Intestinal oleoyl-estrone esterase activity in the Wistar rat.

Low-dose oral oleoyl-estrone (OE) (i.e. in dairy products) is hydrolysed to estrone, which promotes growth and fat deposition. However, pharmacological doses of OE are absorbed largely intact and elicit fat losses. Thus, in order to find out how the intestine handles OE, esterase activity (at pH 5, 7 or 8) was measured in rat stomach, duodenum, jejunum, ileum, cecum, large intestine, and liver using OE as substrate. There were no sex-related differences. Pure pancreatic cholesterol-ester esterase hydrolysed OE even in the absence of taurocholate. The differences in the pH-related activity distribution pattern and selective inhibition and taurocholate dependence show that, in addition to the luminal (i.e. pancreatic) cholesterol-ester esterase, other esterases hydrolyse OE; these combined activities may be sufficient to rapidly dispose of pharmacological doses of OE. Female rats received a tritium-labeled OE gavage; the luminal and tissue label content were measured up to 24 h. The high retention of label in the stomach suggest that this may be a significant site of absorption. The rapid decrease of label in intestinal lumen (and rat tissues) shortly after the administration, hint at rapid absorption and disposal. In conclusion, the high OE-esterase activity and early absorption of OE are indicative of upper gastro-intestinal tract absorption skipping most of the medium-tract esterases.

In the rat, estrone sulphate is the main serum metabolite of oral oleoyl-estrone.

Two different oral doses of oleoyl-estrone: 1 and 10 nmol/g a day were given once to male Wistar rats. The serum levels of free estrone, estrone sulphate, estradiol, and acyl-estrone were measured at intervals up to 72 h after the gavage. Oleoyl-estrone was rapidly absorbed; with the 1 nmol/g dose no changes were observed in plasma acyl-estrone but levels increased dramatically with 10 nmol/g, peaking at 6 h; high acyl-estrone levels were maintained up to 24 h, returning to normalcy at 48 h. With the 10 nmol/g dose, free estrone at most doubled its levels but estrone sulphate concentrations rose by one order of magnitude; in both cases, the increases soon (2 h) reached a plateau that was maintained for almost two days. Estradiol levels remained unchanged except for a transient peak at 2 h at the 10 nmol/g dose. The relationship between free estrone and its sulphate was linear, and those of estrone and estrone sulphate versus acyl-estrone showed the existence of an upper serum concentration limit for both molecules. The results hint at estrone sulphate being an important metabolite of oleoyl-estrone disposal, confirm the limited estrogenic response to oleoyl-estrone administration and agree with a rapid absorption and disposal of oleoyl-estrone, nevertheless maintaining high circulating levels of the ester for a time after its oral administration.

Differential expression of three different prepro-GnRH (gonadotrophin-releasing hormone) messengers in the brain of the european sea bass (Dicentrarchus labrax).

The expression sites of three prepro-gonadotrophin-releasing hormones (GnRHs), corresponding to seabream GnRH (sbGnRH: Ser(8)-mGnRH, mammalian GnRH), salmon GnRH (sGnRH: Trp(7)Leu(8)-mGnRH), and chicken GnRH-II (cGnRH-II: His(5)Trp(7)Tyr(8)-mGnRH) forms were studied in the brain of a perciform fish, the European sea bass (Dicentrarchus labrax) by means of in situ hybridization. The riboprobes used in this study correspond to the three GnRH-associated peptide (GAP)-coding regions of the prepro-GnRH cDNAs cloned from the same species (salmon GAP: sGAP; seabream GAP: sbGAP; chicken GAP-II: cIIGAP), which show little oligonucleotide sequence identity (sGAP versus sbGAP: 42%; cIIGAP versus sbGAP: 36%; sGAP versus cIIGAP: 41%). Adjacent paraffin sections (6 mm) throughout the entire brain were treated in parallel with each of the three anti-sense probes and the corresponding sense probes, demonstrating the high specificity of the hybridization signal. The results showed that both sGAP and sbGAP mRNAs had a broader expression in the olfactory bulbs, ventral telencephalon, and preoptic region, whereas cIIGAP mRNA expression was confined to large cells of the nucleus of the medial longitudinal fascicle. In the olfactory bulbs, both the signal intensity and the number of positive cells were higher with the sGAP probe, whereas sbGAP mRNA-expressing cells were more numerous and intensely stained in the preoptic region. Additional isolated sbGAP-positive cells were detected in the ventrolateral hypothalamus. These results demonstrate a clear overlapping of sGAP- and sbGAP-expressing cells in the forebrain of the European sea bass, in contrast to previous reports in other perciforms showing a clear segregation of these two cell populations.

The GnRH system in the European sea bass (Dicentrarchus labrax).

The cDNA sequences encoding three GnRH forms, sea bream GnRH (sbGnRH), salmon GnRH (sGnRH) and chicken GnRH II (cGnRH II), were cloned from the brain of European sea bass, Dicentrarchus labrax. Comparison of their deduced amino acid sequences to the same forms in the gilthead sea bream, Sparus aurata, and striped bass, Morone saxatilis, revealed high homology of the prepro-cGnRH II (94% and 98% respectively), and prepro-sGnRH (92% to both species). The sbGnRH exhibited dissimilar identities, with high homology to the striped bass (93%), and lower homology (59%) to the gilthead sea bream. Two transcript types were identified for the GnRH-associated peptide (GAP)-sGnRH as well as for the GAP-cGnRH II, which suggests a possible alternative splicing followed by the addition of an early stop codon. In order to obtain antibodies specific for the three GnRH precursors, recombinant GAP proteins were produced. The differential expression of the three GnRHs previously reported in the brain by means of in situ hybridization, using riboprobes corresponding to the GAP-coding regions, was fully confirmed by immunocytochemistry using antibodies raised against the recombinant GAP proteins, indicating that the transcripts are translated into functional proteins. Moreover, this approach allowed us to follow, for the first time, the specific projections of the different cell groups: sGAP fibers are distributed mainly in the forebrain with few projections reaching the pituitary, sbGAP fibers are mainly present in the preoptic area, mediobasal hypothalamus and predominantly project to the pars distalis of the pituitary, whereas cGnRH II fibers have a widespread distribution primarily in the posterior brain, and do not project to the pituitary. These new tools will be extremely useful to study further the development, regulation and functional significance of three independent GnRH systems in the brain of vertebrate species.

Expression of gonadotropin-releasing hormone type-I (GnRH-I) and type-II (GnRH-II) in human peripheral blood mononuclear cells (PMBCs) and regulation of B-lymphoblastoid cell proliferation by GnRH-I and GnRH-II.

GnRH-I and its receptor (GnRHR-I) have previously been demonstrated and shown to be biologically active in the immune system, notably within T cells. Recently however a second form of GnRH (GnRH-II) has been described in the human. The function of both these neuropeptides in B lymphocytes has not previously been explored. The present study investigates GnRH-I and GnRH-II expression in human peripheral mononuclear blood cells (PMBCs) and B lymphoblastoid cells (B-LCLs), as well as their action in regulating B-LCL proliferation in the presence and absence of interleukin-2 (IL-2), both in GnRHR-I mutated lymphocytes and in a normal control. RT-PCR and immunocytochemistry identified locally produced GnRH-I and GnRH-II in all cell groups. Treatment of normal B-LCLs with GnRH-I (10 (-9) M and 10 (-5) M) or with interleukin-2 (IL-2) (50 IU/ml) resulted in a significant increase in cell proliferation compared with the untreated control. IL-2 and GnRH-I (10 (-7) M, 10 (-6) M, 10 (-5) M) induced greater proliferation in normal B-LCLs than IL-2 treatment alone. No significant proliferation occurred in GnRHR-I defective B-LCLs, in response to either GnRH-I (10 (-9) and 10 (-5) M) or IL-2 treatment, nor to IL-2 and GnRH-I (10 (-10) to 10 (-5) M) co-treatment when compared to controls. Co-incubation of IL-2 and IL-2 + GnRH 10 (-5) M with a GnRH antagonist (Cetrorelix; 10 (-6) M) significantly attenuated the proliferation in normal B-LCLs. GnRH-II did not affect proliferation of normal B-LCLs alone, and did not alter the proliferative response to IL-2. Further investigation is required to clarify the physiological relevance of local GnRH-I/GnRH-II in immune system responsiveness.

Expression of gonadotrophin-releasing hormone binding sites in somatic tissues of the gilthead seabream (Sparus aurata): a quantitative autoradiographic study.

In this study, we have analysed the expression of gonadotrophin-releasing hormone (GnRH) binding sites in somatic tissues (intestine, liver, gill, skeletal muscle, ovary, heart, stomach, kidney and spleen) of the gilthead seabream, Sparus aurata using 3-[125I]iodototyrosyl5-mammalian GnRH and auto-radiographic techniques. The qualitative and quantitative analysis showed the existence of a basal expression of specific GnRH binding sites in intestine, skeletal muscle, ovary, stomach and spleen. Furthermore, our data suggest that the level of expression of GnRH binding sites can be significantly enhanced by GnRH treatment in intestine, gill, heart, stomach, kidney and spleen. This study shows that GnRH can exert direct effects in both reproductive and non-reproductive somatic tissues of the gilthead seabream.

GnRH-I and GnRH-II have differential modulatory effects on human peripheral blood mononuclear cell proliferation and interleukin-2 receptor gamma-chain mRNA expression in healthy males.

GnRH-I and its receptor (GnRHR-I) have previously been demonstrated and shown to be biologically active in the immune system, notably within peripheral lymphocytes. Recently however, a second form of GnRH (GnRH-II) has been described in the human. The functions of both these neuropeptides in PMBCs have not been understood yet. The present study was therefore designed to investigate the effects of GnRH-I and/or GnRH-II on human PMBC proliferation in males. Secondly, the effects of GnRH-I and GnRH-II on IL-2 dependent lymphocyte proliferation were examined. Finally, we analysed the role of GnRH-I and GnRH-II in IL-2R gamma-chain expression. Peripheral venous blood samples were obtained from six male healthy volunteers (Mean age 27.75 +/- 1.5). Non-radioactive cell proliferation assay was used for proliferation studies and we used quantitative real-time RT-PCR to examine the role of GnRH-I and GnRH-II on IL-2R gamma-chain expression in PMBCs. Treatment of PMBCs with GnRH-I (10(-9) M and 10(-5) M) and with interleukin-2 (IL-2) (50 U/ml) resulted in a significant increase in cell proliferation compared with the untreated control. PMBCs cotreated with IL-2 and GnRH-I demonstrated higher proliferative responses than IL-2 treatment alone, the enhancement of GnRH-I on IL-2 response being significant only at GnRH-I concentration of 10(-5) M. Co-incubation of IL-2+ GnRH 10(-5) M with a GnRH antagonist (Cetrorelix; 10(-6) M) significantly decreased the proliferation. GnRH-II did not affect the proliferation of PMBCs alone, and did not alter the proliferative response to IL-2. The proliferative responses to GnRH-I (alone and with IL-2) were significantly attenuated by GnRH-II coincubation (each in equal molar concentrations; 10(-9) M to 10(-5) M). It was found that GnRH-I increased the expression of IL-2Rgamma mRNA in a dose dependent manner, with a significant increase of percentage 162.3 +/- 14 of control at 10(-5) M. In contrast, IL-2Rgamma expression was significantly decreased in all concentrations of GnRH-II (10(-9) M to10(-5) M), and the maximum decrease was detected at 10(-5) M, with percentage 37.7 +/- 6.6 of control. All these findings strongly suggest that regulation of IL-2R expression may therefore be an important target for GnRH-I and GnRH-II in PMBCs in males. In summary, present study clearly demonstrates the differential effects of GnRH-I and GnRH-II on PMBC proliferation, IL-2 proliferative response, and IL-2Rgamma expression in PMBCs in males. To our knowledge, our observations provide the first evidence for the interactions of these local neuropeptides at lymphocyte level. Further experimental data in human are warranted to explore the clinical implications of these data.