Inhibition of the SH3 domain-mediated binding of Src to the androgen receptor and its effect on tumor growth.

In human mammary and prostate cancer cells, steroid hormones or epidermal growth factor (EGF) trigger association of the androgen receptor (AR)-estradiol receptor (ER) (alpha or beta) complex with Src. This interaction activates Src and affects the G1 to S cell cycle progression. In this report, we identify the sequence responsible for the AR/Src interaction and describe a 10 amino-acid peptide that inhibits this interaction. Treatment of the human prostate or mammary cancer cells (LNCaP or MCF-7, respectively) with nanomolar concentrations of this peptide inhibits the androgen- or estradiol-induced association between the AR or the ER and Src the Src/Erk pathway activation, cyclin D1 expression and DNA synthesis, without interfering in the receptor-dependent transcriptional activity. Similarly, the peptide prevents the S phase entry of LNCaP and MCF-7 cells treated with EGF as well as mouse embryo fibroblasts stimulated with androgen or EGF. Interestingly, the peptide does not inhibit the S phase entry and cytoskeletal changes induced by EGF or serum treatment of AR-negative prostate cancer cell lines. The peptide is the first example of a specific inhibitor of steroid receptor-dependent signal transducing activity. The importance of these results is highlighted by the finding that the peptide strongly inhibits the growth of LNCaP xenografts established in nude mice.

Estradiol activation of human colon carcinoma-derived Caco-2 cell growth.

This is the first report on estrogen-dependent growth of human-derived colon carcinoma cells. Under selected conditions, growth of subconfluent Caco-2 cells is triggered by estradiol. Cell growth is estradiol concentration dependent, with maximal effect occurring at about 0.4 nM. Growth is prevented by two different antiestrogens: the partial agonist, OH-Tamoxifen, and the pore antagonist, ICI 182,780. The growth effect is specific for estradiol since other hormonal steroids tested do not affect cell growth. The amount of estradiol receptor in subconfluent Caco-2 cells, detected by blot with monoclonal antibodies directed against the receptor as well as estradiol binding assays, is similar to that of the classical estradiol-responsive, human mammary cancer-derived MCF-7 cells. Estradiol treatment of subconfluent Caco-2 cells rapidly and reversibly stimulates four important intermediates in a signal transduction pathway that is known to trigger cell proliferation: two members of the large family of c-src-related tyrosine kinases, c-src and c-yes, and two serine/threonine kinases, the mitogen-activated protein (MAP) kinases, erk-1 and erk-2. Tyrosine kinases activated by estradiol are up-stream MAP kinases and Caco-2 cell proliferation. In fact, genistein, a specific tyrosine kinase inhibitor, abolishes the estradiol stimulatory effect on both erk-2 activity and cell proliferation. Our findings show that in subconfluent Caco-2 cells, the estradiol-receptor complex activates the c-src, c-yes/MAP kinase pathway and activates growth. This could have important implications for the understanding of human intestinal carcinogenesis.

In vitro interaction of estradiol receptor with Ca2+-calmodulin.

Estradiol receptor (ER) activity requires interaction with hormone and specific DNA sequence. We now report that this receptor also interacts with calmodulin (CaM), the major intracellular mediator of Ca2+ action in eucaryotic cells. This interaction has been observed using both CaM-Sepharose and [125I]CaM. Crude and purified [3H]ER complex show high affinity interaction with CaM-Sepharose [dissociation constant (Kd) 0.12 and 0.16 nM, respectively]. Unoccupied receptor shows a similar high affinity interaction. Tamoxifen-ER complex also binds to CaM-Sepharose. Several findings show that this CaM-ER interaction is very specific: lack of this interaction has been observed in the presence of trifluoperazine, an inhibitor of protein binding to CaM; the receptor binds neither Sepharose, nor parvalbumin-Sepharose; competition of interaction of [3H]ER complex with CaM-Sepharose is observed by cold ER complex; rat liver glucocorticoid receptor does not bind to CaM-Sepharose. The interaction of purified receptor with 125I-labeled CaM has been detected by various techniques: centrifugation through sucrose gradient of CaM incubated with receptor shows that CaM binds to a protein forming a complex sedimenting at 5 S. This complex is shifted to the 7.5 S region by a monoclonal antireceptor antibody. Incubation of CaM with receptor followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis fluorography of the immunoprecipitated receptor shows that [125I]CaM coprecipitates with the receptor. Competition of this interaction by an excess of cold CaM is observed. Interaction of the receptor with CaM is also observed by the overlay technique.(ABSTRACT TRUNCATED AT 250 WORDS)

Epidermal growth factor induces protein tyrosine phosphorylation and association of p190 with ras-GTP-ase activating protein in Caco-2 cells.

Epidermal growth factor (EGF) modulates several functions of human enterocytes. We report that this growth factor induces strong tyrosine phosphorylation stimulation of its receptor and several putative substrates of the receptor intrinsic kinase including c-erb B2 in proliferating human colon carcinoma cells (Caco-2). In addition EGF induces stable association of the GTP-ase activating protein of p21ras to the p190 protein and to a 62 mol.wt. tyrosine-phosphorylated protein. This association is probably consequent to EGF stimulation of protein tyrosine phosphorylation and could coordinate progression through cell cycle with polarity, cell-cell interactions and cell mobility.

In vitro phosphorylation and hormone binding activation of the synthetic wild type human estradiol receptor.

A tyrosine kinase purified from calf uterus activates the hormone binding of endogenous estradiol receptor (ER) predephosphorylated and preinactivated by a nuclear phosphotyrosine phosphatase. The kinase also activates and phosphorylates the human estradiol receptor HEO synthesized in vitro, which differs from the wild type receptor HEGO because a glycine is replaced by a valine at position 400. Moreover, the kinase activates and phosphorylates a deletion mutant of HEO which consists almost exclusively of the hormone binding domain. Using HEGO and HEO in parallel and measuring both binding activation and phosphorylation of ER we now observe that the wild type receptor is a good kinase substrate, slightly better than HEO. Furthermore, HEGO like the calf uterus receptor in the presence of estradiol, stimulates the kinase. From present findings it appears that ER and uterus tyrosine kinase are functionally associated and that this association is abolished by glycine to valine substitution at position 400 of ER.

Sex steroid hormones act as growth factors.

We observed that sex steroid hormones, like growth factors, stimulate the Src/Ras/erk pathway of cell lines derived from human mammary or prostate cancers. In addition, hormone-dependent pathway activation can be induced in Cos cells, upon transfection of classic steroid receptors. Cross-talks between sex steroid receptors regulate their association with Src and consequent pathway activation. Oestradiol treatment of MCF-7 cells triggers simultaneous association of ER with Src and p85, the regulatory subunit of phosphatidylinositol-3-kinase (PI3-kinase) and activation of Src- and PI3-K-dependent pathways. Activation of the latter pathway triggers cyclin D1 transcription, that is unaffected by Mek-1 activation. This suggests that simultaneous activation of different signalling effectors is required to target different cell cycle components. Thus, a novel reciprocal cross-talk between the two pathways appears to be mediated by the ER. In all tested cells, activation of the signalling pathways has a proliferative role. Transcriptionally inactive ER expressed in NIH 3T3 cells responds to hormone causing Src/Ras/Erk pathway activation and DNA synthesis. This suggests that in these cells genomic activity is required for later events of cell growth.

Src is an initial target of sex steroid hormone action.

Recent observations that steroids use pathways universally known to be regulated by growth factors and interleukins highlight the following points: (1) Steroid stimulation of the canonical pathway Src/Ras/Erk signaling from membrane to nuclei or its single members has been observed in different cell types including human cancer-derived cells, neurons, osteoblasts, osteocytes, and endothelial cells. This stimulation has been reconstituted and analyzed in transiently transfected cells. (2) Cellular context and intracellular localization of receptors are crucial in determining the biological effects evoked by this hormonal stimulation: proliferation, protection from apoptosis, and vasorelaxation. (3) Classical steroid receptors localized in the extranuclear compartment directly and, in some cases, simultaneously interact with Src. They are capable of unexpected cross talks responsible for the observed effects. (4) Other signaling pathways including P13K/AKT are also stimulated by steroids. The aim of future work will be to arrive at an integrated general view of the different signaling pathways activated by steroids and to analyze the concert between these pathways and the hormonal transcriptional action. This general view should be simultaneously verified in different cell contexts, under different physiologic and pathologic conditions. We expect that the new technologies, above all gene and protein microarray, will make this goal feasible.

Role of non-genomic androgen signalling in suppressing proliferation of fibroblasts and fibrosarcoma cells.

The functions of androgen receptor (AR) in stromal cells are still debated in spite of the demonstrated importance of these cells in organ development and diseases. Here, we show that physiological androgen concentration (10 nM R1881 or DHT) fails to induce DNA synthesis, while it consistently stimulates cell migration in mesenchymal and transformed mesenchymal cells. Ten nanomolar R1881 triggers p27 Ser10 phosphorylation and its stabilization in NIH3T3 fibroblasts. Activation of Rac and its downstream effector DYRK 1B is responsible for p27 Ser10 phosphorylation and cell quiescence. Ten nanomolar androgen also inhibits transformation induced by oncogenic Ras in NIH3T3 fibroblasts. Overexpression of an AR mutant unable to interact with filamin A, use of a small peptide displacing AR/filamin A interaction, and filamin A knockdown indicate that the androgen-triggered AR/filamin A complex regulates the pathway leading to p27 Ser10 phosphorylation and cell cycle arrest. As the AR/filamin A complex is also responsible for migration stimulated by 10 nM androgen, our report shows that the androgen-triggered AR/filamin A complex controls, through Rac 1, the decision of cells to halt cell cycle and migration. This study reveals a new and unexpected role of androgen/AR signalling in coordinating stromal cell functions.

Tyrosine phosphorylation of estradiol receptor by Src regulates its hormone-dependent nuclear export and cell cycle progression in breast cancer cells.

We report that in breast cancer cells, tyrosine phosphorylation of the estradiol receptor alpha (ERalpha) by Src regulates cytoplasmic localization of the receptor and DNA synthesis. Inhibition of Src or use of a peptide mimicking the ERalpha p-Tyr537 sequence abolishes ERalpha tyrosine phosphorylation and traps the receptor in nuclei of estradiol-treated MCF-7 cells. An ERalpha mutant carrying a mutation of Tyr537 to phenylalanine (ER537F) persistently localizes in nuclei of various cell types. In contrast with ERalpha wt, ER537F does not associate with Ran and its interaction with Crm1 is insensitive to estradiol. Thus, independently of estradiol, ER537F is retained in nuclei, where it entangles FKHR-driving cell cycle arrest. Chromatin immunoprecipitation analysis reveals that overexpression of ER537F in breast cancer cells enhances FKHR interaction with cyclin D1 promoter. This mutant also counteracts cell transformation by the activated forms of Src or PI3-K. In conclusion, in addition to regulating receptor localization, ERalpha phosphorylation by Src is required for hormone responsiveness of DNA synthesis in breast cancer cells.

Dephosphorylation of oestradiol nuclear receptor in vitro. A hypothesis on the mechanism of action of non-steroidal anti-oestrogens.

We show that a mouse uterus nuclear phosphatase exists that is capable of inactivating nuclear oestrogen receptor complexed to oestradiol-17 beta in vitro but is ineffective when the receptor is complexed with the two non-steroidal anti-oestrogens, nafoxidine and tamoxifen. We suggest that the long half-life of the tamoxifen-receptor complex versus the short half-life of the oestradiol-receptor complex in uterine nuclei in vivo is the result of the ineffectiveness of the phosphatase in dephosphorylating the anti-oestrogen-receptor complex.

Activation-inactivation of hormone binding sites of the oestradiol-17 beta receptor is a multiregulated process.

The calf uterus oestradiol-17 beta receptor exists in a hormone binding form, which is phosphorylated on tyrosine, and in a non-hormone binding form, which is dephosphorylated. Two enzymes regulate the number of hormone binding sites of the receptor: a kinase which has been purified from cytosol and a phosphatase purified from nuclei. Recent and new findings on the regulation of this activation-inactivation process are reported. In vitro only a fraction (30-60%) of the receptor binding sites are inactivated by the phosphatase. Evidence is given suggesting that this is due to the production during the inactivation process of a powerful inhibitor of the phosphatase. Ca2+-calmodulin stimulates the kinase activity with a parallel increase of phosphorylation on tyrosine and hormone binding sites of the receptor. Nanomolar concentrations of oestradiol-17 beta also stimulate the kinase to activate hormone binding sites. These results suggest that in intact cells inactivation-activation of the oestradiol receptor is a multiregulated process.

Properties of a purified estradiol-dependent calf uterus tyrosine kinase.

A uterus tyrosine kinase has been purified to a single 67-kDa protein when analyzed by SDS-PAGE. Under nondenaturing conditions the molecular weight of the enzyme ranges from 114 to 136 kDa, depending on the procedure employed. The kinase binds calmodulin in a Ca(2+)-dependent manner and the ATP analog [(fluorosulfonyl)benzoyl]adenosine. The purified enzyme phosphorylates the phosphatase-treated uterus estradiol receptor on tyrosine and activates its hormone binding. The kinase phosphorylates actin, calmodulin, and histone H2B. Whatever the substrate, the enzymic activity is dependent on purified estradiol-receptor complex and is activated by Ca(2+)-calmodulin. The kinase activates and phosphorylates the human estradiol receptor (HEO) within the hormone binding domain (HBD) [Migliaccio, et al. (1989) Mol Endocrinol. 3, 1061-1069] as well as four of the five mutants of the HEO obtained by substituting each of the five tyrosine residues present in the HBD of the receptor with phenylalanine by site-directed mutagenesis. The mutant substituted at tyrosine 537 is the only one that is neither phosphorylated nor activated by the kinase. This proves a causal relationship between the phosphorylation of estradiol receptor on tyrosine 537 and its hormone binding activity. A synthetic peptide corresponding to 11 out of 13 amino acids surrounding tyrosine at position 537 of the human estrogen receptor can be phosphorylated by the kinase. This and other findings indicate that this kinase, unlike other tyrosine kinases, phosphorylates tyrosyl residues with acidic amino acids close to the carboxyl side.

A 67 kDa non-hormone binding estradiol receptor is present in human mammary cancers.

The presence of large amounts of a 67 kDa estradiol receptor that does not bind hormone was observed in 8 to 37 human mammary tumors (34 malignant and 3 benign). This form of receptor was detected by its conversion to hormone binding receptor by an endogenous tyrosine kinase in vitro. All 8 tumors were malignant. In these, the incubation of cytosol with ATP was seen to cause a 1- to 5-fold increase in estradiol-specific binding sites. These sites bound estradiol with physiological affinity, and their appearance was associated with tyrosine phosphorylation of estradiol receptor. The enzyme converting the non-hormone binding receptor into the hormone binding receptor is largely present in cytosol and scarce in membranes. It has been extensively purified. It is a 67 kDa protein under denaturating conditions, binds calmodulin-Sepharose in a Ca2+-dependent manner, is stimulated by Ca2+ and calmodulin, phosphorylates exogenous actin, is activated by the estradiol-receptor complex. The enzyme interacts with antibodies directed against the carboxy-terminal and catalytic domains of c-src. Therefore, it is a putative new member of the large c-src-related kinase family. Human mammary cancers with significant amounts of 67 kDa non-hormone binding receptor show relatively low levels of hormone binding estradiol receptor. The presence of non-hormone binding receptor that can be activated by in vitro tyrosine phosphorylation suggests that functional interaction of estradiol receptor with tyrosine kinases is altered in malignant tumors and has bearing on loss of hormone dependence and progression of the mammary cancer malignancy.

The role of estradiol receptor in the proliferative activity of vanadate on MCF-7 cells.

Vanadate stimulates growth of the estradiol-responsive MCF-7 cells in the absence of estrogens through a mechanism requiring tyrosine kinase activity. The proliferative effect of vanadate is mediated by estradiol receptor, and is inhibited by three antiestrogens, hydroxytamoxifen, ICI 164,384, and ICI 182,780. Estradiol abolishes the inhibitory effect of ICI 164,384 or ICI 182,780. Before stimulating cell proliferation, vanadate induces accumulation of tyrosine phosphorylation in several proteins including estradiol receptor and epidermal growth factor receptor. In addition, vanadate increases the binding activity of the estradiol receptor for its ligand. This is the first evidence of in vivo association between estradiol receptor tyrosine phosphorylation and its hormone-binding activation. Antiestrogens abolish the vanadate effect on estradiol receptor and epidermal growth factor receptor phosphorylation and reduce it on general protein tyrosine phosphorylation. These findings show that vanadate, apparently through estradiol receptor tyrosine phosphorylation, triggers activity of this receptor, which in turn stimulates protein tyrosine phosphorylation and induces cell proliferation.