Dietary exposure in utero and during lactation to a mixture of genistein and an anti-androgen fungicide in a rat mammary carcinogenesis model.

Endocrine disruptors may play substantial roles in the high incidence of breast cancer. We previously described how early exposure to the mixture of phytoestrogen genistein (G) and the anti-androgen vinclozolin (V) affects peripubertal mammary development. This study evaluates the carcinogenic potential of exposure to V alone or associated with G from conception until weaning in Wistar rats. Dams were exposed to V, G or GV during pregnancy/lactation. At PND50 offspring were treated with DMBA[7,12-dimethylbenz(a)anthracene]. V or GV maternal exposure decreased number of DMBA-induced mammary tumors in the offspring, without significant modifications in tumor incidence, multiplicity and latency. G exposure decreased number of tumors, incidence and multiplicity. Unexpectedly, GV exposure increased tumor volume (p=0.04 vs controls) and epithelial proliferation (p=0.001 vs controls; p=0.005 vs G,V only). All tumors were in situ carcinomas. Concluding, maternal gestation/lactation exposure to a vinclozolin and genistein mixture significantly increases offspring tumor growth without changes in carcinogenesis susceptibility.

In utero and lactational exposure to vinclozolin and genistein induces genomic changes in the rat mammary gland.

Exposure to low doses of environmental estrogens such as bisphenol A and genistein (G) alters mammary gland development. The effects of environmental anti-androgens, such as the fungicide vinclozolin (V), on mammary gland morphogenesis are unknown. We previously reported that perinatal exposure to G, V, and the GV combination causes histological changes in the mammary gland during the peripubertal period, suggesting alterations to the peripubertal hormone response. We now investigate whether perinatal exposure to these compounds alters the gene expression profiles of the developing glands to identify the dysregulated signaling pathways and the underlying mechanisms. G, V, or GV (1 mg/kg body weight per day) was added to diet of Wistar rats, from conception to weaning; female offspring mammary glands were collected at postnatal days (PNDs) 35 and 50. Genes displaying differential expression and belonging to different functional categories were validated by quantitative PCR and immunocytochemistry. At PND35, G had little effect; the slight changes noted were in genes related to morphogenesis. The changes following exposure to V concerned the functional categories associated with development (Cldn1, Krt17, and Sprr1a), carbohydrate metabolism, and steroidogenesis. The GV mixture upregulated genes (Krt17, Pvalb, and Tnni2) involved in muscle development, indicating effects on myoepithelial cells during mammary gland morphogenesis. Importantly, at PND50, cycling females exposed to GV showed an increase in the expression of genes (Csn2, Wap, and Elf5) related to differentiation, consistent with the previously reported abnormal lobuloalveolar development previously described. Thus, perinatal exposure to GV alters the mammary gland hormone response differently at PND35 (puberty) and in animals with established cycles.

Abnormal peripubertal development of the rat mammary gland following exposure in utero and during lactation to a mixture of genistein and the food contaminant vinclozolin.

The impact of early exposure to endocrine disruptor mixtures on mammary gland development is poorly known. Here, we identify the effects of a conception to weaning exposure of rats to the phytoestrogen genistein (G) and/or the antiandrogen vinclozolin (V) at 1mg/kg-d, alone or in association. Using several approaches, we found that G- and GV-exposed rats displayed significantly greater epithelial branching and proliferation, wider terminal end buds than controls at PND35, as well as ductal hyperplasia and periductal fibrosis. Focal branching defects were present in V-exposed rats. An increased ER and AR expression was observed in G- and GV- as compared to V-exposed rats at PND35. Surprisingly, a significant number of GV- and to a lesser extent, V-exposed animals displayed abnormal hyperplasic alveolar structures at PND50. Thus, gestational and lactational exposure to low doses of genistein plus vinclozolin may seriously affect peripubertal development of the rat mammary gland.

Regulation of the vascular endothelial growth factor (VEGF) receptor Flk-1/KDR by estradiol through VEGF in uterus.

The induction of vascular endothelial growth factor (VEGF) expression by 17beta-estradiol (E(2)) in many target cells, including epithelial cells, fibroblasts and smooth muscle cells, suggests a role for this hormone in the modulation of angiogenesis and vascular permeability. We have already described a cyclic increase in Flk-1/KDR-expressing capillaries in the human endometrium during the proliferative and mid-secretory phases, strongly suggestive of an E(2) effect on Flk-1/KDR expression in the endometrial capillaries. However, it is unclear whether these processes are due to a direct effect of E(2) on endothelial cells. Using immunohistochemistry, we report an increase in Flk-1/KDR expression in endometrial capillaries of ovariectomized mice treated with E(2), or both E(2) and progesterone. This process is mediated through estrogen receptor (ER) activation. In vitro experiments using quantitative RT-PCR analysis demonstrate that Flk-1/KDR expression was not regulated by E(2) in human endothelial cells from the microcirculation (HMEC-1) or macrocirculation (HUVEC), even in endothelial cells overexpressing ERalpha or ERbeta after ER-mediated adenovirus infection. In contrast, Flk-1/KDR expression was up-regulated by VEGF itself, in a time- and dose-dependent manner, with the maximal response at 10 ng/ml. Thus, we suggest that E(2) up-regulates Flk-1/KDR expression in vivo in endothelial cells mainly through the modulation of VEGF by a paracrine mechanism. It is currently unknown whether or not the endothelial origin might account for differences in the E(2)-modulation of VEGF receptor expression, particularly in relation to the vascular bed of sex steroid-responsive tissues.

Phytoestrogens as modulators of steroid action in target cells.

Although numerous reports exist on the potential beneficial role of nutritional phytoestrogens in human health, their molecular mechanism in target cells is still not completely understood. Phytoestrogens promote estrogen and antiestrogen effects by interacting with numerous molecules, carrier proteins, enzymes and membrane and nuclear receptors, directly or indirectly involved in the transfer of estrogen signals. The hypothesis that the ER beta subtype plays a key role in antiproliferative effect of phytoestrogens, especially in breast cancer, is examined here. This review focus on the effects of phytoestrogens in developmental processes such as those linked to reproductive function, tumorigenesis and angiogenesis.

Presence of estrogen receptor beta in the human endometrium through the cycle: expression in glandular, stromal, and vascular cells.

The recent discovery of a new isoform of estrogen receptor (ER) beta has prompted the reexamination of estrogen action on target organs. Here, we describe the endometrial expression of human ERbeta and compare its distribution with that of ERalpha in the endometrial functional zone. Using immunocytochemistry with well characterized polyclonal antibodies against ERbeta, we have detected specific ERbeta expression in all endometrial compartments (glandular, stromal, and vascular); the specificity of the immunostaining is confirmed by lack of staining of the uterine sections with anti-ERbeta antibodies previously incubated with peptide preparation. The highest levels of ERbeta expression are observed in epithelial cells during the periovulatory period (days 14 and 15), as well as in stromal cells and cells of the vascular wall in the late-secretory phase; both smooth muscle cells and endothelial cells express ERbeta, as deduced from immunocytochemistry and RT-PCR analysis. ERbeta staining is usually low compared with that of ERalpha, except at days 24-26. The presence of ERbeta in decidualized stromal cells is deduced from immunocytochemistry using antismooth alpha-actin and anti-ERbeta antibodies or from RT-PCR analysis of ERbeta and insulin-like growth factor-BP transcripts in the same cells; the presence of ERbeta-positive stromal cells located close to vascular smooth muscle cells during this period suggests some specific role of this receptor during decidualization. ERalpha is also present in the cells of the endometrial vascular wall, in addition to the nuclei of glandular epithelial and stromal cells. Vascular ERalpha expression is highest during the periovulatory period, suggesting a regulation by estradiol, and a role in vascular function. Moreover, different variations of ERbeta and ERalpha in arterioles might have implications for the modulation of vascular function, possibly of vascular tone, during the menstrual cycle. Finally, these data suggest that ERbeta may have important roles in endometrial function, in addition to the well known role of ERalpha in endometrial proliferation and differentiation.

Ovarian steroids in endometrial angiogenesis.

Angiogenesis, the sprouting of new blood vessels from pre-existing ones, is fundamental for human endometrial development and differentiation, which are necessary for implantation. This vascular process is supposed to be mainly mediated by the vascular endothelial growth factor (VEGF), also named vascular permeability factor (VPF). We report here the expression and modulation of VEGF and its receptors, Flk-1/KDR and Flt-1, in the functionalis throughout the menstrual cycle. Using immunocytochemistry, VEGF is localized in glandular epithelial cells and in the surrounding stroma, as well as in capillaries and spiral arterioles. The localization of VEGF on the endothelium correlates with the presence of Flt-1 and Flk-1/KDR receptors on vascular structures, including capillary strands that have not yet formed a lumen and that have been previously described in tumors as angiogenic capillaries. The strongest immunoreactivity for both VEGF and Flk-1/KDR receptor on endothelial cells is detected in the proliferative and midsecretory phases. Enhanced expression of VEGF and its Flk-1 receptors on narrow capillary strands during the proliferative phase may account for the rapid capillary growth associated with endometrial regeneration from the residual basal layer following menstrual shedding of the functionalis. The vascular expression of Flt-1 is more important in the secretory than in the proliferative phase, associated with a high microvascular density and an increase in vascular permeability in the implantation period. Consistently with these in vivo observations, the treatment of isolated endometrial stromal cells with estradiol (E(2)), or E(2) + progesterone, significantly increased VEGF mRNA over the control value in a dose-dependent manner. These results demonstrate that the expression of VEGF and its receptors is cyclically modulated by ovarian steroids, and that this endothelial growth factor acts on the endothelium in a paracrine fashion to control endometrial angiogenesis and permeability.

Vascular endothelial growth factor is modulated in vascular muscle cells by estradiol, tamoxifen, and hypoxia.

Vascular endothelial growth factor (VEGF) promotes neovascularization, microvascular permeability, and endothelial proliferation. We described previously VEGF mRNA and protein induction by estradiol (E2) in human endometrial fibroblasts. We report here E2 induction of VEGF expression in human venous muscle cells [smooth muscle cells (SMC) from human saphenous veins; HSVSMC] expressing both ER-alpha and ER-beta estrogen receptors. E2 at 10(-9) to 10(-8) M increases VEGF mRNA in HSVSMC in a time-dependent manner (3-fold at 24 h), as analyzed by semiquantitative RT-PCR. This level of induction is comparable with E2 endometrial induction of VEGF mRNA. Tamoxifen and hypoxia also increase HSVSMC VEGF mRNA expression over control values. Immunocytochemistry of saphenous veins and isolated SMC confirms translation of VEGF mRNA into protein. Immunoblot analysis of HSVSMC-conditioned medium detects three bands of 18, 23, and 28 kDa, corresponding to VEGF isoforms of 121, 165, and 189 amino acids. Radioreceptor assay of the conditioned medium produced by E2-stimulated HSVSMC reveals an increased VEGF secretion. Our data indicate that VEGF is E2, tamoxifen, and hypoxia inducible in cultured HSVSMC and E2 inducible in aortic SMC, suggesting E2 modulation of VEGF effects in angiogenesis, vascular permeability, and integrity.

Expression of vascular endothelial growth factor receptors in the human endometrium: modulation during the menstrual cycle.

Angiogenesis is fundamental for human endometrial development and differentiation necessary for implantation. These vascular changes are thought to be mediated by the vascular endothelial growth factor (VEGF), whose specific receptors have not been examined in detail thus far. We conducted the present study to determine, by immunocytochemistry and computerized image analysis of the functionalis, the expression and modulation of the receptors Flk-1/KDR and Flt-1, which mediate VEGF effects on endothelial mitogenicity, chemotaxis, and capillary permeability. VEGF receptors are expressed mainly in endometrial endothelial cells, with variations of intensity and number of stained capillaries related to the phase of the cycle. The number of capillaries immunostained for Flk-1/KDR was maximal in the proliferative phase (ratio Flk-1/CD34: 1), twice as high as the number of Flt-1-expressing capillaries (ratio Flt-1/CD34: 0.47). The staining intensity for Flk-1 decreased during the late proliferative and early secretory phases, to increase again in the midsecretory period. The number of Flt-1-labeled capillaries was about 2-fold higher in the secretory than in the proliferative phase; however, the proportion of Flt-1-positive cells did not change, owing to the associated increase in vascular density that characterizes progression of the functionalis from the proliferative to the secretory stage. The staining intensity for Flt-1 was higher during the late proliferative and secretory phases (especially in the midsecretory phase) and the premenstrual period. In contrast, the proportion of capillaries expressing Flk-1/KDR decreased in the secretory phase (ratio Flk-1/Von Willebrand factor: 0.55). Enhanced expression of Flk-1/KDR, and of Flt-1, on narrow capillary strands at the beginning of and during the proliferative phase may account for the rapid capillary growth associated with endometrial regeneration following menstrual shedding. The high coexpression of Flk-1/KDR and Flt-1 observed on capillaries during the midsecretory period correlates with an increase of endometrial microvascular density and of permeability characteristic of this phase of the cycle, which is a prerequisite for implantation. Finally, strong expression of Flt-1, but not Flk-1/KDR, was observed on dilated capillaries during the premenstrual period and the late proliferative phase, suggesting preferential association of Flt-1 with nonproliferating capillaries at those times; activation of this receptor by VEGF could be involved in premenstrual vascular hyperpermeability, edema, and extravasation of leukocytes. In addition to the endothelial localization, we found that epithelial cells expressed Flt-1 and Flk-1/KDR. We conclude that Flt-1 and Flk-1/KDR in the functionalis are modulated in parallel or independently according to the phase of the cycle, and that these changes are responsible for VEGF actions on endometrial vascular growth and permeability. The molecular mechanisms concerning these regulations will require further investigation.

Expression of metalloproteinases and their inhibitors in blood vessels in human endometrium.

Matrix metalloproteinases (MMPs) are zinc-requiring enzymes that can degrade components of the extracellular matrix and that are implicated in tissue remodeling. Their role in the onset of menstruation in vivo has been proven; however, the expression and functions of MMPs and tissue inhibitors of metalloproteinases (TIMPs) in vascular structures are poorly understood. We determined by immunocytochemistry, using characterized monoclonal antibodies, the distribution of MMPs and of their inhibitors TIMP-1 and TIMP-2 in the endometrium during the menstrual cycle. MMP-1, MMP-2, MMP-3, MMP-9, TIMP-1, and TIMP-2 had differing distributions and patterns of expression. In addition to the localization of MMP-9 in the epithelium and of MMP-2, MMP-3, and MMP-1 in the stromal tissue, these MMPs were detected in the vascular structures. MMP-2 (72-kDa gelatinase) and tissue inhibitors TIMP-1 and TIMP-2 were detectable in vessels throughout the cycle. In contrast, MMP-3 (stromelysin-1) was detected only in late-secretory and menstrual endometrial vessels, while MMP-9 (92-kDa gelatinase) was detected in spiral arteries during the secretory phase and in vascular structures during the midfollicular and menstrual phases. The expression of MMP-2 and MMP-9 in endometrial vessels during the proliferative and secretory periods suggests their relationship to vascular growth and angiogenesis. The pronounced expression of MMP-3 (stromelysin-1) in the vessels situated in the superficial endometrial layer during menses suggests that this metalloproteinase initiates damage in the vascular wall during menstrual breakdown. The finding of an intense expression of TIMP-1 and TIMP-2 in the vessels delineating necrotic from non-necrotic areas during menses also suggests that they could limit tissue damage, allowing regeneration of the endometrium after menses. These data indicate that, in addition to expression in epithelial cells and stromal tissue, MMPs are expressed in endometrial vascular cells in a cycle-specific pattern, consistent with regulation by steroid hormones and with specific roles in the vascular remodeling processes occurring in the endometrium during the cycle.

[Effect of estrogens on vascular proliferation]. / Effet des oestrogènes sur la prolifération vasculaire.

Studies on the effect of oestrogen on the circulatory apparatus have shown changes in vascular reactivity and structural alterations of blood vessels that participate in vascular growth and remodelling, whether physiological or pathological (atherosclerosis, ischaemia, restenosis). Direct vascular effects of oestradiol are mediated by functional steroid receptors, ER alpha and ER beta. ER alpha is predominantly found in arterial smooth muscle cells. During the menstrual cycle and pregnancy, endometrial vascular growth is required to allow embryo implantation and the development of the blood supply for fetal growth; oestradiol, in association with progesterone, promotes the growth of endometrial arteries, via ER and unknown mechanisms which probably involve the production of growth factors; oestradiol also induces endometrial angiogenesis, via the production of vascular endothelial growth factor (VEGF) by epithelial cells and fibroblasts. Oestradiol inhibits the proliferation of smooth muscle cells in the arterial wall (except in the genital tract), explaining in part the protective role of oestrogen against restenosis and chronic graft rejection. Further studies are required to determine the molecular mechanisms of these actions and the respective role of ER alpha and ER beta.

N-glycosylation of the prolactin receptor is not required for activation of gene transcription but is crucial for its cell surface targeting.

The functional importance of the three oligosaccharide chains linked to Asn35, Asn80 and Asn108, of the long form of the PRL receptor (PRLR) was investigated by individual or multiple substitutions of asparagyl residues using site-directed mutagenesis and transient transfection of these mutated forms of PRLR in monkey kidney cells, Chinese hamster ovary, and human 293 fibroblast cells that exhibit different levels of protein expression. Scatchard analysis performed on monkey kidney cells revealed that the mutants possess the same affinity for PRL as compared with wild-type PRLR. A strong reduction (90%) of the aglycosylated PRLR expression at the cell surface of monkey kidney or human 293 cells was observed. Immunohistochemistry experiments using an anti-PRLR monoclonal antibody showed an accumulation of the deglycosylated receptor in the Golgi area of transfected monkey kidney cells. Upon PRL stimulation, the aglycosylated PRLR associated with Janus kinase 2 was phosphorylated and was able to activate a beta-casein gene promoter in transfected 293 fibroblast cells. The active form of the PRLR was thus acquired independently of glycosylation. By contrast, no functional activity was detectable in transfected Chinese hamster ovary cells that expressed low levels of PRLR. These studies demonstrate that the glycosylation on the asparagyl residues of the extracellular domain of the PRLR is crucial for its cell surface localization and may affect signal transduction, depending on the cell line.

Paracrine action of vascular endothelial growth factor in the human endometrium: production and target sites, and hormonal regulation.

Vascular endothelial growth factor (VEGF) is an endothelium-specific growth factor with potent angiogenic activity and a stimulator of microvascular permeability. Because endometrial cyclic development is associated with vascular growth, we examined the expression of VEGF protein throughout the menstrual cycle and studied the regulation of VEGF mRNA by ovarian steroids in isolated human endometrial stromal cells. VEGF was localized immunohistochemically in glandular epithelial cells and in the surrounding stroma, as well as in capillaries and spiral arterioles, a localization which has not been described before. The strongest immunoreactivity for VEGF on endothelial cells was detected in the late proliferative and secretory phases. The localization of VEGF bound to the endothelium correlates with the presence of flt-1 and flk/KDR receptors on vascular structures, including capillary strands which have not yet formed a lumen, present during the mid-secretory period, which corresponds to a high estroprogestin influence and to implantation. Heparinase treatment of the sections decreases the staining intensity of VEGF bound to endothelial cells, suggesting that VEGF also binds to heparin-like molecules on the cell surface. These new results demonstrate a major role of VEGF on capillary formation and on hyperpermeability and edema during the menstrual cycle. Consistent with these in vivo observations, the treatment of isolated endometrial stromal cells with estradiol (E2) or E2 plus progesterone, significantly increased VEGF mRNA over the control value in a dose-dependent manner; the VEGF mRNA response to E2 was rapid (3h) and persisted with continuous estradiol treatment up to 12 days. Three species, VEGF_121, VEGF165 and VEGF189, were observed upon hormonal stimulation. The estradiol up-regulation of VEGF response did not require de novo protein synthesis as it was not blocked by cycloheximide. Also, the ability of the pure anti-estrogen ICI 182,780 to significantly block induction of VEGF mRNA by E2 suggests estrogen receptor-mediated transcriptional regulation. These results demonstrate that VEGF is an estrogen-responsive angiogenic factor that acts on vascular endothelium in a paracrine fashion, as previously suggested. This growth factor controls angiogenesis and hyperpermeability required for adequate receptivity to implantation of the cycling human endometrium. These findings also raise the possibility that estrogen effects on uterine edema, proliferation and tumoral transformation may involve local increases in tissue VEGF production.

The short form of the prolactin (PRL) receptor silences PRL induction of the beta-casein gene promoter.

The PRL receptor (PRLR) is a member of the cytokine receptor superfamily. Rats and mice express two forms of PRLR, short (SPRLR) and long (LPRLR), which differ in the length and sequence of their cytoplasmic domains. We have analyzed the ability of each form of rat PRLR to transduce lactogenic signals in a bovine mammary gland epithelial cell line. The rat PRLR forms were expressed and detected by RT-PCR, indirect immunofluorescence, and cell surface ligand binding. When the biological activity of each form of PRLR was assessed by transient transfection, we found that the long form was able to activate the beta-casein gene promoter and that the short form was inactive. Interestingly, the coexpression of both forms of PRLR resulted in a block of PRL signal to the milk protein gene promoter as a function of the concentration of the SPRLR. Similar results were obtained when LPRLR was coexpressed with totally or partially inactive tyrosine mutants of either the Nb2 form or the LPRLR form. Thus, these results suggest that the SPRLR form has at least one clear biological function, i.e. to silence lactogenic signals and to contribute to a differential and acute PRL effect in rat tissues. Furthermore, the data derived from coexpression of LPRLR and PRLR mutants confirm a crucial role of the C-terminal tyrosine residue in lactogenic signaling and the dimerization of PRLRs.

Dominant negative and cooperative effects of mutant forms of prolactin receptor.

In addition to a long form of 591 amino acids (aa), two other forms of PRL receptor (PRLR), differing in the length of their cytoplasmic domains, have been identified in the rat. The Nb2 form, lacking 198 aa in the cytoplasmic domain, is able to transmit a lactogenic signal similar to the long form, whereas the short form of 291 aa is inactive. The ability of PRL to activate the promoter of the beta-casein gene or the lactogenic hormone responsive element fused to the luciferase reporter was assessed in Chinese hamster ovary cells or 293 fibroblasts transiently transfected with PRLR cDNAs. The function of the short form was examined after cotransfection of both the long and short forms. These results clearly show that the short form acts as a dominant negative inhibitor through the formation of inactive heterodimers, resulting in an inhibition of Janus kinase 2 (JAK2) activation. The present study also investigates the possible participation of cytoplasmic receptors in the signal transduction pathway, using cotransfection experiments and a new approach that selectively determines the contribution of cytoplasmic receptors in the process of signal transduction. We cotransfected Chinese hamster ovary cells with two cDNA constructs: a cytoplasmic (soluble) form of the receptor with a deleted signal peptide (delta-19), which is unable to bind PRL, and a functionally inactive receptor mutant (lacking box 1), which is anchored in the plasma membrane and able to bind PRL. This approach has allowed us to show that delta-19, lacking expression at the plasma membrane, can transduce the hormonal message, at least to a limited extent (up to 30% of wild type efficiency), providing that association/activation occurs with a PRL-PRLR complex initiated at the cell surface level; box 1 of the cytoplasmic form is necessary to rescue this partial transcriptional activity of the inactive mutant. This partial recovery is also parallel to the partial activation of JAK2, indicating that the signal transduction pathway implicated JAK2. Our results provide evidence that heterodimerization of receptors can be implicated either in the positive or in negative activation of gene transcription.

Internalization of prolactin receptor and prolactin in transfected cells does not involve nuclear translocation.

Prolactin (PRL) interacts with a specific, well characterized plasma membrane receptor (PRLR) that is coupled to signal transduction pathways involving Jak2, Fyn, and MAP kinases, and signal transducers and activators of transcription (STAT). Although a few previous studies have indicated nuclear translocation of PRL in IL-2 stimulated T lymphocytes, PRL-dependent Nb2 lymphoma cell lines and 235-1 lactotrophs, the mechanisms of nuclear targeting remain unknown and conflicting results have been reported concerning the putative nuclear translocation of the PRLR. We therefore decided to investigate nuclear translocation of PRLR and PRL in various cell lines transfected with an expression plasmid encoding PRLR, using confocal laser microscopy. We have constructed various cDNAs of the long and short forms of the rat PRLR containing an oligonucleotide encoding a Flag epitope inserted either just before the N-terminal amino acid or in the C-terminal end of the mature receptor (named N-terminal or C-terminal Flag-tagged PRLR). The corresponding receptors function as the PRLR in transfected cells: they are expressed at the plasma membrane and in compartments of the secretory pathway, they bind PRL with normal affinity (Kd= 4x10(-10) M) and have the same capacity to stimulate the transcriptional activity of a milk protein (beta-casein) gene as wild-type PRLR. In addition, the tagged receptors are much more efficiently immunodetected using anti-Flag antibodies, as compared to anti-PRL antibodies (U5 or U6). Immunofluorescence combined with detailed confocal laser microscopy showed that addition of PRL (0 to 12 hours) to COS-7, CHO and NIH-3T3 transfected fibroblasts induces rapid internalization of the receptor (long form), without any translocation to the nucleus. Using PRL-R tagged both in the N-terminal or C-terminal regions of the mature receptor excludes the possibility of a cleaved fragment which could have been subsequently imported into the nucleus. An absence of nuclear translocation of PRLR was also observed in a 293 cell line stably expressing the receptor, and in physiological targets for PRL, i.e. in Nb2 lymphoma cells expressing the Nb2 form of the receptor or in BGME mammary gland epithelial cells upon overexpression of a Flag-tagged PRLR. Similarly, the short form of the PRLR was not detected in nuclei of transfected COS cells upon PRL treatment. Clearly, our results provide evidence that internalization of the plasma membrane PRLR does not lead to nuclear translocation of the receptor, or part of it, in most fibroblasts and epithelial cells at physiological concentrations of PRL. Also, in co-localization experiments, PRL was internalized without nuclear translocation. Activation of STATs transcription factors and MAP kinases, as well as translocation of these proteins to the nucleus following their phosphorylation, probably remains the intracellular mechanism coupling stimulation to nuclear events.

Prolactin activates tyrosyl phosphorylation of insulin receptor substrate 1 and phosphatidylinositol-3-OH kinase.

Prolactin (PRL) has been demonstrated to induce tyrosine phosphorylation and activation of the cytoplasmic tyrosine kinase JAK2. The present study represents an initial effort to identify the phosphorylation repertoire of the PRL receptor (PRLR). For this purpose we have modified the rat PRLR cDNA to encode an additional N-terminal epitope specifically designed to allow the rapid purification of the PRLR and associated proteins from transfected cells. The Flag-tagged PRLR was stably expressed in the human 293 cell line. PRL induced tyrosine phosphorylation of proteins of 85, 95, and 185 kDa from 10 to 30 min after PRL stimulation. Immunoblot analysis of immunoprecipitation indicates that p85 corresponds to the 85-kDa regulatory subunit of phosphatidylinositol (PI)-3' kinase, p95 to PRLR, and p185 to insulin receptor substrate 1 (IRS-1). Both PI-3' kinase and IRS-1 appear to associate with PRLR in a PRL-dependent manner. These results thus indicate that kinases other than JAK2, namely PI-3' kinase, are activated by PRL.

Estrogen receptors in the cardiovascular system.

Various direct effects of estradiol on arterial tissue suggest the presence of estrogen receptors (ER) in the vascular wall. The study of ER detection has made an important progress over the last 10 years with the advent and widespread use of monoclonal antibodies against the receptor protein. Using immunocytochemical methods and monoclonal antibodies, we have detected estrogen receptors in the tunica media of arteries from the reproductive tract; their concentration depends on the hormonal status. These receptors are apparently absent from saphenous veins (taken from patients undergoing surgical removal of varicose veins). We also document here results on the cardiovascular system we discuss their implications in blood vessel relaxation and cell proliferation.

Progesterone receptor expression in human saphenous veins.

BACKGROUND: Clinical and epidemiological observations regarding varicose veins, such as their predominance in women and the occurrence of venous stasis during sex-hormone therapy, the luteal phase of the menstrual cycle, and pregnancy, suggest a sex hormone-dependency of this venous pathology. In the present study, analysis of steroid receptors was used to determine if these effects were due to a direct hormonal action on the saphenous vein. METHODS AND RESULTS: Biopsy samples were obtained from patients undergoing stripping removal of varicose saphenous veins. Patients were men (n = 5) and premenopausal (n = 15) or postmenopausal (n = 10) women. Progesterone receptors (PR) and estrogen receptors (ER) were determined by both enzyme immunoassay (EIA) and immunocytochemistry by use of monoclonal antibodies. Ninety percent of the biopsy samples showed PR positivity by EIA (range, 5 to 53 fmol/mg cytosol protein). When present, PR staining was observed in the cell nuclei of the tunica media and the subendothelial layer (neointima). No significant variation was observed in the PR content of different regions within the same saphenous vein. In contrast, no ER or extremely low levels of ER (< 5 fmol/mg cytosol protein) were detected by EIA in 25 of 30 varicose biopsy samples. Reverse transcription-polymerase chain reaction (RT-PCR) was used to analyze PR and ER mRNAs in biopsy samples that were PR positive/ER negative. With primers to the hormone-binding region encoded by PR mRNA, a RT-PCR product of the expected size was detected and its identity confirmed by Southern blot by use of a PR cDNA probe. In contrast, no RT-PCR product could be detected by use of primers to the DNA-binding domain, the hinge region, and the ligand-binding domain encoded by ER mRNA. CONCLUSIONS: These results indicate that human saphenous veins from both sexes express PR, as previously described for arterial blood vessels. This observation suggests that progesterone acts directly on these veins via a classic receptor-mediated pathway.