The nuclear orphan receptors COUP-TF and ARP-1 positively regulate the trout estrogen receptor gene through enhancing autoregulation.

The rainbow trout estrogen receptor (rtER) is a positively autoregulated gene in liver cells. In a previous report, we showed that upregulation is mediated by an estrogen response element (ERE) located in the proximal promoter of the gene and that a half binding site for nuclear receptors (5'-TGACCT-3') located 15 bp upstream of the ERE is involved in the magnitude of the estrogen response. We now report that the human orphan receptor COUP-TF and a COUP-TF-like protein from trout liver are able to bind to the consensus half-site. When cotransfected with the rtER gene proximal promoter, COUP-TF had no regulatory functions on its own. Interestingly, COUP-TF enhanced rtER transactivation properties in the presence of estradiol in a dose-dependent manner when cotransfected with the rtER gene promoter. Unliganded retinoid receptor heterodimers had the same helper function as COUP-TF in the presence of estradiol but were switched to repressors when the ligand all-trans-retinoic acid was added. Mutation of the consensus half-site only slightly reduced COUP-TF helper function, suggesting that it actually results from a complex mechanism that probably involves both DNA binding of COUP-TF to the promoter and protein-protein interaction with another transcription factor bound to the promoter. Nevertheless, a DNA-binding-defective mutant of COUP-TF was also defective in ER helper function. Competition footprinting analysis suggested that COUP-TF actually establishes contacts with the consensus upstream half-site and the downstream ERE half-site that would form a DR-24-like response element. Interaction of COUP-TF with the DR-24 element was confirmed in footprinting assays by using nuclear extracts from Saccharomyces cerevisiae expressing COUP-TF. Finally, interaction of COUP-TF with mutants of the rtER gene promoter showed that COUP-TF recognizes the ERE when the upstream half-site is mutated. These data show that COUP-TF may activate transcription through interaction with other nuclear receptors. This cross-talk between liganded nuclear receptors and orphan receptors is likely to modulate the spectrum of action of a particular ligand-receptor complex and may participate in the cell-type specificity of the ligand effect.

A novel orphan receptor specific for a subset of thyroid hormone-responsive elements and its interaction with the retinoid/thyroid hormone receptor subfamily.

The steroid/hormone nuclear receptor superfamily comprises several subfamilies of receptors that interact with overlapping DNA sequences and/or related ligands. The thyroid/retinoid hormone receptor subfamily has recently attracted much interest because of the complex network of its receptor interactions. The retinoid X receptors (RXRs), for instance, play a very central role in this subfamily, forming heterodimers with several receptors. Here we describe a novel member of this subfamily that interacts with RXR. Using a v-erbA probe, we obtained a cDNA which encodes a novel 445-amino-acid protein, RLD-1, that contains the characteristic domains of nuclear receptors. Northern (RNA) blot analysis showed that in mature rats, the receptor is highly expressed in spleen, pituitary, lung, liver, and fat. In addition, weaker expression is observed in several other tissues. Amino acid sequence alignment and DNA-binding data revealed that the DNA-binding domain of the new receptor is related to that of the thyroid/retinoid subgroup of nuclear receptors. RLD-1 preferentially binds as a heterodimer with RXR to a direct repeat of the half-site sequence 5'-G/AGGTCA-3', separated by four nucleotides (DR-4). Surprisingly, this binding is dependent to a high degree on the nature of the spacing nucleotides. None of the known nuclear receptor ligands activated RLD-1. In contrast, a DR-4-dependent constitutive transcriptional activation of a chloramphenicol acetyltransferase reporter gene by the RLD-1/RXR alpha heterodimer was observed. Our data suggest a highly specific role for this novel receptor within the network of gene regulation by the thyroid/retinoid receptor subfamily.

Mutations that alter ligand-induced switches and dimerization activities in the retinoid X receptor.

The retinoid X receptor (RXR) heterodimerizes with a variety of nuclear receptors. In addition, RXR forms homodimers in the presence of its ligand, 9-cis-retinoic acid. From deletion and point mutation analysis we present evidence that a short region (amino acids 413 to 443) in the carboxy terminus of RXR alpha is critical for both homo- and heterodimeric interactions as well as for diverse functional activities. In addition, we present evidence that homo- and heterodimer functions can be separated. The deletion of 19 amino acids from the C-terminal end of RXR dramatically reduced the transcriptional activation function of RXR. The removal of 10 additional amino acids resulted in a receptor (delta RXR3) that had completely lost its ligand-dependent homodimer function but retained its heterodimer activities. Heterodimer function was abolished by the deletion of an additional 20 amino acids. Single amino acid substitutions in the region generated receptors with altered RXR homodimer DNA binding, while simultaneous mutation of three Leu residues (Leu-418, -419 and -422) completely abolished both RXR homodimer and heterodimer DNA binding activities. Mutation of Leu-430 to Phe (L430-F) resulted in a receptor that bound to DNA strongly as homodimers in a ligand-independent manner, while another single amino acid exchange (L422-Q) led to a mutant that behaved in a manner exactly opposite to that of wild-type RXR in that the homodimerization of the mutant occurred in the absence of ligand and was inhibited by 9-cis-retinoic acid. In transfection assays, both L422-Q and L430-F failed to act as homodimers but retained their heterodimer function. Our studies demonstrate the unique properties of the RXR ligand binding domain and point to specific residues that mediate homo- and heterodimer activities and ligand-induced conformational switches.

COUP orphan receptors are negative regulators of retinoic acid response pathways.

The vitamin hormone retinoic acid (RA) regulates many complex biological programs. The hormonal signals are mediated at the level of transcription by multiple nuclear receptors. These receptors belong to the steroid/thyroid hormone receptor superfamily that also includes a large number of orphan receptors whose biological roles have not yet been determined. Although much has been learned in recent years about RA receptor (RAR) functions, little is known about how specific RA response programs are restricted to certain tissues and cell types during development and in the adult. It has been recently shown that RAR activities are regulated by retinoid X receptors (RXR) through heterodimer formation. In an effort to isolate and further characterize nuclear receptors that modulate RAR and/or RXR activities, we have screened cDNA libraries by using a RXR alpha cDNA probe. Two clones, COUP alpha and COUP beta, identical and closely related to the orphan receptor COUP-TF, were obtained. We show that COUP proteins dramatically inhibit retinoid receptor activities on certain response elements that are activated by RAR/RXR heterodimers or RXR homodimers. COUP alpha and -beta bind strongly to these response elements, including a palindromic thyroid hormone response element and a direct repeat RA response element as well as an RXR-specific response element. In addition, we found that the previously identified COUP-TF binding site in the ovalbumin gene functions in vitro as an RA response element that is repressed in the presence of COUP. Our data suggest that the COUP receptors are a novel class of RAR and RXR regulators that can restrict RA signaling to certain elements. The COUP orphan receptors may thus play an important role in cell- or tissue-specific repression of subsets of RA-sensitive programs during development and in the adult.

The LIM/homeodomain protein islet-1 modulates estrogen receptor functions.

LIM/Homeodomain (HD) proteins are classically considered as major transcriptional regulators which, in cooperation with other transcription factors, play critical roles in the developing nervous system. Among LIM/HD proteins, Islet-1 (ISL1) is the earliest known marker of motoneuron differentiation and has been extensively studied in this context. However, ISL1 expression is not restricted to developing motoneurons. In both embryonic and adult central nervous system of rodent and fish, ISL1 is found in discrete brain areas known to express the estrogen receptor (ER). These observations led us to postulate the possible involvement of ISL1 in the control of brain functions by steroid hormones. Dual immunohistochemistry for ISL1 and ER provided evidence for ISL1-ER coexpression by the same neuronal subpopulation within the rat hypothalamic arcuate nucleus. The relationship between ER and ISL1 was further analyzed at the molecular level and we could show that 1) ISL1 directly interacts in vivo and in vitro with the rat ER, as well as with various other nuclear receptors; 2) ISL1-ER interaction is mediated, at least in part, by the ligand binding domain of ER and is significantly strengthened by estradiol; 3) as a consequence, ISL1 prevents ER dimerization in solution, thus leading to a strong and specific inhibition of ER DNA binding activity; 4) ISL1, via its N-terminal LIM domains, specifically inhibits the ER-driven transcriptional activation in some promoter contexts, while ER can serve as a coactivator for ISL1 in other promoter contexts. Taken together, these data suggest that ISL1-ER cross-talk could differentially regulate the expression of ER and ISL1 target genes.

An evolutionary conserved COUP-TF binding element in a neural-specific gene and COUP-TF expression patterns support a major role for COUP-TF in neural development.

The COUP transcription factors (COUP-TF and ARP-1) are the most highly conserved members of the nuclear receptor superfamily throughout evolution. Previous studies indicated that COUP orphan receptors may be involved in early neurogenesis in Drosophila and zebrafish. Here we identified a neural-specific gene, arrestin, whose transcription can be regulated by endogenous COUPs through a DR-7 element (direct repeat with a 7-base pair spacer) located upstream of the transcription start site. Importantly, the COUP binding site of the arrestin gene promoter is conserved among mouse, bovine, and human. However, the mouse element is also capable of responding to retinoic acid while the element in the human gene does not. Expression of COUP-TF correlates with the known expression sites of the arrestin gene in vivo, notably during the differentiation of the retina. We also show that COUP-TF is expressed in a spatio-temporally defined pattern in the murine central nervous system during embryogenesis. It appears that the expression pattern of COUP-TF is unique in certain regions of the developing brain, which would indicate a novel role for COUP-TF and/or ARP-1, distinct from their role in restricting other hormonal signaling pathways. Together our data suggest that COUPs play a crucial role in controlling a subset of neural-specific programs during development.

One of the two trout proopiomelanocortin messenger RNAs potentially encodes new peptides.

POMC is the precursor for a number of biologically active peptides such as ACTH, alpha-MSH, beta-MSH, and beta-endorphin. It is well known that some of these peptides, especially beta-endorphin, are involved in the regulation of reproductive functions in mammals. In order to investigate the possible role of POMC-derived peptides in the control of fish reproduction, we have cloned and sequenced two different trout POMC cDNAs called POMC A and POMC B. These cDNAs exhibited limited sequence homology (44%). The deduced amino acid sequences also showed weak similarity (43%), despite the high conservation of some peptide sequences (alpha-MSH, beta-MSH, and beta-endorphin). The POMC A coding sequence exhibited an unusual length, generating the longest endorphin ever sequenced. The long carboxy-terminal part of the beta-endorphin A contained three potential dibasic cleavage sites, allowing the occurrence of three new peptides: EQWGREEGEE, ALGE, and YHFQG. Using in situ hybridization, we found that the two POMC genes were expressed in the same pituitary cells. POMC A mRNA was the only one detectable in the hypothalamus of sexually inactive fish, whereas the two POMC genes were expressed in the hypothalamus of sexually active fish. These results indicate that two functional POMC genes are present in the rainbow trout. In POMC neurons, the expression of the POMC B gene is likely to be under the control of sexual steroids.

Cooperation between the human estrogen receptor (ER) and MCF-7 cell-specific transcription factors elicits high activity of an estrogen-inducible enhancer from the trout ER gene promoter.

The human estrogen receptor (hER) is expressed in breast cancer MCF-7 cells and plays a major role in tumorigenic processes. In this report, we demonstrate that MCF-7-specific factors can cooperate with the hER to increase its transactivation activity. We previously demonstrated that the rainbow trout ER (rtER) gene is up-regulated by the rtER protein itself, through an enhancer that contains an imperfect estrogen-responsive element (FP1 area). By performing footprinting experiments, we have delineated two other regulatory regions (FP2 and FP3 areas) in the 0.2-kb enhancer. We show, by transient transfections, that hER poorly transactivates this enhancer in CHO-K1 and Ishikawa cells whereas, in MCF-7 cells, transcriptional activation occurs at a level about 20-fold higher than when the enhancer estrogen-responsive element (FP1) is the only regulatory region included in the reporter gene. These results indicate that areas other than FP1 are important regulatory sites of this enhancer. Site-directed mutagenesis demonstrated that the FP1 area is absolutely necessary for induction by estradiol as well as for basal activity of this enhancer in MCF-7 cells. Gel shift experiments showed that MCF-7 cells contain a factor that binds to the FP3 area and is poorly expressed in all other tested cell lines. As suggested by site-directed mutagenesis and deletion experiments, this FP3-binding protein may enhance the hER transactivation ability in MCF-7 cells. These data reinforce the idea that cell-specific transcription factors cooperate with steroid receptors to achieve maximal induction of hormone-responsive genes.

COUP-TFI (chicken ovalbumin upstream promoter-transcription factor I) regulates cell migration and axogenesis in differentiating P19 embryonal carcinoma cells.

The developmental expression patterns of the nuclear orphan receptors COUP-TFs (chicken ovalbumin upstream promoter-transcription factors) have been correlated to neurogenesis in several animal species. Nevertheless, the role of COUP-TFs in neurogenesis remains unknown. We have studied the functional involvement of COUP-TFI in retinoic acid (RA)-induced neuronal differentiation of P19 embryonal carcinoma cells through two complementary approaches: 1) deregulated expression of COUP-TFI, and 2) inactivation of endogenous COUP-TFs by means of a dominant-negative COUP-TFI mutant. Low levels of wild-type (wt)COUP-TFI transgene expression did not inhibit neural cell fate and primarily enhanced neuron outgrowth from RA-treated P19 aggregates. In contrast, high COUP-TFI expression impeded the neuronal differentiation of P19 cells induced with RA, resulting in cell cultures lacking neurons. This morphological effect was correlated to an elevated level of E-cadherin mRNA. The dominant-negative COUP-TFI mutant induced cell packing after RA treatment and inhibited neurite extension and neuron outgrowth from aggregates. A RGD peptide interference assay indicated that endogenous COUP-TFs could favor migration of neurons through an integrin-dependent mechanism. Accordingly, vitronectin mRNA levels were shown to be up-regulated by COUP-TFI by RT-PCR analysis, and COUP-TFI stimulated the mouse vitronectin promoter activity in transient transfection assays. Taken together, these data indicate that COUP-TFI is not simply a global repressor of retinoid functions, but shows a high selectivity for regulating genes involved in cellular adhesion and migration processes that are particularly important for neuronal differentiation.

Retinoic acid receptors and retinoid X receptor-alpha down-regulate the transforming growth factor-beta 1 promoter by antagonizing AP-1 activity.

Overexpression of the multifunctional growth factor transforming growth factor-beta 1 (TGF beta 1) has been connected to numerous diseases in human. TGF beta 1 expression is largely governed by three AP-1 binding sites located in two different promoters of this gene. We have examined the ability of retinoid receptors to inhibit the activity of the two promoters (especially the promoter 1) by cotransfection assays in the hepatocellular carcinoma cell line HepG2. When the TGF beta 1 promoter activity is induced by 12-O-tetradecanoyl phorbol13-acetate (an activator of AP-1-controlled gene transcription), this activity can be strongly repressed by retinoic acid receptor-alpha (RAR alpha), RAR beta, or retinoid X receptor-alpha (RXR alpha) as well as other members of the nuclear receptor family. Repression was hormone dependent and a function of receptor concentration. Heterodimerization of RAR alpha or RAR beta with RXR alpha did not modify the inhibition activities of these receptors, indicating that heterodimer formation is not required for antagonizing of AP-1 activity. On further examining the anti-AP-1 activity of RXR alpha we observed that three different AP-1-controlled promoters (TGF beta 1, collagenase, and cFos) can be inhibited. Using gel shift assays, we demonstrated that RXR alpha inhibits Jun and Fos DNA binding and that 9-cis RA enhances this inhibition, suggesting that a mechanism involving direct protein-protein interaction between RXR and AP-1 components mediates the inhibitory effect observed in vivo. Transfection analyses with RXR alpha point mutations revealed that residues L422, C432, and, to a lesser extent, residues L418 and L430, are involved in ligand-induced anti-AP1 activity of RXR alpha in vivo. Thus both types of retinoid receptors can inhibit AP-1-activated promoters, including the TGF beta 1 gene promoter, via a mechanism that involves protein-protein interaction.

Eukaryotic conditional expression system.

Existing conditional expression systems can be classified in two major categories that are based either on the induction or on the de-repression of transcription. The system described here combines both mechanisms, since a unique transcription factor can be shifted from a repression to a stimulation activity by simply changing its ligand. The resulting advantage of this system is the complete absence of basal expression before active induction. The principle of this method is based on the unexpected ability of the chimeric protein containing the DNA-binding domain of the yeast Gal4 transcription factor fused to the COOH half of the estradiol receptor (GalER), to act as a repressor when bound to the drug 4OH-tamoxifen, in the context of a previously described optimized Gal4-responsive promoter. The efficacy of this system has been assessed in transient expression assays using the chloramphenicol acetyl transferase (CAT), and in situ, through the activity of a Gal4 responsive beta-galactosidase gene.

Differential regulation of the estrogen receptor mRNA by estradiol in the trout hypothalamus and pituitary.

In an attempt to understand the molecular mechanisms by which steroids can modulate brain functions in fish, we first localized the cells which produce estrogen receptor mRNA in the rainbow trout forebrain (Salbert et al., 1991). We now report how estradiol itself can alter the estrogen receptor mRNA content of these cells in a sterile strain of female rainbow trout. We also examined liver and pituitary levels of the estrogen receptor mRNA under the same estrogenic treatment. As revealed by slot blot and in situ hybridisations, a single injection (1.5 mg/kg) of estradiol can induce a strong increase (about five-fold) in the estrogen receptor mRNA levels in the liver, as well as a moderate increase (about two-fold) in two nuclei of the hypothalamus/preoptic area: the nucleus lateralis tuberis and the nucleus preopticus periventricularis. Conversely, no modifications of these levels were observed in the pars intermedia and the proximal pars distalis of the pituitary. Moreover, a comparison between estrogen receptor mRNA levels in the brain of sexually active female trout and in the brain of these sterile animals revealed that, in these latter, estrogen receptor mRNA levels are lower but can be increased by a single estradiol injection and reached the levels observed in mature females.

Absence of direct regulation of prolactin cells by estradiol-17 beta in rainbow trout (Oncorhynchus mykiss).

The effects of estradiol-17 beta (E2) implants on plasma prolactin (PRL) concentrations, pituitary PRL content and pituitary PRL mRNA levels were examined in rainbow trout (Oncorhynchus mykiss). Intact immature fish treated with 1 mg estradiol-17 beta did not show significant changes in both PRL mRNA levels and pituitary PRL content after 3 days of treatment. In a similar experiment, no changes were observed in plasma PRL levels followed during 7 days. Similarly, lack of estradiol-17 beta effect on plasma PRL levels and on final PRL pituitary content was observed in ovariectomized female rainbow trout treated during 48 days with 25 mg estradiol-17 beta and in mature male fish over a 3-week treatment period. Localization of estradiol receptor (ER) mRNAs in the pituitary was carried out by Northern blot analysis using a full-length rainbow trout estrogen receptor (rtER) cDNA as a probe. The rostral pars distalis of the pituitary which contained mostly PRL cells showed the lower amount of rtER mRNA when compared to other parts of the pituitary. Moreover, two mRNAs of different size (3.5 and 1.4 kb) were detected in different parts of the pituitary. Further hybridization experiments using probes containing part of the rtER cDNA (E domain or C and D domains) indicated that the small-sized mRNA (1.4 kb) probably encodes a truncated ER protein lacking hormone binding domain or an ER-related protein. Thus, only the 3.56 kb mRNA appeared to be involved in the regulation of pituitary function by estradiol. In situ hybridization analysis allowed a more precise localization of this rtER mRNA in the pituitary.(ABSTRACT TRUNCATED AT 250 WORDS)

Localization of the estradiol receptor mRNA in the forebrain of the rainbow trout.

In situ hybridization was used to localize the cells that express the estradiol receptor gene (ER) in the forebrain (hypothalamus, preoptic area, telencephalon) of the rainbow trout (Oncorhynchus mykiss). Both sense and anti-sense [35S]UTP-labeled single-stranded RNA probes were generated from the estradiol binding domain of the ER cDNA. The sense probe was used to evaluate the background of the hybridization reaction. In the forebrain, specific signal appeared in three areas: the posterior hypothalamus, the preoptic area, and the ventral telencephalon. Our localization correlates with [3H]estradiol binding studies in other teleost species. In the pituitary, we observed a weak signal when compared to the signal observed in the forebrain (about ten grains/cell in the pituitary against 35 grains/cell in the posterior hypothalamus). A significant difference was also observed between the intensity of labeling per cell when different forebrain nuclei were compared. We provide here evidence for a tissue-specific regulation of the ER mRNA levels in the trout hypothalamo-pituitary axis.

Distribution of estrogen receptor-immunoreactive cells in the brain of the rainbow trout (Oncorhynchus mykiss).

Using antibodies against the hormone binding domain of the trout estrogen receptor (ER), the distribution of ER-immunoreactive (ER-IR) cells was studied in the brain of maturing diploid and triploid female rainbow trout using a streptavidin-biotin-peroxidase method followed by a nickel-intensified diaminobenzidine reaction. This technique resulted in an excellent signal/background ratio allowing unambiguous identification of positive cells. In all animals, ER-IR cells were consistently located in three brain regions, the ventral telencephalon, the anterior ventral preoptic region, and the mediobasal hypothalamus. About 250 ER-IR cells were observed in the ventral and dorsal parts of the ventral telencephalon. In the anterior nucleus preopticus periventricularis, about 2400 ER-IR cells were observed surrounding the preoptic recess. In the posterior hypothalamus, approximately 2700 ER-IR cells were located in the anterior, posterior and inferior divisions of the nucleus lateralis tuberis and in the nucleus saccus vasculosus. In these regions cell nuclei exhibiting different densities of staining were observed and absolutely no labeling of cytoplasmic processes was detected. These results are in partial agreement with those obtained either after injection of tritiated-estradiol in other teleots species or in situ hybridization of ER mRNAs in trout. In particular, no immunoreactivity was observed in the thalamic region nor in the nucleus posterioris periventricularis. These data indicate that target cells for estradiol are essentially located in brain regions involved in the neuroendocrine control of pituitary functions and having direct connections with the hypophysis.

Effects of nonylphenol on estrogen receptor conformation, transcriptional activity and sexual reversion in rainbow trout (Oncorhynchus mykiss).

Estrogenic potency of 4-n-nonylphenol diethoxylate, 4-n-nonylphenol (NP) and metabolites were tested using two bioassays: rainbow trout hepatocyte culture and recombinant yeast stably expressing rainbow trout estrogen receptor (rtER) and containing estrogen-dependent reporter genes. Since NP was the only compound active in both systems, its interaction with rtER was studied in more detail. Qualitative and quantitative differences were observed in the presence of 17beta-estradiol (E2) or NP when estrogen-dependent promoters containing one to three estrogen-responsive elements were used in yeast. Moreover, limited proteolysis of rtER after E2 or NP binding presented different patterns after SDS-PAGE analysis suggesting that NP induces a differential conformation of rtER compare to E2. This finding may have important implications with respect to the biological activity of NP. Thus, the effects of NP on the activation of an E2-dependent gene and on sexual differentiation were assessed on all-male trout embryos exposed to NP for 1 h per day for 10 days. Although in situ hybridization demonstrated that E2, and to a lesser extend NP, were able to increase rtER mRNA level in the liver of embryos, no indication of total or partial sexual reversion was observed (even in E2 treated fishes) when the gonads were examined 8 months after hatching.

Interplay between liganded and orphan nuclear receptors controls reproductive pathways.

Nuclear receptors are transcription factors that belong to an evolutionary ancient superfamily. These proteins, which are even present in primitive metazoans, are implicated in all levels of cell fate: proliferation, differentiation, and apoptosis. Some of these nuclear receptors behave as ligand-inducible transcription factors, as they have acquired during evolution the ability to bind ligands. This is the case for some proteins that recognize small hydrophobic signaling molecules, and particularly the estrogen receptor (ER or NR3A1), which regulates the target gene's transcription rate under estrogen binding. It is now known that the ER alone regulates the transcription of many genes, such as those implicated in reproductive functions. However, this ER-mediated signaling pathway could be modulated by other transcription factors. Our work has established that two other orphan nuclear receptors (SF-1 or NR5A1 and the COUP-TFs, NR2F1 and NR2F2) can enhance two ER-regulated genes implicated in salmonid reproductive functions: the ER gene itself, and the sGTHIIbeta gene. Moreover, some xenoestrogens could disturb these regulations. Therefore, our data contribute to the concept that interplay between nuclear receptors is an important event for the transcriptional regulation of genes controlling cellular functions.

Dynamic characteristics of serotonin and dopamine metabolism in the rainbow trout brain: a regional study using liquid chromatography with electrochemical detection.

Aminergic metabolism was studied in discrete brain regions of the postovulated female rainbow trout using a liquid chromatography electrochemical detection method. 3 Methoxytyramine (3MT) was the major dopaminergic catabolite, suggesting that catechol-o-methyl transferase is the main dopamine (DA) catabolic enzyme. Two populations of brain regions were found: one with a high DA content and low 3MT/DA ratio (hypothalamus and telencephalon), suggesting that these regions could present a high density of DA perikarya; the other with a high 3MT/DA ratio (pituitary, preoptic area, myelencephalon and optic tectum) suggesting that these regions could present a high density of DA axonal endings. 5 Hydroxytryptamine (5HT) content differed, but an homogeneous distribution of monoamine oxidase was found in different brain regions. High 5HT content was found in the hypothalamus and telencephalon; 5HT was however not detectable in the pituitary.

Monolayer and aggregate cultures of rainbow trout hepatocytes: long-term and stable liver-specific expression in aggregates.

An aggregate culture system for rainbow trout hepatocytes was developed to study liver-specific mRNA expression. Maintenance of differentiated functions and morphology of hepatocytes were examined using both monolayer and aggregate systems. The rainbow trout estrogen receptor and vitellogenin genes were induced by estradiol and their mRNAs used as markers of cell differentiation during cell culture. In monolayer culture, rainbow trout hepatocytes established very few cell-cell contacts in minimal media. The use of more complete media promotes cell-cell contacts and cell islet formation. Hepatocyte response to estradiol stimulation was generally lower than in vivo but a correlation between the degree of cellular organization and the intensity of the hormonal response was observed. However, in this system hepatocytes progressively lost their specific hormonal response between 5 and 10 days. In aggregates with DMEM/F12 and Ultroser SF, cell-cell contacts were maximized and stabilized during at least one month. The levels of rainbow trout estrogen receptor and vitellogenin mRNAs induced by estradiol were stable and maintained at a level comparable to in vivo levels; vitellogenin synthesis and secretion remained fully functional for the duration of the culture.