Category Archives: EMT

Anti-cancer, Anti-metastatic, Breast cancer, cardio-protective, CDK, CDK2, CDK4, cell-cycle arrest, Chapter 7 Isolates and Cancer Research, CYP3A, EMT, ER, ER-negative, G0/G1, G1, growth-inhibitory, MDR, metastasis, Multi-Drug Resistance, Multi-drug resistance, NAD(P)H, P-gp, p21, p27, ROS

Schisandrin

Cancer: Leukemia, breast

Action: Anti-metastatic, cardio-protective, MDR, CYP3A, cell-cycle arrest

Leukemia

Schisandrin B (Sch B) has previously been demonstrated to be a novel P-glycoprotein (P-gp) inhibitor. Recent investigation revealed that Sch B was also an effective inhibitor of the multi-drug resistance-associated protein 1 (MRP1). Sch B's ability to reverse MRP1-mediated drug resistance was tested using HL60/ADR and HL60/MRP human promyelocytic leukemia cell lines, with the overexpression of MRP1 but not P-gp. At the equimolar concentration, Sch B demonstrated significantly stronger potency than the drug probenecid, a MRP1 inhibitor (Sun, Xu, Lu, Pan & Hu, 2007).

Up-regulates CYP3A

The ability of Schisandrin B (Sch B) to modulate cytochrome P450 3A activity (CYP3A) and alter the pharmacokinetic profiles of CYP3A substrate (midazolam) was investigated in vivo in treated rats. Rats were routinely administered with physiological saline (negative control group), ketoconazole (75mg/kg, positive control group), or varying doses of Sch B (experimental groups) for 3 consecutive days. Thereafter, changes in hepatic microsomal CYP3A activity and the pharmacokinetic profiles of midazolam and 1′-hydroxy midazolam in plasma were studied to evaluate CYP3A activity.

The results indicated that Sch B had a significant dose-dependent effect on inhibition of rat hepatic microsomal CYP3A activity. These results suggest that a 3-day treatment of Sch B could increase concentration and oral bioavailability of drugs metabolized by CYP3A (Li, Xin, Yu, & Wu, 2013).

Attenuates Metastasis

NADPH oxidase 4 (NOX4) is a potential target for intervention of cancer metastasis, as reactive oxygen species (ROS) generated by this enzyme plays important roles in TGF-β signaling, an important inducer of cancer metastasis. Zhang, Liu & Hu (2013) show that TGF-β induces ROS production in breast cancer 4T1 cells and enhances cell migration; that the effect of TGF- β depends on NOX4 expression; and that knockdown of NOX4 via RNAi significantly decreases the migration ability of 4T1 cells in the presence or absence of TGF-β and significantly attenuates distant metastasis of 4T1 cells to lung and bone.

Sch B significantly suppresses the lung and bone metastasis of 4T1 cells via inhibiting EMT, suggesting its potential application in targeting the process of cancer metastasis. Sch B significantly suppressed the spontaneous lung and bone metastasis of 4T1 cells inoculated s.c. without significant effect on primary tumor growth and significantly extended the survival time of the mice. Sch B did not inhibit lung metastasis of 4T1 cells that were injected via tail vein. Delayed start of treatment with Sch B in mice with pre-existing tumors did not reduce lung metastasis. These results suggested that Sch B acted at the step of local invasion (Liu et al., 2012).

Cardiotoxicity Protective/ Attenuates Metastasis

Sch B is capable of protecting Dox-induced chronic cardiotoxicity and enhancing its anti-cancer activity. To the best of our knowledge, Sch B is the only molecule ever proved to function as a cardio-protective agent as well as a chemotherapeutic sensitizer, which is potentially applicable for cancer treatment.

Pre-treatment with Sch B significantly attenuated Dox-induced loss of cardiac function and damage of cardiomyocytic structure. Sch B substantially enhanced Dox cytotoxicities toward S180 in vitro and in vivo in mice, and increased Dox cytotoxcity against 4T1 in vitro. Although we did not observe this enhancement against the implanted 4T1 primary tumor, the spontaneous metastasis to lung was significantly reduced in combined treatment group compared to Dox alone group (Xu et al., 2011).

Cell-cycle Arrest/Breast Cancer

Schizandrin inhibits cell proliferation through the induction of cell-cycle arrest with modulating cell-cycle-related proteins in human breast cancer cells. Schizandrin exhibited growth-inhibitory activities in cultured human breast cancer cells, and the effect was the more profound in estrogen receptor (ER)-positive T47D cells than in ER-negative MDA-MB-231 cells. When treated with the compound in T47D cells, schizandrin induced the accumulation of a cell population in the G0/G1 phase, which was further demonstrated by the induction of CDK inhibitors p21 and p27 and the inhibition of the expression of cell-cycle checkpoint proteins including cyclin D1, cyclin A, CDK2 and CDK4 (Kim et al., 2010).

References

Kim SJ, Min HY, Lee EJ, et al. (2010). Growth inhibition and cell-cycle arrest in the G0/G1 by schizandrin, a dibenzocyclooctadiene lignan isolated from Schisandra chinensis, on T47D human breast cancer cells. Phytother Res, 24(2):193-7. doi: 10.1002/ptr.2907.


Li WL, Xin HW, Yu AR, Wu XC. (2013). In vivo effect of Schisandrin B on cytochrome P450 enzyme activity. Phytomedicine, 20(8), 760-765


Liu Z, Zhang B, Liu K, Ding Z, Hu X. (2012). Schisandrin B attenuates cancer invasion and metastasis via inhibiting epithelial-mesenchymal transition. PLoS One, 7(7):e40480. doi: 10.1371/journal.pone.0040480.


Sun M, Xu X, Lu Q, Pan Q, Hu X. (2007). Schisandrin B: A dual inhibitor of P-glycoprotein and Multi-drug resistance-associated protein 1. Cancer Letters, 246(1-2), 300-307.


Xu Y, Liu Z, Sun J, et al. (2011). Schisandrin B prevents doxorubicin-induced chronic cardiotoxicity and enhances its anti-cancer activity in vivo. PLoS One, 6(12):e28335. doi: 10.1371/journal.pone.0028335.


Zhang B, Liu Z, Hu X. (2013). Inhibiting cancer metastasis via targeting NAPDH oxidase 4. Biochem Pharmacol, 86(2):253-66. doi: 10.1016/j.bcp.2013.05.011.

apoptosis, cancer stem cells, Chapter 7 Isolates and Cancer Research, CSC, CSCs, EMT, induces apoptosis

Pterostilbene

Cancer: Liver

Action: Induces apoptosis, cancer stem cells

Induces Apoptosis

Pterostilbene (PT) extracted from blueberries dose-dependently reduced the enrichment of CD133 (+) Mahlavu cells upon irradiation; PT treatment also prevented tumor sphere formation, reduced stemness gene expression, and suppressed invasion and migration abilities as well as increasing apoptosis of CD133 (+) Mahlavu CSCs (Lee et al., 2013).

CSCs

PT effectively suppresses the generation of CSCs and metastatic potential under the influence of M2 TAMs via modulating EMT associated signaling pathways, specifically NF-κB/miR488 circuit. Thus, PT could be an ideal anti-CSC agent in clinical settings (Mak et al., 2013).

References

Lee CM, Su YH, Huynh TT, et al. (2013). BlueBerry Isolate, Pterostilbene, Functions as a Potential Anti-cancer Stem Cell Agent in Suppressing Irradiation-Mediated Enrichment of Hepatoma Stem Cells. Evid Based Complement Alternat Med, 2013:258425. doi: 10.1155/2013/258425.


Mak KK, Wu AT, Lee WH, et al. (2013). Pterostilbene, a bioactive component of blueberries, suppresses the generation of breast cancer stem cells within tumor microenvironment and metastasis via modulating NF-κ B/microRNA 448 circuit. Mol Nutr Food Res, 57(7):1123-34. doi: 10.1002/mnfr.201200549.

A2058, Akt, anti-carcinogenic, anti-inflammatory, Anti-metastatic, anti-mitogenic, anti-oxidant, anti-proliferative, apoptosis, Apoptotic, Breast cancer, Breast cancer cell lines, Cervical cancer, Chapter 7 Isolates and Cancer Research, chemo-preventive, Chemo-preventive agent, Chemotherapy, Cytostatic, cytotoxic, EMT, ER, FAK, honeybee hives, Immune, Immunomodulatory, inflammation, inhibits NF-κB, JNK, Lung cancer, MAPK, MCF-7/Adr, MCF-7/wt, Mcl-1, Melanoma, Oral cancer, p38, p65, PANC-1, Pancreatic cancer, Prostate cancer, ROS, S, SCC-9, TIMP-2, TNF, Twist

Caffeic acid phenethyl ester (CAPE)

Cancer:
Breast, prostate, leukemia, cervical., oral., melanoma

Action: EMT, anti-mitogenic, anti-carcinogenic, anti-inflammatory, immunomodulatory

Anti-mitogenic, Anti-carcinogenic, Anti-inflammatory, Immunomodulatory Properties

Caffeic acid phenethyl ester (CAPE), an active component of propolis from honeybee hives, is known to have anti-mitogenic, anti-carcinogenic, anti-inflammatory, and immunomodulatory properties. A variety of in vitro pharmacology for CAPE has been reported. A study using CAPE showed a positive effect on reducing carcinogenic incidence. It is known to have anti-mitogenic, anti-carcinogenic, anti-inflammatory, and immunomodulatory properties in vitro (Orban et al., 2000) Another study also showed that CAPE suppresses acute immune and inflammatory responses and holds promise for therapeutic uses to reduce inflammation (Huang et al., 1996).

Caffeic acid phenethyl ester (CAPE) specifically inhibits NF-κB at µM concentrations and shows ability to stop 5-lipoxygenase-catalyzed oxygenation of linoleic acid and arachidonic acid. Previous studies have demonstrated that CAPE exhibits anti-oxidant, anti-inflammatory, anti-proliferative, cytostatic, anti-viral., anti-bacterial., anti-fungal., and, most importantly, anti-neoplastic properties (Akyol et al., 2013).

Multiple Immunomodulatory and Anti-inflammatory Activities

The results show that the activation of NF-kappa B by tumor necrosis factor (TNF) is completely blocked by CAPE in a dose- and time-dependent manner. Besides TNF, CAPE also inhibited NF-kappa B activation induced by other inflammatory agents including phorbol ester, ceramide, hydrogen peroxide, and okadaic acid. Since the reducing agents reversed the inhibitory effect of CAPE, it suggests the role of critical sulfhydryl groups in NF-kappa B activation. CAPE prevented the translocation of the p65 subunit of NF-kappa B to the nucleus and had no significant effect on TNF-induced I kappa B alpha degradation, but did delay I kappa B alpha resynthesis. When various synthetic structural analogues of CAPE were examined, it was found that a bicyclic, rotationally constrained, 5,6-dihydroxy form was superactive, whereas 6,7-dihydroxy variant was least active.

Thus, overall our results demonstrate that CAPE is a potent and a specific inhibitor of NF-kappa B activation and this may provide the molecular basis for its multiple immunomodulatory and anti-inflammatory activities (Natarajan et al., 1996).

Breast Cancer

Aqueous extracts from Thymus serpyllum (ExTs), Thymus vulgaris (ExTv), Majorana hortensis (ExMh), and Mentha piperita (ExMp), and the phenolic compounds caffeic acid (CA), rosmarinic acid (RA), lithospermic acid (LA), luteolin-7-O-glucuronide (Lgr), luteolin-7-O-rutinoside (Lr), eriodictiol-7-O-rutinoside (Er), and arbutin (Ab), were tested on two human breast cancer cell lines: Adriamycin-resistant MCF-7/Adr and wild-type MCF-7/wt.

ExMh showed the highest cytotoxicity, especially against MCF-7/Adr, whereas ExMp was the least toxic; particularly against MCF-7/wt cells. RA and LA exhibited the strongest cytotoxicity against both MCF-7 cell lines, over 2-fold greater than CA and Lgr, around 3-fold greater than Er, and around 4- to 7-fold in comparison with Lr and Ab. Except for Lr and Ab, all other phytochemicals were more toxic against MCF-7/wt, and all extracts exhibited higher toxicity against MCF-7/Adr. It might be concluded that the tested phenolics exhibited more beneficial properties when they were applied in the form of extracts comprising their mixtures (Berdowska et al., 2013).

Prostate Cancer

Evidence is growing for the beneficial role of selective estrogen receptor modulators (SERM) in prostate diseases. Caffeic acid phenethyl ester (CAPE) is a promising component of propolis that possesses SERM activity. CAPE-induced inhibition of AKT phosphorylation was more prominent (1.7-folds higher) in cells expressing ER-α such as PC-3 compared to LNCaP. In conclusion, CAPE enhances the anti-proliferative and cytotoxic effects of DOC and PTX in prostate cancer cells (Tolba et al., 2013).

EMT, Prostate Cancer

CAPE suppressed the expression of Twist 2 and growth of PANC-1 xenografts without significant toxicity. CAPE could inhibit the orthotopic growth and EMT of pancreatic cancer PANC-1 cells accompanied by down-regulation of vimentin and Twist 2 expression (Chen et al., 2013).

CAPE is a well-known NF-κB inhibitor. CAPE has been used in folk medicine as a potent anti-inflammatory agent. Recent studies indicate that CAPE treatment suppresses tumor growth and Akt signaling in human prostate cancer cells (Lin et al., 2013). Combined treatments of CAPE with chemotherapeutic drugs exhibit synergistic suppression effects. Pharmacokinetic studies suggest that intraperitoneal injection of CAPE at concentration of 10mg/kg is not toxic. CAPE treatment sensitizes cancer cells to chemotherapy and radiation treatments. In addition, CAPE treatment protects therapy-associated toxicities (Liu et al., 2013).

Cervical Cancer

CAPE preferentially induced S- and G2 /M-phase cell-cycle arrests and initiated apoptosis in human cervical cancer lines. The effect was found to be associated with increased expression of E2F-1, as there is no CAPE-mediated induction of E2F-1 in the pre-cancerous cervical Z172 cells. CAPE also up-regulated the E2F-1 target genes cyclin A, cyclin E and apoptotic protease activating of factor 1 (Apaf-1) but down-regulated cyclin B and induced myeloid leukemia cell differentiation protein (Mcl-1) (Hsu et al., 2013).

Oral Cancer

CAPE attenuated SCC-9 oral cancer cells migration and invasion at noncytotoxic concentrations (0  µM to 40 µM). CAPE exerted its inhibitory effects on MMP-2 expression and activity by upregulating tissue inhibitor of metalloproteinase-2 (TIMP-2) and potently decreased migration by reducing focal adhesion kinase (FAK) phosphorylation and the activation of its downstream signaling molecules p38/MAPK and JNK (Peng et al., 2012).

Melanoma

CAPE is suggested to suppress reactive-oxygen species (ROS)-induced DNA strand breakage in human melanoma A2058 cells when compared to other potential protective agents. CAPE can be applied not only as a chemo-preventive agent but also as an anti-metastatic therapeutic agent in lung cancer and because CAPE is a nuclear factor-κB (NF-κB) inhibitor and 5α reductase inhibitor, it has potential for the treatment of prostate cancer (Ozturk et al., 2012).

References

Akyol S, Ozturk G, Ginis Z, et al. (2013). In vivo and in vitro antõneoplastic actions of caffeic acid phenethyl ester (CAPE): therapeutic perspectives. Nutr Cancer, 65(4):515-26. doi: 10.1080/01635581.2013.776693.


Berdowska I, Ziel iński B, Fecka I, et al. (2013). Cytotoxic impact of phenolics from Lamiaceae species on human breast cancer cells. Food Chem, 15;141(2):1313-21. doi: 10.1016/j.foodchem.2013.03.090.


Chen MJ, Shih SC, Wang HY, et al. (2013). Caffeic Acid phenethyl ester inhibits epithelial-mesenchymal transition of human pancreatic cancer cells. Evid Based Complement Alternat Med, 2013:270906. doi: 10.1155/2013/270906.


Hsu TH, Chu CC, Hung MW, et al. (2013). Caffeic acid phenethyl ester induces E2F-1-mediated growth inhibition and cell-cycle arrest in human cervical cancer cells. FEBS J, 280(11):2581-93. doi: 10.1111/febs.12242.


Huang MT, Ma W, Yen P, et al. (1996). Inhibitory effects of caffeic acid phenethyl ester (CAPE) on 12-O-tetradecanoylphorbol-13-acetate-induced tumor promotion in mouse skin and the synthesis of DNA, RNA and protein in HeLa cells. Carcinogenesis, 17(4):761–5. doi:10.1093/carcin/17.4.761.


Lin HP, Lin CY, Liu CC, et al. (2013). Caffeic Acid phenethyl ester as a potential treatment for advanced prostate cancer targeting akt signaling. Int J Mol Sci, 14(3):5264-83. doi: 10.3390/ijms14035264.


Liu CC, Hsu JM, Kuo LK, et al. (2013). Caffeic acid phenethyl ester as an adjuvant therapy for advanced prostate cancer. Med Hypotheses, 80(5):617-9. doi: 10.1016/j.mehy.2013.02.003.


Natarajan K, Singh S, Burke TR Jr, Grunberger D, Aggarwal BB. (1996). Caffeic acid phenethyl ester is a potent and specific inhibitor of activation of nuclear transcription factor NF-kappa B. Proc Natl Acad Sci USA, 93(17):9090-5.


Orban Z, Mitsiades N, Burke TR, Tsokos M, Chrousos GP. (2000). Caffeic acid phenethyl ester induces leukocyte apoptosis, modulates nuclear factor-kappa B and suppresses acute inflammation. Neuroimmunomodulation, 7(2): 99–105. doi:10.1159/000026427.


Ozturk G, Ginis Z, Akyol S, et al. (2012). The anti-cancer mechanism of caffeic acid phenethyl ester (CAPE): review of melanomas, lung and prostate cancers. Eur Rev Med Pharmacol Sci, 16(15):2064-8.


Peng CY, Yang HW, Chu YH, et al. (2012). Caffeic Acid phenethyl ester inhibits oral cancer cell metastasis by regulating matrix metalloproteinase-2 and the mitogen-activated protein kinase pathway. Evid Based Complement Alternat Med, 2012:732578. doi: 10.1155/2012/732578.


Tolba MF, Esmat A, Al-Abd AM, et al. (2013). Caffeic acid phenethyl ester synergistically enhances docetaxel and paclitaxel cytotoxicity in prostate cancer cells. IUBMB Life, 65(8):716-29. doi: 10.1002/iub.1188.

angiogenesis, Anti-angiogenesis, Anti-angiogenic, anti-tumor, apoptosis, Bladder cancer, Breast cancer, cell-cycle arrest, Chapter 7 Isolates and Cancer Research, chemo-preventive, Cip1/p21, Colon Cancer or Colorectal cancer, EGFR, EMT, epidermal growth factor receptor, ERK, ERK1, Fet, Geo, and HCT116, G1, HL-60, HT-29, Induces cell-cycle arrest, iNOS, Lung cancer, metastasis, Nitric Oxide, p21, PKC, S, Silybum marianum, STAT, STAT3, Thyroid cancer, TNF

Silibinin

Cancer:
Lung, leukemia, colorectal, thyroid, breast, bladder

Action: Anti-angiogenesis, EMT, cell-cycle arrest

Cell-cycle Arrest, Colon Cancer

Silibinin, an active constituent of milk thistle (Silybum marianum [(L.) Gaertn.]), has been reported to inhibit proliferation and induce cell-cycle arrest of human colon cancer cells, Fet, Geo, and HCT116 (Hogan et al., 2007). Silibinin Up-regulates the expression of cyclin-dependent kinase inhibitors and induces cell-cycle arrest and apoptosis in human colon carcinoma HT-29 cells (Agarwal et al., 2003). Also in HT-29 cells, treatment with beta-escin, a principal component of horse chestnut, tinduces growth arrest at the G1-S phase together with an induction of Cip1/p21 and an associated reduction in the phosphorylation of retinoblastoma protein (Patlolla et al., 2006).

Lung Cancer

Silibinin also has anti-angiogenic effects on lung adenocarcinomas in vitro, as it strongly decreased both tumor number and tumor size (an anti-tumor effect that correlates with reduced anti-angiogenic activity) (Tyagi et al., 2009). Further, silibinin inhibits mouse lung tumorigenesis in vivo, in part by targeting tumor microenvironment. Tumor necrosis factor-alpha (TNF-α) and interferon-gamma (IFN-γ) can be pro- or anti-tumorigenic, but in lung cancer cell lines they induce pro-inflammatory enzymes cyclooxygenase 2 (COX2) and inducible nitric oxide synthase (iNOS). Accordingly, the mechanism of silibinin action was examined on TNF-α + IFN-γ (hereafter referred as cytokine mixture) elicited signaling in tumor-derived mouse lung epithelial LM2 cells.

Both signal transducers and activators of the transcription (STAT)3 (tyr705 and ser727) and STAT1 (tyr701) were activated within 15 min of cytokine mixture exposure, while STAT1 (ser727) activated after 3 h. Cytokine mixture also activated Erk1/2 and caused an increase in both COX2 and iNOS levels. Pre-treatment of cells with a MEK, NF-κB, and/or epidermal growth factor receptor (EGFR) inhibitor inhibited cytokine mixture-induced activation of Erk1/2, NF-κB, or EGFR, respectively, and strongly decreased phosphorylation of STAT3 and STAT1 and expression of COX2 and iNOS.

Together, the results show that STAT3 and STAT1 could be valuable chemo-preventive and therapeutic targets within the lung tumor microenvironment in addition to being targets within the tumor itself, and that silibinin inhibit their activation as a plausible mechanism of its efficacy against lung cancer (Tyagi et al., 2011).

Leukemia

Silibinin also affects cellular differentiation in the human promyelocytic leukemia HL-60 cell culture system. Treatment of HL-60 cells with silibinin inhibited cellular proliferation and induced cellular differentiation in a dose-dependent manner.

Silibinin enhanced protein kinase C (PKC) activity and increased protein levels of both PKCα and PKCβ in 1,25-(OH)2D3-treated HL-60 cells. PKC and extracellular signal-regulated kinase (ERK) inhibitors significantly inhibited HL-60 cell differentiation induced by silibinin alone or in combination with 1,25-(OH)2D3, indicating that PKC and ERK may be involved in silibinin-induced HL-60 cell differentiation (Kang et al., 2001).

Thyroid Cancer, Breast Cancer

Silibinin inhibits TPA-induced cell migration and MMP-9 expression in thyroid and breast cancer cells. Matrix metalloproteinases (MMPs) play an important role in cancer metastasis, cell migration and invasion. The effects of silibinin were investigated on 12-O-tetradecanoylphorbol-13-acetate (TPA)-induced cell migration and MMP-9 expression in thyroid and breast cancer cells. These results revealed that the levels of MMP-9 mRNA and protein expression were significantly increased by TPA but not MMP-2 in TPC-1 and MCF7 cells.

TPA-induced phosphorylation of MEK and ERK was also inhibited by silibinin. Taken together, these results suggest that silibinin suppresses TPA-induced cell migration and MMP-9 expression through the MEK/ERK-dependent pathway in thyroid and breast cancer cells (Oh et al., 2013).

Bladder Cancer

Silibinin induced apoptosis and inhibited proliferation of bladder cancer cells and metastasis. In the present study, Wu et al. (2013) utilized a novel highly metastatic T24-L cell model, and found that silibinin treatment not only resulted in the suppression of cell migration and invasion in vitro, but also decreased bladder cancer lung metastasis and prolonged animal survival in vivo. Inactivation of β-catenin/ZEB1 signaling by silibinin leads to dual-block of EMT and stemness.

Lung Cancer, EMT

Silibinin formulation might facilitate the design of clinical trials to test the administration of silibinin meglumine-containing injections, granules, or beverages in combination with EGFR TKIs in patients with EGFR-mutated NSCLC. Silibinin meglumine notably decreased the overall volumes of NSCLC tumors as efficiently as did the EGFR tyrosine kinase inhibitor (TKI) gefitinib. Concurrent treatment with silibinin meglumine impeded the regrowth of gefitinib-unresponsive tumors, resulting in drastic tumor growth prevention.

Because the epithelial-to-mesenchymal transition (EMT) is required by a multiplicity of mechanisms of resistance to EGFR TKIs, we evaluated the ability of silibinin meglumine to impede the EMT in vitro and in vivo. Silibinin-meglumine efficiently prevented the loss of markers associated with a polarized epithelial phenotype as well as the de novo synthesis of proteins associated with the mesenchymal morphology of transitioning cells (Cuf` et al., 2013).

Breast cancer

Myeloid-derived suppressor cells (MDSC)s increase in blood and accumulate in the tumor microenvironment of tumor-bearing animals, contributing to immune suppression in cancer. Silibinin, a natural flavonoid from the seeds of milk thistle, has been developed as an anti-inflammatory agent and supportive care agent to reduce the toxicity of cancer chemotherapy. The goals of this study were to evaluate the effect of silibinin on MDSCs in tumor-bearing mice and antitumor activity of silibinin in a mouse model of breast cancer. 4T1 luciferase-transfected mammary carcinoma cells were injected into in the mammary fat pad female BALB/c mice, and female CB17-Prkdc Scid/J mice. Silibinin treatment started on day 4 or day 14 after tumor inoculation continued every other day.

Tumor growth was monitored by bioluminescent imaging (BLI) measuring total photon flux. Flow cytometry measured total leukocytes, CD11b+ Gr-1+ MDSC, and T cells in the blood and tumors of tumor-bearing mice. The effects of silibinin on 4T1 cell viability in vitro were measured by BLI. Treatment with silibinin increased overall survival in mice harboring tumors derived from the 4T1-luciferase breast cancer cell line, and reduced tumor volumes and numbers of CD11b+Gr-1+ MDSCs in the blood and tumor, and increased the content of T cells in the tumor microenvironment.

Silibinin failed to inhibit tumor growth in immunocompromised severe combined immunodeficiency mice, supporting the hypothesis that anticancer effect of silibinin is immune-mediated. The antitumor activity of silibinin requires an intact host immune system and is associated with decreased accumulation of blood and tumor-associated MDSCs.

References

 

Agarwal C, Singh RP, Dhanalakshmi S, et al. (2003). Silibinin Up-regulates the expression of cyclin-dependent kinase inhibitors and causes cell-cycle arrest and apoptosis in human colon carcinoma HT-29 cells. Oncogene, 22:8271–8282.

 

Cufí S, Bonavia R, Vazquez-Martin A, Corominas-Faja B, et al. (2013). Silibinin meglumine, a water-soluble form of milk thistle silymarin, is an orally active anti-cancer agent that impedes the epithelial-to-mesenchymal transition (EMT) in EGFR-mutant non-small-cell lung carcinoma cells. Food Chem Toxicol, 60:360-8. doi: 10.1016/j.fct.2013.07.063.

Hogan FS, Krishnegowda NK, Mikhailova M, Kahlenberg MS. (2007). Flavonoid, silibinin, inhibits proliferation and promotes cell-cycle arrest of human colon cancer. J Surg Res, 143:58–65.

Kang SN, Lee MH, Kim KM, Cho D, Kim TS. (2001). Induction of human promyelocytic leukemia HL-60 cell differentiation into monocytes by silibinin: involvement of protein kinase C. Biochemical Pharmacology, 61(12):1487–1495

Oh SJ, Jung SP, Han J, et al. (2013). Silibinin inhibits TPA-induced cell migration and MMP-9 expression in thyroid and breast cancer cells. Oncol Rep, 29(4):1343-8. doi: 10.3892/or.2013.2252.

Patlolla JM, Raju J, Swamy MV, Rao CV. (2006). Beta-escin inhibits colonic aberrant crypt foci formation in rats and regulates the Cell-cycle growth by inducing p21(waf1/cip1) in colon cancer cells. Mol Cancer Ther, 5:1459–1466.

Tyagi A, Singh RP, Ramasamy K, et al. (2009). Growth Inhibition and Regression of Lung Tumors by Silibinin: Modulation of Angiogenesis by Macrophage-Associated Cytokines and Nuclear Factor-κ B and Signal Transducers and Activators of Transcription 3. Cancer Prev Res, 2(1):74-83

Tyagi A, Agarwal C, Dwyer-Nield LD, et al. (2011). Silibinin modulates TNF‐α and IFN ‐γ mediated signaling to regulate COX2 and iNOS expression in tumorigenic mouse lung epithelial LM2 cells. Molecular Carcinogenesis. doi: 10.1002/mc.20851.

Wu K, Ning Z, Zeng J, et al. (2013). Silibinin inhibits β -catenin/ZEB1 signaling and suppresses bladder cancer metastasis via dual-blocking epithelial-mesenchymal transition and stemness. Cell Signal, 25(12):2625-2633. doi: 10.1016/j.cellsig.2013.08.028.

Forghani P, Khorramizadeh MR & Waller EK. (2014) Silibinin inhibits accumulation of myeloid-derived suppressor cells and tumor growth of murine breast cancer. Cancer Medicine. Volume 3, Issue 2, pages 215–224, April 2014 DOI: 10.1002/cam4.186

Anti-cancer, anti-inflammatory, apoptosis, Apoptotic, Breast cancer, cancer stem cells, Chapter 7 Isolates and Cancer Research, Chemotherapy, CSC, CSCs, DNMT2, EMT, IKK, inflammation, inhibits NF-κB, JNK, p53, p65, Pro-apoptotic, promotes apoptosis, ROS, STAT, Tanacetum parthenium

Parthenolide

Cancer:
Myeloma, ovarian adenocarcinoma, breast, acute myelogenous leukemia, epithelial-to-mesenchymal transition (EMT)

Action: Anti-cancer, anti-inflammatory, inhibits NF-κB, promotes apoptosis

Inhibits NF-κB & Promotes Apoptosis

Parthenolide, a sesquiterpene lactone derived from the leaves of feverfew (Tanacetum parthenium (L.)), is considered a main bioactive component of this herb. Feverfew has been used orally or as an infusion for the treatment of migraine, arthritis, fever, and stomachache. Besides its anti-inflammatory and anti-migraine properties, parthenolide also shows anti-cancer activities in a variety of cell lines. It contains an alpha-methylene-gamma-lactone ring and an epoxide moiety which are able to interact with nucleophilic sites of biologically important molecules.

Parthenolide modulates multiple targets, thereby contributing to its various in vitro and in vivo effects. Inhibition of NF-kappaB activity, constitutive in many types of cancers via either interaction with IKK or more directly with the p65 subunit of NF-kappaB, is considered one of the main mechanisms of its action. In addition, inhibition of STAT and MAP kinase activities and the induction of sustained JNK activity as well as p53 activity via influencing MDM2 and HDAC1 levels lead to an increased susceptibility of cancer cells to chemo- and radio- therapy. At the epigenetic level, parthenolide reduces HDAC1 level and, by inhibiting DNMT2 activity, induces global hypomethylation of DNA, which can restore the expressions of some suppressor genes.

Moreover, this compound reduces the cellular level of GSH in cancer cells, followed by ROS accumulation and apoptosis. A unique property of parthenolide is its ability to induce cell death mainly in cancer cells, while sparing healthy ones and it also protects normal cells from UVB and oxidative stress. More remarkably, it seems to have the potential to target some cancer stem cells. Its wide array of biological activity and low toxicity make parthenolide a very promising drug with multi-pharmacological potential, largely dependent on the cellular context (Koprowska et al., 2010).

Multiple Myeloma

It has been shown that parthenolide is a potent anti-MM-CSC agent. Multiple myeloma (MM) is an incurable plasma cell malignancy where nearly all patients succumb to a relapse. The current preclinical models of MM target the plasma cells, constituting the bulk of the tumor, leaving the cancer stem cells to trigger a relapse. It demonstrated preferential toxicity toward MM-CSCs over non-tumorigenic MM cells. Addition of the bone marrow stromal compartment abrogated andrographolide activity while having no effect on parthenolide cytoxicity. It hence has anti-CSC activity in myeloma, suggesting that it has the potential to improve the survival of patients with MM by eliminating the relapse-causing MM-CSCs (Gunn et al., 2011).

Acute Myelogenous Leukemia

Parthenolide (PTL), a naturally occurring small molecule, induces robust apoptosis in primary human acute myelogenous leukemia (AML) cells and blast crisis CML (bcCML) cells while sparing normal hematopoietic cells. Furthermore, analysis of progenitor cells using in vitro colony assays, as well as stem cells using the non-obese diabetic/severe combined immunodeficient (NOD/SCID) xenograft model, show that PTL also preferentially targets AML progenitor and stem cell populations.

Notably, in comparison to the standard chemotherapy drug cytosine arabinoside (Ara-C), PTL is much more specific to leukemia cells. The molecular mechanism of PTL-mediated apoptosis is strongly associated with inhibition of nuclear factor κB (NF-κB), pro-apoptotic activation of p53, and increased reactive oxygen species (ROS) (Guzman, et al., 2005).

PTL is known to be a potent inhibitor of NF-κB (Bork et al., 1997). The mechanism of NF-κB down-regulation appears to occur via inhibition of the IKK complex. Guzman et al. (2005) observed strong inhibition of NF-κB in primary AML cells and speculate that this activity contributes to the efficacy of PTL. However, previous genetic studies using a dominant-negative repressor of NF-κB activity have shown that inhibition of NF-κB alone is not sufficient to mediate the robust cell death observed with PTL. Rather, blockade of the NF-κB pathway appears to sensitize primary AML cells to death and induces a relatively slow spontaneous apoptosis (~50% cell death in 36 h) (Guzman et al., 2002). Similarly, studies by Romano et al. (2000) showed that treatment of primary AML blasts with NF-κB decoy oligonucleotides was not sufficient to induce a strong apoptotic response.

Consequently, PTL must be affecting other pathways relevant to AML-specific survival. One such pathway appears to be mediated by the activity of p53. PTL induced rapid up-regulation of p53 protein with concomitant phosphorylation on serine (Woynarowski & Konopa, 1981).

Ovarian Carcinoma

Results suggest that parthenolide may induce apoptotic cell death in ovarian carcinoma cell lines by activating the mitochondrial pathway and the caspase-8- and Bid-dependent pathways. The apoptotic effect of parthenolide appears to be mediated by the formation of reactive oxygen species and the depletion of GSH. Parthenolide might be beneficial in the treatment of epithelial ovarian adenocarcinoma and combination therapy (Kwak et al., 2013).

Epithelial-to-Mesenchymal Transition (EMT)

Detyrosinated tubulin, a post-translational modification of α-tubulin and a hallmark of stable microtubules, has gained recent attention given its association with tumor progression, invasiveness, and chemoresistance. Also, epithelial-to-mesenchymal transition (EMT) promotes tubulin detyrosination through tubulin tyrosine ligase (TTL) suppression. Given the induction of EMT associated with inflammation and cancer progression, Whipple et al. (2013) tested anti-inflammatory nuclear factor-kappaB (NF-κB) inhibitors on a panel of human breast carcinoma cells to examine their effects on detyrosinated tubulin to identify more specific tubulin-directed anti-cancer treatments.

Breast Cancer

Sesquiterpene lactones, parthenolide and costunolide, selectively decrease detyrosinated tubulin independent of their inhibition of NF-κB. Live-cell scoring of suspended cells treated with parthenolide and costunolide show reduction in the frequency of microtentacles and inhibition of reattachment. Selective targeting of detyrosinated tubulin with parthenolide and costunolide can reduce McTN frequency and inhibit tumor cell reattachment. These actions are independent of their effects on NF-κB inhibition, presenting a novel anti-cancer property and therapeutic opportunity to selectively target a stable subset of microtubules in circulating tumor cells to reduce metastatic potential with less toxicity in breast cancer patients (Whipple et al., 2013).

References

Bork PM, Schmitz ML, Kuhnt M, Escher C, Heinrich M. (1997). Sesquiterpene lactone containing Mexican Indian medicinal plants and pure sesquiterpene lactones as potent inhibitors of transcription factor NF-kappaB. FEBS Lett, 402:85-90.


Gunn EJ, Williams JT, Huynh DT, et al. (2011). The natural products parthenolide and andrographolide exhibit anti-cancer stem cell activity in multiple myeloma. Leuk Lymphoma, 52(6):1085-97.


Guzman ML, Rossi RM, Karnischky L, et al. (2005). The sesquiterpene lactone parthenolide induces apoptosis of human acute myelogenous leukemia stem and progenitor cell. Blood, 105(11): 4163–4169. doi: 10.1182/blood-2004-10-4135.


Guzman ML, Swiderski CF, Howard DS, et al. (2002). Preferential induction of apoptosis for primary human leukemic stem cells. Proc Natl Acad Sci U S A, 99:16220-16225.


Koprowska K, Czyz M. (2010). Molecular mechanisms of parthenolide's action: Old drug with a new face. Postepy Hig Med Dosw, 64:100-14.


Kwak SW, Park ES, Lee CS. (2013). Parthenolide induces apoptosis by activating the mitochondrial and death receptor pathways and inhibits FAK-mediated cell invasion. Mol Cell Biochem.


Romano MF, Lamberti A, Bisogni R, et al. (2000). Enhancement of cytosine arabinoside-induced apoptosis in human myeloblastic leukemia cells by NF-kappa B/Rel-specific decoy oligodeoxynucleotides. Gene Ther, 7:1234-1237.


Whipple RA, Vitolo MI, Boggs AE, et al. (2013). Parthenolide and costunolide reduce microtentacles and tumor cell attachment by selectively targeting detyrosinated tubulin independent from NF- κ B inhibition. Breast Cancer Res,15(5):R83.


Woynarowski JM, Konopa J. (1981). Inhibition of DNA biosynthesis in HeLa cells by cytotoxic and anti-tumor sesquiterpene lactones. Mol Pharmacol,19:97-102.

Anti-cancer, cancer stem cells, Chapter 7 Isolates and Cancer Research, Chemoprevention, CSC, CSCs, EMT, Notch

Curcumin and CSCs

Action: Anti-cancer

The anticancer effect of curcumin has been demonstrated in many cell and animal studies, and recent research has shown that curcumin can target cancer stem cells (CSCs). CSCs are proposed to be responsible for initiating and maintaining cancer, and contribute to recurrence and drug resistance. A number of studies have suggested that curcumin has the potential to target CSCs through regulation of CSC self-renewal pathways (Wnt/β-catenin, Notch, Sonic Hedgehog) and specific microRNAs involved in acquisition of epithelial–mesenchymal transition (EMT). The potential impact of curcumin, alone or in combination with other anticancer agents, on CSCs was evaluated as well. Furthermore, the safety and tolerability of curcumin have been well-established by numerous clinical studies. Importantly, the low bioavailability of curcumin has been dramatically improved through the use of structural analogues or special formulations. More clinical trials are underway to investigate the efficacy of this promising agent in cancer chemoprevention and therapy. In this article, we review the effects of curcumin on CSC self-renewal pathways and specific microRNAs, as well as its safety and efficacy in recent human studies. In conclusion, curcumin could be a very promising adjunct to traditional cancer treatments (Li & Zhang, 2014).

Reference

Li Y, Zhang T. (2014) Targeting Cancer Stem Cells by Curcumin and Clinical Applications. Cancer Letters. 23 January 2014

Anti-cancer, cancer stem cells, Chapter 7 Isolates and Cancer Research, Chemoprevention, CSC, CSCs, EMT, Notch

Cancer stem cell (CSC)

microRNA

Action: Anti-cancer

The anticancer effect of curcumin has been demonstrated in many cell and animal studies, and recent research has shown that curcumin can target cancer stem cells (CSCs). CSCs are proposed to be responsible for initiating and maintaining cancer, and contribute to recurrence and drug resistance. A number of studies have suggested that curcumin has the potential to target CSCs through regulation of CSC self-renewal pathways (Wnt/β-catenin, Notch, Sonic Hedgehog) and specific microRNAs involved in acquisition of epithelial-mesenchymal transition (EMT). The potential impact of curcumin, alone or in combination with other anticancer agents, on CSCs was evaluated as well. Furthermore, the safety and tolerability of curcumin have been well-established by numerous clinical studies. Importantly, the low bioavailability of curcumin has been dramatically improved through the use of structural analogues or special formulations. More clinical trials are underway to investigate the efficacy of this promising agent in cancer chemoprevention and therapy. In this article, we review the effects of curcumin on CSC self-renewal pathways and specific microRNAs, as well as its safety and efficacy in recent human studies. In conclusion, curcumin could be a very promising adjunct to traditional cancer treatments (Li & Zhang, 2014).

Reference

Li Y, Zhang T. (2014) Targeting Cancer Stem Cells by Curcumin and Clinical Applications. Cancer Letters. 23 January 2014