Adrenoreceptors and bc - may 2010

Adrenoceptors and breast cancer:
Review article
Roisman R., Klemm O., Raphaeli G., and Roisman I.
Dedicated to Mrs. Minka Klavins and Prof. Janis V. Klavins
Albert Einstein College of Medicine, New York, NY, USA
Correspondence to:
Isaac Roisman, M.D., Dip. Surg., M. Surg., D.Sc.
P.O.Box 45470, Haifa 31453, Israel
Tel.: (972-4)8388393, Fax: (972-4)8379503 Adrenoceptors and breast cancer:
Review article
Introduction
The incidence of breast cancer has increased greatly in Israel over the past decade. It is estimated that in Israel in 2009 approximately 4800 new patients will suffer from Despite recent advances in the diagnosis and treatment of breast cancer, this disease continues to be a major cause of death. One of the biggest challenges in breast cancer treatment is bone metastasis. Breast cancer cells are capable of migrating to the bone marrow and utilizing the marrow microenvironment to remain quiescent. The preprotachykinin-1 (PPT-I) gene encodes for the tachykinin peptides, which interact with neurokinin (NK) receptors. Studies have correlated this interaction with breast cancer cells integration into the bone marrow and breast cancer progression (1). Environmental and psychological stresses have been shown to be associated with an increased incidence of cancer in man and animals. Stress-induced neuron chemical hormonal and immunological changes have been shown to influence tumor development. Stress may promote mammary carcinogenesis by affecting the neuroendocrine system and I or immune function. Neuroendocrine affects may involve changes in adrenocortical steroids or opioid peptides which may exert their effects by One of the risk factors for breast cancer is the increased amount of adipose tissue after menopause which elevates estradiol production. The adrenergic system plays a role in regulating energy balance through thermogensis and lipid mobilization from brown or white adipose tissues (3). The human fat cells are equipped with adrenergic receptors (adreno receptors) β1, β2 Physiology
The degree of affinity for adrenaline (epinephrine) is β2 > β1> β3 and the noradrenaline
(norephinephrine) it is β1 ≥ β2 > β3 (5).
Norepinephrine, epinephrine and dopamine are members of biogenic amines. They share a common precursor - tyrosine. It is converted to L-dopa by tyrosine hydroxylase and L-dopa is converted to dopamine by dopa decarboxylase. In the nerve terminal dopamine is converted to norepinepherine. If phenylethanol - N - methyl transferase (PNMT) is present norepinephrine is methylated to epinephrine. Adrenergic neurons secrete norepinephrine because they Adreno receptors may be activated by norepinephrine, which is released from adrenergic neurons, or by epinephrine, which is secreted into the circulation by the adrenal medulla. Among the sympathetic adrenoreceptors, receptor type is related to In addition to their role as neurotransmitters and stress hormones, catecholamines play a trophic role in the control of cell replication and differentiation in target cells that express adrenergic receptors. In some cell lines, β -adrenergic stimulation elicits a small, promotional effect on cell replication, whereas in others, stimulation of these receptors and the consequent rise in intracellular cAMP levels inhibits mitosis. β - adrenoreceptors on cancer cells, thus, recapitulate both the promotional and inhibitory roles of these receptors in cell replication seen in the development of normal cells. Location and mechanism of autonomic action Vascular smooth muscle, skin, renal and splanchnic gastrointestinal tract, bladder sphincter, iris, radial Gastrointestinal tract wall, presynaptic adrenergic Heart, salivary gland, adipose tissue, kidney stimulation of adenylyl cyclase, increase cAMP Va Vascular smooth muscle of skeletal muscle, GI wall, The β -adrenergic agonist isoproterenol, stimulates mammary epithelial cell division in vitro, as well as the development of end bud structures in the mammary gland of ovary ectomized mice from which arise the mammary carcinoma induced by administration of dimethylbenz (α) anthracene (DMBA). Specific β -adrenergic receptors of the β2 subtype are present in epithelial cell membranes from lactating The hormonal modulations of receptors which affect uterine contractility correlates with the onset of psychological responses of the uterus such as contraction and relaxation. In analogy with the uterus the regulation of the physiological status of the mammary gland is achieved by modification of endocrine, autonomic and mechanical factors during adolescence, the menstrual cycle, pregnancy parturition and lactation. The mammary gland, as other paired endocrine glands (adrenals, ovaries and testes), High levels of β -adrenergic receptors are measured as palpable mammary tumors, reaching a maximal concentration well before the actual increase in tumor mass. The hormone sensitivity of the tumoral β -adrenergic receptor is further confirmed by the high receptor concentration measured in progressing mammary tumors. Stress effects may involve ACTH, glucocorticoids, catecholamines, prolactin, opioids and immunosuppression, all factors crucially involved in tumor growth. Catecholestrogens, their receptors, together with their catabolizing enzyme, catechol- o-methyltransferease(COMT), are locally formed in both normal and neoplastic mammary tissues. COMT levels are significantly increased in the cytosol of malignant tumor cells than in the cytosol of benign tumor or normal cells (7).
Adrenoceptors and cancer
Recent studies in human cancer cell lines in animal models have shown that the growth of adenocarcinomas of the lungs, pancreas and colon are under β -adrenergic The expression of β -adrenergic receptors has been correlated with the over- expression of the arachidonic acid-metabolizing enzymes cyclooxygenase-2 (COX-2) and lipoxygenases (LOX) in adenocarcinomas of lungs, colon, prostate and pancreas. Inhibitors of these enzymes have been identified as cancer preventive agents in animal Many of breast adenocarcinomas over express COX-2 and / or LOX (13). This may say that a subset of breast cancers may also be under β adrenergic control. Studies have demonstrated that three estrogen-responsive and three non-estrogen responsive human cell lines derived from breast adenocarcinoma show a reduction in DNA synthesis in response to beta-blockers or inhibitors of the arachidonic acid- Another study analysis by reverse transcription polymerase chain reaction (RT-PCR) revealed expression of β 2-adrenergic receptors in all six breast cancer cell lines tested (MDA-MB-361, ZR-75-l, MCF-7, MDA-MB-453, MDA-MB-468, MDA-MB-4355). β 1 receptors were not found in two estrogen non-responsive cell lines (MDA-MB- It was found that the second messenger cAMP may be a growth promoter for mouse, rat and human mammary epithelioma (15, 16). The effects of cAMP observed in malignant cells are involved in redifferentiation amounting to renormalization of number of properties including morphology, adhesive properties, lectin agglutination, cell movement and biochemical functions A correlation between β adreno receptor (β -AR) stimulation and estrogen and progesterone receptor functions was found in human breast cancer (18). β 2-adrenergic stimulation induced cell proliferation in hormone-dependent human breast cancer cell line (C6-5), but without involving the female steroid hormone In C6-5 cells, the presence of functional β -AR's could be reasonable related to cell proliferation when exposed to different concentrations of clenbuterol, a β 2-AR agonist showed increased cell proliferation without involving significantly lower than that induced by oestradiol β adreno receptor-mediated inhibition of DNA synthesis was not shared by another cancer cell line, C6 rat glioma, that expresses a different β - receptor subtype a lower levels whereas found that MDA-MB-231 cells express β 2- receptors exclusively, C6 cell express primarily the β1 subtype (19). In mammary tissue there are data that support a role of catecholamines in the control of many cellular activities. Initial experiments indicate epinephrine sensitive adenylate cyclase activities in 7, 12 - dimethylbenz (α) anthracene - induced mammary carcinoma. Two groups have demonstrated the presence of β -adrenergic receptors (β -AR) from mammary glands of lactating rats. β -adrenergic compounds stimulated the enzyme leading to the generation of cAMP and its activation was completely abolished by the β -AR blocking drug propranolol. β -adrenergic - related increases in cAMP formation undoubtedly influence lactose production by the acinar secretory end pieces. The initial response to β -AR is usually an increase in adenylate cyclase activity resulting in an increased cellular cAMP Among the epithelial, endocrine, and secretory cancer cell lines that express adrenoreceptors, MDA-MB-231 human breast cancer cells exhibit comparatively high concentrations. It is thus of critical interest that stimulation of these receptors leads to immediate inhibition of DNA synthesis and, with prolonged exposure, reductions in the total number of cancer cells: inhibition of DNA synthesis is a reliable predictor of chemotherapeutic responses in breast cancer cells. In prostate or breast cancer cells stimulated by EGF or androgen or estradiol, small peptides (6-10 amino acids) derived from ER or AR sequences involved in the receptor interaction with Src, prevent AR/ER/Src association, Src/Erk pathway stimulation, cyclin D1 expression and DNA synthesis. The peptide action is restricted to cells expressing the steroid receptors and to signals mediated by these receptors. Remarkably, the peptides do not modify. Although there has been no systematic screening of breast cancer cell lines for β -adrenergic expression these receptors have identified in both estrogen-dependent type and estrogen-independent type, including C6-5, BF 20, T47-D, VHB-1 and MCF-7. Regardless of the ancillary mechanisms involved in β -receptor — mediated inhibition of mitosis in MDA-MB-231 breast cancer cells, the fact that inhibition does not disappear with receptor down regulation and desensitization raises the possibility for therapeutic strategies employing receptor agonists, alone or in combination with glucocorticoids and phosphodiesterase Screening of human cancers for the presence of β -adrenoreceptors or other cAMP — linked neurotransmitter receptors may establish new treatment strategies. β -adrenergic receptors (β -AR's) were identified in CG-5 breast cancer cells using a radiometric assay. The total β -AR concentration was measured using the highly potent β -adrenergic antagonist CGP 12 177, and the densities of β -AR subtypes were discriminated in the presence of highly selective unlabelled ligands (CGP 207 12A The second messenger cAMP was found to be a growth promoter for mouse, rat and human mammary epithelioma and its levels are elevated in several breast carcinomas. The effects of cAMP observed in malignant cells are often involved in redifferentiation, amounting to apparent renormalization of a number of properties including morphology, adhesive properties, lectin agglutination, cell movement and biochemical functions. A correlation between β -AR stimulation and estrogen and progesterone receptor functions was found in human breast cancer. It was observed that β2-adrenergic stimulation induced cell proliferation in a hormone-dependent human breast cancer cell line (CG-5), but without involving the CG-5 cells (mammary breast cell cancer cell line) contain measurable concentrations of specific β AR's coupled to adenylate cyclase. The characteristics of these β -AR's, identified by binding and competition assays, are those of β 1-AR and β2 -AR subtypes. β 2-AR concentration is significantly higher than β 1-AR concentration in CG-5 cell membranes. Negligible concentrations of β -AR's were found in MCF-7 breast cancer cells from which CG-5 cells are derived. In C6-5 cells the presence of functional β -AR's could be reasonably related to cell proliferation when exposed to different concentrations of clenbuterol, a β 2-AR agonist, showed increased cell proliferation without involving steroid hormone receptors. Although the enhancement of CG-5 cell growth was significantly lower than that induced by estradiol the presence of functional β -AR’s (with the prevalence of the β 2-AR subtype) in tumor cell line suggests that β -adrenergic stimulation and resulting cAMP production may be responsible for CG-5 cell proliferation. Medroxyprogesterone acetate (MPA) is one of the most widely used compounds in the endocrine therapy of advanced breast cancer in women. The mechanisms underlying the antitumor activity of MPA are poorly understood. This steroid presents a high affinity for progesterone (PgR) as well as for androgen (AR) and glucocorticoid receptors (GR) in human mammary tumors. The most easily explained effects of MPA are related to its glucocorticoid-like action. Suppression of adrenal function by MPA is believed to be caused both by an inhibitory action at the pituitary level and by direct inhibition of steroidogenesis. In addition to ER and PgR, which are the most widely used markers of differentiated endocrine functions in breast cancer; AR and GR (Glucocorticoid receptors) are present in a substantial number of mammary tumors and established cell lines. The ZR-75-1 human breast cancer cell line is an unusually appropriate system to study the direct effect of MPA on cell growth. ZR-75-1 cells contain functional receptors for estrogens, androgens, progestins and glucocorticoids. Progestins inhibit ZR-75-1 cell proliferation exclusively in presence of estrogens and in absence of insulin. MPA further decreased the growth of ZR-75- 1 cells co-incubated with maximally inhibitory concentrations of either 5 alpha-dihydrotestosterone ((DHT) or dexamethasone (DEX) although at about 300-fold higher MPA concentrations with DHT-treated than with DEX-treated ZR-75-1 cells, thus demonstrating a highly predominant androgenic effect. The main action of MPA on ZR-75-1 human breast cancer cell growth is due to its androgen receptor-mediated inhibitory action. The majority of breast cancer are adenocarcinomas and many of them over express cyclooxygenase - 2 (COX-2) (9) and/or lipoxygenases (LOX). This raises the possibility that comparable to findings in adenocarcinomas of the lungs, pancreas, colon and prostate, and a subset of breast cancer may also be under beta adrenergic control. Studies have demonstrated that three estrogen-responsive and three non- estrogen responsive human cell lines derived from breast adenocarcinomas demonstrated a significant reduction in DNA synthesis in response to beta-blockers or inhibitors of the arachidonic acid metabolizing enzymes COX-2 (9) and LOX-5. Analysis by reverse transcription polymerase chain reaction (RT-PCR) revealed expression of β2-adrenergic receptors in all six breast cancer cell tested (MDA-MB- 361, ZR-75-1, MCF-7, MDA-MB -453, MDA-MB-468, MDA-MB-435S) whereas β1 receptors were not found in two estrogen non-responsive cell lines (MDA-MB-435S, Expression of mRNA that encodes a G-protein coupled inward by rectifying potassium channel 1 (GIRK1) (7) has been shown in 40% breast cancer samples. This expression of GIRK1 was associated with a more aggressive clinical behavior. Previous studies indicated that the beta-adrenergic agonist isoproterenol stimulates growth. GIRK currents have been shown to be increased in cells stimulated with the beta-adrenergic agonist isoproterenol in rat atrial myocytes transferred with β1 or β2 receptors. Two po1ymorphisms in the β2 or β3 adrenergic receptors were found to be correlated with decreased risk for breast cancer, suggesting an important role of this receptor family in the genesis of breast cancer. In C6-5 cells (16, 19) the presence of functional β -AR's could be reasonable related to cell proliferation when exposed to different concentration of clenbuterol, a β 2-AR agonist showed increased cell proliferation without involving significantly lower than that induced by estradiol β adreno receptor-mediated inhibition of DNA synthesis was not shared by another cancer cell line, C6 rat glioma, that expresses a different β - receptor subtype a lower levels whereas (20) found that MOA-MB-23 1 cells express β 2-receptors exclusively, C6 cell express primarily the β1 subtype. There is increasing evidence that describes a histamine role in normal and cancer cell proliferation. To better understand the importance of histamine in breast cancer development, the expression of histamine H3 (H3R) and H4 (H4R) receptors and their association with proliferating cell nuclear antigen (PCNA), histidine decarboxylase (HDC) and histamine content were explored in mammary biopsies. Additionally, we investigated whether H3R and H4R were implicated in the biological responses triggered by histamine in MDA-MB-231(20) breast cancer cells. Centrally assess estrogen receptor (ER) and progesterone receptor (PgR) levels by immunohistochemistry and investigate their predictive value for benefit of chemo- endocrine compared with endocrine adjuvant therapy alone in two randomized clinical trials for node-negative breast cancer. Low levels of ER and PgR are predictive of the benefit of adding chemotherapy to endocrine therapy. Low PgR may add further predictions among pre-and perimenopausal but not postmenopausal patient whose tumors express ER. The majority of all breast cancers are hormone responsive, traditionally defined by he expression of oestogen receptor (ER) alpha and/or progesterone receptors. In contrast to ERalpha, the clinical significance of the relatively recently identified ERbeta is still ERalpha and ERbeta seem to be differentially associated to clinicopathological parameters, and this would support the fact that they might have different functions in In prostate or breast cancer cells stimulated by EGF or androgen or estradiol, small peptides (6-10 amino acids) derived from ER or AR sequences involved in the receptor interaction with Src, prevent AR/ER/Src association, Src/Erk pathway stimulation, cyclin D1 expression and DNA synthesis. The peptide action is restricted to cells expressing the steroid receptors and to signals mediated by these receptors. Epidermal growth factor (EGF), transforming growth factor-alpha (TGFalpha), amphiregulin (AREG), betacellulin (BTC), heparin-binding EGF-like growth factor (HB-EGF),epiregulin (EREG) and neuregulins1-4 (NRG1-4) were quantified in 363 tumors by real-time reverse transcription-polymerase chain reaction using TaqMan Paget's disease (PD) of the breast as well as the vulva is a rare condition, therefore anti-hormonal therapy is not indicated. The high frequency of Her-2/neu and COX-2 overexpression, however, suggests that these molecules could be therapeutically Epidemiological evidence indicates that the association between body weight and breast cancer risk may differ across menopausal status as well as the estrogen receptor (ER) and progesterone receptor (PR) tumor status. The relation between body weight and breast cancer risk is critically dependent on the tumor's ER/PR status and the woman's menopausal status. Body weith control is the effective strategy for preventing ER+PR+ tumors after menopause. ErbB3 transactivation can make tumor cells resistance to ErbB1/ErbB2 targeting drugs. This urges for a reliable method to determine cel surface ErbB3 levels, but their hands iodinated NRG1 beta is unstable and tends to underestimate the umber of ErbB3 receptors in a radio-receptor assay. Furthermore, they show by differential competition with unlabled NRG/YYDLL and betacellulin that the number of ErbB3 and ErbB4 receptors can be quantified separately on cultured human breast cancer cells. Esterogen receptor (ER) antagonists have been widely used for breast cancer treatment, but the efficacy and drug resistance remain to be clinical concerns. The purpose of this study was to determine whether the extracts of coptis, an anti- inflammatory herb, improve the anticancer efficacy of ER antagonists, Their results showed that the combined treatment of ER antagonists and the crude extract of coptis or its purified compound berberine conferred synergetic growth inhibitory effect on MCF-7 cells (ER+), but not on MDA-MB-231 cells (R-). Similar results were observed in the combined treatment of fulvestrant, a specific aromatase antagonist. Analysis of the expression of breast cancer related genes indicated the EGFR, HER2, bci-2, and COX-2 were significantly downregulated, while IFN-beta and p21 were The negative association between he oestrogen receptor (ER) and the human epidermal growth factor 2 (HER-2) in breast cancer travels in both directions. ER+ tumors are less likely HER-2+ and HER-2+ are less likely ER+. Studies the age- related immunohistochemical (IHC) expression of ER, HER-2 in 2,227 tumors using Estrogen receptors (ERs) are overexpressed in human breast cancers (BCs) and associated with differentiated tumors and with a more favorable prognosis (22-34). Paradoxically, ERs mediate the mitogenic action of estrogens in human BC cells and the efficacy of antiestrogens in adjuvant therapy of primary tumors. The exact mechanism underlying the ER protection against cancer progression to metastasis remains to be investigated. They show that ERs decrease invasiveness of BC cells. Detailed studies revealed that the unliganded and the E2-activated ERs decrease cancer cell invasion in vitro through two distinct mechanisms. In the presence of ligand, ERalpha inhibits invasion through a mechanism requiring the functional ERalpha domains involved in the transcriptional activation of target genes. Hormone receptors play important roles in breast cancer. The expression of hormone receptors in breast cancer was investigated to evaluate the importance of hormone receptors in the clinicopathology of breast cancer. Androgen receptor (AR), estrogen receptor (ER) and progesterone receptor (PR) expression characteristics were evaluated using immunohistochemistry stain, comparing patient age, tumor size and axillary lymph node status for 23 pure mucinous and 105 non-mucinous infiltrating ductal carcinomas in the human female Findings revealed that mucinous carcinoma samples from the breast show distinct clinicopathologic and hormone receptor expression features compared to non- There is increasing evidence that describes a histamine role in normal and cancer cell proliferations. To better understand the importance of histamine in breast cancer development, the expression of histamine H3 (H3R) nad H4 (H4R) receptors and their association with proliferating cell nuclear antigen (PCNA), histidine decarboxylase (HDC) and histamine content were explored in mammary biopsies. Additionally, we investigated whether H3R and H4R were implicated in the biological MDA-MB-231 β -adrenergic receptors (β -AR's) were identified in C6-5 breast cancer cells using a radiometric assay. The total β -AR concentration was measured using the highly potent β -adrenergic antagonist CGP 12 177, and the densities of β -AR subtypes were discriminated in the presence of highly selective unlabelled ligands (CGP 20712A and The second messenger cAMP was found to be a growth promoter for mouse, rat and human mammary epithelioma and its levels are elevated in several breast carcinomas. It was observed that β 2-adrenergic stimulation induced cell proliferation in a hormone dependent human breast cancer cell line (CG-5), but without involving the female steroid hormone receptor system. CG-5 cells (mammary breast cell cancer cell line) contain measurable concentrations of specific β AR's coupled to adenylate cyclase. The characteristics of these β -AR's, identified by binding and competition assays, are those of β 1-AR and β 2-AR subtypes. β 2-AR concentration is significantly higher than β 1-AR concentration in CG-5 cell membranes. Negligible concentrations of β – AR's were found in MCF-7 breast cancer cells from which CG-5 cells are derived. Although the enhancement of CG-5 cell growth was significantly lower than that induced by estradiol the presence of functional β -AR’s (with the prevalence of the β2- subtype AR) in tumor cell line suggests that β -adrenergic stimulation and resulting cAMP production may be responsible for CG-S cell proliferation. Medroxyprogesterone acetate (MPA) is one of the most widely used compounds in the endocrine therapy of advanced breast cancer in women. The mechanisms underlying the antitumor activity of MPA are poorly understood. This steroid presents a high affinity for progesterone (PgR) as well as for androgen (AR) and glucocorticoid receptors (GR) in human mammary tumors. The most easily explained effects of MPA are related to its glucocorticoid-like action. Suppression of adrenal function by MPA is believed to be caused both by an inhibitory action at the pituitary level and by direct inhibition of steroidogenesis. In addition to ER and PgR, which are the most widely used markers of differentiated endocrine functions in breast cancer; AR and GR are present in a substantial number of mammary tumors and established cell lines. The ZR-75-1 human breast cancer cell line is an unusually appropriate system to study the direct effect of MPA on cell growth. ZR-75-1 cells contain functional receptors for estrogens, androgens progestins and glucocorticoids. Progestins inhibit ZR-75- 1 cell proliferation exclusively in presence of estrogens and in absence of insulin. MPA further decreased the growth of ZR-75-1 cells co-incubated with maximally inhibitory concentrations of either 5 alpha-dihydrotestosterone (DHT) or dexamethasone (DEX) at about 300-fold higher MPA concentrations with DHT- treated than with DEX-treated ZR-75- 1 cells, thus demonstrating a highly predominant androgenic effect. The main action of MPA on ZR-75-1 human breast cancer cell growth is due to its androgen receptor-mediated inhibitory action.
In normal and malignant mammary tissues there are data supporting a role for catecholeamines in the control of many cellular activities. The presence of functional β-AR's in human mammary cell lines has been described. All six breast cell lines express either GIRK2 or GIRK4 indicating that functional GIRK potassium channels are possible in these cancer cell lines. The direct control of cell proliferation shown in vitro could eventually open new avenues for adjuvant therapies in the treatment of Bibliography
1. Reddy BY, Trzaska KA, Murthy RG, et al. Neurokinin receptors as potential targets in breast cancer treatment. Curr Drug Discov Technol, 2008; 5:15-19 2. Tejwani GA, Gudehithlu KP, Hanissian SH, et al. Facilitation of dimethylbenz[α]antracene- induced rat mammary tumorigensis by restraint stress: role of β-endorphin, prolactin and naltrexone. Carcinogenesis, 1991; 12:637-641. 3. Lafontan M, Berlan M. Fat cell adrenergic receptors and the control of white and brown fat cell function. J Lipid Res. 1993; 34:1057-1091. 4. Huang XE, Hamajima N, Sito T, et al. Possible association of beta2- and beta3- adrenergic receptor gene polymorphism with susceptibility to breast cancer. Breast Cancer Res. 2001; 3: 264-269. Epub 2001 Apr 26. 5. Arch JR, Kaumann AJ. Beta 3 and atypical beta-adrenoceptors. Med Res Rev. 6. Marchetti B, Spinola PG, Pelletier G, et al. A potential role for catecholamines in the development and progression of carcinogen-induced mammary tumors: hormonal control of beta-adrenergic receptors and correlation with tumor growth. J Steroid Biochem Mol Biol. 1991; 38:307-320. 7. Plummer HK, Yu Q, Cakir Y, et al. Expression of inwardly rectifying potassium channels (GIRKs) and beta-adrenergic regulation of breast cancer cell lines. BMC 8. Schuller HM, Tithof PK, Williams M, et al. The tobacco-specific carcinogen 4- (methylnitrosamino)-1-(3-pyridyl)-1-butanone is a beta-adrenergic agonist and stimulates DNA synthesis in lung adenocarcinoma via beta-adrenergic receptor- mediated release of arachidonic acid. Cancer Res. 1999; 59:4510-4515. 9. Schuller HM, Plummer HK, Bochsler PN, et al. Co-expression of beta adrenergic receptors and cyclooxygenase-2 in pulmonary adenocarcinoma. Int J Oncol. 10. Schuller HM, Porter B, Riechert A. Beta-adrenergic modulation of NNK-induced lung carcinogenesis in hamsters. J Cancer Res Clin Oncol.2000; 126:624-630. 11. Masur K, Niggemann B, Zanker KS, et al. Norepinephrine-induced migration of SW 480 colon carcinoma cells is inhibited by beta-blockers. Cancer Res. 2001; 12. Weddle DL, Tithoff P, Williams M, et al. Beta-adrenergic growth regulation of human cancer cell lines derived from pancreatic ductal carcinoma. 13. Parrett ML, Harris RE, Joarder FS, et al. Cyclooxygenase-2 gene expression in human breast cancer. Int J Oncology. 1997; 10:503-507. 14. Cakir Y, Plummer HK, Tithof PK, et al. Beta-adrenergic and arachidonic acid- mediated growth regulation of human breast cancer cell lines. Int J Oncol. 2002; 15. Yang Y, Guzman R, Richards J, et al. Growth factor- and cyclic nucleotide- induced proliferation of normal and malignant mammary epithelial cells in primary culture. Endocrinology. 1980; 107:35-41. 16. Badino GR, Novelli A, Girardi C, et al. Evidence for functional beta- adenoceptors subtypes in CG-5 breast cancer cell. Pharmacol Res. 1996; 33:255- 17. Yabushita H, Sartorelli AC. Effects of sodium butyrate, dimethylsulfoxide and dibutyryl cAMP on the poorly differentiated ovarian adenocarcinoma cell line 18. Draoui A, Vandewalle B, Hornez L, et al. Beta-adrenergic receptors in human breast cancer: identification, characterization and correlation with progesterone and estradiol receptors. Anticancer Res. 1991; 11:677-680. 19. Re G, Badino P, Girardi C, et al. Effects of beta-2 agonist (clenbuterol) on cultured human (CG-5) breast cancer cells. Pharmacol Res. 1992; 26:377-384. 20. Slotkin TA, Zhang J, Dancel R, et al. Beta-adrenoceptor signaling and its control of cell replication in MDA-MB-231 human breast cancer cells. Breast Cancer Res 21. Neven P, Van Calster B, Van den Bempt I, et al. Age interacts with the expression of steroid and HER-2 receptors in operable invasive breast cancer. Breast Cancer Res Treat. 2008; 110:153-159. 22. Maynadier M, Nirdé P, Ramirez JM, et al. Role of estrogens and their receptors in adhesion and invasiveness of breast cancer cells. Adv Exp Med Biol. 2008; 617: 23. Cho LC, Hsu YH. Expression of androgen, estrogen and progesterone receptors in mucinous carcinoma of the breast. Kaohsiung Med Sci. 2008; 24: 227-232. 24. Medina V, Croci M, Crescenti E, et al. The role of histamine in human mammary carcinogenesis: H3 and H4 receptors as potential therapeutic targets for breast cancer treatment. Cancer Biol Ther. 2008; 7: 28-35. 25. Subbaramaiah K, Hudis C, Chang SH, et al. EP2 and EP4 receptors regulate aromatase expression in human adipocytes and breast cancer cells. Evidence of a BRCA1 and p300 exchange. J Biol Chem. 2008; 283: 3433-3444. 26. Viale G, Regan MM, Maiorano E, et al. Chemoendocrine compared with endocrine adjuvant therapies for node-negative breast cancer: predictive value of centrally reviewed expression of estrogen and progesterone receptors – International Breast Cancer Study Group. J Clin Oncol. 2008; 26: 1404-1410. 27. Borgquist S, Holm C, Stendahl M, et al. Oestrogen receptors alpha and beta show different association to clinicopathological parameters and their co-expression might predict a better response to endocrine treatment in breast cancer. Clin 28. Auricchio F, Migliaccio A, Castoria G. Sex-steroid hormones and EGF signalling in breast and prostate cancer cells: targeting the association of Src with steroid 29. Révillion F, Lhotellier V, Hornez L, et al. ErbB/HER ligands in human breast cancer; and relationships with their receptors the bio-pathological features and 30. Horn LC, Purz S, Krumpe C, et al. COX-2 and Her-2/neu are overexpressed in Paget's disease of the vulva and the breast: results of a preliminary study. Arch 31. Dawood S, Broglio K, Kau SW, et al. Triple receptor-negative breast cancer: the effect of race on response to primary systemic treatment and survival outcomes. J 32. Suzuki R, Orsini N, Saji S, et al. Body weight and incidence of breast cancer defined by estrogen and progesterone receptor status - a meta-analysis. Int J 33. Van der woning SP and van Zoelen EJ. Quantification of ErbB3 receptor density on human breast cancer cells, using a stable radio-labeled mutant of NRG1beta. Biochem Biophys Res Commun. 2009; 378: 285-289. 34. Lui J, He C, Zhou K, et al. Coptis extracts enhance the anticancer effect of estrogen receptor antagonists on human breast cancer cells. Biochem Biophys

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