Dopamine activation of an orphan of the steroid receptor superfamily.

The chicken ovalbumin upstream promoter transcription factor (COUP-TF) is a member of the steroid receptor superfamily and participates in the regulation of several genes. While a number of functions have been ascribed to COUP-TF, no ligand or activator molecule has been identified, and thus it is classified as one of a group of orphan receptors. Activation of COUP-TF by physiological concentrations of the neurotransmitter dopamine was observed in transient transfection assays. Treatment of transfected cells with the dopamine receptor agonist alpha-ergocryptine also activated COUP-dependent expression of a reporter gene. COUP-TF that contained a deletion in the COOH-terminal domain was not activated by these compounds. These observations suggest that dopamine may be a physiological activator of COUP-TF.

Dopaminergic and ligand-independent activation of steroid hormone receptors.

The current view of how steroid hormone receptors affect gene transcription is that these receptors, on binding ligand, change to a state in which they can interact with chromatin and regulate transcription of target genes. Receptor activation is believed to be dependent only on this ligand-binding event. Selected steroid hormone receptors can be activated in a ligand-independent manner by a membrane receptor agonist, the neurotransmitter dopamine. In vitro, dopamine faithfully mimicked the effect of progesterone by causing a translocation of chicken progesterone receptor (cPR) from cytoplasm to nucleus. Dual activation by progesterone and dopamine was dissociable, and a serine residue in the cPR was identified that is not necessary for progesterone-dependent activation of cPR, but is essential for dopamine activation of this receptor.

Subgroup of reproductive functions of progesterone mediated by progesterone receptor-B isoform.

Progesterone regulates reproductive function through two intracellular receptors, progesterone receptor-A (PR-A) and progesterone receptor-B (PR-B), that arise from a single gene and function as transcriptional regulators of progesterone-responsive genes. Although in vitro studies show that PR isoforms can display different transcriptional regulatory activities, their physiological significance is unknown. By selective ablation of PR-A in mice, we show that the PR-B isoform modulates a subset of reproductive functions of progesterone by regulation of a subset of progesterone-responsive target genes. Thus, PR-A and PR-B are functionally distinct mediators of progesterone action in vivo and should provide suitable targets for generation of tissue-selective progestins.

Molecular cloning of the chicken progesterone receptor.

To define the functional domains of the progesterone receptor required for gene regulation, complementary DNA (cDNA) clones encoding the chicken progesterone receptor have been isolated from a chicken oviduct lambda gt11 cDNA expression library. Positive clones expressed antigenic determinants that cross-reacted with six monospecific antibodies derived from two independent sources. A 36-amino acid peptide sequence obtained by microsequencing of purified progesterone receptor was encoded by nucleotide sequences in the longest cDNA clone. Analysis of the amino acid sequence of the progesterone receptor deduced from the cDNA clones revealed a cysteine-rich region that was homologous to a region found in the estrogen and glucocorticoid receptors and to the avian erythroblastosis virus gag-erb-A fusion protein. Northern blot analysis with chicken progesterone receptor cDNA's indicated the existence of at least three messenger RNA species. These messages were found only in oviduct and could be induced by estrogens.

Nucleotide and primary amino acid sequence of porcine lactoferrin.

A cDNA encoding porcine lactoferrin (pLF) was isolated from a porcine mammary gland lambda gt11 cDNA library using human lactoferrin cDNA as the hybridization probe. Nucleotide sequence analysis indicates that pLF is 686 amino acids in length and shares 72.6%, 70.7% and 62.2% overall amino acid sequence identity with bovine, human and murine lactoferrin, respectively.

New insights into activation of the steroid hormone receptor superfamily.

For many years the prevailing view of how steroid hormone receptors exert their effects on gene transcription has been that these intracellular receptor proteins, upon association with their specific cognate ligands, undergo a transformation to a state where they are capable of interacting with chromatin and regulating the transcription of specific genes. It has become implicit dogma in the field of biochemical endocrinology that receptor activation is absolutely dependent upon this ligand-binding event. However, recent studies described here by Bert O'Malley and colleagues have shown that certain members of the steroid hormone receptor superfamily can be activated in a totally ligand-independent manner by a cell membrane receptor agonist, the neurotransmitter dopamine.

Neuroendocrine regulation of the hypothalamic pituitary adrenal axis by the nurr1/nur77 subfamily of nuclear receptors.

The present study was designed to examine the role of the nurr1/nur77 subfamily of nuclear receptor transcription factors in the regulation of the hypothalamic/pituitary/adrenal axis at the neuroendocrine level. We demonstrate that this nuclear receptor subfamily can regulate the expression of the CRF and POMC genes by interacting with a specific cis-acting sequence in their proximal promoter regions. To examine the physiological significance of this response, we have focused on the POMC gene. We provide evidence that nurr1 and nur77 are rapidly induced by CRF in primary pituitary cells and that this induction is mimicked by forskolin in an anterior pituitary cell line. Further, we demonstrate that both nurr1- and forskolin-dependent induction of a POMC-chloramphenicol acetyltransferase reporter gene are inhibited by mutation of the nurr1-binding site within the POMC promoter and that this site alone can confer cAMP responsiveness to a heterologous promoter. Finally, we provide evidence that the nurr1/nur77 response sequence is pivotal to both nurr1/nur77-dependent positive regulation and glucocorticoid receptor-dependent negative regulation of the POMC gene. These data strongly support the conclusion that the nurr1/nur77 subfamily plays an important coordinate neuroendocrine-regulatory role at all levels of the hypothalamic/pituitary/adrenal axis.

Identification of a new brain-specific transcription factor, NURR1.

We have identified and cloned a novel member of the nuclear receptor superfamily. The cDNA was isolated from a mouse brain cDNA library and encodes a protein 598 amino acids in length with a predicted mol wt of 66 kilodaltons. The amino acid sequence of the protein is closely related to an additional family member and immediate early gene product, Nur77, and the novel factor is referred to as Nurr1 (Nur-related factor 1). The relationship between Nurr1 and Nur77 suggests that these proteins constitute an additional subfamily within the nuclear receptor superfamily. Like Nur77, the expression of Nurr1 is induced by membrane depolarization of PC12 cells. However, while Nur77 shows an early transcriptional response to nerve growth factor stimulation, the failure of Nurr1 to respond to this agent suggests a differential selectivity of the two proteins in terms of their transcriptional responses to specific stimuli. Finally, both proteins are differentially expressed during development and in tissues of the adult mouse. Unlike Nur77, Nurr1 appears to be predominantly located in brain tissue, suggesting a primary role for this putative transcription factor in regulation of gene expression in the central nervous system.

Structural organization and regulation of the chicken estrogen receptor.

We have cloned the chicken estrogen receptor (ER) from a chicken oviduct lambda gt11 library using the human ER cDNA sequence. This chicken ER sequence is virtually identical to the recently published sequence. One noteable difference is an amino acid change from glutamine to arginine located toward the central region of the sequence. The size of the ER protein predicted from the 589 amino acids is approximately 66,000 which fits well with the range of molecular weights previously published for the calf uterine and human ER (65,000-70,000). We observed the size of the chicken ER mRNA to be approximately 7.8 kilobases which is in agreement with the previously published size of 7.5 kilobases. In vivo secondary stimulation of chicken oviduct total RNA with diethylstilbestrol does not induce chicken ER mRNA. A time course following the chicken ER mRNA levels after secondary stimulation with diethylstilbestrol indicated a decrease in mRNA levels 8 h after DES administration. A similar study was performed using progesterone for the secondary stimulation. An increase in the chicken ER mRNA levels was observed 24 h after stimulation with progesterone. Two regions of very high homology were delineated by analyzing the sequence of this chicken ER cDNA and comparing it to the sequences of the human ER, human glucocorticoid, and chicken progesterone receptors and the P75-erbA fusion product of the avian erythroblastosis virus. The first concensus region is 72 amino acids in length and the second region of high homology is 62 amino acids long. Detailed comparisons of these regions for the steroid hormone receptors and v-erb A are presented. Possible functions for the individual regions of high homology are discussed.

Structure-function properties of the chicken progesterone receptor A synthesized from complementary deoxyribonucleic acid.

The chicken progesterone receptor (PR) cDNA has been cloned and sequenced in our laboratory. Functional receptor A was synthesized from cDNA in two independent systems, by transient transfection of receptor-negative COS M6 cells and by in vitro transcription and translation. These receptors exhibited DNA and hormone binding properties similar to the native PR from oviduct. The ability of receptor to induce target gene transcription was measured by cotransfection of receptor-negative CV-1 cells with expression vectors containing the receptor A cDNA and a progesterone-inducible promotor linked to the chloramphenicol acetyl transferase (CAT) gene. In these assays, receptor A produced hormone-dependent induction of CAT activity. In order to define the functional domains of receptor A, expression constructs coding for C-terminal deletion proteins were prepared. Deletion of the C-terminus resulted in loss of hormone binding activity as well as a loss of CAT induction. However, when 290 amino acids were removed from the C-terminus, this severely truncated receptor protein produced hormone-independent target gene activation. Mutant receptor proteins which retained the highly conserved cysteine-rich (C1) region were able to bind to DNA-cellulose, although removal of 290 amino acids from the C-terminus resulted in reduced affinity for DNA. Deletion of part or all of the C1 region resulted in loss of both DNA-binding and transcriptional activation capacities. These results confirm that C1 functions in DNA binding and transcriptional activation and that hormone binding activity can be localized to the C-terminal half of the protein.

Sequence and expression of a functional chicken progesterone receptor.

We have cloned and sequenced 4.5 kilobases (Kb) of cDNA encoding the chicken progesterone receptor. The complete cDNA contains an open reading frame of 2361 nucleotides in length and encodes a polypeptide of 787 amino acids with a mol wt of 85.9 K. At least four mRNA species have been detected in chick oviduct cells. Direct sequencing of variant cDNAs has suggested that two of the mRNAs (4.5 Kb and 3.6 Kb) differ only in the length of their 3'-untranslated regions. A third mRNA (1.8 Kb) produces a truncated polypeptide which encodes the immunoreactive NH2 terminal sequence of the receptor but lacks the hormone binding regional and half of the DNA-binding domain. The polypeptide expressed from the receptor cDNA in progesterone receptor negative Cos M-6 cells is indistinguishable from oviduct progesterone receptor in terms of hormone binding and antibody reactivity. Furthermore, the cloned receptor is capable of activating transcription of a target gene. This activation is progesterone dependent (with half-maximal stimulation at approximately 3.3 x 10(-10) M) and specific for the target gene.

Progesterone, in addition to estrogen, induces cyclin D1 expression in the murine mammary epithelial cell, in vivo.

Previous investigations, in vitro, have demonstrated that progestins can induce the transcription of the cell cycle regulator, cyclin D1, thereby suggesting that cyclin D1 may mediate, at the molecular level, the proposed mitogenic effects of progesterone during mammary epithelial cell proliferation. To extend these initial studies into an in vivo context, comparative cyclin D1 Northern and immunohistochemical analyses were performed on mammary gland tissue isolated from wild type (WT) females as well as from the recently reported progesterone receptor knockout (PRKO) mouse model. Northern analysis revealed that estrogen induced cyclin D1 expression, 5- to 7-fold over control levels, both in the WT and PRKO female. Immunohistochemistry demonstrated that, for both test groups, the number of mammary epithelial cells expressing cyclin D1 increased significantly as compared with control values, in response to estrogen. In the case of estrogen plus progesterone treatment, Northern analysis revealed that, in the WT gland, cyclin D1 transcription increased approximately 3-fold over estrogen induced levels, an increase that was paralleled by an equivalent increase in the number of mammary epithelial cells expressing cyclin D1. Conversely, under the same hormone regimen, the PRKO mammary gland did not exhibit a further increase in cyclin D1 induction over estrogen only levels. Finally, these studies not only demonstrate that in the mammary epithelial cell, both estrogen and progesterone can induce the expression of cyclin D1 but also show that this induction correlates with mammary gland proliferation in the mouse.

Endocrine defects in mice carrying a null mutation for the progesterone receptor gene.

Mice carrying a null mutation of the progesterone receptor gene exhibit several reproductive abnormalities, including anovulation, attenuated lordotic behavior, uterine hyperplasia, and lack of mammary gland development. The hormonal correlates of these abnormalities are unknown, however, and were the focus of these studies. Serum samples from female wild-type (WT) and progesterone receptor knockout (PRKO) mice were obtained and analyzed by RIA for LH, FSH, PRL, estrogen (E2), and progesterone. Hypothalamic tissues were also processed for measurement of LHRH by RIA. Serum LH levels in PRKO mice were found to be elevated by approximately 2-fold over basal (metestrus) values in WT mice. By contrast, basal FSH levels were not different in PRKO and WT mice. Basal levels of E2 and progesterone in serum were likewise similar in the two groups, as were hypothalamic LHRH concentrations. Basal PRL levels were slightly higher in PRKO vs. WT mice. Ovariectomy of both groups of mice was accompanied by significant increases in both LH and FSH. At 5 days following ovariectomy, LH levels were elevated in both groups by 2-fold over PRKO basal and 4-fold over WT basal levels; however, by 10 days postovariectomy LH levels had continued to rise to a greater extent in PRKO mice than in WT animals. The FSH response to ovariectomy was greater for the PRKO mice at 5 days, but was no different from WT at 10 days. Of seven PRKO mice that were exposed to male odor, none exhibited preovulatory surges 3 days later, on the day of presumptive proestrus; this was in marked contrast with WT females, in which 100% exhibited robust LH surges. These results confirm the essential role of progesterone receptors in the regulation of hypothalamic and/or pituitary processes that govern gonadotropin secretion. The finding that basal LH levels are elevated in PRKO mice confirms that circulating progesterone normally conveys a significant portion of the total ovarian negative feedback control of the gonadotropin. That gonadotropin responses to ovariectomy are slightly enhanced in PRKO mice suggests that adrenal progesterone may contribute to the imposition of negative feedback control. The apparent inability of PRKO mice to respond to male odor suggests that anovulation in these mice may not be solely due to reproductive abnormalities within the ovary itself; rather, PRKO mice additionally harbor neuroendocrine defects that render them incapable of mounting normal preovulatory gonadotropin surges. It remains to be determined how the absence of PR in brain and pituitary of PRKO mice may produce this hormonal acyclicity and, conversely, how the presence of PR in brain and pituitary of WT mice may be obligatory in the generation of gonadotropin surges.

Reconstitution of estrogen-dependent transcriptional activation of an adenoviral target gene in select regions of the rat mammary gland.

Estrogen regulates proliferation and morphogenesis of mammary ductal epithelium by interacting with a specific intracellular estrogen receptor (ER) that acts as a hormone-dependent transcriptional regulator of gene expression. The mechanisms by which ER regulates transcription in response to estrogen have been analyzed extensively in tissue culture and in cell-free systems. These studies have demonstrated that the transcriptional activity of ER is strongly influenced by cellular context and highlight the need to address ER transcriptional activity in an appropriate cellular background. Thus, to gain insight into the mechanistic role of ER in mammary epithelial morphogenesis, we have used an adenoviral gene delivery strategy to introduce an estrogen-responsive reporter gene into the mammary epithelium and to monitor the activity of endogenous ERs in their natural environment where cellular context including stromal-epithelial interactions can be taken into account. Using this approach, we first demonstrated highly efficient adenoviral delivery throughout the mammary epithelium using a beta-galactosidase (betagal) reporter gene under the control of the constitutively active cytomegalovirus (CMV) promoter. Next, we constructed an adenoviral vector by substituting the CMV promoter with an estrogen-dependent promoter fragment-linked betagal (Ad-ERE-tk-betagal). This adenoviral reporter system provides evidence that ER positive mammary epithelial cells display a differential sensitivity in a region-specific manner toward estrogen induction. Our data suggest that the availability of factor(s) other than ER is necessary for ER-mediated gene activation and may be important in modulating the differential responses of mammary epithelial cells to estrogen.

Restricted spatiotemporal expression of lactoferrin during murine embryonic development.

Lactoferrin is a member of the transferrin family of iron-binding glycoproteins. Lactoferrin is induced by estrogen in the mouse uterus during early pregnancy. However, the expression and function, if any, of lactoferrin in the preimplantation embryo during this developmental period has not been investigated. In the current study, the spatiotemporal expression of lactoferrin during murine embryogenesis was examined using in situ hybridization and immunohistochemical analyses. Lactoferrin expression was first detected in the 2-4 cell fertilized embryo and continued until the blastocyst stage of development. Interestingly, at the 16-cell stage, coinciding with the first major differentiation step in the embryo, lactoferrin messenger RNA (mRNA) is synthesized by the inner cells, whereas the protein is selectively taken up by the outside cells. This differential pattern of lactoferrin messenger RNA and protein localization continues until the blastocyst stage, with expression almost absent in the hatched blastocyst. Lactoferrin expression does not resume in the embryo until the latter half of gestation, where it is first detected in neutrophils of the fetal liver at embryonic day 11.5 and later in epithelial cells of the respiratory and digestive systems. Our results show that lactoferrin is expressed in a tightly regulated spatiotemporal manner during murine embryogenesis and suggest a novel paracrine role for this protein in the development of the trophoectodermal lineage during preimplantation development.

Expression and characterization of recombinant murine lactoferrin.

Lactoferrin (Mw=78 kDa) is a member of the transferrin family of iron-binding glycoproteins. Previous studies carried out primarily in vitro indicate that the protein has multifunctional properties and may be involved in regulation of iron homeostasis, inhibition of bacterial growth and regulation of immune responses. However, the significance and species specificity of these proposed functions in vivo have not been adequately addressed due to lack of sufficient purified homospecies lactoferrin for analysis in small animal models. We previously reported the successful production of biologically active recombinant human lactoferrin using an Aspergillus expression system. In the present study, we report the production of recombinant murine lactoferrin using a similar expression strategy. Recombinant murine lactoferrin was purified to homogeneity and was similar in size and immunoreactivity to native murine milk lactoferrin. The recombinant protein was correctly processed at its N-terminus and was glycosylated. Interestingly, while both human and murine lactoferrin bind iron in a 2:1 molar ratio, iron bound to recombinant murine lactoferrin was more acid labile than human lactoferrin, demonstrating species-specific variation in the stability of iron-binding to this protein. Finally, the availability of recombinant murine lactoferrin will now facilitate the study of the species specificity of lactoferrin action in a mouse model system.

Cloning and structural organization of the gene encoding the murine nuclear receptor transcription factor, NURR1.

NURR1 is an immediate early gene product and a member of the nuclear receptor superfamily of transcription factors. Using the NURR1 cDNA as a probe, we isolated the genomic DNA encoding NURR1 from a mouse 129SvEv genomic library. The NURR1 gene is approximately 6.2 kb long and is organized into 7 exons separated by 6 introns. Structural analysis of the NURR1 reveals that this gene shares a similar structure with that of the nuclear receptor NUR77/NGF1-B. As in NUR77, the promoter region of NURR1 lacks an identifiable TATA box, but is GC-rich. The proximal promoter region also contains an ATF/CREB consensus binding site that may participate in cAMP-mediated induction of this immediate early gene product. Isolation and structural characterization of the NURR1 gene provides information for further developmental and transcriptional regulation studies of this gene.

An inducible expression system for the production of human lactoferrin in Aspergillus nidulans.

The production and secretion of human lactoferrin (hLF) in Aspergillus nidulans is described. The hLF cDNA was expressed under the control of the strong ethanol-inducible alcohol dehydrogenase (alcA) promoter. Recombinant hLF (re-hLF) is produced at levels up to 5 micrograms/ml. Approximately 30% of the re-hLF produced in this system is secreted into the growth medium. The re-hLF is indistinguishable from native hLF with respect to size and immunoreactivity. Furthermore, re-hLF is functional by the criterion of iron-binding capacity. The A. nidulans expression system offers an inexpensive, convenient method for the controlled production of mg amounts of biologically active mammalian glycoproteins.

A novel, highly regulated, rapidly inducible system for the expression of chicken progesterone receptor, cPRA, in Saccharomyces cerevisiae.

A rapidly inducible and tightly regulated system for the expression of protein in yeast is based on a chimeric promoter constructed of two copies of a vitellogenin-estrogen-response element (ERE) which are inserted upstream from the promoter of the yeast gene encoding iso-1-cytochrome c. The chimeric promoter was inserted in a yeast expression plasmid upstream from the coding sequence of ubiquitin fused in frame to a cDNA encoding the full-length chicken progesterone receptor A (cPRA). The resultant plasmid (YEpA2) was co-transformed in Saccharomyces cerevisiae with a plasmid which encodes the human estrogen receptor. Estradiol (E2)-induced transactivation of the chimeric promoter results in transcription of the cPRA gene from YEpA2, and synthesis of cPRA. The fusion protein, ubiquitin-cPRA, is rapidly cleaved in vivo to produce cPRA. Analysis of samples by Western immunoblot shows that cPRA is almost undetectable in the absence of E2, and that treatment with 50 nM E2 results in a 500-1000-fold induction of cPRA (0.06-0.3% of the total protein) after 1 h. The plasmid-expressed soluble receptor is stable and demonstrates the correct affinity for its ligand. We have prepared yeast extracts using enzymatic digestion of the cell wall with oxalyticase followed by hypotonic shock. This has resulted in a dramatic increase in the % of receptor which binds hormone compared to previous studies which used mechanical disruption techniques. The cPRA is biologically active since it activates transcription of a co-transformed reporter gene containing its response element.(ABSTRACT TRUNCATED AT 250 WORDS)

In situ detection of progesterone receptor mRNA in the chicken oviduct using probe-on slides.

A relatively simple, rapid and versatile method for in situ hybridization of mRNA involving the use of probe-on slides is outlined. Chicken progesterone receptor transcripts have been localized in situ in the chick oviduct by using specific hybridization probes. The accumulation of relatively large quantities of progesterone receptor transcripts occurs in diethylstilbestrol (DES)-treated chickens. A uniformly 35S-labeled oligodeoxyribonucleotide probe was incubated with paraffin-embedded sections. Hybridization to the mRNA was found as discrete deposits of silver granules in the glandular and epithelial cells. The ability to tag low amounts of mRNA in the cell by this relatively easy but sensitive protocol allows efficient molecular analysis of developmental expression of a given gene. Probe-on slides should prove useful in any kind of in situ hybridization protocol using frozen sections, paraffin sections or tissue culture cells.