Phytoestrogen protection against breast cancer

Breast cancer is a kind of common malignancies with the high mortality rate in Western population. However, the people in the Asian societies have much lower incidences of this cancer than the individuals from the Western societies. Several investigations have been performed to explain this phenomenon, for instance, the Japanese women had markedly high concentrations of circulating and excreting phytoestrogen, indicating that the low mortality in breast cancer might be due to high soy intake [44, 45]. Moreover, a case-control study conducted among Asian-American women in Los Angeles County showed that soy intake reduced breast cancer risk, confirming the inverse association between dietary phytoestrogen and breast cancer [46]. Although phytoestrogen potentially exhibited an obvious protective effect in the breast cancer therapy in clinical studies, further basic biological investigations are necessary for obtaining theoretical support in the further experimental research. Herein, the mechanism of phytoestrogen action on integrating signaling pathways in breast cancer will be discussed for providing a molecular basis of future pharmacological studies of these compounds.

The signaling pathways mediating the apoptosis, invasion, metastasis and proliferation of breast cancer cells have been simplified and described in Fig. 2, which potentially mediate the phytoestrogen effects on breast cancer. They are composed of nuclear ER (genomic ER)-initiated, membrane ER (non-genomic ER)-mediated, growth factor (GF)-transduction, G protein receptor (GPR)-directed, and apoptotic signaling pathways. The activated nuclear ERα and/or ERβ could induce the modification of gene expression in breast cancer. Although encoded by unique genes, ERα and ERβ have certain functional domains with a highly similar affinity to ligand- and DNA-binding sites, suggesting that these two receptors might play redundant roles. The mammary cell has a predominant distribution of ERα [6, 47]. In the classic pathway to activate transcriptomes, the activated ERs dimerizes and forms a complex for binding to a specific DNA sequence, the estrogen response element (ERE). In non-classic pathway, E2-ER complex interacts with several transcription factors such as AP1, SP1 and NFkB to modulate gene expression without ERE [48]. Another genomic pathway is mediate by a ligand-independent manner, showing that GF activates intracellular kinase pathway to phosphorylate ER at ERE-containing promoters [6]. Apart form nuclear genomic action, the membrane ER has been demonstrated as a G protein-coupled receptor. The activated membrane ER induces the discretion of the G-protein α subunit to trigger the activation of Src kinases and PI3 kinase (PI3-K), respectively followed by downstream protein kinase C (PKC) and kinase cascade to extra-cellular regulated protein kinase (Erk), which are involved in proliferation and survival of breast cancer cells [47]. The PI3-K activation also triggers the recruitment of AKT, a serine-threnine kinase to control cell survival via activating downstream anti-apoptotic signals (e.g. Bcl-2) and transcription factors (e.g. NFkB and CREB) [49, 50]. In addition, growth factor receptors (GFR), including insulin-like growth factor receptor (IGFR) and epidermal growth factor receptor (EGFR), are the other E2-membrane signaling pathways within breast cancer cells. IGFR mediates the signal pathway through tethering ERα to plasma membrane, activating EGFR, and initiating PI3-K and Erk signaling [51]. In the ER-negative breast cancer cell, E2 directly interacted with GPR30 to induce the activation of downstream Scr-coupled Erk and cAMP/PKA signaling networks via Gβg-subunit protein [49]. The apoptotic signaling pathway is inactivated in most cancer cells, including a group of proteases such as caspase-8 and caspase-3 that cross-talk with EGF survival signaling network [50].

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Fig. 2.

A dynamic model of phytoestrogen actions on modulating signaling pathways in the breast cancer cell. The arrows and hammers respectively present stimulation and inhibition. Abbreviations: E2, estradiol; PE, phytoestrogen; ER, estrogen receptor, mER; membrane estrogen receptor; ERE, estrogen response element; TF, transcription factor; P, phosphorylation; EGF, epidermal growth factor; IGF, insulin-like growth factor; GFR, growth factor receptor; SOS, son of sevenless; Grb, growth factor-bound protein; Ras, related RAS viral oncogene homolog; PI3-K, phosphatidylinositol 3-OH kinase; cAMP, cyclic adenosine 3′,5′-monophosphate; CREB, cAMP response element binding protein; PKC, protein kinase C; Raf, v-raf-1 murine leukemian viral oncogene; Mek, mitogen/extracellular signal protein kinase; NFkB, nuclear factor-kappaB; PKA, protein kinase A; casp8, caspase-8; casp3, caspase-3.

The intracellular mechanisms of phytoestrogen protection against cellular proliferation of breast cancers might be via: (1) binding to nuclear ER and inhibiting genomic ER-mediated gene expression, (2) interaction with membrane ER, blocking protein kinases and suppressing transcription factors, (3) inhibiting GFR activation and its downstream signaling networks, (4) activating caspases to initiate cellular apoptosis, (5) reducing the G-protein mediated signaling pathway in the ER-negative mammary cancer cell [red hammers and blue arrows in Fig. 2]. The nuclear ER interaction is the most completely studied mechanism of phytoestrogen effect. The phytoestrogen-rich pueraria mirifica showed a strong competitive binding ability to ERα and/or possibly synthesized suppressor of ERα in the therapy of rat mammary tumor [52, Fig. 2-(1)]. Phytoestrogen is recently demonstrated to modulate ERα through the activation of ligand-independent pathway. Ginsenoside, a phytoestrogenic ingredient extracted from ginseng root, preferentially activated ERα via the phosphorylation of a transcription factor (AF-1) without the ligand-receptor interaction [53, Fig. 2-(2)]. However, isoflavone was demonstrated to selectively activate ERβ rather than ERα in the breast cancer cell line MCF-7, indicating a potential ERβ-relevant mechanism underlying protective effect of dietary phytoestrogen against mammary tumor [54, Fig. 2-(3)]. Moreover, genistein (an isoflavone) might induce a self-limiting mechanism of E2-stimulated ERβ gene expression in breast cancer cells [55, Fig. 2-(4)].

Although individual phytoestrogen interacted with various types of ER, most of phytoestrogen effects were ERα-dependent due to the predominant expression of this subtype in breast cells [6]. Furthermore, 8-prenylnaringenin was proven to activate membrane ERα and to interfere with an ER associated PI3-K pathway, resulting in the apoptosis and proliferation of MCF-7 breast cells [56, Fig. 2-(5)]. In the same cell line, resveratrol was also demonstrated to inactivate non-genomic ERα-mediated PI3-K/PKC signaling network because of lacking of a specific chemical structure part in this chemical. Meanwhile, resveratrol interfered with the Src-activated MAPK (including Mek and Erk) pathway, to reduce the generation of transcription factors [57, Fig. 2-(6)]. In ER-deficient mammary tumor cells, isoflavone selectively inhibited nuclear NFkB transduction of specific target gene through a new mechanism via depressing upstream Erk and Mek activities [58, Fig. 2-(7)]. Several other investigations have demonstrated the phytoestrogenic modulation of the PI3-K downstream signaling pathway. Genistein offspring not only elevated the quantity of ER binding sites, but also markedly repressed PKC activity in carcinogen-induced mammary tumorigenesis of female rats, [59, Fig. 2-(8)]. Regarding their regulatory effect on another downstream signaling, AKT, phytoestrogen stimulated the protein expression of the tumor suppressor PTEN that led to inhibiting the function of the AKT kinase in the growth of MCF-7 breast cancer cells [60, Fig. 2-(9)]. Bcl-2 is an anti-apoptotic protein controlled by AKT kinase; genistein showed an inhibitory effect on the Bcl-2 phosphorylation in human breast cells [61, Fig. 2-(10)]. Licochalcone-A, a flavone-like molecule, exerted an anti-tumor cytotoxic effect on MCF-7 cells in a manner of repressing the anti-apoptotic Bcl-2 and modifying the bcl-2/bax ratio to induce apoptosis [62, Fig. 2-(11)]. Regarding CREB (a signaling factor in the AKT pathway), isoflavone was capable of attenuating the interaction between the kinase and its promoters to decrease the cyclooxygenase-2 expression. The cyclooxgenase-2 is an important factor to mediate the breast carcinogenesis [63, Fig. 2-(12)].

Besides modifying ER signaling networks, phytoestrogen, including genistein, exhibited a stimulatory action on the EGFR expression but did not trigger the activation of downstream signaling target (Mek and Erk) in the mammary gland, indicating a potential ER-independent mechanism underlying their protection against breast cancer [64, Fig. 2-(13)]. In the ER-negative breast cancer cells, two major kinds of phytoestrogens, genistein and quercetin, modulated the activation of growth factors via the G protein-coupled receptor homologue GPR30. The competitive binding of phytoestrogens and natural E2 to GRP30 were speculated as a new implication for understanding phytoestrogenic protection against breast cancer progression [65, Fig. 2-(14)]. Based on the finding of caspase-3 deficiency in MCF-7 cells, genistein exerted a significantly strong anti-tumor effect with the reconstitution of caspase-3, suggesting that a caspase-dependent pathway initiated by phytoestrogens to induce the apoptosis of breast cancer cells [66, Fig. 2-(15)]. Taken together, phytoestrogen plays an important role in modulating mechanisms of ER-dependent and ER-independent signaling pathways, and would be recognized as a useful therapy for breast cancers in future clinical studies.