-related |
AZT | azidothymidine |
BA | benzoquinone ansamycin |
BLM | bleomycin |
CDK | cyclin-dependent kinase |
CHK | checkpoint kinase |
CIS | cytokine-induced senescence |
DDR | DNA damage response |
EGCG | (-)-epigallocatechin-3-gallate |
GA | geldanamycin |
GBM | glioblastoma; |
GR | glucocorticoid receptor |
HPMC | human peritoneal mesothelial cell |
HSP90 | heat shock protein 90 |
IFN | interferon |
IFN-γ | interferon gamma |
IR | ionizing radiation |
NE | norepinephrine |
NSCLC | non-small cell lung cancer |
OIS | oncogene-induced senescence |
Par-4 | prostate apoptosis response-4 |
PARP | poly (ADP-ribose) polymerase |
PLK | polo-like kinase |
PT | pterostilbene |
Rb | retinoblastoma |
ROS | reactive oxygen species |
RSV | resveratrol |
SASP | senescence-associated secretory phenotype |
TERT | telomerase reverse transcriptase |
TIS | therapy-induced senescence |
TMZ | temozolomide |
TNF | tumor necrosis factor |
TNKS | tankyrase |
TNKS1 | tankyrase 1 |
TNKS2 | tankyrase 2 |
TRF1 | telomeric repeat binding factor 1 |
TRF2 | telomeric repeat binding factor 2 |
TSG | tumor suppressor gene |
XRT | radiation therapy |
ZDV | zidovudine |
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Stilbene Compounds | Cell Models | Target/Mechanism | Outcome | Reference |
---|---|---|---|---|
Resveratrol | ||||
RSV | U-87MG | hTERT mRNA↓ | cell growth↓, cell death↑ | [140] |
RSV | HT-29, WiDr | Telomerase activity↓ | cell proliferation↓ | [141] |
RSV | MCF-7 | Telomerase activity↓ hTERT expression↓ | S phase arrest↑ apoptosis↑ | [142] |
RSV | Ovaria cancer cells | hTERT expression↓ Slug↓, pScr and HIF-1α↓ | EMT↓ invasion↓ | [143] |
Resveratrol Derivatives | ||||
RSV derivative (E)-4-(4-methoxystyryl) aniline | Colon cancer cells | hTERT expression↓ cMyc expression↓ | cytotoxicity↑ | [144] |
RSV derivative 3,3’,4,4’,5,5’-Hexahydroxy-trans-Stilbene (M8) | Human peritoneal mesothelial cells | mitochondrial reactive oxygen species↑ | senescence↑, cell cycle arrest↑ | [145] |
RSV sulfate metabolites | HT29, MCF-7 | hTERT mRNA↓, cMyc ↓ | cell death↑ | [146] |
Resveratrol Combined Therapy | ||||
RSV + XRT | Prostate cancer cells | p21CIP1/WAF1, p27Kip1, p53↑ Fas, TRAIL1↑, p-H2AX↑ | senescence↑ apoptosis↑ | [147] |
RSV + IR | Lung cancer cells | ROS↑, DDR↑ | senescence | [148] |
RSV + quercetin | Rat glimoma cells | caspase 3/7 activation↑ | senescence | [149] |
RSV + 5-FU | Colon cancer cells | Telomerase activity↓ Stat3 and Akt↓ | apoptosis | [150,151] |
RSV + TMZ | Glioblastoma cells | Mitotic catastrophe p-ATM, p-Chk2↑ | senescence↑ autophagy↑ | [152] |
Pterostilbene | ||||
PT | Lung cancer cells | Molecular docking to hTERT | cell death | [153] |
PT | Lung cancer cells | ATM-CHK-p53 | senescence↑ | [154] |
PT | Breast cancer cells | cMyc expression↓ hTERT expression↓ | apoptosis cell cycle arrest | [155] |
PT | Lung cancer cells | hTERT activity↓, hTERT expression↓, DDR↑, p53-dependent | S phase arrest↑ senescence↑ | [134] |
PIC | Hepatic stellate cell | p16INK4a↑, p53↑ Bcl-xl↓, SMAD↓ | Inflammation↓ hepatocarcinogenesis↓ | [156] |
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Lee, Y.-H.; Chen, Y.-Y.; Yeh, Y.-L.; Wang, Y.-J.; Chen, R.-J. Stilbene Compounds Inhibit Tumor Growth by the Induction of Cellular Senescence and the Inhibition of Telomerase Activity. Int. J. Mol. Sci. 2019, 20, 2716. https://doi.org/10.3390/ijms20112716
Lee Y-H, Chen Y-Y, Yeh Y-L, Wang Y-J, Chen R-J. Stilbene Compounds Inhibit Tumor Growth by the Induction of Cellular Senescence and the Inhibition of Telomerase Activity. International Journal of Molecular Sciences. 2019; 20(11):2716. https://doi.org/10.3390/ijms20112716
Chicago/Turabian StyleLee, Yu-Hsuan, Yu-Ying Chen, Ya-Ling Yeh, Ying-Jan Wang, and Rong-Jane Chen. 2019. "Stilbene Compounds Inhibit Tumor Growth by the Induction of Cellular Senescence and the Inhibition of Telomerase Activity" International Journal of Molecular Sciences 20, no. 11: 2716. https://doi.org/10.3390/ijms20112716
APA StyleLee, Y. -H., Chen, Y. -Y., Yeh, Y. -L., Wang, Y. -J., & Chen, R. -J. (2019). Stilbene Compounds Inhibit Tumor Growth by the Induction of Cellular Senescence and the Inhibition of Telomerase Activity. International Journal of Molecular Sciences, 20(11), 2716. https://doi.org/10.3390/ijms20112716