Up-regulation of polymeric immunoglobulin receptor mRNA in mammary epithelial cells by IFN-gamma.

As shown in previous in vivo experiment, the amount of polymeric immunoglobulin receptor (pIgR), which mediates the transcytosis of pIgA across epithelial cells, is regulated by lactogenic hormones (PRL and cortisol) during the development of the mammary gland. In the present in vitro study, it appeared that these hormones were insufficient to induce the strong expression of the gene that we observed in vivo. Several papers have shown that IFN-gamma is a strong stimulator of pIgR gene expression in different models. In contrast, nothing is known of the effects of IFN-gamma on pIgR gene expression in the mammary gland. We report here that IFN-gamma strongly increased pIgR mRNA levels through a direct effect on mammary epithelial cells. We show that IFN-gamma activated not only Stat1 but also Stat5 and that expression of the pIgR and IRF-1 genes was strongly correlated following IFN-gamma stimulation in mammary epithelial cells. In conclusion, these experiments enabled the analysis of different types of regulation of pIgR gene expression in the mammary gland and suggest possible co-operation between circulating hormones and locally produced cytokines, leading to pIgR gene expression in the mammary gland.

Expression of BRCA1 gene in ewe mammary epithelial cells during pregnancy: regulation by growth hormone and steroid hormones.

OBJECTIVE: Steroid hormones (estradiol and progesterone) in association with prolactin and growth hormone are involved in lobulo alveolar development of the mammary gland during pregnancy. We hypothesized that the BRCA1 gene may be induced by these different hormones. METHODS AND RESULTS: In this study, we have demonstrated by Northern blot and in situ hybridization, that the expression of ovine (o) BRCA1 mRNA in mammary epithelial cells increased dramatically during a short period in the second half of pregnancy (days 70 to 112) and decreased at the end of pregnancy. The increase in oBRCA1 mRNA expression is concomitant with rapid lobulo alveolar growth. Using an in vivo protocol to artificially induce mammary gland development, we demonstrated by the real-time RT-PCR method that growth hormone in association with estrogen, progesterone and hydrocortisone induces an increase of BRCA1 mRNA expression in the ewe mammary gland. Moreover, we showed that estradiol and progesterone induce oBRCA1 expression in primary cultures of ewe mammary gland. CONCLUSIONS: These results suggest that BRCA1 is a potential regulator of the effects of steroid hormones and growth hormone in the induction of mammary epithelial cell proliferation.

Recombinant extracellular domain of rabbit growth hormone receptor and biological activity of somatogenic hormones.

The cDNA of the extracellular domain of rabbit growth hormone receptor (rbGHR-ECD) was cloned in the prokaryotic expression vector pMON, to enable its expression in Escherichia coli after induction with nalidixic acid. The bacterially expressed rbPRLR-ECD protein, contained within the refractile-body pellet, was solubilized in 4.5 M urea, refolded, and purified on a Q-Sepharose column, pH 8, by stepwise elution with NaCl. The bioactive monomeric 28-kDa fraction was eluted in 0.15 M NaCl, yielding 50 mg/2.5 l of induced culture. The purified protein was over 98% homogeneous, as shown by SDS-PAGE in the presence or absence of reducing agent, and by chromatography on a Superdex column. Gel filtration was used to determine the stoichiometry of rbGHR-ECD's interaction with human (h), ovine (o), chicken (ch) and common carp (cc) GHs and with bovine (b) and caprine (c) placental lactogens (PLs). The formation of 2:1 complexes was indicated in all cases. Binding experiments using radiolabelled oGH as a ligand revealed it to be the most effective competitor, followed by bPL, cPL, hGH chGH and ccGH, with respective IC50 values of 0.27, 0.94, 1.55, 2.13, 41.9 and 51.2 nM. Rabbit GHR-ECD inhibited the bPL-inducible proliferation of FDC-P1 cells stably transfected with rbGHR and Nb2 cells possessing rat PRLR. The biological activity of oGH, hGH, cPL, bPL, chGH and ccGH was tested in the FDC-P1 cells stably transfected with rbGHR and yielded the respective EC50 values (in nM) of 0.024, 0.023, 0.021, 0.24, 4.71 and 0.49. These results indicate remarkable discrepancies between the binding capacities and biological activities: the possible reasons for these findings are discussed.

Characterization and modulation of a prolactin receptor mRNA isoform in normal and tumoral human breast tissues.

The role of prolactin (PRL) and its specific receptor (R-PRL) in human breast tumorigenesis remains unclear. We have investigated here the presence of extracellular-deleted hPRL-R isoforms in normal human breast, fibrocystic disease, primary breast carcinoma (ductal carcinoma, ductulo-lobular and lobular) and breast cancer cell lines (T47-D and MCF-7). RT-PCR and Southern blot analysis demonstrated the expression of full-length hPRL-R transcript in all samples tested. We also detected a hPRL-R transcript generated by alternative exon 6 splicing. This isoform has a 170 bp deletion in its extracellular sub-domain that induces a frameshift. Thus, the predicted amino-acid sequence should encode a putative soluble protein with the N-terminal sub-domain of the hPRL-R and 10 additional carboxy-terminal residues. This isoform should not bind PRL as previously demonstrated by other experiments. Moreover, the ratio of full-length to deleted form of hPRL-R transcripts differs from normal to tumoral breast tissue. This ratio is higher in tumoral mammary gland than in normal tissue. Our data suggest that the alternative splicing of the hPRL-R gene towards the deleted transcript may be a mechanism to down- or up-regulate the expression of the native transcript of hPRL-R in accordance to the physiological or pathological state of the mammary gland.

Increase in prolactin receptor (PRL-R) mRNA level in the mammary gland after hormonal induction of lactation in virgin ewes.

In order to examine the hormonal regulation of the prolactin-receptor (PRL-R) gene expression during mammary gland development, ewes were treated to induce lactation via an estrogen-progesterone-hydrocortisone and ovine growth hormone treatment. In situ hybridization analysis was used and revealed that sex steroids increased PRL-R mRNA levels in the mammary gland. Using RNase protection assay we showed that the estradiol + progesterone treatment increased both the levels of the long and the short forms of PRL-R mRNA. Addition of hydrocortisone increased the level of alphaS1-casein transcripts and the level of the ratio of the long to the short form of the PRL-R mRNA. This ratio can be further enhanced by addition of ovine growth hormone to the latter treatment. This suggests a role of hydrocortisone and ovine growth hormone in the alternative splicing that leads to the preferential expression of the long form of the PRL-R mRNA. In conclusion, the present experiments suggest that estrogen, progesterone and hydrocortisone are the major regulators of the PRL-R gene expression during pregnancy and prepare the mammary gland for its differentiation.

Detection and regulation of leptin receptor mRNA in ovine mammary epithelial cells during pregnancy and lactation.

Adipocyte-epithelial cell interactions and their secretions are critical determinants of mammary gland development. In this present study, we examined the possible involvement of leptin and its receptors in the process of mammogenesis/lactogenesis. We demonstrated by reverse transcription and polymerase chain reaction analysis that long and short forms of leptin receptors were expressed in the ovine mammary gland during pregnancy and lactation. Furthermore, quantitative determinations, via ribonuclease protection assays, provided evidence that the level of leptin receptor expression was greatest during mid-pregnancy when active growth of the mammary gland is initiated. Location of the leptin receptors, as determined by in situ hybridization analysis, revealed that leptin receptor transcripts were expressed specifically in mammary epithelial cells. These data provide evidence that leptin, with its receptors, could be an important mediator in regulating mammary gland growth and development.

In vitro expression of long and short ovine prolactin receptors: activation of Jak2/STAT5 pathway is not sufficient to account for prolactin signal transduction to the ovine beta-lactoglobulin gene promoter.

The recent finding that sheep had long (l-oPRLR) and short (s-oPRLR) prolactin receptors provided new tools to further explore prolactin signaling to target genes. Here we used CHO cells transfected with l-oPRLR or s-oPRLR cDNAs to compare the activation of known key steps of prolactin signaling by the two receptors. We found that prolactin stimulated l-oPRLR tyrosine phosphorylation, although it lacked the last tyrosine residue found in other long prolactin receptors. In addition, l-oPRLR and s-oPRLR both responded to prolactin stimulation by (1) Janus kinase 2 (Jak2) tyrosine phosphorylation, (2) DNA-binding activation of signal transducer and activator of transcription 5 (STAT5), (3) stimulation of transcription from a promoter made of six repeats of STAT5-responsive sequence. However, although it contains STAT5-binding consensus sequences, the ovine beta-lactoglobulin promoter (-4000 to +40) was transactivated by l-oPRLR, but not by s-oPRLR. Taken together, our results indicate that activation of Jak2/STAT5 pathway alone is not sufficient to account for prolactin-induced transcription of this milk protein gene, and that sequences of its promoter, other than STAT5-specific sequences, account for the opposite transcriptional activation capabilities of l-oPRLR and s-oPRLR.

Insulin-like growth factor II (IGF-II) mRNA expression during skeletal muscle development of double-muscled and normal bovine foetuses.

We investigated the IGF-II gene expression in developing Semitendinosus muscle in foetal normal and double-muscled cattle. Samples from normal and double-muscled foetuses ranging from 90 to 210 d post-conception were collected and total RNA extracted. Northern blot analysis was performed using the human IGF-II cDNA probe. Five IGF-II transcripts, 5.1, 4.4, 3.7, 2.6 and 1.7 kb, were detected in muscle samples. Throughout gestation, all transcripts, except for the 5.1 kb one, decreased similarly in both genetic types. In double-muscled foetuses, the amount of the 5.1 kb transcript was higher than those of the other transcripts and its expression remained stable throughout the gestational stages analysed. These results indicated that the regulation of IGF-II gene transcription was distinct in both genetic types. The IGF-II foetal plasma concentrations increased throughout gestation. In bovine foetuses, the first muscle cell differentiation was concomitant with a high autocrine IGF-II mRNA expression and low plasma IGF-II levels in both genetic types. The second step of muscle cell differentiation was associated with high IGF-II plasma concentrations and the autocrine expression of IGF-II was reduced.

Demonstration of in vivo mammogenic and lactogenic effects of recombinant ovine placental lactogen and mammogenic effect of recombinant ovine GH in ewes during artificial induction of lactation.

The present study demonstrates that ovine placental lactogen (oPL) (ovine chorionic somatotrophin) may have an important role in the mammogenesis and/or lactogenesis of the ewe. Its effects were compared with that already described for ovine growth hormone (oGH). In the first experiment, 40 nulliparous ewes were induced to lactate by means of a 7 day (days 1-7) oestro-progestative treatment (E2+P4). The ewes from Group 1 (n=12) received no further treatment, while those of the other groups received either recombinant oGH (roGH, 28 micrograms/kg, i.m., twice daily, Group 2, n=12) or recombinant oPL (roPL, 79 micrograms/kg, i.m., twice daily, Group 3, n=12) from day 11 to 20. All ewes received 25 mg hydrocortisone acetate (HC) twice daily on days 18-20. Control Group 00 (n=2) received no steroid treatment at all, and the control Group 0 (n=2) received only the E2+P4 treatment. Thirteen ewes (three from each experimental group and the two of each control group) were slaughtered at the end of hormone treatments (day 21) before any milking stimulus. The 27 remaining ewes from Groups 1-3 were machine-milked and milk yields recorded daily from day 21 to 76. The E2+P4 treatment enhanced the plasma levels of oPRL, oGH and IGF-I between days 1 and 7 by 1.5, 2. 3 and 2.6 times respectively (P=0.002); roGH treatment induced a highly significant enhancement of IGF-I plasma levels from day 11 to 20, whereas a similar effect appeared for roPL-treated ewes only from day 17 to 20 (P<0.01). Eight weeks after the last exogenous hormone injections, milk yields of both roGH- and roPL-treated groups progressively rose to twice that of unsupplemented groups (P<0.001). The mammary DNA content on day 21 was higher for animals which received either oGH or oPL but, due to individual variations in so few samples (n=3), this difference was not significant. No beta-casein was measured in mammary tissue from control ewes, whereas steroid-treated ewes (E2+P4+HC) had higher casein concentrations regardless of subsequent hormonal treatment on days 11-20 (P<0.001). beta-Casein concentrations in mammary parenchyma of roGH-treated ewes did not differ from that of ewes which received only E2+P4+HC; roPL supplementation clearly enhanced expression of beta-casein (P<0.001). IGF-I stimulation by either roGH or roPL was more precisely examined during a second experiment, in which two twice-daily i.m. doses (58 or 116 micrograms/kg) of either roGH or roPL were administered to four groups of six ewes that were E2+P4 treated as those of Experiment 1. A control group (n=6) received no exogenous hormone from day 11 to 13. On day 13, hourly blood samples were taken from all ewes over 11 h. Both doses of roGH significantly stimulated IGF-I in a dose-dependent manner. The 58 micrograms/kg dose of roPL did not significantly stimulate IGF-I, but although being somewhat less efficient than the 58 micrograms/kg dose of roGH, the 116 micrograms/kg dose of roPL significantly stimulated IGF-I secretion (P<0. 001). These results suggest that mammogenesis and/or lactogenesis in the ewe is in part controlled by somatotrophic hormones such as oGH and oPL and that IGF-I could be one of the mediators of these hormones.

Cloning, preparation and characterization of biologically active recombinant caprine placental lactogen.

Caprine placental lactogen (cPL) cDNA was cloned by reverse transcription (RT)-PCR from total RNA of goat placenta. The PCR product encoding for the mature protein was gel purified, ligated to pGEM-T and finally subcloned into a pET8c prokaryotic expression vector. E. coli cells (BL-21) transformed with this vector overexpressed large amounts of cPL upon induction with Isopropyl-1-thio-beta-D-galactopyranoside. The expressed protein, found in the inclusion bodies, was refolded and purified to homogeneity on Q-Sepharose and SP-Sepharose columns, yielding two electrophoretically pure fractions (cPL-Q and cPL-S), composed of over 98% of monomeric protein of the expected molecular mass of approximately 23 kDa. Binding of cPL to the extracellular domain (ECD) of prolactin receptors (PRLR) from rat (r), rabbit (rb), and bovine (b), growth hormone receptors (GHR) from human (h) and rabbit, and binding to rabbit mammary gland membranes revealed similar binding profiles for cPL-Q, cPL-S and ovine (o)PL. Caprine PL was capable of forming 1:2 complexes with hGHR-ECD, rbGHR-ECD, rPRLR-ECD and rbPRLR-ECD whereas with bPRLR-ECD only a 1:1 complex was detected. The biological activity of both cPL fractions resulting from proper renaturation was further evidenced by their ability to stimulate proliferation of Nb2 cells, FDC-P1 cells transfected with rabbit or human GHRs and by stimulation of beta-casein synthesis in rabbit and ovine mammary gland acini cultures.

Developmental expression and localization of the prolactin receptor (PRL-R) gene in ewe mammary gland during pregnancy and lactation: estimation of the ratio of the two forms of PRL-R messenger ribonucleic acid.

In this study, we have analyzed the developmental expression of the prolactin receptor (PRL-R) gene in the ewe mammary gland during pregnancy and lactation. Using Northern and slot-blot analysis and in situ hybridization, we showed that the level of PRL-R mRNA in mammary epithelial cells increased during the second half of pregnancy, decreased at the end of pregnancy, and remained relatively stable during lactation with a level above that observed at the beginning of pregnancy. As shown by RNase protection assay, the ratio of the long to the short form of the PRL-R mRNA was always above 1. This ratio increased between Day 70 of pregnancy and term and decreased progressively during lactation. The high level of PRL-R mRNA before the induction of alphaS1-casein gene expression suggests that PRL may be involved in the growth and development of the mammary gland. More precisely, the increase of the ratio of the long to the short form of the PRL-R during lactogenesis suggests that the latter form may have a dominant negative action in the activation of milk protein gene transcription. Thus the long/short-form ratio of the PRL-R may play a key role in the shift between growth and differentiation of the mammary gland.

In vivo study of prolactin (PRL) intracellular signalling during lactogenesis in the rat: JAK/STAT pathway is activated by PRL in the mammary gland but not in the liver.

The rat prolactin receptor (PRL-R) exists in two forms, which differ in the length of the cytoplasmic domains, tissue distribution, and biological activity. The short form predominates in liver while the long form is prevalent in mammary gland. We have compared activation by PRL of the JAK2-STAT pathway (protein tyrosine phosphorylation and STAT5 activation) in mammary gland and liver in an in vivo rat model of induction of lactogenesis by PRL injections, and we have studied the relative proportion of both forms of the receptor in these tissues by reverse transcription-polymerase chain reaction. Rats were ovario-hysterectomized on Day 19 of pregnancy, treated with bromocriptine, subsequently injected with 250 micrograms ovine PRL i.p. on Day 20, and killed 0-12 h after. Western blots of solubilized mammary gland and liver membranes immunoprecipitated with anti-PRL-R or anti-JAK2 antibodies showed that the PRL-R is constitutively associated with JAK2 and that the long form of the PRL-R is present in both tissues, while the short form was detected only in liver. Phosphorylated proteins corresponding to the long form of PRL-R and JAK2 appeared 15-60 min after ovine PRL injection in mammary extracts but not in liver. At these same times, an electrophoretic mobility shift assay, using a rat beta-casein probe specific for STAT5 binding, showed activated STAT5 in mammary gland cytosol and nuclear extracts. In the liver, low levels of activated STAT5 were detected in non-treated animals, which were not modified by PRL. Quantitative RT-PCR of liver and mammary PRL-R mRNA showed that the amount of the long form of PRL-R mRNA is roughly comparable in both tissues, while the short form is predominant in liver and in a minority in mammary tissue. Both forms were down-regulated by PRL only in mammary glands. Thus, during lactogenesis, mammary tissue responds to PRL by activation of JAK2 and STAT5, while the liver does not respond to PRL in spite of the presence of PRL-R associated with JAK2 and pre-existing activated STAT5. Thus, liver tissue may lack a critical component for activation of the PRL pathway, or the large quantities of the short form of the PRL-R may associate with the long form to constitute inactive heterodimers.

Ontogenesis of LH and FSH receptors in postnatal rabbit testes: age-dependent differential expression of long and short RNA transcripts.

The ontogeny of testicular LH and FSH receptors was studied in New Zealand rabbits from 20 to 180 days postpartum. The concentrations of free receptors (per mg total proteins) were very low at day 20. They increased steeply at day 30 for the LH receptor and at day 50 for the FSH receptor. Three RNA bands (1.2, 2.5 and 3 kb) were repeatedly detected on northern blots for the LH receptor and two bands (1.2 and 2.2 kb) were detected for the FSH receptor. The 1.2 kb band (which cannot give rise to full-length, membrane-anchored receptor) was present throughout the 20-180 day period for each receptor. However, the higher molecular mass bands were nearly undetectable at day 20. The 2.5 and 3 kb bands of the LH receptor increased twofold between day 20 and day 120, while the 2.2 kb band of the FSH receptor increased fivefold between day 20 and day 75. Thus the very low concentrations, or even absence, of the larger transcripts of both LH and FSH receptors were correlated with the inability to detect their cognate protein until 20 days of age. Subsequently, coordinated increases in high molecular mass transcripts and protein were observed for both receptors. Total LH receptor content increased in parallel to the previously reported increase in plasma testosterone between day 65 and day 100. FSH receptor density began to increase steeply at day 50, just at the onset of spermatogenesis. Thus, postnatal testicular development in the rabbit seems to entail the transcription of high molecular mass, translatable transcripts of the gonadotrophin receptors.

Development of a constitutively active mutant form of the prolactin receptor, a member of the cytokine receptor family.

The extracellular domain of the PRL receptor (PRL-R) is composed of two subdomains of approximately 100 amino acids, S1 and S2. To explore the functional significance of these subdomains in PRL binding and signal transduction, deletion mutants of S1 or/and S2 subdomains were constructed. We report here the inability of each of these mutant receptor forms to bind PRL after expression in COS-7 cells. We also studied the abilities of these different mutant receptors to respond to hormonal stimulation after transfection of each mutant complementary DNA into CHO-K1 cells along with a chimeric gene containing the promoter of a milk protein gene (beta-lactoglobulin) fused to chloramphenicol acetyltransferase coding sequence. Somewhat unexpectedly, a constitutively (PRL-independent) mutant form of the PRL-R was obtained after deletion of the S2 subdomain. Moreover, we analyzed, in CHO-K1 cells, the biological activity of chimeric receptors constructs in which each subdomain sequence was replaced by an unrelated, but coding, sequence of foreign protein, and we confirmed a specific requirement for the S1 sequence in the constitutive activity. In contrast, the S2 subdomain produced an inhibitory effect on S1 constitutive activity. Cotransfection experiments with the wild-type receptor and the constitutive mutant receptor provided evidence that the wild-type receptor was able to inhibit the constitutive activity of the deleted mutant. Furthermore, in the mouse mammary epithelial cell line HC11, the constitutive PRL-R form was able to induce transcription of the beta-casein gene in the absence of PRL. These results suggest a complex signal transduction process that implicates each extracellular PRL-R subdomain. Possible mechanisms for the constitutive effect are discussed.

Polymeric-Ig receptor gene expression in rabbit mammary gland during pregnancy and lactation: evolution and hormonal regulation.

The polymeric immunoglobulin receptor (poly Ig-R) mediates transcytosis of IgA and IgM antibodies produced by local plasma cells across epithelial cells of mucosal and glandular tissues. Gene expression of the poly-Ig R was analyzed in rabbit mammary gland during pregnancy and lactation. The poly Ig-R was expressed as early as day 8 (G8) of gestation and mRNA accumulation remained low until about G18. From G21, the mRNA abundance increased and reached steady state levels approximately 5-fold higher at day 15 of lactation (L15) when compared to basal levels at G8. The hormonal regulation of poly-Ig receptor gene expression was assessed in mammary organ cultures. Poly-Ig R mRNA accumulation in mammary explants cultured for 24 or 48 h in the presence of ovine prolactin (oPRL) was significantly increased to a maximal 4-fold level at 1 microgram ml-1 of oPRL. Estradiol (100 pg ml-1) or progesterone (1 microgram ml-1) did not further stimulate poly-Ig R expression. In contrast, their combination resulted in a significant 30-50% decrease of poly-Ig-R mRNA levels. The addition of 1 microgram ml-1 of cortisol to medium in the absence or presence of estradiol or progesterone decreased the amount of poly-Ig-R mRNA. The results suggest that until mid-pregnancy, poly-Ig-R expression is inhibited by elevated progesterone-estradiol concentrations and that the subsequent increase is due to the concomitant decrease of the two circulating steroids and the increase of serum prolactin levels.

Effects of anoestrus and bromocryptine treatment on the expression of prolactin and LH receptors in the rabbit ovary during lactation.

The aim of the present study was to correlate the number of prolactin and LH receptors in the ovary with the changes in sexual behaviour that occur within a few days following parturition in rabbits. Multiparous New Zealand white rabbits at days 0, 3 and 10 of lactation were tested for their receptivity upon presentation to a male. Rabbits were classed as either receptive or nonreceptive at each stage of lactation; half of the animals in each class were treated with bromocryptine to examine the effects of prolactin deprivation. Ovarian receptors for LH and prolactin, as well as the concentration of their corresponding mRNA, were measured at each stage of lactation in every group. Results indicate that receptive behaviour is correlated with significantly more follicles on the rabbit ovary (diameter > 1 mm; P < 0.05) and an increase in the concentration of LH receptor mRNA (P < 0.001) and prolactin receptors (P < 0.05). In addition, on day 4 of lactation, there were significantly fewer follicles in nonreceptive rabbits (P < 0.05). LH receptor content remained constant on days 1 and 4 of lactation but increased on day 11 (P < 0.05). Bromocryptine treatment had no effect on the number of follicles or on the amount of LH receptor mRNA in does, but it significantly increased LH receptors (P < 0.01), and the concentration of prolactin receptor mRNA (P < 0.001), particularly on day 11 of lactation (P < 0.05), and prolactin receptor content (P < 0.001). Receptive rabbit ovaries therefore display more follicles that can respond to an LH surge via newly transcribed LH receptors than do nonreceptive.(ABSTRACT TRUNCATED AT 250 WORDS)

Preparation of the extracellular domain of the rabbit prolactin receptor expressed in Escherichia coli and its interaction with lactogenic hormones.

The cDNA of the extracellular domain of the rabbit prolactin receptor (rbPRLR-ECD) was cloned in the prokaryotic expression vector pTrc99A to enable its expression in Escherichia coli after induction with isopropyl-1-thio-beta-D-galactopyranoside. The bacterially expressed rbPRLR-ECD protein, contained within the refractile body pellet, was solubilized in 4.5 M urea, refolded, and purified on a Q-Sepharose column by stepwise elution with NaCl. The bioactive monomeric fraction was eluted in 0.05 M NaCl, yielding 15-20 mg/8 liters of induced culture. The purified protein was > 98% homogeneous, as shown by SDS-polyacrylamide gel electrophoresis in the presence or absence of reducing agent and by chromatography on a Superdex column. Its molecular mass was 25 kDa as determined by SDS-polyacrylamide gel electrophoresis in the absence of reducing agent and 22 kDa as determined by gel filtration. Binding experiments revealed remarkable differences between rabbit and porcine prolactins (PRLs) and the other tested lactogenic hormones. Gel filtration was used to determine the stoichiometry of the rbPRLR-ECD interaction with ovine, rabbit, and porcine PRLs, with human growth hormone and its truncated des-7 analogue, and with bovine placental lactogen (bPL) and des-13-bPL. The formation of only 1:1 complexes was indicated, except with bPL, for which a 2:1 complex was detected. Identical stoichiometry was also obtained using excess radiolabeled rbPRLR-ECD in gel filtration experiments. Interaction of 125I-labeled ovine PRL with rbPRLR-ECD secreted into conditioned medium by rbPRLR-ECD cDNA-transfected COS 7 cells also indicated formation of 1:1 molar complexes. Despite the differences in binding potency and stoichiometries of the interaction with rbPRLR-ECD, all seven tested hormones were biologically active in inducing PRL receptor-mediated casein synthesis in explants of rabbit mammary gland. We therefore propose that the formation of the 1:2 complexes with soluble rbPRLR-ECD is not predictive of biological activity of the different lactogenic hormones.

Expression of prolactin (PRL) receptor gene and PRL-binding sites in rabbit intestinal epithelial cells.

Specific binding sites for PRL were identified on isolated intestinal epithelial cells from both male and female rabbits. These receptors exhibited a very high affinity for PRL (Kd = 5 x 10(-11) M) and were immunologically very similar to the well characterized mammary PRL receptor. About 3500 PRL receptors/cell were expressed on isolated epithelial cells from rabbit jejunum. These receptors were distributed in precise portions of the gut, being highly expressed in the proximal small intestine (duodenum and jejunum), moderately expressed in the ileum, and barely detectable in the colon. The levels of intestinal epithelial PRL receptors were low in 15-day-old rabbits, moderate at 1 month, and reached adult levels at 2 months, indicating enhanced PRL receptor expression in the intestine as development proceeded. The PRL receptor gene was specifically and highly expressed in the rabbit intestine, and four PRL receptor transcripts were detected that were identical to the transcripts characterized in the mammary gland. In individual intestinal segments, the expression of PRL-binding sites was always highly correlated with the level of PRL receptor mRNA. These results show that isolated intestinal epithelial cells express the PRL receptor gene as well as specific binding sites with a high affinity for PRL. They suggest that PRL regulates intestinal functions by exerting direct actions on the intestinal epithelial cells.

Identification of prolactin and growth hormone binding proteins in rabbit milk.

Two distinct soluble proteins that specifically bind 125I-labeled human growth hormone (GH) are identified in the supernatant of ultracentrifuged rabbit milk, using HPLC gel filtration. The higher molecular weight proteins is GH specific, whereas the other one is specific for prolactin (PRL). The PRL-binding protein has a very high affinity for the hormone, almost 10 times higher than the affinity of the mammary gland membrane receptor. The PRL-binding protein is immunoprecipitated by a monoclonal antibody against the PRL receptor; another monoclonal antibody, which inhibits the PRL binding to mammary gland membranes, is a poor competitor for the PRL binding to the milk protein. These findings suggest that the milk PRL-binding protein corresponds to the binding domain of the receptor, but also that the conformation of the receptor and of the binding protein might differ. The milk and the plasma GH-binding proteins have a similar binding affinity. In cross-linking experiments using 125I-labeled human GH, the Mr of the GH-binding protein and of the PRL-binding protein were estimated to be 51,000 and 33,000, respectively. The binding proteins identified in the present work are probably responsible for the transport of their specific ligands in the milk. It is also conceivable that they have a role in the effects of GH and PRL in the mammary gland and/or the intestine of the young.

Prolactin receptor gene expression in rat mammary gland and liver during pregnancy and lactation.

The expression of two forms of PRL receptor messenger RNA was measured at different stages of pregnancy and lactation in mammary gland and liver from Sprague-Dawley rats, using 32P-labeled complementary DNA probes encoding the extracellular part of the receptor (E probe), common to the two forms and a probe encoding the intracellular part of the long form of the receptor (I probe), that only recognizes sequences specific to the long form of the receptor. Hybridizations were performed in Northern blots obtained from electrophoreses of poly (A+) enriched RNA preparations from mammary glands and livers of rats on days 0, 6, 12, 19, and 21 of pregnancy and 5, 10, 15, and 20 of lactation. The Northern blots were also hybridized with a chicken beta-actin probe, to correct for the amount of mRNA added and the different metabolic states of the tissues. Both tissues expressed the same forms of PRL receptor mRNAs, namely bands at 2.5, 3, and 5.5 kilobases encoding the long form of the receptor and a major band at 1.8 kilobases encoding the short form. The liver expressed all the receptor mRNA forms in much higher quantity than the mammary gland, independent of the reproductive state. In liver there was an increase of all the transcripts on day 19 of pregnancy, followed by an abrupt decline at the onset of lactation, to levels lower than those of virgin rats. In contrast, mammary gland PRL receptor mRNAs were low in virgin and pregnant animals, increased significantly at day 21 of pregnancy, and continued to increase throughout lactation. Treatment of day 19 pregnant rats with the antiprogesterone RU 486 induced, 24 h later, PRL receptor mRNAs in mammary gland but not in liver. There were no significant differences in the relative proportions of long to short forms of PRL receptor mRNAs at the different reproductive states, but the proportion of the long form was slightly greater in mammary gland than in liver. Membrane PRL receptor concentrations were also measured in the same tissues used for the mRNA study by binding to a 125I-labeled monoclonal antibody (U5), which specifically recognizes the PRL receptor at a site different from the hormone binding site. The quantity of receptor measured by U5 binding was approximately 3 times higher than that measured with 125I-labeled ovine PRL.(ABSTRACT TRUNCATED AT 400 WORDS)