Category Archives: Radio-sensitizer

Akt, angiogenesis, Anti-angiogenic, Anti-cancer, anti-inflammatory, Anti-metastatic, AP-1, apoptosis, BAX, Bcl-2, c-Fos, c-Jun, c-Myc, cell-cycle arrest, Cervical cancer, Chapter 7 Isolates and Cancer Research, Chemo-sensitizer, cytotoxic, ERK, G0/G1, G1, G2/M, IAP, IKK, IL-2, IL-6, Immune, Immunomodulatory, induces apoptosis, Lung cancer, Ovarian cancer, p16, p21, p53, PARP, pro-oxidative, Radio-sensitizer, radio-sensitizing, ROS, TIMP-2, TNF, XIAP

Saikosaponin

Cancers:
Cervical, colon, liver, lung, ovarian, liver, breast, hepatocellular

Action: Anti-angiogenic, anti-metastatic, chemo-sensitizer, pro-oxidative, cell-cycle arrest

T cell-mediated autoimmune, induces apoptosis, immune regulating, radio-sensitizer

Induces Apoptosis

Long dan xie gan tang, a well known Chinese herbal formulation, is commonly used by patients with chronic liver disease in China. Accumulated anecdotal evidence suggests that Long dan tang may have beneficial effects in patients with hepatocellular carcinoma. Long dan tang is comprised of five herbs: Gentiana root, Scutellaria root, Gardenia fruit, Alisma rhizome, and Bupleurum root. The cytotoxic effects of compounds from the five major ingredients isolated from the above plants, i.e. gentiopicroside, baicalein, geniposide, alisol B acetate and saikosaponin-d, respectively, on human hepatoma Hep3B cells, were investigated.

Annexin V immunofluorescence detection, DNA fragmentation assays and FACScan analysis of propidium iodide-staining cells showed that gentiopicroside, baicalein, and geniposide had little effect, whereas alisol B acetate and saikosaponin-d profoundly induced apoptosis in Hep3B cells. Alisol B acetate, but not saikosaponin-d, induced G2/M arrest of the cell-cycle as well as a significant increase in caspase-3 activity. Interestingly, baicalein by itself induced an increase in H(2)O(2) generation and the subsequent NF-kappaB activation; furthermore, it effectively inhibited the transforming growth factor-beta(1) (TGF-beta(1))-induced caspase-3 activation and cell apoptosis.

Results suggest that alisol B acetate and saikosaponin-d induced cell apoptosis through the caspase-3-dependent and -independent pathways, respectively. Instead of inducing apoptosis, baicalein inhibits TGF-beta(1)-induced apoptosis via increase in cellular H(2)O(2) formation and NF-kappaB activation in human hepatoma Hep3B cells (Chou, Pan, Teng & Guh, 2003).

Breast

Saikosaponin-A treatment of MDA-MB-231 for 3 hours and of MCF-7 cells for 2 hours, respectively, caused an obvious increase in the sub G1 population of cell-cycles.

Apoptosis in MDA-MB-231 cells was independent of the p53/p21 pathway mechanism and was accompanied by an increased ratio of Bax to Bcl-2 and c-myc levels and activation of caspase-3. In contrast, apoptosis of MCF-7 cells may have been initiated by the Bcl-2 family of proteins and involved p53/p21 dependent pathway mechanism, and was accompanied by an increased level of c-myc protein. The apoptosis of both MDA-MB-231 and MCF-7 cells showed a difference worthy of further research (Chen, Chang, Chung, & Chen, 2003).

Hepatocellular Carcinoma

The signaling pathway mediating induction of p15(INK4b) and p16(INK4a) during HepG2 growth inhibition triggered by the phorbol ester tumor promoter TPA (12-O-tetradecanoylphorbol 13-acetate) and the Chinese herbal compund Saikosaponin A was investigated.

Expressions of proto-oncogene c-jun, junB and c-fos were induced by TPA and Saikosaponin A between 30 minutes to 6 hours of treatment. Pre-treatment of 20 microg/ml PD98059, an inhibitor of MEK (the upstream kinase of ERK), prevents the TPA and Saikosaponin A triggered HepG2 growth inhibition by 50% and 30%, respectively. In addition, AP-1 DNA-binding assay, using non-isotopic capillary electrophoresis and laser-induced fluorescence (CE/LIF), demonstrated that the AP-1-related DNA-binding activity was significantly induced by TPA and Saikosaponin A, which can be reduced by PD98059 pre-treatment.

Results suggest that activation of ERK, together with its downstream transcriptional machinery, mediated p15(INK4b) and p16(INK4a) expression that led to HepG2 growth inhibition (Wen-Sheng, 2003).

The effects of Saikosaponin D (SSd) on syndecan-2, matrix metalloproteinases (MMPs) and tissue inhibitor of metalloproteinases-2 (TIMP-2) in livers of rats with hepatocellular carcinoma (HCC) was investigated.

The model group had more malignant nodules than the SSd group. Model-group HCC cells were grade III; SSd-group HCC cells were grades I-II. Controls showed normal hepatic cell phenotypes and no syndecan-2+ staining. Syndecan-2+ staining was greater in the model group (35.2%, P < or = 0.001) than in controls or the SSd group (16.5%, P < or = 0.001). The model group had more intense MMP-2+ staining than controls (0.37 vs 0.27, P< or =0.01) or the SSd group (0.31 vs 0.37, P< or =0.05); and higher MMP-13+ staining (72.55%) than in controls (12.55%, P< or =0.001) and SSd group (20.18%, P< or =0.01).

The model group also had more TIMP-2+ staining (57.2%) than controls (20.9%, P< or =0.001) and SSd group (22.7%, P< or=0.001). Controls and SSd group showed no difference in TIMP-2+ rates.

SSd inhibited HCC development, and downregulated expression of syndecan-2, MMP-2, MMP-13 and TIMP-2 in rat HCC liver tissue (Jia et al., 2012).

T Cell-mediated Autoimmune

Saikosaponin-d (Ssd) is a triterpene saponin derived from the medicinal plant, Bupleurum falcatum L. (Umbelliferae). Previous findings showed that Ssd exhibits a variety of pharmacological and immunomodulatory activities including anti-inflammatory, anti-bacterial, anti-viral and anti-cancer effects.

Results demonstrated that Ssd not only suppressed OKT3/CD28-costimulated human T cell proliferation, it also inhibited PMA, PMA/Ionomycin and Con A-induced mouse T cell activation in vitro. The inhibitory effect of Ssd on PMA-induced T cell activation was associated with down-regulation of NF-kappaB signaling through suppression of IKK and Akt activities. In addition, Ssd suppressed both DNA binding activity and the nuclear translocation of NF-AT and activator protein 1 (AP-1) of the PMA/Ionomycin-stimulated T cells. The cell surface markers, such as IL-2 receptor (CD25), were also down-regulated along with decreased production of pro-inflammatory cytokines of IL-6, TNF-alpha and IFN-gamma.

Results indicate that the NF-kappaB, NF-AT and AP-1 (c-Fos) signaling pathways are involved in the T cell inhibition evoked by Ssd. Ssd could be a potential candidate for further study in treating T cell-mediated autoimmune conditions (Wong, Zhou, Cheung, Li, & Liu, 2009).

Cervical Cancer

Saikosaponin-a and -d, two naturally occurring compounds derived from Bupleurum radix, have been shown to exert anti-cancer activity in several cancer cell lines. However, the effect of a combination of saikosaponins with chemotherapeutic drugs have never been addressed. Investigated as to whether these two saikosaponins have chemo-sensitization effect on cisplatin-induced cancer cell cytotoxicity was carried out.

Two cervical cancer cell lines, HeLa and Siha, an ovarian cancer cell line, SKOV3, and a non-small-cell lung cancer cell line, A549, were treated with saikosaponins or cisplatin individually or in combination. Cell death was quantitatively detected by the release of lactate dehydrogenase (LDH) using a cytotoxicity detection kit. Cellular ROS was analyzed by flow cytometry. Apoptosis was evaluated by AO/EB staining, flow cytometry after Anexin V and PI staining, and Western blot for caspase activation. ROS scavengers and caspase inhibitor were used to determine the roles of ROS and apoptosis in the effects of saikosaponins on cisplatin-induced cell death.

Both saikosaponin-a and -d sensitized cancer cells to cisplatin-induced cell death in a dose-dependent manner, which was accompanied with induction of reactive oxygen species (ROS) accumulation.

Results suggest that saikosaponins sensitize cancer cells to cisplatin through ROS-mediated apoptosis, and the combination of saikosaponins with cisplatin could be an effective therapeutic strategy (Wang et al., 2010).

Colon Cancer

Saikosaponin-a (SSa)-induced apoptosis of HCC cells was associated with proteolytic activation of caspase-9, caspase-3, and PARP cleavages and decreased levels of IAP family members, such as XIAP and c-IAP-2, but not of survivin. SSa treatment also enhanced the activities of caspase-2 and caspase-8, Bid cleavage, and the conformational activation of Bax. Moreover, inhibition of caspase-2 activation by the pharmacological inhibitor z-VDVAD-fmk, or by knockdown of protein levels using a si-RNA, suppressed SSa-induced caspase-8 activation, Bid cleavage, and the conformational activation of Bax. Although caspase-8 is an initiator caspase like caspase-2, the inhibition of caspase-8 activation by knockdown using a si-RNA did not suppress SSa-induced caspase-2 activation.

Results suggest that sequential activation of caspase-2 and caspase-8 is a critical step in SSa-induced apoptosis (Kim & Hong, 2011).

Immune Regulating

Tumor necrosis factor-alpha (TNF- α ) was reported as an anti-cancer therapy due to its cytotoxic effect against an array of tumor cells. However, its undesirable responses of TNF- α on activating NF- κB signaling and pro-metastatic property limit its clinical application in treating cancers. Therefore, sensitizing agents capable of overcoming this undesirable effect must be valuable for facilitating the usage of TNF- α -mediated apoptosis therapy for cancer patients. Previously, saikosaponin-d (Ssd), a triterpene saponin derived from the medicinal plant, Bupleurum falcatum L. (Umbelliferae), exhibited a variety of pharmacological activities such as anti-inflammatory, anti-bacterial, anti-viral and anti-cancer.

Investigation found that Ssd could potentially inhibit activated T lymphocytes via suppression of NF- κ B, NF-AT and AP-1 signaling. Ssd significantly potentiated TNF- α -mediated cell death in HeLa and HepG2 cancer cells via suppression of TNF- α -induced NF- κ B activation and its target genes expression involving cancer cell proliferation, invasion, angiogenesis and survival. Also, Ssd revealed a significant potency in abolishing TNF- α -induced cancer cell invasion and angiogenesis in HUVECs while inducing apoptosis via enhancing the loss of mitochondrial membrane potential in HeLa cells.

Collectively, findings indicate that Ssd has significant potential to be developed as a combined adjuvant remedy with TNF- α for cancer patients (Wong et al., 2013).

Radio-sensitizer

Saikosaponin-d (SSd), a monomer terpenoid purified from the Chinese herbal drug Radix bupleuri, has multiple effects, including anti-cancer properties. Treatment with SSd alone and radiation alone inhibited cell growth and increased apoptosis rate at the concentration used. These effects were enhanced when SSd was combined with radiation. Moreover, SSd potentiated the effects of radiation to induce G0/G1 arrest in SMMC-7721 hepatocellular carcinoma cells, and reduced the G2/M-phase population under hypoxia. SSd potentiates the effects of radiation on SMMC-7721 cells; thus, it is a promising radio-sensitizer. The radio-sensitizing effect of SSd may contribute to its effect on the G0/G1 and G2/M checkpoints of the cell-cycle (Wang et al., 2013).

References

Chen JC, Chang NW, Chung JG, Chen KC. (2003). Saikosaponin-A induces apoptotic mechanism in human breast MDA-MB-231 and MCF-7 cancer cells. The American Journal of Chinese Medicine, 31(3), 363-77.


Chou CC, Pan SL, Teng CM, Guh JH. (2003). Pharmacological evaluation of several major ingredients of Chinese herbal medicines in human hepatoma Hep3B cells. European Journal of Pharmaceutical Sciences, 19(5), 403-12.


Jia X, Dang S, Cheng Y, et al. (2012). Effects of saikosaponin-d on syndecan-2, matrix metalloproteinases and tissue inhibitor of metalloproteinases-2 in rats with hepatocellular carcinoma. Journal of Traditional Chinese Medicine, 32(3), 415-22.


Kim BM, Hong SH. (2011). Sequential caspase-2 and caspase-8 activation is essential for saikosaponin a-induced apoptosis of human colon carcinoma cell lines. Apoptosis, 16(2), 184-197. doi: 10.1007/s10495-010-0557-x.


Wang BF, Dai ZJ, Wang XJ, et al. (2013). Saikosaponin-d increases the radiosensitivity of smmc-7721 hepatocellular carcinoma cells by adjusting the g0/g1 and g2/m checkpoints of the cell-cycle. BMC Complementary and Alternative Medicine, 13:263. doi:10.1186/1472-6882-13-263


Wang Q, Zheng XL, Yang L, et al. (2010). Reactive oxygen species-mediated apoptosis contributes to chemo-sensitization effect of saikosaponins on cisplatin-induced cytotoxicity in cancer cells. Journal of Experimental & Clinical Cancer Research, 9(29), 159. doi: 10.1186/1756-9966-29-159.


Wen-Sheng, W. (2003). ERK signaling pathway is involved in p15INK4b/p16INK4a expression and HepG2 growth inhibition triggered by TPA and Saikosaponin A. Oncogene, 22(7), 955-963.


Wong VK, Zhang MM, Zhou H, et al. (2013). Saikosaponin-d Enhances the Anti-cancer Potency of TNF- α via Overcoming Its Undesirable Response of Activating NF-Kappa B Signaling in Cancer Cells. Evidence-based Complementary and Alternative Medicine, 2013(2013), 745295. doi: 10.1155/2013/745295.


Wong VK, Zhou H, Cheung SS, Li T, Liu L. (2009). Mechanistic study of saikosaponin-d (Ssd) on suppression of murine T lymphocyte activation. Journal of Cellular Biochemistry, 107(2), 303-15. doi: 10.1002/jcb.22126.

ABC, Anti-cancer, anti-inflammatory, apoptosis, apoptosis-inducing, Apoptotic, autophagic cell death, Autophagy, BAX, Breast cancer, Chapter 7 Isolates and Cancer Research, chemo-prevention, chemo-preventive, chemo-preventive activity, Chemo-preventive effects, Chemoprevention, Chemotherapy, chemotherapy-induced cytotoxicity, Colon Cancer or Colorectal cancer, enhances chemo-sensitivity, ER, Fibrosarcoma, induces apoptosis, Lung cancer, Lymphoma, MDR, Melanoma, Multi-Drug Resistance, Multi-drug resistance, Neuroblastoma, Pancreatic cancer, Pro-apoptotic, Prostate cancer, Radio-sensitizer, radiotherapy, ROS, Sarcoma, Skin cancer, TRAIL

Resveratrol 98%

Cancer:
Breast, lymphoma, breast, gastric, colorectal, esophageal, prostate, pancreatic, leukemia, skin, lung

Action: Chemoprevention, anti-inflammatory, MDR, chemotherapy-induced cytotoxicity, radio-sensitizer, enhances chemo-sensitivity

Resveratrol (RSV) is a phytoalexin found in food products including berries and grapes, as well as plants (including Fallopia japonica (Houtt.), Gnetum cleistostachyum (C. Y. Cheng), Vaccinium arboretum (Marshall), Vaccinium angustifolium (Aiton) and Vaccinium corymbosum (L.)

Although resveratrol is ubiquitous in nature, it is found in a limited number of edible substances, most notably in grapes. In turn, due to the peculiar processing methodology, resveratrol is found predominantly in red wines. Thus, resveratrol received intense and immediate attention. A large number of resveratrol anti-cancer activities were reported, affecting all the steps of cancerogenesis, namely initiation, promotion, and progression. Thereafter, an exponential number of reports on resveratrol accumulated and, so far, more than 5,000 studies have been published (Borriello et al., 2014).

Up to the end of 2011, more than 50 studies analyzed the effect of resveratrol as an anti-cancer compound in animal models of different cancers, including skin cancer (non-melanoma skin cancer and melanoma); breast, gastric, colorectal, esophageal, prostate, and pancreatic cancers; hepatoma, neuroblastoma, fibrosarcoma, and leukemia (Ahmad et al., 2004; Hayashibara et al., 2002; Pozo-Guisado et al., 2005; Mohan et al., 2006; Tang et al., 2006). In general, these preclinical studies suggest a positive activity of the molecule in lowering the progression of cancer, reducing its dimension, and decreasing the number of metastases (Vang et al., 2011).

Breast

Resveratrol was shown to have cancer chemo-preventive activity in assays representing three major stages of carcinogenesis. It has been found to mediate anti-inflammatory effects and inhibit cyclooxygenase and hydroperoxidase functions (anti-promotion activity). It has also been found to inhibit the development of pre-neoplastic lesions in carcinogen-treated mouse mammary glands in culture and inhibited tumorigenesis in a mouse skin cancer model (Jang et al., 1997).

In addition, resveratrol, a partial ER agonist itself, acts as an ER antagonist in the presence of estrogen leading to inhibition of human breast cancer cells (Lu et al., 1999).

Besides chemo-preventive effects, resveratrol appears to exhibit therapeutic effects against cancer itself. Limited data in humans have revealed that RSV is pharmacologically safe (Aggarwal et al., 2004).

Chemotherapy-Induced Cytotoxicity

RSV markedly enhanced Dox-induced cytotoxicity in MCF-7/adr and MDA-MB-231 cells. Treatment with a combination of RSV and Dox significantly increased the cellular accumulation of Dox by down-regulating the expression levels of ATP-binding cassette (ABC) transporter genes, MDR1, and MRP1. Further in vivo experiments in the xenograft model revealed that treatment with a combination of RSV and Dox significantly inhibited tumor volume by 60%, relative to the control group.

These results suggest that treatment with a combination of RSV and Dox would be a helpful strategy for increasing the efficacy of Dox by promoting an intracellular accumulation of Dox and decreasing multi-drug resistance in human breast cancer cells (Kim et al., 2013).

Radio-sensitizer/Lung Cancer

Previous studies indicated that resveratrol (RV) may sensitize tumor cells to chemotherapy and ionizing radiation (IR). However, the mechanisms by which RV increases the radiation sensitivity of cancer cells have not been well characterized. Here, we show that RV treatment enhances IR-induced cell killing in non-small-cell lung cancer (NSCLC) cells through an apoptosis-independent mechanism. Further studies revealed that the percentage of senescence-associated β-galactosidase (SA-β-gal)-positive senescent cells was markedly higher in cells treated with IR in combination with RV compared with cells treated either with IR or RV alone, suggesting that RV treatment enhances IR-induced premature senescence in lung cancer cells.

Collectively, these results demonstrate that RV-induced radio-sensitization is associated with significant increase of ROS production, DNA-DSBs and senescence induction in irradiated NSCLC cells, suggesting that RV treatment may sensitize lung cancer cells to radiotherapy via enhancing IR-induced premature senescence (Luo et al., 2013).

Lymphoma

Ko et al. (2011) examined the effects of resveratrol on the anaplastic large-cell lymphoma (ALCL) cell line SR-786. Resveratrol inhibited growth and induced cellular differentiation, as demonstrated by morphological changes and elevated expression of T cell differentiation markers CD2, CD3, and CD8. Resveratrol also triggered cellular apoptosis, as demonstrated by morphological observations, DNA fragmentation, and cell-cycle analyzes. Further, the surface expression of the death receptor Fas/CD95 was increased by resveratrol treatment. Our data suggest that resveratrol may have potential therapeutic value for ALCL.

Skin Cancer

Treatment with combinations of resveratrol and black tea polyphenol (BTP) also decreased expression of proliferating cell nuclear antigen in mouse skin tissues/tumors than their solitary treatments as determined by immunohistochemistry. In addition, histological and cell death analysis also confirmed that resveratrol and BTP treatment together inhibits cellular proliferation and markedly induces apoptosis. Taken together, results for the first time lucidly illustrate that resveratrol and BTP in combination impart better suppressive activity than either of these agents alone and accentuate that development of novel combination therapies/chemo-prevention using dietary agents will be more beneficial against cancer (George et al., 2011).

Prostate Cancer

Resveratrol-induced ROS production, caspase-3 activity and apoptosis were inhibited by N-acetylcysteine. Bax was a major pro-apoptotic gene mediating the effects of resveratrol as Bax siRNA inhibited resveratrol-induced apoptosis. Resveratrol enhanced the apoptosis-inducing potential of TRAIL, and these effects were inhibited by either dominant negative FADD or caspase-8 siRNA. The combination of resveratrol and TRAIL enhanced the mitochondrial dysfunctions during apoptosis. These properties of resveratrol strongly suggest that it could be used either alone or in combination with TRAIL for the prevention and/or treatment of prostate cancer (Shankar et al., 2007).

Breast Cancer

Scarlatti et al. (2008) demonstrate that resveratrol acts via multiple pathways to trigger cell death, induces caspase-dependent and caspase-independent cell death in MCF-7 casp-3 cells, induces only caspase-independent cell death in MCF-7vc cells, and stimulates macroautophagy. Using BECN1 and hVPS34 (human vacuolar protein sorting 34) small interfering RNAs, they demonstrated that resveratrol activates Beclin 1-independent autophagy in both cell lines, whereas cell death via this uncommon form of autophagy occurs only in MCF-7vc cells. They also show that this variant form of autophagic cell death is blocked by the expression of caspase-3, but not by its enzymatic activity. In conclusion, this study reveals that non-canonical autophagy induced by resveratrol can act as a caspase-independent cell death mechanism in breast cancer cell.

References

Aggarwal BB, Bhardwaj A, Aggarwal RS et al. (2004). Role of Resveratrol in Prevention and Therapy of Cancer: Preclinical and Clinical Studies. Anti-cancer Research, 24(5A): 2783-2840.


Ahmad KA, Clement MV, Hanif IM, et al (2004). Resveratrol inhibits drug-induced apoptosis in human leukemia cells by creating an intracellular milieu nonpermissive for death execution. Cancer Res, 64:1452–1459


Borriello A, Bencivenga D, Caldarelli I, et al. (2014). Resveratrol: from basic studies to bedside. Cancer Treat Res, 159:167-84. doi: 10.1007/978-3-642-38007-5_10.


George J, Singh M, Srivastava AK, et al (2011). Resveratrol and black tea polyphenol combination synergistically suppress mouse skin tumors growth by inhibition of activated MAPKs and p53. PLoS ONE, 6:e23395


Hayashibara T, Yamada Y, Nakayama S, et al (2002). Resveratrol induces down-regulation in survivin expression and apoptosis in HTLV-1-infected cell lines: a prospective agent for adult T cell leukemia chemotherapy. Nutr Cancer, 44:193–201


Jang M, Cai L, Udeani GO, et al. (1997). Cancer Chemo-preventive Activity of Resveratrol, a Natural Product Derived from Grapes. Science, 275(5297):218-220.


Kim TH, Shin YJ, Won AJ, et al. (2013). Resveratrol enhances chemosensitivity of doxorubicin in Multi-drug-resistant human breast cancer cells via increased cellular influx of doxorubicin. Biochim Biophys Acta, S0304-4165(13)00463-7. doi: 10.1016/j.bbagen.2013.10.023.


Ko YC, Chang CL, Chien HF, et al (2011). Resveratrol enhances the expression of death receptor Fas/CD95 and induces differentiation and apoptosis in anaplastic large-cell lymphoma cells. Cancer Lett, 309:46–53


Lu R, Serrero G. (1999). Resveratrol, a natural product derived from grape, exhibits antiestrogenic activity and inhibits the growth of human breast cancer cells. Journal of Cellular Physiology, 179(3):297-304.


Luo H, Wang L, Schulte BA, et al. (2013). Resveratrol enhances ionizing radiation-induced premature senescence in lung cancer cells. Int J Oncol, 43(6):1999-2006. doi: 10.3892/ijo.2013.2141.


Mohan J, Gandhi AA, Bhavya BC, et al. (2006). Caspase-2 triggers Bax-Bak-dependent and – independent cell death in colon cancer cells treated with resveratrol. J Biol Chem, 281:17599–17611


Pozo-Guisado E, Merino JM, Mulero-Navarro S, et al. (2005). Resveratrol-induced apoptosis in MCF-7 human breast cancer cells involves a caspase-independent mechanism with down-regulation of Bcl-2 and NF-kappaB. Int J Cancer, 115:74–84.


Scarlatti F, Maffei R, Beau I, et al (2008). Role of non-canonical Beclin 1-independent autophagy in cell death induced by resveratrol in human breast cancer cells. Cell Death Differ, 8:1318–1329


Shankar S, Siddiqui I, Srivastava RK. (2007). Molecular mechanisms of resveratrol (3,4,5- trihydroxy-trans-stilbene) and its interaction with TNF-related apoptosis inducing ligand (TRAIL) in androgen-insensitive prostate cancer cells. Mol Cell Biochem, 304:273–285


Tang HY, Shih A, Cao HJ, et al. (2006). Resveratrol-induced cyclooxygenase-2 facilitates p53-dependent apoptosis in human breast cancer cells. Mol Cancer Ther, 5:2034–2042


Vang O, Ahmad N, Baile CA, et al. (2011). What is new for an old molecule? Systematic review and recommendations on the use of resveratrol. PLoS ONE, 6:e19881

A549, anti-tumor, anti-tumor activity, apoptosis, Apoptotic, BAX, Bcl-2, Breast cancer, CDC2, cell-cycle arrest, Chapter 7 Isolates and Cancer Research, COX-2, G2/M, induces apoptosis, Lung cancer, MCF-7, p21, p53, Panc-28, Pancreatic cancer, PC3, Pro-apoptotic, pro-apoptotic with 5-FU, Prostate cancer, Radio-sensitizer, radio-sensitizing, ROS

Oleanolic Acid (OA)

Cancer:
Pancreatic, hepatocellular carcinoma, prostate, lung, gastric, breast

Action: Radio-sensitizer, pro-apoptotic with 5-FU

Oleanolic acid (OA), a pentacyclic triterpenoid isolated from several plants, including Rosa woodsii (Lindl.), Prosopis glandulosa (Torr.), Phoradendron juniperinum (Engelm. ex A. Gray), Syzygium claviflorum (Roxburgh), Hyptis capitata (Jacq.) and Ternstromia gymnanthera (L.) exhibits potential anti-tumor activity against many tumor cell lines. Mistletoe contains water-insoluble triterpenoids, mainly oleanolic acid, that have anti-tumorigenic effects (StrŸh et al., 2013).

Pancreatic Cancer

Results of a study by Wei et al. (2012) showed that the proliferation of Panc-28 cells was inhibited by OA in a concentration-dependent manner, with an IC50 (The half maximal inhibitory concentration) value of 46.35 µg ml−1. The study also showed that OA could induce remarkable apoptosis and revealed that OA could induce Reactive Oxygen Species (ROS) generation, mitochondrial depolarization, release of cytochrome C, lysosomal membrane permeabilization and leakage of cathepin B. Further study confirmed that ROS scavenger vitamin C could reverse the apoptosis induced by OA in Panc-28 cells.

These results provide evidence that OA arrests the cell-cycle and induces apoptosis, possibly via ROS-mediated mitochondrial and a lysosomal pathway in Panc-28 cell.

The effects of the combination of OA and 5-fluorouracil (5-FU) on Panc-28 human pancreatic cells showed that combined use synergistically potentiated cell death effects on these cells, and that the pro-apoptotic effects were also increased. The expression of apoptosis related proteins was also affected in cells treated with the combination of OA and 5-FU, including activation of caspases-3 and the expression of Bcl-2/Bax, survivin and NF-κB (Wei et al., 2012).

Radio-sensitizer

The combined treatment of radiation with OA significantly decreased the clonogenic growth of tumor cells and enhanced the numbers of intracellular MN compared to irradiation alone. Furthermore, it was found that the synthesis of cellular GSH was inhibited concomitantly with the down-regulation of γ-GCS activity. Therefore, the utilization of OA as a radio-sensitizing agent for irradiation-inducing cell death offers a potential therapeutic approach to treat cancer (Wang et al., 2013).

Prostate Cancer, Lung Cancer, Gastric Cancer, Breast Cancer

Twelve derivatives of oleanolic acid (OA) have been synthesized and evaluated for their inhibitory activities against the growth of prostate PC3, breast MCF-7, lung A549, and gastric BGC-823 cancer cells by MTT assays. Within these series of derivatives, compound 17 exhibited the most potent cytotoxicity against PC3 cell line (IC50=0.39 µM) and compound 28 displayed the best activity against A549 cell line (IC50=0.22 µM). SAR analysis indicates that H-donor substitution at C-3 position of oleanolic acid may be advantageous for improvement of cytotoxicity against PC3, A549 and MCF-7 cell lines (Hao et al., 2013).

Hepatocellular Carcinoma

OA induced G2/M cell-cycle arrest through p21-mediated down-regulation of cyclin B1/cdc2. Cyclooxygenase-2 (COX-2) and p53 were involved in OA-exerted effect, and extracellular signal-regulated kinase-p53 signaling played a central role in OA-activated cascades responsible for apoptosis and cell-cycle arrest. OA demonstrated significant anti-tumor activities in hepatocellular carcinoma (HCC) in vivo and in vitro models. These data provide new insights into the mechanisms underlying the anti-tumor effect of OA (Wang et al., 2013).

References

Hao J, Liu J, Wen X, Sun H. (2013). Synthesis and cytotoxicity evaluation of oleanolic acid derivatives. Bioorg Med Chem Lett, 23(7):2074-7. doi: 10.1016/j.bmcl.2013.01.129.


StrŸh CM, JŠger S, Kersten A, et al. (2013). Triterpenoids amplify anti-tumoral effects of mistletoe extracts on murine B16.f10 melanoma in vivo. PLoS One, 8(4):e62168. doi: 10.1371/journal.pone.0062168.


Wang J, Yu M, Xiao L, et al. (2013). Radio-sensitizing effect of oleanolic acid on tumor cells through the inhibition of GSH synthesis in vitro. Oncol Rep, 30(2):917-24. doi: 10.3892/or.2013.2510.


Wang X, Bai H, Zhang X, et al. (2013). Inhibitory effect of oleanolic acid on hepatocellular carcinoma via ERK-p53-mediated cell-cycle arrest and mitochondrial-dependent apoptosis. Carcinogenesis, 34(6):1323-30. doi: 10.1093/carcin/bgt058.


Wei JT, Liu M, Liuz, et al. (2012). Oleanolic acid arrests cell-cycle and induces apoptosis via ROS-mediated mitochondrial depolarization and lysosomal membrane permeabilization in human pancreatic cancer cells. Journal of Applied Toxicology, 33(8):756–765. doi: 10.1002/jat.2725


Wei J, Liu H, Liu M, et al. (2012). Oleanolic acid potentiates the anti-tumor activity of 5-fluorouracil in pancreatic cancer cells. Oncol Rep, 28(4):1339-45. doi: 10.3892/or.2012.1921.

anti-tumor, anti-tumor activity, apoptosis, Chapter 7 Isolates and Cancer Research, cytotoxic, Melanoma, PC3, PC3 and DU145, Prostate cancer, Prostate cancer cell lines, Radio-sensitizer, radio-sensitizing, U251

Oleandrin

Cancer: Prostate, glioma, melanoma

Action: Radio-sensitizer

Anvirzel is an extract of Nerium oleander (L.) currently undergoing, as Anvirzelª Phase I clinical evaluation as a potential treatment for cancer. Two of the active components of Anvirzel are the cardiac glycosides, oleandrin and oleandrigenin.

Prostate Cancer

In continuing research on the anti-tumor activity of this novel plant extract, the relative abilities of oleandrin and oleandrigenin to inhibit FGF-2 export from two human prostate cancer cell lines, DU145 and PC3, were examined. An ELISA assay was utilized to determine the FGF-2 concentration in the cell culture medium before and after exposure to cardiac glycosides or the parent extract material Anvirzel.

Studies also were conducted with Anvirzel (a hot water extract of Nerium oleander, known as Anvirzelª) and ouabain (found in the ripe seeds of African plants Strophanthus gratus). Oleandrin (0.1 ng/mL) produced a 45.7% inhibition of FGF-2 release from PC3 cells and a 49.9% inhibition from DU145 cells. Non-cytotoxic concentrations (100 ng/mL) of Anvirzel produced a 51.9% and 30.8% inhibition of FGF-2 release, respectively, in the two cell lines. These results demonstrate that Anvirzel, like oleandrin, inhibited FGF-2 export in vitro from PC3 and DU145 prostate cancer cells in a concentration- and time-dependent fashion and may, therefore, contribute to the anti-tumor activity of this novel treatment for cancer (Smith et al., 2001).

Radio-sensitizers; Prostate Cancer

In the present study Nasu et al. (2002) explored the relative radio-sensitization potential of oleandrin, a cardiac glycoside contained within the plant extract known as Anvirzelª. The data show that oleandrin produces an enhancement of sensitivity of PC-3 human prostate cells to radiation; at a cell survival of 0.1, the enhancement factor was 1.32. The magnitude of radio-sensitization depended on duration of exposure of cells to drug prior to radiation treatment.

While a radio-sensitizing effect of oleandrin was evident with only 1 hour of cell exposure to drug, the effect greatly increased with 24 hours of oleandrin pre-treatment.

Activation was greatest when cells were exposed simultaneously to oleandrin and radiation. Inhibition of caspase-3 activation with Z-DEVD-FMK abrogated the oleandrin-induced enhancement of radiation response suggesting that both oleandrin and radiation share a caspase-3 dependent mechanism of apoptosis in the PC-3 cell line.

Glioma, Melanoma

Twelve human tumor cell lines were chosen to examine determinants of human tumor cell sensitivity to cardiac glycosides. In vitro cell culture models of human glioma HF U251 and U251 cells as well as human parental and modified melanoma BRO cells were also included in these studies. Cardiac glycosides such as oleandrin, ouabain and bufalin increased expression of Na+, K+ -ATPase alpha 1 and therefore total Na+, K+ -ATPase activity, which is associated with increased cellular levels of glutathione. Additionally, an increased colony-forming ability was noted in cells with high levels of Na+, K+ -ATPase alpha 1 expression, suggesting that Na+, K+ -ATPase alpha 1 isoform may be actively involved in tumor growth and cell survival (Lin, Ho, & Newman, 2010)

References

Lin Y, Ho DH, Newman RA. (2010). Human tumor cell sensitivity to oleandrin is dependent on relative expression of Na+, K+ -ATPase subunitst. J Exp Ther Oncol, 8(4):271-86.


Nasu S, Milas L, Kawabe S, Raju U, Newman R. (2002). Enhancement of radiotherapy by oleandrin is a caspase-3 dependent process. Cancer Letters, 185(2):145–151. doi:10.1016/S0304-3835(02)00263-X


Smith JA, Madden T, Vijjeswarapu M, Newman RA. (2001). Inhibition of export of fibroblast growth factor-2 (FGF-2) from the prostate cancer cell lines PC3 and DU145 by anvirzel and its cardiac glycoside component, oleandrin. Biochemical Pharmacology, 62(4):469-472. doi:10.1016/S0006-2952(01)00690-6.

angiogenesis, Anti-cancer, Anti-cancer effect, anti-tumor, anti-tumor activity, apoptosis, Apoptotic, BAX, Bcl-2, BCR, Breast cancer, CAM, CDC2, CDC25C, CDK4, cell-cycle arrest, Chapter 7 Isolates and Cancer Research, Endometrial cancer, ER, ER modulator, ERK, G2/M, Hec1A, KIP1, MCF-7, MCF7, MDA-MB-453, p16, p27, PC3, Pro-apoptotic, Radio-sensitizer, several species of the genus Epimedium

Icaritin

Cancer:
Endometrial., chronic myeloid leukemia, prostate, breast

Action: Radio-sensitizer, cell-cycle arrest, ER modulator

Icaritin is a compound in several species of the genus Epimedium (L.).

Cell-cycle Arrest

Icariin and icaritin with prenyl group have been demonstrated to have selective estrogen receptor modulating activities. Icaritin-induced growth inhibition was associated with G(1) arrest (P<0.05), and G(2)-M arrest depending upon doses. Consistent with G(1) arrest, icaritin increased protein expressions of pRb, p27(Kip1) and p16(Ink4a), while showing decrease in phosphorylated pRb, Cyclin D1 and CDK4.

Comparatively, icariin has much lower effects on PC-3 cells and showed only weak G(1) arrest, suggesting a possible structure-activity relationship. These findings suggested a novel anti-cancer efficacy of icaritin mediated selectively via induction of cell-cycle arrest but not associated with estrogen receptors in PC-3 cells (Huang et al., 2007).

Estrogen Receptor (ER) Modulator; Endometrial Cancer

Icaritin has selective estrogen receptor (ER) modulating activities, and posseses anti-tumor activity. The effect of icaritin on cell growth of human endometrial cancer Hec1A cells was investigated and it was found that icaritin potently inhibited proliferation of Hec1A cells. Icaritin also induced cell apoptosis accompanied by activation of caspases. Icaritin treatment also induced expression of pro-apoptotic protein Bax with a concomitant decrease of Bcl-2 expression.

These results demonstrate that icaritin induced sustained ERK 1/2 activation and inhibited growth of endometrial cancer Hec1A cells, and provided a rationale for preclinical and clinical evaluation of icaritin for endometrial cancer therapy (Tong et al., 2011).

Breast cancer

In research carried out to probe breast cancer cell growth mechanisms, icaritin has been found to strongly inhibit the growth of breast cancer MDA-MB-453 and MCF7 cells. At concentrations of 2–3 µM, icaritin induced cell-cycle arrest at the G2/M phase accompanied by a down-regulation of the expression levels of the G2/M regulatory proteins such as cyclinB, cdc2 and cdc25C.

Icaritin at concentrations of 4–5 µM, however, induced apoptotic cell death. In addition, icaritin also induced a sustained phosphorylation of extracellular signal-regulated kinase (ERK) in these breast cancer cells.

Icaritin more potently inhibited growth of the breast cancer stem/progenitor cells compared to anti-estrogen tamoxifen. These results indicate that icaritin is a potent growth inhibitor for breast cancer cells and provides a rationale for preclinical and clinical evaluations of icaritin for breast cancer therapy (Guo et al., 2011).

Radio-sensitizer

The combination of Icaritin at 3 µM or 6 µM with 6 or 8 Gy of ionizing radiation (IR) in the clonogenic assay yielded an ER (enhancement ratio) of 1.18 or 1.28, CI (combination index) of 0.38 or 0.19 and DRI (dose reducing index) of 2.51 or 5.07, respectively. These findings strongly suggest that Icaritin exerted a synergistic killing effect with radiation on the tumor cells. It suppressed angiogenesis in chick embryo chorioallantoic membrane (CAM) assay. These results, taken together, indicate Icaritin is a new radio-sensitizer and can enhance anti-cancer effect of IR or other therapies (Hong et al., 2013).

Chronic Myeloid Leukemia (CML)

The mechanism of anti-leukemia for Icaritin is involved in the regulation of Bcr/Abl downstream signaling. Icaritin may be useful for an alternative therapeutic choice of Imatinib-resistant forms of CML. Icaritin potently inhibited proliferation of K562 cells (IC50 was 8 µM) and primary CML cells (IC50 was 13.4 µM for CML-CP and 18 µM for CML-BC), induced CML cells apoptosis, and promoted the erythroid differentiation of K562 cells in a time-dependent manner. Furthermore, Icaritin was able to suppress the growth of primary CD34+ leukemia cells (CML) and Imatinib-resistant cells, and to induce apoptosis (Zhu et al., 2011).

References

Guo YM, Zhang XT, Meng J, Wang ZY. (2011). An anti-cancer agent icaritin induces sustained activation of the extracellular signal-regulated kinase (ERK) pathway and inhibits growth of breast cancer cells. European Journal of Pharmacology, 658(2–3):114–122. doi:10.1016/j.ejphar.2011.02.005.


Hong J, Zhang Z, Lv W, et al. (2013). Icaritin Synergistically Enhances the Radiosensitivity of 4T1 Breast Cancer Cells. PLoS One, 8(8):e71347. doi: 10.1371/journal.pone.0071347.


Huang X, Zhu D, Lou Y. (2007). A novel anti-cancer agent, icaritin, induced cell growth inhibition, G1 arrest and mitochondrial transmembrane potential drop in human prostate carcinoma PC-3 cells. Eur J Pharmacol, 564(1-3):26-36.


Tong JS, Zhang QH, Huang X, et al. (2011). Icaritin Causes Sustained ERK1/2 Activation and Induces Apoptosis in Human Endometrial Cancer Cells. PLoS ONE, 6(3): e16781. doi:10.1371/journal.pone.0016781.


Zhu JF, Li ZJ, Zhang GS, et al. (2011). Icaritin shows potent anti-leukemia activity on chronic myeloid leukemia in vitro and in vivo by regulating MAPK/ERK/JNK and JAK2/STAT3 /AKT signalings. PLoS One, 6(8):e23720. doi: 10.1371/journal.pone.0023720.

A375 and Hs294, A431, angiogenesis, anti-apoptotic, Anti-cancer, Anti-cancer effect, anti-inflammatory, Anti-metastatic, anti-oxidant, anti-oxidative, anti-proliferative, anti-proliferative effect, apoptosis, apoptosis induction, Apoptotic, Autophagy, BAX, Bcl-2, Bcl-xL, BCRP/ABCG2, Berberis amurensis, BIU-87 and T24, Breast cancer, Breast cancer cell lines, CDK, cell-cycle arrest, Cervical cancer, Chapter 7 Isolates and Cancer Research, chemo-enhancing, chemo-preventive, Chemo-preventive agent, Chemoprevention, Chemotherapy, Colon Cancer or Colorectal cancer, COX-2, cytotoxic, Diarrhea or Constipation, ER, ER-negative, ER-positive, FAK, G0/G1, G1, growth-inhibitory, hepato-protective, HIF, HL-60, inflammation, Leukemia, Liver cancer, LNCaP, DU145, PC-3, Lymphoma, MCF-7, MCF-7, MDA-MB-231, Melanoma, metastasis, Nitric Oxide, OVCAR-3, SKOV-3, PARP, PC3, PGE2, Pro-apoptotic, Prostate cancer, Radio-sensitizer, radiotherapy, ROS, SiHa and CaSki, Skin cancer, T98G, type, u-PA, VEGF, VEGF

Berberine

Cancer:
Liver,leukemia, breast, prostate, epidermoid (squamous-cell carcinoma), cervical.,testicular, melanoma, lymphoma, hepatoma

Action: Radio-sensitizer, anti-inflammatory, cell-cycle arrest, angiogenesis, chemo-enhancing, anti-metastatic, anti-oxidative

Berberine is a major phytochemical component of the roots and bark of herbal plants such as Berberis, Hydrastis canadensis and Coptis chinensis. It has been implicated in the cytotoxic effects on multiple cancer cell lines.

Anti-inflammatory

Berberine is an isoquinoline alkaloid widely distributed in natural herbs, including Rhizoma Coptidis chinensis and Epimedium sagittatum (Sieb. et Zucc.), a widely prescribed Chinese herb (Chen et al., 2008). It has a broad range of bioactivities, such as anti-inflammatory, anti-bacterial., anti-diabetes, anti-ulcer, sedation, protection of myocardial ischemia-reperfusion injury, expansion of blood vessels, inhibition of platelet aggregation, hepato-protective, and neuroprotective effects (Lau et al., 2001; Yu et al., 2005; Kulkarni & Dhir, 2010; Han et al., 2011; Ji, 2011). Berberine has been used in the treatment of diarrhea, neurasthenia, arrhythmia, diabetes, and so forth (Ji, 2011).

Angiogenesis, Chemo-enhancing

Inhibition of tumor invasion and metastasis is an important aspect of berberine's anti-cancer activities (Tang et al., 2009; Ho et al., 2009). A few studies have reported berberine's inhibition of tumor angiogenesis (Jie et al., 2011; Hamsa & Kuttan, 2012). In addition, its combination with chemotherapeutic drugs or irradiation could enhance the therapeutic effects (Youn et al., 2008; Hur et al., 2009).

Cell-cycle Arrest

The potential molecular targets and mechanisms of berberine are rather complicated. Berberine interacts with DNA or RNA to form a berberine-DNA or a berberine-RNA complex, respectively (Islam & Kumar. 2009; Li et al., 2012). Berberine is also identified as an inhibitor of several enzymes, such as N-acetyltransferase (NAT), cyclooxygenase-2 (COX-2), and telomerase (Sun et al., 2009).

Other mechanisms of berberine are mainly related to its effect on cell-cycle arrest and apoptosis, including regulation of cyclin-dependent kinase (CDK) family of proteins (Sun et al., 2009; Mantena, Sharma, & Katiyar, 2006) and expression regulation of B-cell lymphoma 2 (Bcl-2) family of proteins (such as Bax, Bcl-2, and Bcl-xL) (Sun et al., 2009), and caspases (Eom et al., 2010; Mantena, Sharma, & Katiyar, 2006). Furthermore, berberine inhibits the activation of the nuclear factor κ-light-chain-enhancer of activated B cells (NF-κB) and induces the formation of intracellular reactive oxygen species (ROS) in cancer cells (Sun et al., 2009; Eom et al., 2010). Interestingly, these effects might be specific for cancer cells (Sun et al., 2009).

Several studies have shown that berberine has anti-cancer potential by interfering with the multiple aspects of tumorigenesis and tumor progression in both in vitro and in vivo experiments. These observations have been well summarized in recent reports (Sun et al., 2009; Tan et al., 2011). Berberine inhibits the proliferation of multiple cancer cell lines by inducing cell-cycle arrest at the G1 or G 2 / M phases and by apoptosis (Sun et al., 2009; Eom et al., 2010; Burgeiro et al., 2011). In addition, berberine induces endoplasmic reticulum stress (Chang et al., 1990; Eom et al., 2010) and autophagy (Wang et al., 2010) in cancer cells.

However, compared with clinically prescribed anti-cancer drugs, the cytotoxic potency of berberine is much lower, with an IC50 generally at 10 µM to 100 µM depending on the cell type and treatment duration in vitro (Sun et al., 2009). Besides, berberine also induces morphologic differentiation in human teratocarcinoma (testes) cells (Chang et al., 1990).

Anti-metastatic

The effect of berberine on invasion, migration, metastasis, and angiogenesis is mediated through the inhibition of focal adhesion kinase (FAK), NF-κB, urokinase-type plasminogen-activator (u-PA), matrix metalloproteinase 2 (MMP-2), and matrix metalloproteinase 9 (MMP-9) (Ho et al., 2009; Hamsa & Kuttan. (2011); reduction of Rho kinase-mediated Ezrin phosphorylation (Tang et al., 2009); reduction of the expression of COX-2, prostaglandin E, and prostaglandin E receptors (Singh et al., 2011); down-regulation of hypoxia-inducible factor 1 (HIF-1), vascular endothelial growth factor (VEGF), pro-inflammatory mediators (Jie et al., 2011; Hamsa & Kuttan, 2012).

Hepatoma, Leukaemia

The cytotoxic effects of Coptis chinensis extracts and their major constituents on hepatoma and leukaemia cells in vitro have been investigated. Four human liver cancer cell lines, namely HepG2, Hep3B, SK-Hep1 and PLC/PRF/5, and four leukaemia cell lines, namely K562, U937, P3H1 and Raji, were investigated. C. chinensis exhibited strong activity against SK-Hep1 (IC50 = 7 microg/mL) and Raji (IC50 = 4 microg/mL) cell lines. Interestingly, the two major compounds of C. chinensis, berberine and coptisine, showed a strong inhibition on the proliferation of both hepatoma and leukaemia cell lines. These results suggest that the C. chinensis extract and its major constituents berberine and coptisine possess active anti-hepatoma and anti-leukaemia activities (Lin, 2004).

Leukemia

The steady-state level of nucleophosmin/B23 mRNA decreased during berberine-induced (25 g/ml, 24 to 96 hours) apoptosis of human leukemia HL-60 cells. A decline in telomerase activity was also observed in HL-60 cells treated with berberine. A stable clone of nucleophosmin/B23 over-expressed in HL-60 cells was selected and found to be less responsive to berberine-induced apoptosis. About 35% to 63% of control vector–transfected cells (pCR3) exhibited morphological characteristics of apoptosis, while about 8% to 45% of nucleophosmin/B23-over-expressed cells (pCR3-B23) became apoptotic after incubation with 15 g/ml berberine for 48 to 96 hours.

These results indicate that berberine-induced apoptosis is associated with the down-regulation of nucleophosmin/B23 and telomerase activity. Nucleophosmin/B23 may play an important role in the control of the cellular response to apoptosis induction (Hsing, 1999).

Prostate Cancer

In vitro treatment of androgen-insensitive (DU145 and PC-3) and androgen-sensitive (LNCaP) prostate cancer cells with berberine inhibited cell proliferation and induced cell death in a dose-dependent (10-100 micromol/L) and time-dependent (24–72 hours) manner. Berberine significantly (P < 0.05-0.001) enhanced apoptosis of DU145 and LNCaP cells with induction of a higher ratio of Bax/Bcl-2 proteins, disruption of mitochondrial membrane potential., and activation of caspase-9, caspase-3, and poly(ADP-ribose) polymerase.

The effectiveness of berberine in checking the growth of androgen-insensitive, as well as androgen-sensitive, prostate cancer cells without affecting the growth of normal prostate epithelial cells indicates that it may be a promising candidate for prostate cancer therapy (Mantena, 2006).

In another study, the treatment of human prostate cancer cells (PC-3) with berberine-induced dose-dependent apoptosis; however, this effect of berberine was not seen in non-neoplastic human prostate epithelial cells (PWR-1E). Berberine-induced apoptosis was associated with the disruption of the mitochondrial membrane potential., release of apoptogenic molecules (cytochrome c and Smac/DIABLO) from mitochondria and cleavage of caspase-9,-3 and PARP proteins.

Berberine-induced apoptosis was blocked in the presence of the anti-oxidant, N-acetylcysteine, through the prevention of disruption of mitochondrial membrane potential and subsequently release of cytochrome c and Smac/DIABLO. Taken together, these results suggest that the berberine-mediated cell death of human prostate cancer cells is regulated by reactive oxygen species, and therefore suggests that berberine may be considered for further studies as a promising therapeutic candidate for prostate cancer (Meeran, 2008).

Breast Cancer

DNA microarray technology has been used to understand the molecular mechanism underlying the anti-cancer effect of berberine carcinogenesis in two human breast cancer cell lines, the ER-positive MCF-7 and ER-negative MDA-MB-231 cells; specifically, whether it affects the expression of cancer-related genes. Treatment of the cancer cells with berberine markedly inhibited their proliferation in a dose- and time-dependent manner. The growth-inhibitory effect was much more profound in MCF-7 cell line than that in MDA-MB-231 cells.

IFN-β is among the most important anti-cancer cytokines, and the up-regulation of this gene by berberine is, at least in part, responsible for its anti-proliferative effect. The results of this study implicate berberine as a promising extract for chemoprevention and chemotherapy of certain cancers (Kang, 2005).

Breast Cancer Metastasis

Berberine also inhibits the growth of Anoikis-resistant MCF-7 and MDA-MB-231 breast cancer cell lines by inducing cell-cycle arrest. Anoikis, or detachment-induced apoptosis, may prevent cancer progression and metastasis by blocking signals necessary for survival of localized cancer cells. Resistance to anoikis is regarded as a prerequisite for metastasis; however, little is known about the role of berberine in anoikis-resistance.

The anoikis-resistant cells have a reduced growth rate and are more invasive than their respective adherent cell lines. The effect of berberine on growth was compared to that of doxorubicine, which is a drug commonly used to treat breast cancer, in both the adherent and anoikis-resistant cell lines. Berberine promoted the growth inhibition of anoikis-resistant cells to a greater extent than doxorubicine treatment. Treatment with berberine-induced cell-cycle arrest at G0/G1 in the anoikis-resistant MCF-7 and MDA-MB-231 cells was compared to untreated control cells. These results reveal that berberine can efficiently inhibit growth by inducing cell-cycle arrest in anoikis-resistant MCF-7 and MDA-MB-231 cells. Further analysis of these phenotypes is essential for understanding the effect of berberine on anoikis-resistant breast cancer cells, which would be relevant for the therapeutic targeting of breast cancer metastasis (Kim, 2010).

Melanoma

Berberine inhibits melanoma cancer cell migration by reducing the expressions of cyclooxygenase-2, prostaglandin E2 and prostaglandin E2 receptors. The effects and associated molecular mechanism of berberine on human melanoma cancer cell migration using melanoma cell lines A375 and Hs294 were probed in an in vitro cell migration assay, indicating that over- expression of cyclo-oxygenase (COX)-2, its metabolite prostaglandin E2 (PGE2) and PGE2 receptors promote the migration of cells.

Moreover, berberine inhibited the activation of nuclear factor-kappa B (NF-kB), an up- stream regulator of COX-2, in A375 cells, and treatment of cells with caffeic acid phenethyl ester, an inhibitor of NF-kB, inhibited cell migration. Together, these results indicate that berberine inhibits melanoma cell migration, an essential step in invasion and metastasis, by inhibition of COX-2, PGE2 and PGE2 receptors (Sing, 2011).

Cell-cycle Arrest, Squamous-cell Carcinoma

The in vitro treatment of human epidermoid carcinoma A431 cells with berberine decreases cell viability and induces cell death in a dose (5-75 microM)- and time (12–72 hours)-dependent manner, which was associated with an increase in G(1) arrest. G(0)/G(1) phase of the cell-cycle is known to be controlled by cyclin dependent kinases (Cdk), cyclin kinase inhibitors (Cdki) and cyclins.

Pre-treatment of A431 cells with the pan-caspase inhibitor (z-VAD-fmk) significantly blocked the berberine-induced apoptosis in A431 cells confirmed that berberine-induced apoptosis is mediated through activation of caspase 3-dependent pathway.

Together, these results indicate berberine as a chemotherapeutic agent against human epidermoid carcinoma A431 (squamous-cell) cells in vitro; further in vivo studies are required to determine whether berberine could be an effective chemotherapeutic agent for the management of non-melanoma skin cancers (Mantena, 2006).

Cervical Cancer, Radio-sensitizer

Cervical cancer remains one of the major killers amongst women worldwide. In India, a cisplatin based chemo/radiotherapy regimen is used for the treatment of advanced cervical cancer. Evidence shows that most of the chemotherapeutic drugs used in current clinical practice are radio-sensitizers. Natural products open a new avenue for treatment of cancer, as they are generally tolerated at high doses. Animal studies have confirmed the anti-tumorigenic activity of natural products, such as curcumin and berberine.

Berberine is a natural chemo-preventive agent, extracted from Berberis aristata, which has been shown to suppress and retard carcinogenesis by inhibiting inflammation.

The combined therapy of cisplatin/berberine and radiotherapy produced up-regulation of pro-apoptotic proteins Bax and p73, while causing down regulation of the anti-apoptotic proteins Bcl-xL, COX-2, cyclin D1. This additionally was accompanied by increased activity of caspase-9 and caspase-3, and reduction in telomerase activity. Results demonstrated that the treatment combination of berberine/cisplatin had increased induction of apoptosis relative to cisplatin alone (Komal., Singh, & Deshwal., 2013).

Anti-oxidative; Breast, Liver and Colon Cancer

The effect of B. vulgaris extract and berberine chloride on cellular thiobarbituric acid reactive species (TBARS) formation (lipid peroxidation), diphenyle–alpha-picrylhydrazyl (DPPH) oxidation, cellular nitric oxide (NO) radical scavenging capability, superoxide dismutase (SOD), glutathione peroxidase (GPx), acetylcholinesterase (AChE) and alpha-gulcosidase activities were spectrophotometrically determined.

Barberry crude extract contains 0.6 mg berberine/mg crude extract. Barberry extract showed potent anti-oxidative capacity through decreasing TBARS, NO and the oxidation of DPPH that is associated with GPx and SOD hyperactivation. Both berberine chloride and barberry ethanolic extract were shown to have inhibitory effect on the growth of breast, liver and colon cancer cell lines (MCF7, HepG2 and CACO-2, respectively) at different incubation times starting from 24 hours up to 72 hours and the inhibitory effect increased with time in a dose-dependent manner.

This work demonstrates the potential of the barberry crude extract and its active alkaloid, berberine, for suppressing lipid peroxidation, suggesting a promising use in the treatment of hepatic oxidative stress, Alzheimer and idiopathic male factor infertility. As well, berberis vulgaris ethanolic extract is a safe non-toxic extract as it does not inhibit the growth of PBMC that can induce cancer cell death (Abeer et al., 2013).

Source:

Alkaloids Isolated from Natural Herbs as the Anti-cancer Agents. Evidence-Based Complementary and Alternative Medicine. Volume 2012 (2012) http://dx.doi.org/10.1155/2012/485042

References

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Chang KSS, Gao C, Wang LC. (1990). Berberine-induced morphologic differentiation and down-regulation of c-Ki-ras2 protooncogene expression in human teratocarcinoma cells. Cancer Letters, 55(2):103–108.


Chen J, ZHao H, Wang X, et al. (2008). Analysis of major alkaloids in Rhizoma coptidis by capillary electrophoresis-electrospray-time of flight mass spectrometry with different background electrolytes. Electrophoresis, 29(10):2135–2147.


Eom KS, Kim HJ, So HS, et al. (2010). Berberine-induced apoptosis in human glioblastoma T98G Cells Is mediated by endoplasmic reticulum stress accompanying reactive oxygen species and mitochondrial dysfunction. Biological and Pharmaceutical Bulletin, 33(10):1644–1649.


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Hamsa TP & Kuttan G. (2011). Berberine inhibits pulmonary metastasis through down-regulation of MMP in metastatic B16F-10 melanoma cells. Phytotherapy Research, 26(4):568–578.


Hamsa TP & Kuttan G. (2012). Anti-angiogenic activity of berberine is mediated through the down-regulation of hypoxia-inducible factor-1, VEGF, and pro-inflammatory mediators. Drug and Chemical Toxicology, 35(1):57–70.


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Ho YT, Yang JS, Li TC, et al. (2009). Berberine suppresses in vitro migration and invasion of human SCC-4 tongue squamous cancer cells through the inhibitions of FAK, IKK, NF-κB, u-PA and MMP-2 and -9. Cancer Letters, 279(2):155–162.


Hur JM, Hyun MS, Lim SY, Lee WY, Kim D. (2009). The combination of berberine and irradiation enhances anti-cancer effects via activation of p38 MAPK pathway and ROS generation in human hepatoma cells. Journal of Cellular Biochemistry, 107(5):955–964.


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Wu HL, Hsu CY, Liu WH, Yung BYM. (1999). Berberine‐induced apoptosis of human leukemia HL‐60 cells is associated with down‐regulation of nucleophosmin/B23 and telomerase activity. International Journal of Cancer, 81(6):923–929.


Youn MJ, So HS, Cho HJ, et al. (2008). Berberine, a natural product, combined with cisplatin enhanced apoptosis through a mitochondria/caspase-mediated pathway in HeLa cells. Biological and Pharmaceutical Bulletin, 31(5):789–795.


Yu HH, Kim KJ, Cha JD, et al. (2005). Antimicrobial activity of berberine alone and in combination with ampicillin or oxacillin against methicillin-resistant Staphylococcus aureus. Journal of Medicinal Food, 8(4):454–461.

anti-proliferative, Chapter 8 Injectables and Cancer Research, Chemotherapy, chemotherapy support, Fatigue, Immune, immunomodulary, Lymphoma, Nausea and Vomiting, Radio-sensitizer, radiotherapy, Weight Gain or Weight Loss

Kangai Injection

Cancers: Cervical., lung, non-Hodgkin”s lymphoma, stomach

Action: Anti-proliferative, chemotherapy support, immunomodulary, radio-sensitizer

Non-Hodgkin’s Lymphoma

The influence of Kangai injection on blood serum vascular endothelial growth factor of non-Hodgkin”s lymphoma patients, and its synergistic effect, attenuation and improvement of quality of life was evaluated.

Eighty-five non-Hodgkin”s lymphoma patients were randomized into a treatment group or control group. The patients in the treatment group were treated by Kangai injection and cyclophosphamide / doxorubicin / vincristine / prednisolone (CHOP) combined chemotherapy, while those in the control group were treated by CHOP chemotherapy only.

The concentration of vascular endothelial growth factor in blood serum of the patients of the treatment group decreased after therapy (P < 0.05), acute curative effect gradually increased, quality of life was raised significantly (P < 0.05), and adverse reactions of the combined chemotherapy decreased markedly (P < 0.05).

Kangai injection, with CHOP chemotherapy, has a synergistic effect. It can attenuate progression of non-Hodgkin”s lymphoma, and improve quality of life. Additionally, it can decrease the concentration of serum vascular endothelial growth (Tang, 2006).

Stomach Cancer; Chemotherapy

Eighty patients with advanced stomach cancer were randomly divided into treatment group (chemotherapy+ GAMA injection) and control group (chemotherapy only). Observation was conducted on cellular immunization, short-termeffect, quality of life improvement, and toxic side-effects in both groups.

In the treatment group, both NK cellular activity and CD4/CD8 ratios were higher after the treatment (P < 0.01). CD3 and CD4 were both increased (P < 0.05). In the control group, the NK cellular activity, CD3, CD4, CD4/CD8 ratio were all lower after the treatment (P < 0.05). The short-term  efficacy rate was 45% in the treatment group and 40% in the control group. The difference was not significant. The treatment group was apparently lower than the control group in leukopenia, nausea and/or vomiting, and peripheral nerve toxicity (P < 0.05). Compared with the control group, less fatigue, better appetite, and Karnofsky score increases were observed in the treatment group (P < 0.01). The treatment group was also more effective in relieving pain and promoting weight gain than the control group (P < 0.05).

Treating advanced stomach cancer, with the combination of Kangai injection and chemotherapy, may decrease the adverse effects of chemotherapy on patients′cellular immune functions and other side effects, and thereby, improve the quality of life of patients (Wu & Yang, 2007).

NSCLC; Chemotherapy

Seventy eight patients with stage IIIB/IV NSCLC were randomly divided into two groups: treatment group (n=40) received GAMA injection and chemotherapy, and control group (n=38) only received chemotherapy.

The short-termeffect, Karnofsky scores of life quality, and the incidence of pancytopenia in treatment group were superior to those in the control group (72.5% vs 47.4%, P<0.05; 87.5% vs 55.3%, P < 0.01; P < 0.01).

Kangai injection can improve the short-term effect, quality of life, and pancytopenia prevalence in patients with intermediate and advanced-stage NSCLC (Wen, Xie, Xie & Feng, 2006).

Radiotherapy side-effects

One hundred ten cases of patients with malignant tumors wasrandomly divided into the treatment group or the control group. The treatment group was given Kangai injection for 40 days after radiotherapy, while the control group was treated by radiotherapy only.

Tumor growth in the treatment group and the control group were 66.7% and 43.4%, respectively. Karnofsky score improvements were 52.6% and 32.1%, respectively. The incidence of leukopenia was 22.8% and 42.5%, respectively. All differences were significant (P < 0.05). There was no significant difference in levels of lymphocytres between the treatment group before and after therapy (P > 0.05). However, there was significant difference in the control group before and after therapy (P< 0.05).

Kangai injection can improve the curative effect and alleviate the side-effects of radiotherapy on treating malignant tumors (Cao et al., 2005).

Leukemia

Kangai injection combination of fludarabine (Flud), cytosine arabinoside (Ara-C), and granulocyte colony-stimulating factor (G-CSF) (FLAG) in refractory/relapsed acute leukemia (AL) patients was investigated. The remission rate of treatment and total effective rate treatment group were 57.1% (16/28) and 71.4% (21/28), the control group were 52.3% (11/21) and 61.9% (13/21); there were no significant differences in the two groups. Duration of neutrophils less than 0.5 x 10(9)/L in treatment group was (14 +/- 6) day, control group was (23 +/- 3) day, Duration of platelet less than 25 x 10(9)/L in treatment group was (17 +/- 6) day, control group was (31 +/- 2) day, treatment group of III-IV degree of infection was 6.9% (1/28) and control group was 23.8% (5/21) between the two groups were significantly different (P < 0.05). treatment group of III- IV degree of gastrointestinal; toxicity was 10.7% (3/28) and control group was 28. 5% (6/ 21).

Kangai injection plus FLAG regimen could increase the remission rate, shorten the period of bone marrow suppression, significantly reduced the incidence and degree of infection, play an important role in attenuated efficiency (Wan et al., 2011).

References

Cao, H. (2005). Treating 57 cases of malignant tumor by Kangai injection and radiotherapy. Zhejiang Journal of Integrated Traditional Chinese and Western Medicine, 2005(12), R730.5. doi: cnki:sun:zjzh.0.2005-12-005.


Tang, Q. (2006). Influence of Kangai injection on blood serum vascular endothelial growth factor of non-Hodgkin lymphoma patient. Journal of Leukemia & Lymphoma, 15(1).


Wan, Q., Xi, A., Zhang, C., Liu X.(2011) Clinical study of kangai injection plus FLAG regimen for refractory/relapsed acute leukemia. Zhongguo Zhong Yao Za Zhi, 36(22):3207-9.


Wen, J.Y., Xie, Z., Xie, J.R., & Feng, L.P. (2006). Kangai injection mixed with chemotherapy in intermediate and advanced-stage non-small-cell lung cancer. Journal of Guandong Medical College, 24(1), 1005-4057.


Wu, L., & Yang, Y. (2007). A clinical study of treating advanced gastric cancer with the combination of Kangai injection and chemotherapy. Proceeding of Clinical Medicine, 18(7), 1671-8631.

ABCG2, AIF, anti-apoptotic, Anti-cancer, Anti-metastatic, anti-proliferative, anti-tumor, apoptosis, Apoptotic, Artemisia annua, Bcl-2, BCRP, Breast cancer, Chapter 8 Injectables and Cancer Research, Chemotherapy, Colon Cancer or Colorectal cancer, cytotoxic, Derivative of artemisinin, Down-regulates, epidermal growth factor receptor, Esophageal cancer, G0/G1, G1, G2/M, ICAM-1, induces apoptosis, Lymphoma, MDR, metastasis, Multi-Drug Resistance, Multi-drug resistance, Osteosarcoma, Ovarian cancer, p21, p53, Pancreatic cancer, Prostate cancer, Radio-sensitizer, Sarcoma, Skin cancer

Artesunate

Cancer: Colon, esophageal., pancreatic, ovarian, multiple myeloma and diffuse large B-cell lymphoma, osteosarcoma, lung, breast, skin, leukemia/lymphoma

Action: Anti-metastatic, MDR, radio-sensitizer

Pulmonary Adenocarcinomas

Artesunate exerts anti-proliferative effects in pulmonary adenocarcinomas. It mediates these anti-neoplastic effects by virtue of activating Bak (Zhou et al., 2012). At the same time, it down-regulates epidermal growth factor receptor expression. This results in augmented non-caspase dependent apoptosis in the adenocarcinoma cells. Artesunate mediated apoptosis is time as well as dose-dependent. Interestingly, AIF and Bim play significant roles in this Bak-dependent accentuated apoptosis (Ma et al., 2011). Adenosine triphosphate (ATP)-binding cassette subfamily G member 2 (ABCG2) expression is also attenuated while transcription of matrix metallopeptidase 7 (MMP-7) is also down-regulated (Zhao et al., 2011). In addition, arsenuate enhances the radio-sensitization of lung carcinoma cells. It mediates this effect by down-regulating cyclin B1 expression, resulting in augmented G2/M phase arrest (Rasheed et al., 2010).

Breast Cancer

Similarly, artesunate exhibits anti-neoplastic effects in breast carcinomas. Artesunate administration is typically accompanied by attenuated turnover as well as accentuated peri-nuclear localization of autophagosomes in the breast carcinoma cells. Mitochondrial outer membrane permeability is typically augmented. As a result, artesunate augments programmed cellular decline in breast carcinoma cells (Hamacher-Brady et al., 2011).

Skin Cancer

Artesunate also exerts anti-neoplastic effects in skin malignancies. It mediates these effects by up-regulating p21. At the same time it down-regulates cyclin D1 (Jiang et al., 2012).

Colon Cancer

Artemisunate significantly inhibited both the invasiveness and anchorage independence of colon cancer SW620 cells in a dose-dependent manner. The protein level of intercellular adhesion molecule 1 (ICAM-1) was down-regulated as relative to the control group.

Artemisunate could potentially inhibit invasion of the colon carcinoma cell line SW620 by down-regulating ICAM-1 expression (Fan, Zhang, Yao & Li, 2008).

Multi-drug resistance; Colon Cancer

A profound cytotoxic action of the antimalarial., artesunate (ART), was identified against 55 cancer cell lines of the U.S. National Cancer Institute (NCI). The 50% inhibition concentrations (IC50 values) for ART correlated significantly to the cell doubling times (P = 0.00132) and the portion of cells in the G0/G1 (P = 0.02244) or S cell-cycle phases (P = 0.03567).

Efferth et al., (2003) selected mRNA expression data of 465 genes obtained by microarray hybridization from the NCI data-base. These genes belong to different biological categories (drug resistance genes, DNA damage response and repair genes, oncogenes and tumor suppressor genes, apoptosis-regulating genes, proliferation-associated genes, and cytokines and cytokine-associated genes). The constitutive expression of 54 of 465 (=12%) genes correlated significantly to the IC50 values for ART. Hierarchical cluster analysis of these 12 genes allowed the differentiation of clusters with ART-sensitive or ART-resistant cell lines (P = 0.00017).

Multi-drug-resistant cells differentially expressing the MDR1, MRP1, or BCRP genes were not cross-resistant to ART. ART acts via p53-dependent and- independent pathways in isogenic p53+/+ p21WAF1/CIP1+/+, p53-/- p21WAF1/CIP1+/+, and p53+/+ p21WAF1/CIP1-/- colon carcinoma cells.

Multi-drug resistance; Esophageal Cancer

The present study aimed to investigate the correlation between ABCG2 expression and the MDR of esophageal cancer and to estimate the therapeutic benefit of down-regulating ABCG2 expression and reversing chemoresistance in esophageal cells using artesunate (ART).

ART is a noteworthy antimalarial agent, particularly in severe and drug-resistant cancer cases, as ART is able to reverse drug resistance. ART exerted profound anti-cancer activity. The mechanism for the reversal of multi-drug resistance by ART in esophageal carcinoma was analyzed using cellular experiments, but still remains largely unknown (Liu, Zuo, & Guo, 2013).

Pancreatic Cancer

The combination of triptolide and artesunate could inhibit pancreatic cancer cell line growth, and induce apoptosis, accompanied by expression of HSP 20 and HSP 27, indicating important roles in the synergic effects. Moreover, tumor growth was decreased with triptolide and artesunate synergy. Results indicated that triptolide and artesunate in combination at low concentrations can exert synergistic anti-tumor effects in pancreatic cancer cells with potential clinical applications (Liu & Cui, 2013).

Ovarian Cancer

Advanced-stage ovarian cancer (OVCA) has a unifocal origin in the pelvis. Molecular pathways associated with extrapelvic OVCA spread are also associated with metastasis from other human cancers and with overall patient survival. Such pathways represent appealing therapeutic targets for patients with metastatic disease.

Pelvic and extrapelvic OVCA implants demonstrated similar patterns of signaling pathway expression and identical p53 mutations.

However, Marchion et al. (2013) identified 3 molecular pathways/cellular processes that were differentially expressed between pelvic and extrapelvic OVCA samples and between primary/early-stage and metastatic/advanced or recurrent ovarian, oral., and prostate cancers. Furthermore, their expression was associated with overall survival from ovarian cancer (P = .006), colon cancer (1 pathway at P = .005), and leukemia (P = .05). Artesunate-induced TGF-WNT pathway inhibition impaired OVCA cell migration.

Multiple Myeloma, B-cell Lymphoma

Findings indicate that artesunate is a potential drug for treatment of multiple myeloma and diffuse large B-cell lymphoma (DLBCL) at doses of the same order as currently in use for treatment of malaria without serious adverse effects. Artesunate treatment efficiently inhibited cell growth and induced apoptosis in cell lines. Apoptosis was induced concomitantly with down-regulation of MYC and anti-apoptotic Bcl-2 family proteins, as well as with cleavage of caspase-3. The IC50 values of artesunate in cell lines varied between 0.3 and 16.6 µm. Furthermore, some primary myeloma cells were also sensitive to artesunate at doses around 10 µm. Concentrations of this order are pharmacologically relevant as they can be obtained in plasma after intravenous administration of artesunate for malaria treatment (Holien et al., 2013).

Osteosarcoma, Leukemia/Lymphoma

Artesunate inhibits growth and induces apoptosis in human osteosarcoma HOS cell line in vitro and in vivo (Xu et al. 2011). ART alone or combined with chemotherapy drugs could inhibit the proliferation of B/T lymphocytic tumor cell lines as well ALL primary cells in vitro, probably through the mechanism of apoptosis, which suggest that ART is likely to be a potential drug in the treatment of leukemia/lymphoma (Zeng et al., 2009).

References

Efferth, T., Sauerbrey, A., Olbrich, A., et al. (2003) Molecular modes of action of artesunate in tumor cell lines. Mol Pharmacol, 64(2):382-94.


Fan, Y., Zhang, Y.L., Yao, G.T., & Li, Y.K. (2008). Inhibition of Artemisunate on the invasion of human colon cancer line SW620. Lishizzhen Medicine and Materia Medica Research, 19(7), 1740-1741.


Hamacher-Brady, A., Stein, H.A., Turschner, S., et al. (2011). Artesunate activates mitochondrial apoptosis in breast cancer cells via iron-catalyzed lysosomal reactive oxygen species production. J Biol Chem. 2011;286(8):6587–6601. doi: 10.1074/jbc.M110.210047.


Holien, T., Olsen, O.E., Misund, K., et al. (2013). Lymphoma and myeloma cells are highly sensitive to growth arrest and apoptosis induced by artesunate. Eur J Haematol, 91(4):339-46. doi: 10.1111/ejh.12176.


Jiang, Z., Chai, J., Chuang, H.H., et al. (2012). Artesunate induces G0/G1 cell-cycle arrest and iron-mediated mitochondrial apoptosis in A431 human epidermoid carcinoma cells. Anti-cancer Drugs, 23(6):606–613. doi: 10.1097/CAD.0b013e328350e8ac.


Liu, L., Zuo, L.F., Guo, J.W. (2013). Reversal of Multi-drug resistance by the anti-malaria drug artesunate in the esophageal cancer Eca109/ABCG2 cell line. Oncol Lett, 6(5):1475-1481.


Liu, Y. & Cui, Y.F. (2013). Synergism of cytotoxicity effects of triptolide and artesunate combination treatment in pancreatic cancer cell lines. Asian Pac J Cancer Prev, 14(9):5243-8.


Ma, H., Yaom Q., Zhang, A.M., et al. (2011). The effects of artesunate on the expression of EGFR and ABCG2 in A549 human lung cancer cells and a xenograft model. Molecules, 16(12):10556–10569. doi: 10.3390/molecules161210556.


Marchion, D.C., Xiong, Y., Chon, H.S., et al. (2013). Gene expression data reveal common pathways that characterize the unifocal nature of ovarian cancer. Am J Obstet Gynecol, S0002-9378(13)00827-2. doi: 10.1016/j.ajog.2013.08.004.


Rasheed, S.A., Efferth, T., Asangani, I.A., Allgayer, H. (2010). First evidence that the antimalarial drug artesunate inhibits invasion and in vivo metastasis in lung cancer by targeting essential extracellular proteases. Int J Cancer, 127(6):1475–1485. doi: 10.1002/ijc.25315.


Xu, Q., Li, Z.X., Peng, H.Q., et al. (2011). Artesunate inhibits growth and induces apoptosis in human osteosarcoma HOS cell line in vitro and in vivo. J Zhejiang Univ-Sci B (Biomed & Biotechnol), 12(4):247–255. doi: 10.1631/jzus.B1000373.


Zhao, Y., Jiang, W., Li, B., et al. (2011). Artesunate enhances radiosensitivity of human non-small-cell lung cancer A549 cells via increasing no production to induce cell-cycle arrest at G2/M phase. Int Immunopharmacol, 11(12):2039–2046. doi: 10.1016/j.intimp.2011.08.017.


Zeng, Y., Ni, X., Meng, W.T., Wen, Q., Jia, Y.Q. (2009). Inhibitive effect of artesunate on human lymphoblastic leukemia/lymphoma cells. Sichuan Da Xue Xue Bao Yi Xue Ban, 40(6):1038-43.


Zhou, C., Pan, W., Wang, X.P., Chen, T.S. (2012). Artesunate induces apoptosis via a bak-mediated caspase-independent intrinsic pathway in human lung adenocarcinoma cells. J Cell Physiol, 227(12):3778–3786. doi: 10.1002/jcp.24086.

Breast cancer, Chapter 8 Injectables and Cancer Research, Chemo-sensitizer, Chemotherapy, Colon Cancer or Colorectal cancer, Cytostatic, G2/M, Immune, Liver cancer, Lung cancer, Lymphoma, Radio-sensitizer, radiotherapy, Rectal cancer

Ai Di Injection (ADI)

Cancers: Breast, colorectal., glioma, lung

Action: Chemo-sensitizer, cytostatic, radio-sensitizer

 

Ingredients: Mylabris phalerata (ban mao), Panax ginseng (ren shen), Astragalus membranaceus (huang qi).

TCM functions: Clearing Heat, removing Toxin, resolving stagnant Blood, dissolving lumps.

Indications: Primary liver cancer, lung cancer, colorectal cancer, malignant lymphoma, and gynecological malignancies.

Dosage and usage:

For adults: 50-100ml, mixed with 400-500ml of 0.9% NaCl injection or 5-10% glucose injection for intravenous drip, once daily.

When combined with radiotherapy or chemotherapy, the course of treatment is synchronized to radiotherapy or chemotherapy.

Application before or after the surgery: 10 days as a course of treatment.

Intervention treatment: 10 days as a course of treatment.

Single application: 15 days as a cycle, with 3 days interval., 2 cycles as a course of treatment.

 

Cachexia patients in advanced stage: 30 consecutive days as a course of treatment (Drug Information Reference in Chinese: See end).

 

Glioma; Radio-sensitization

The inhibition ratio was determined by MTT assay, the change in the cell-cycle was analyzed by flow cytometry and the expression of cyclin B1 and Wee1 was detected by Western blot analysis. The reproductive activity of the group treated with irradiation (IR) and Aidi injection was suppressed significantly, and the cloning efficiency and divisional index also declined. Aidi injection (15 µg/ml) induced G2/M phase arrest in the cell line after 48 h.

 

Aidi injection (ADI) is effective in radio-sensitization. The possible mechanisms involved may be associated with G2/M phase cell arrest, the down-regulation of cyclin B1 and up-regulation of Wee1 expression, which influences cell size by inhibiting the entry into mitosis, through inhibiting Cyclin-dependent kinase 1 (Xu, Song, Qin, Wang, & Zhou, 2012).

 

Breast Cancer

ADI significantly inhibited the proliferation of MCF-7 cells in a dose-dependent manner. The IC50 of ADI was 55.71 mg/mL after treatment for 48 h. The 60 mg/mL ADI was used as the therapeutic drug concentration. Microarray analysis identified 45 miRNAs that were up-regulated and 55 miRNAs that were down-regulated in response to ADI treatment. Many ADI-induced miRNAs were related to breast cancers. The 12 potential target genes of mir-126 were predicted by both TargetScan and PicTar software.

 

The miRNA may serve as therapeutic targets for ADI, and its modulation of expression is an important mechanism of ADI inhibition of breast cancer cell growth (Zhang, Zhou, Lu, Du, & Su, 2011).

 

Colorectal Cancer; FOLFOX4

A consecutive cohort of 100 patients was divided into two groups. The experimental group was treated with a combination of Aidi injection and FOLFOX4, while the control group was only administered FOLFOX4. After a minimum of two courses of treatment, efficacy, quality of life, and side-effects were evaluated.

 

The response rate of the experimental group was not significantly different compared to the control group (P > 0.05). However, there were significant differences in clinical benefit response and KPS score. In addition, adverse gastrointestinal reactions and the incidence of leukopenia were lower than that of the control group (P < 0.05).

Aidi injection, combined with FOLFOX4, is associated with reduced toxicity of chemotherapy, enhanced clinical benefit response, and improved quality of life in patients with advanced colorectal cancer (Xu, Huang, Li, Li, & Tang, 2011).

 

NSCLC

Ninety-eight cases of advanced NSCLC were randomly divided into two groups: a trial group and control group. In the trial group Navelbine/Cisplatin (NP) plus Ai Di Injection (ADI) (60-80 ml) was administered intravenously, via dissolution in 400 ml of normal saline, per day for 8-10 days. In the control group, only NP chemotherapy was administered at the dosages of: Navelbine (25 mg/m², d1, 8) and Cisplastin (40 mg/m², d1-3). Each patient received at least two cycles of treatment.

 

The effective rate in the trial group and the control group was 53.1% and 44.9% respectively, without significant difference between the two groups (P > 0.05). However, the rate of progression, adverse reactions in the bone marrow, digestive tract, and immune function in the trial group were all lower than those in the control group (P < 0.05). In addition, improvement in Karnofsky score in the trial group was higher than that in the control group (P < 0.05).

 

A chemotherapy regiment of NP, combined with ADI, shows benefit in the treatment of advanced NSCLC. AI could minimize the adverse reactions of chemotherapy, and improve the quality of life in patients with NSCLC (Wang et al., 2004).

 

NSCLC; Meta-analysis

PubMed (1980-2008), Cochrane Central Register of Controlled Trials (The Cochrane Library, Issue 3, 2008), EMBASE (1984-2008), CancerLit (1996-2003), CBMdisc (1980-2008), CNKI database (1980-2008), Wanfang database (1980-2008), and Chongqing VIP database (1980-2008) were searched. Relevant Chinese periodicals were manually searched as well. All randomized controlled trials comparing Aidi Injection with other treatment methods of NSCLC were included. Two reviewers selected studies, assessed the quality of studies, and extracted the data independently.

 

Fourteen randomized controlled trials were included in the meta-analysis, but unfortunately, the quality of reports of the 14 included studies were poor. Aidi Injection combined with cobalt-60, or navelbine and platinol (NP), showed statistically significant differences in improving the response rate, compared to the use of cobalt-60 alone (P = 0.0002) or NP alone (P = 0.04). However, Aidi Injection combined with etoposide and platinol (EP), taxinol and platinol (TP) or gamma knife showed no significant differences when compared with single use of EP (P=0.60), TP (P=0.16) or gamma knife (P=0.34), respectively. The RR and 95% CI of EP, TP, and gamma knife were 1.17 [0.65, 2.09], 1.27 [0.91, 1.78] and 1.08 [0.92, 1.26] respectively.

 

Six studies indicated that Aidi Injection, combined with NP or gamma knife, could improve quality of life. Six studies showed that Aidi Injection, combined with NP or TP, could improve the bone marrow’s hematopoietic function. The results of the meta-analysis indicate that Aidi Injection may have adjuvant therapeutic effects in the treatment of NSCLC patients. However, sample sizes are small, study quality is poor, and the existence of publication bias had been found. The effects of Aidi Injection need to be confirmed by large multicenter randomized controlled trials (Ma, Duan, Feng, She, Chen & Zhang, 2009).

 

NSCLC; Neo-adjuvant Chemotherapy

Sixty patients, with stage IIIA non-small-cell lung cancer (NSCLC), underwent two courses of bronchial arterial infusion (BAI) chemotherapy, before tumor incision. They were assigned to either the treatment or control group, using a random number table. Thirty patients were allocated to each. An ADI of 100 mL, added into 500 mL of 5% glucose, was given to the patients in the treatment group via intravenous drip. Treatment was once a day, beginning 3 days prior and throughout each of two 14-day courses of chemotherapy.

 

Levels of T-lymphocyte subsets, natural killer cell activity, and interleukin-2 in peripheral blood were measured before and after the treatment. The effective rate in the treatment group was higher than that in the control group (70.0% vs. 56.7%, P < 0.05).

 

Moreover, bone marrow suppression and liver function damage (P < 0.05) was less in the treatment group relative to the control. Cellular immune function was suppressed in NSCLC patients, but was ameliorated after treatment, showing a significant difference when compared to the control group (P < 0.05).

 

ADI could potentially act as an ideal auxiliary drug for patients with stage IIIA NSCLC, receiving BAI neo-adjuvant chemotherapy, before surgical operation. It could enhance the effectiveness of chemotherapy, ameliorate adverse reactions, and elevate patient’s cellular immune function (Sun, Pei, Yin, Wu & Yang, 2010).

 

References

Ma, W.H., Duan, K.N., Feng, M., She, B., Chen, Y., & Zhang, R.M. (2009). Aidi Injection as an adjunct therapy for non-small-cell lung cancer: a systematic review. Journal of Chinese Integrative Medicine, 7(4), 315-324.

Sun, X.F., Pei, Y.T., Yin, Q.W., Wu, M.S., & Yang, G.T. (2010). Application of Aidi injection in the bronchial artery infused neo-adjuvant chemotherapy for stage III A non-small-cell lung cancer before surgical operation. Chinese Journal of Integrative Medicine, 16(6), 537-541.

Wang, D., Chen, Y., Ren, J., Cai, Y., M. Liu, M., & Zhan, Q. (2004). A randomized clinical study on efficacy of Aidi injection combined with chemotherapy in the treatment of advanced non-small-cell lung cancer. Journal of Chinese Integrative Medicine, 7(3), 247-249.

Xu, H.X., Huang, X.E., Li, Y., Li, C.G., & Tang, J.H. (2011). A clinical study on safety and efficacy of Aidi injection combined with chemotherapy. Asian Pacific Journal of Cancer Prevention, 12(9), 2233-2236.

Xu, X.T., Song, Y., Qin, S., Wang, L.L., & Zhou, J.Y. (2012). Radio-sensitization of SHG44 glioma cells by Aidi injection in vitro. Molecular Medicine Reports, 5(6), 1415-1418.

Zhang, H., Zhou, Q.M., Lu, L.L., Du, J., & Su, S.B. (2011). Aidi injection alters the expression profiles of microRNAs in human breast cancer cells. Journal of Traditional Chinese Medicine, 31(1), 10-16.

anti-tumor, apoptosis, Apoptotic, AT6.3, Breast cancer, Chapter 7 Isolates and Cancer Research, Enhances tamoxifen, PARP, Prostate cancer, Radio-sensitizer, radio-sensitizing

Daidzein & S-(-)-equol

Cancer: Breast, prostate

Action: Enhances tamoxifen, radio-sensitizer

Daidzein & Genistein Concentrations; Breast Cancer

A systematic search by Mário L de Lemos (2001) through primary English-language literature on MEDLINE (1966–January 2001), EMBASE (1982–January 2001) and Current Contents (1998–January 2001) found that genistein and daidzein at low concentrations were found to stimulate breast tumor growth in in vitro and in vivo animal studies, and antagonize the anti-tumor effect of tamoxifen in vitro. However, at high concentrations, genistein inhibited tumor growth and enhanced the effect of tamoxifen in vitro.

At concentrations below 10 µmol/L, phytoestrogens can stimulate breast tumor growth and antagonize the anti-tumor effects of tamoxifen, particularly in an environment of low endogenous estrogen. In contrast, phytoestrogens inhibit breast tumor growth and enhance the anti-tumor effects of tamoxifen at concentrations above 10 µmol/L (de Lemos, 2002; Akaza et al., 2004).

Breast cancer

Daidzein or its major metabolite equol at a dose molar equivalent to tamoxifen [1.0 mg(2.7 µmol)/kg or 10 mg (27 µmol)/kg/day] was treated orally to rats bearing 7,12-dimethylbenz(a)anthracene(DMBA)-induced mammary tumors or ovariectomized athymic nude mice implanted with human MCF-7 breast cancer xenograft and an estrogen pellet. The growth of tumors was monitored for several weeks after the treatment. The cell-cycle and apoptotic stages in mammary tumors collected from rats were analyzed by flow cytometry. Immunohistochemistry analysis was also used to determine the expression of caspase-3.

Oral treatment with daidzein or equol at a human equivalent dose suppressed the growth of both DMBA-induced mammary tumors and human MCF-7 breast cancer xenografts in rodents, the inhibitory activity being superior to that of genistein or tamoxifen. Strong apoptosis induced by daidzein or equol contributes to the anti-tumor potential.

Daidzein and its metabolite equol showed the potential of inhibiting the growth of mammary tumors in rodents. Daidzein or equol could be used as a core structure to design new drugs for breast cancer therapy. Our results indicate that consumption of daidzein may protect against breast cancer (Liu et al., 2012).

Equol Production

S-(-)-equol is a metabolite of the soy isoflavone daidzein and is produced by intestinal bacteria in some, but not in all, humans after soy consumption (Setchell & Clerici, 2010). The ability of S-equol to play a role in the treatment of estrogen or androgen-mediated diseases or disorders was first proposed in 1984 (Setchell et al., 1984). The ability to do so depends on two things: soy and bacteria. First, the soy must contain the soy isoflavone daidzein and the amount may influence equol production. Second, the human must have certain strains of bacteria living within the intestine. Twenty-one different strains of intestinal bacteria cultured from humans have the ability to transform daidzein into S-equol or a related intermediate compound (Setchell & Clerici, 2010).

Several studies indicate that only 25 to 30 percent of the adult population of Western countries produces S-equol after eating soy foods containing isoflavones, (Rowland et al., 2000; Atkinson et al., 2005) significantly lower than the reported 50–60% frequency of equol-producers in adults from Japan, Korea, or China (Song et al., 2006).

Equol Production; Prostate Cancer

Akaza et al. (2004) recently conducted a case-controlled study on those who are able to degrade daidzein, a soybean isoflavone, to equol and those without this ability. The incidence of prostate cancer is known to be lower in residents in Japan. On the other hand, American residents in the United States have a markedly higher incidence of prostate cancer.

The number of subjects was 295 in Japan (133 patients and 162 controls), 122 in Korea (61 patients and 61 controls) and 45 in the United States (24 patients and 21 controls). The percentage of equol producers among patients and controls was 29% and 46% in Japan (P = 0.004) and 30% and 59% in Korea (P = 0.001), respectively. The active isoflavone level was markedly lower and the percentage of equol producers was also lower (17% for patients and 14% for controls) for Americans as compared to the Japanese and Koreans.

These results suggest that the ability to produce equol, or equol itself, is closely related to the lower incidence of prostate cancer. The results also suggest that a diet based on soybean isoflavones will be useful in preventing prostate cancer.

Prostate cancer

The age-adjusted incidence rate of prostate cancer (PCa) has been reported to be lower among Asians than Western populations. A traditional Japanese meal., high in soybean products or isoflavones, may be associated with a decreased risk of PCa. Equol, which is converted from daidzein by human intestinal flora, is biologically more active than any other isoflavone aglycone.

Five out of 6 articles showed significant association of isoflavones with a decreased risk of PCa, and two of them consistently showed that equol-producers carry a significantly reduced risk of PCa. Furthermore, 5 human intestinal bacteria that can convert daidzein into equol were identified in the last 5 years. If equol can reduce risk of PCa, a possible strategy for reducing the risk of PCa may be to increase the proportion of equol-producers by changing the intestinal flora to carry an equol-producing bacterium, with dietary alteration or probiotic technology (Sugiyama et al., 2013).

Equol Enhances Tamoxifen

Charalambous, Pitta, & Constantinou (2013) found that equol (>50  µM) and 4-hydroxy-tamoxifen (4-OHT; >100 nM) significantly reduced the breast cancer MCF-7 cell viability. Furthermore, the combination of equol (100 µM) and 4-OHT (10 µM) induced apoptosis more effectively than each compound alone. Subsequent treatment of MCF-7 cells with the pan-caspase inhibitor Z-VAD-FMK inhibited equol- and 4-OHT-mediated apoptosis, which was accompanied by PARP and α-fodrin cleavage, indicating that apoptosis is mainly caspase-mediated.

Equol may be used therapeutically in combination treatments and clinical studies to enhance tamoxifen's effect by providing additional protection against estrogen-responsive breast cancers.

Radio-sensitizer

Sensitivity of cells to equol, radiation and a combination of both was determined by colonogenic assays. Induction of apoptosis by equol, radiation and the combination of both was also determined by acridine orange/ethidium bromide double staining fluorescence microscopy. DNA strand breaks were assessed by Comet assay.

MTT assay showed that equol (0.1-350 µM) inhibited MDA-MB-231 and T47D cell growth in a time- and dose-dependent manner. Treatment of cells with equol for 72 hours (MDA-MB-231) and 24 hours (T47D) was found to inhibit cell growth with IC50 values of 252 µM and 228 µM, respectively. Furthermore, pre-treatment of cells with 50 µM equol for 72 hours (MDA-MB-231) and 24 hours (T47D) sensitized the cells to irradiation. Equol was also found to enhance radiation-induced apoptosis. Comet assay results showed that the radio-sensitizing effect of equol was accompanied by increased radiation-induced DNA damage.

These results suggest for the first time that equol can be considered as a radio-sensitizing agent and its effects may be due to increasing cell death following irradiation, increasing the remaining radiation-induced DNA damage and thus reducing the surviving fraction of irradiated cells (Taghizadeh et al., 2013).

References

Akaza H, Miyanaga N, Takashima N, Naito S, et al. (2004). Comparisons of percent equol producers between prostate cancer patients and controls: case-controlled studies of isoflavones in Japanese, Korean and American residents. Japanese Journal of Clinical Oncology, 34(2): 86–9.


Atkinson, C., Frankenfeld, C.L., Lampe, J.W. (2005). Gut bacterial metabolism of the soy isoflavone daidzein: exploring the relevance to human health. Experimental Biology and Medicine (Maywood, N.J.), 230(3):155–70.


Charalambous C, Pitta CA, Constantinou AI. (2013). Equol enhances tamoxifen's anti-tumor activity by induction of caspase-mediated apoptosis in MCF-7 breast cancer cells. BMC Cancer, 13:238. doi: 10.1186/1471-2407-13-238.


de Lemos ML. (2001). Effects of soy phytoestrogens genistein and daidzein on breast cancer growth. Ann Pharmacother, 35(9):1118-21.


de Lemos ML. (2002). Safety Issues of Soy Phytoestrogens in Breast Cancer Patients. JCO, 20(13):3040-3042.


Liu X, Suzuki N, Santosh Laxmi YR, Okamoto Y, Shibutani S. (2012). Anti-breast cancer potential of daidzein in rodents. Life Sci, 91(11-12):415-9.


Rowland IR, Wiseman H, Sanders TA, Adlercreutz H, Bowey EA. (2000). Interindividual variation in metabolism of soy isoflavones and lignans: influence of habitual diet on equol production by the gut microflora. Nutrition and Cancer, 36(1):27–32. doi:10.1207/S15327914NC3601_5.


Setchell KD, Borriello SP, Hulme P, Kirk DN, Axelson M. (1984). Nonsteroidal estrogens of dietary origin: possible roles in hormone-dependent disease. The American Journal of Clinical Nutrition, 40(3):569–78.


Setchell KD, Clerici C. (2010). Equol: history, chemistry, and formation. The Journal of Nutrition, 140 (7): 1355S–62S. doi:10.3945/jn.109.119776.


Song KB, Atkinson C, Frankenfeld CL, Jokela T, et al. (2006). Prevalence of daidzein-metabolizing phenotypes differs between Caucasian and Korean American women and girls. The Journal of Nutrition, 136(5):1347–51.


Sugiyama Y, Masumori N, Fukuta F, et al. (2013). Influence of isoflavone intake and equol-producing intestinal flora on prostate cancer risk. Asian Pac J Cancer Prev, 14(1):1-4.


Taghizadeh B, Ghavami L, Nikoofar A, Goliaei B. (2013). Equol as a potent radiosensitizer in estrogen receptor-positive and -negative human breast cancer cell lines. Breast Cancer.

Akt, angiogenesis, Anti-cancer, anti-inflammatory, anti-oxidant, anti-proliferative, AP-1, apoptosis, Apoptotic, Bcl-xL, Breast cancer, BxPC-3, c-Jun, CCNE2, CDK, CDK2, CDK4, cell-cycle arrest, Chapter 7 Isolates and Cancer Research, chemo-enhancing, chemo-preventive, Chemo-sensitizer, chemo-sensitizing, chemo-sensitzer, Colon Cancer or Colorectal cancer, COX-2, CSCs, EpCAM, G1, G2/M, hepato-protective, HT-29, IKK, IL-6, Immunomodulatory, including Terminalia chebula, inflammation, inhibits VEGF, iNOS, JNK, Lung cancer, Mcl-1, Ovarian cancer, p53, p65, Pancreatic cancer, Pro-apoptotic, Radio-protective, Radio-sensitizer, ROS, TAM resistance, TNF, VEGF, VEGF

Luteolin

Cancer: Colorectal., ovarian, pancreatic

Action: Anti-inflammatory, immunomodulatory, radio-sensitizer, chemo-sensitizer

Luteolin is a flavonoid found in many plants and foods, including Terminalia chebula (Retz.), Prunella vulgaris (L.) and Perilla frutescens [(L.) Britton].

Luteolin is contained in Ocimum sanctum L . or Ocimum tenuiflorum L , commonly known as Holy Basil in English or Tulsi in various Indian languages, which is an important medicinal plant in the various traditional and folk systems of medicine in Southeast Asia. Scientific studies have shown it to possess anti-inflammatory, analgesic, anti-pyretic, anti-diabetic, hepato-protective, hypolipidemic, anti-stress, and immunomodulatory activities. It has been found to prevent chemical-induced skin, liver, oral., and lung cancers and mediates these effects by increasing the anti-oxidant activity, altering the gene expressions, inducing apoptosis, and inhibiting angiogenesis and metastasis.

Colon Cancer

Luteolin inhibited cyclin-dependent kinase (CDK)4 and CDK2 activity, resulting in G1 arrest with a concomitant decrease of phosphorylation of retinoblastoma protein. Activities of CDK4 and CDK2 decreased within 2 hours after luteolin treatment, with a 38% decrease in CDK2 activity (P < 0.05) observed in cells treated with 40 µmol/l luteolin. Luteolin also promoted G2/M arrest at 24 hours post-treatment by down-regulating cyclin B1 expression and inhibiting cell division cycle (CDC)2 activity. Luteolin promoted apoptosis with increased activation of caspases 3, 7, and 9 and enhanced poly(ADP-ribose) polymerase cleavage and decreased expression of p21CIP1/WAF1, survivin, Mcl-1, Bcl-xL, and Mdm-2. Lim et al. (2007) demonstrated that luteolin promotes both cell-cycle arrest and apoptosis in the HT-29 colon cancer cell line, providing insight about the mechanisms underlying its anti-tumorigenic activities.

Radio-protective

The aqueous extract of Perilla frutescens has been shown to protect mice against γ-radiation-induced sickness and mortality and to selectively protect the normal tissues against the tumoricidal effects of radiation. The chemo-preventive and radio-protective properties of Perilla emphasize aspects that warrant future research to establish its activity and utility in cancer prevention and treatment (Baliga et al., 2013).

Anti-inflammatory

Pre-treatment of RAW 264.7 macrophages with luteolin, luteolin-7-glucoside, quercetin, and the isoflavonoid genistein inhibited both the LPS-stimulated TNF-α and interleukin-6 release, whereas eriodictyol and hesperetin only inhibited TNF-α release. From the compounds tested, luteolin and quercetin were the most potent in inhibiting cytokine production with an IC50 of less than 1 and 5 µM for TNF-α release, respectively. Moreover, luteolin inhibited LPS-induced phosphorylation of Akt. Treatment of macrophages with LPS resulted in increased IκB-α phosphorylation and reduced the levels of IκB-α. Pre-treatment of cells with luteolin abolished the effects of LPS on IκB-α.

Xagorari et al. (2001) concluded that luteolin inhibits protein tyrosine phosphorylation, nuclear factor-κB-mediated gene expression and pro-inflammatory cytokine production in murine macrophages.

Anti-inflammatory; Neuroinflammation

Pre-treatment of primary murine microglia and BV-2 microglial cells with luteolin inhibited LPS-stimulated IL-6 production at both the mRNA and protein levels. Whereas luteolin had no effect on the LPS-induced increase in NF-κB DNA binding activity, it markedly reduced AP-1 transcription factor binding activity. Consistent with this finding, luteolin did not inhibit LPS-induced degradation of IκB-α but inhibited JNK phosphorylation.

Luteolin consumption reduced LPS-induced IL-6 in plasma 4 hours after injection. Furthermore, luteolin decreased the induction of IL-6 mRNA by LPS in the hippocampus but not in the cortex or cerebellum. Taken together, these data suggest luteolin inhibits LPS-induced IL-6 production in the brain by inhibiting the JNK signaling pathway and activation of AP-1 in microglia. Thus, luteolin may be useful for mitigating neuroinflammation (Jang et al., 2008).

Immunostimulatory and Anti-inflammatory

Luteolin (Lut) possesses significant anti-inflammatory activity in well-established models of acute and chronic inflammation, such as xylene-induced ear edema in mice (ED50= 107 mg/ kg), carrageenin-induced swellingof the ankle, acetic acid-induced pleurisy and croton oil-induced gaseous pouch granuloma in rats. Lut had a marked inhibitory effect on the inflammatory exudation, but did not affect the number of leucocytes. Its combined immunostimulatory and anti-inflammatory activity, and inhibitory effect upon immediate hypersensitive response, provide the pharmacologic bases for the beneficial effects of Lut in the treatment of chronic bronchitis (Chen et al., 1986).

Anti-inflammatory

Luteolin dose-dependently inhibited the expression and production of those inflammatory genes and mediators in macrophages stimulated with lipopolysaccharide (LPS). Semi-quantitative reverse-transcription polymerase chain reaction (RT-PCR) assay further confirmed the suppression of LPS-induced TNF- α, IL-6, iNOS and COX-2 gene expression by luteolin at a transcriptional level. Luteolin also reduced the DNA binding activity of nuclear factor-kappa B (NF-κB) in LPS-activated macrophages.

In addition, luteolin significantly inhibited the LPS-induced DNA binding activity of activating protein-1 (AP-1). It was also found that luteolin attenuated the LPS-mediated protein kinase B (Akt) and IKK phosphorylation, as well as reactive oxygen species (ROS) production. In sum, these data suggest that, by blocking NF-κB and AP-1 activation, luteolin acts to suppress the LPS-elicited inflammatory events in mouse alveolar macrophages, and this effect was mediated, at least in part, by inhibiting the generation of reactive oxygen species. These observations suggest a possible therapeutic application of this agent for treating inflammatory disorders in the lung (Chen et al., 2007).

Pancreatic Cancer; Chemo-enhancing

Simultaneous treatment or pre-treatment (0, 6, 24 and 42h) of flavonoids and chemotherapeutic drugs and various concentrations (0-50µM) were assessed using the MTS cell proliferation assay. Pre-treatment for 24 hours with 13µM of either Apigenin or Luteolin, followed by Gem for 36 h was optimal to inhibit cell proliferation.

Pre-treatment of cells with 11-19µM of either flavonoid for 24 hours resulted in 59%–73% growth inhibition when followed by Gem (10µM, 36 hours). Lut (15µM, 24 hours) pre-treatment followed by Gem (10µM, 36h), significantly decreased protein expression of nuclear GSK-3β and NF-κB p65 and increased pro-apoptotic cytosolic cytochrome c. Pre-treatment of human pancreatic cancer cells BxPC-3 with low concentrations of Lut effectively aid in the anti-proliferative activity of chemotherapeutic drugs (Johnson et al., 2013).

Ovarian Cancer

Recent studies further indicate that luteolin potently inhibits VEGF production and suppresses ovarian cancer cell metastasis in vitro. Lastly, oridonin and wogonin were suggested to suppress ovarian CSCs as is reflected by down-regulation of the surface marker EpCAM.

Unlike NSAIDS (non-steroid anti-inflammatory drugs), well-documented clinical data for phyto-active compounds are lacking. In order to evaluate objectively the potential benefit of these compounds in the treatment of ovarian cancer, strategically designed, large scale studies are warranted (Chen et al., 2012).

Chemo-sensitizer

The sensitization effect of luteolin on cisplatin-induced apoptosis is p53 dependent, as such effect is only found in p53 wild-type cancer cells but not in p53 mutant cancer cells. Moreover, knockdown of p53 by small interfering RNA made p53 wild-type cancer cells resistant to luteolin and cisplatin. The critical role of c-Jun NH(2)-terminal kinase (JNK) was identified in regulation of p53 protein stability: luteolin activates JNK, and JNK then stabilizes p53 via phosphorylation, leading to reduced ubiquitination and proteasomal degradation.

An in vivo nude mice xenograft model confirmed that luteolin enhanced the cancer therapeutic activity of cisplatin via p53 stabilization and accumulation. In summary, data from this study reveal a novel molecular mechanism involved in the anti-cancer effects of luteolin and support its potential clinical application as a chemo-sensitizer in cancer therapy (Shi et al., 2007).

Breast Cancer; Chemo-sensitzer

Luteolin is a flavonoid that has been identified in many plant tissues and exhibits chemo-preventive or chemo-sensitizing properties against human breast cancer. However, the oncogenic molecules in human breast cancer cells that are inhibited by luteolin treatment have not been identified.

Relatively high levels of cyclin E2 (CCNE2) protein expression were detected in tamoxifen-resistant (TAM-R) MCF-7 cells. These results showed that the level of CCNE2 protein expression was specifically inhibited in luteolin-treated (5µM) TAM-R cells, either in the presence or absence of 4-OH-TAM (100nM). Combined treatment with 4-OH-TAM and luteolin synergistically sensitized the TAM-R cells to 4-OH-TAM. The results of this study suggest that luteolin can be used as a chemo-sensitizer to target the expression level of CCNE2 and that it could be a novel strategy to overcome TAM resistance in breast cancer patients (Tu et al., 2013).

References

Baliga MS, Jimmy R, Thilakchand KR, et al. (2013). Ocimum sanctum L (Holy Basil or Tulsi) and its phytochemicals in the prevention and treatment of cancer. Nutr Cancer, 65(1):26-35. doi: 10.1080/01635581.2013.785010.

Chen CY, Peng WH, Tsai KD and Hsu SL. (2007). Luteolin suppresses inflammation-associated gene expression by blocking NF- κ B and AP-1 activation pathway in mouse alveolar macrophages. Life Sciences, 81(23-24):1602-1614. doi:10.1016/j.lfs.2007.09.028

Chen MZ, Jin WZ, Dai LM, Xu SY. (1986). Effect of luteolin on inflammation and immune function. Chinese Journal of Pharmacology and Toxicology, 1986-01.

Chen SS, Michael A, Butler-Manuel SA. (2012). Advances in the treatment of ovarian cancer: a potential role of anti-inflammatory phytochemicals. Discov Med, 13(68):7-17.

Jang S, Kelley KW, Johnson RW. (2008). Luteolin reduces IL-6 production in microglia by inhibiting JNK phosphorylation and activation of AP-1. PNAS, 105(21):7534-7539

Johnson JL, Gonzalez de Mejia E. (2013). Interactions between dietary flavonoids apigenin or luteolin and chemotherapeutic drugs to potentiate anti-proliferative effect on human pancreatic cancer cells, in vitro. Food Chem Toxicol, S0278-6915(13)00491-2. doi: 10.1016/j.fct.2013.07.036.

Lim DY, Jeong Y, Tyner Al., Park JHY. (2007). Induction of cell-cycle arrest and apoptosis in HT-29 human colon cancer cells by the dietary compound luteolin. Am J Physiol Gastrointest Liver Physiol, 292: G66-G75. doi:10.1152/ajpgi.00248.2006.

Shi R, Huang Q, Zhu X, et al. (2007). Luteolin sensitizes the anti-cancer effect of cisplatin via c-Jun NH2-terminal kinase-mediated p53 phosphorylation and stabilization. Molecular Cancer Therapeutics, 6(4):1338-1347. doi: 10.1158/1535-7163.MCT-06-0638.

Tu SH, Ho CT, Liu MF, et al. (2013). Luteolin sensitizes drug-resistant human breast cancer cells to tamoxifen via the inhibition of cyclin E2 expression. Food Chem, 141(2):1553-61. doi: 10.1016/j.foodchem.2013.04.077.

Xagorari A, Papapetropoulos A, Mauromatis A, et al. (2001). Luteolin inhibits an endotoxin-stimulated phosphorylation cascade and pro-inflammatory cytokine production in macrophages. JPET, 296(1):181-187.

Anti-cancer, Anti-estrogenic, anti-oxidant, anti-proliferative, Breast cancer, Cachexia-inducing, cachexia-inhibiting, cancer stem cells, CCND2, Chapter 7 Isolates and Cancer Research, Endometrial cancer, ER, Hair Loss, inflammation, Lung cancer, MKN45cl85 and 85As2mLuc, pneumonitis, Prostate cancer, Radio-protective, radio-protective effect, Radio-sensitizer, radiotherapy, S, Weight Gain or Weight Loss

Isoflavones

Cancer: Prostate, breast, endometrial

Action: Anti-estrogenic effects, radio-protective effect, pneumonitis, cachexia-inhibiting

Prostate Cancer, Breast Cancer

Isoflavones have been investigated in detail for their role in the prevention and therapy of prostate cancer. This is primarily because of the overwhelming data connecting high dietary isoflavone intake with reduced risk of developing prostate cancer. A number of investigations have evaluated the mechanism(s) of anti-cancer action of isoflavones such as genistein, daidzein, biochanin A, equol, etc., in various prostate cancer models, both in vitro and in vivo.

Nuclear receptors are considered to be a central goal for maximizing treatment opportunities in breast cancer. Among natural ligands for estrogen receptors (ER and ERβ), which are members of the nuclear receptors super-family, are found isoflavones. These natural compounds have a similar structure to the main female hormone 17β-estradiol. A rich source of isoflavones is soy and its products. Three isoflavones of the aglycone form (genistein, daidzein, glycitein) are predominantly found in soybean and red clover. Other important isoflavones are biochanin A and formononetin (Bialešová et al., 2013).

Breast Cancer

Soy isoflavones do not function as an estrogen, but rather exhibit anti-estrogenic properties. However, their metabolism differs between humans and animals and therefore the outcomes of animal studies may not be applicable to humans. The majority of breast cancer cases are hormone-receptor-positive; therefore, soy isoflavones should be considered a potential anti-cancer therapeutic agent (Douglas et al., 2013).

Anti-cancer Effects

Use of soy isoflavone mixture has been advocated as an alternative, wherein daidzein can negate harmful effects of genistein. Recent research indicates the novel role of genistein and other isoflavones in the potentiation of radiation therapy, epigenetic regulation of key tumor suppressors and oncogenes, and the modulation of miRNAs, epithelial-to-mesenchymal transition, and cancer stem cells, which has renewed the interest of cancer researchers in this class of anti-cancer compounds (Ahmad et al. 2013).

Radiation-induced Pneumonitis, Radiation-induced Side-effects

Radiation-induced pneumonitis and fibrosis have restricted radiotherapy for lung cancer. In a preclinical lung tumor model, soy isoflavones showed the potential to enhance radiation damage in tumor nodules and simultaneously protect normal lung from radiation injury. Soy isoflavones given pre- and post-radiation protected the lungs against adverse effects of radiation including skin injury, hair loss, increased breathing rates, inflammation, pneumonitis and fibrosis, providing evidence for a radio-protective effect of soy (Hillman et al., 2013 a).

Radio-sensitizer

Combined soy and radiation caused a significantly stronger inhibition of tumor progression compared to each modality alone in contrast to large invasive tumor nodules seen in control mice. At the same time, soy reduced radiation injury in lung tissue by decreasing pneumonitis, fibrosis and protecting alveolar septa, bronchioles and vessels (Hillman et al., 2013 b).

Endometrial Cancer

Because of their anti-oxidant and anti-mutagenic properties, flavonoids may reduce cancer risk. Some flavonoids have anti-estrogenic effects that can inhibit the growth and proliferation of endometrial cancer cells. The intake of flavanols, flavanones, flavonols, anthocyanidins, flavones, isoflavones, and proanthocyanidins was measured and high consumption of selected proanthocyanidins may reduce endometrial cancer risk (Rossi et al., 2013).

Breast Cancer Protection

The evidence to date from observational epidemiologic studies, suggests that soy food intake, in the amount consumed in Asian populations (about 10 to 20 mg isoflavones per day), may be associated with a reduction of risk of breast cancer development as well as mortality and recurrence among women with breast cancer. The large number of clinical intervention studies on soy that have investigated intermediate biomarkers of breast cancer risk, including circulating estrogen levels, mammographic density, and breast tissue changes (cell proliferation), have not shown clear beneficial or deleterious effects (Wu et al., 2013).

Cachexia-Inhibiting

Isoflavones possess anti-proliferative effects of cachexia-inducing cells (MKN45cl85 and 85As2mLuc) cancer cell lines. Isoflavone treatment on the models induced tumor cytostasis, attenuation of cachexia, and prolonged survival whereas discontinuation of the treatment resulted in progressive tumor growth and weight loss (Yanagihara et al., 2013).

Methylation Effects

There is an inverse correlation between estrogenic marker complement (C)3 and genistein, which suggests an anti-estrogenic effect. Isoflavones induced dose-specific changes in RARβ2 and CCND2 gene methylation, which correlated with genistein levels. Research by Qin & Zhu (2009) provides novel insights into estrogenic and methylation effects of dietary isoflavones.

References

Ahmad A, Biersack B, Li Y, et al. (2013). Perspectives on the Role of Isoflavones in Prostate Cancer. AAPS J, 15(4):991-1000.


Bialešová L, Brtko J, Lenko V, Macejov‡ D. (2013). Nuclear receptors – target molecules for isoflavones in cancer chemoprevention. Gen Physiol Biophys.


Douglas CC, Johnson SA, Arjmandi BH. (2013). Soy and its isoflavones: the truth behind the science in breast cancer. Anti-cancer Agents Med Chem, 13(8):1178-87.


Hillman GG, Singh-Gupta V, Lonardo F, et al [a]. (2013). Radioprotection of Lung Tissue by Soy Isoflavones. J Thorac Oncol.


Hillman GG, Singh-Gupta V, Hoogstra DJ, et al [b]. (2013). Differential effect of soy isoflavones in enhancing high intensity radiotherapy and protecting lung tissue in a preclinical model of lung carcinoma. Radiother Oncol. doi: 10.1016/j.radonc.2013.08.015.


Rossi M, Edefonti V, Parpinel M, et al. (2013). Proanthocyanidins and other flavonoids in relation to endometrial cancer risk: a case-control study in Italy. Br J Cancer, 109(7):1914-1920. doi: 10.1038/bjc.2013.447.


Wu AH, Lee E, Vigen C. (2013). Soy isoflavones and breast cancer. Am Soc Clin Oncol Educ Book, 2013:102-6. doi: E10.1200/EdBook_AM.2013.33.102.


Yanagihara K, Takigahira M, Mihara K, et al. (2013). Inhibitory effects of isoflavones on tumor growth and cachexia in newly established cachectic mouse models carrying human stomach cancers. Nutr Cancer, 65(4):578-89. doi: 10.1080/01635581.2013.776089.