Jacqueline Paly

Prolactin stimulates milk protein promoter in CHO cells cotransfected with prolactin receptor cDNA

A functional biological system was developed by cotransfecting mammalian cell lines with the cDNA of the prolactin receptor (PRL-R) and a fusion gene containing the promoter of the milk protein, ovine beta-lactoglobulin linked to the coding sequence of the chloramphenicol acetyltransferase (CAT) gene. Surprisingly, this system is effective even if a non-mammary cell line is used, since Chinese hamster ovary (CHO) cells transfected both transiently and stably with PRL-R cDNA respond to PRL, as observed by stimulation of the reporter gene. This newly developed system should help precisely define the functional domains of both the PRL-R molecule and of the regulatory elements of a PRL target gene.

A limited cytoplasmic region of the prolactin receptor critical for signal transduction

Prolactin receptors (PRL-R) are members of the cytokine receptor superfamily, which have in common, an absence of any known consensus sequence for signal transduction in their cytoplasmic domains. Four areas of high sequence homology have been identified in the cytoplasmic domains of PRL and growth hormone (GH) receptors, which may be important for signal transduction. The aim of this study was to investigate the role of these cytoplasmic regions in the functional activity of the PRL-R. Several mutant forms of PRL-R were constructed either by truncation or by deletion of the cDNA. Biological activities of these mutant receptors were assayed in CHO cells using a functional assay consisting in the co-transfection of PRL-R cDNA, along with a PRL responsive promoter fused to the coding sequence of the chloramphenicol acetyl transferase (CAT) gene. Progressive truncation of the cytoplasmic domain led to a progressive loss of ability to transactivate the CAT gene. Fully active PRL-R could be obtained when 217 of 358 aa of the cytoplasmic domain were present. Deletion of the first region of homology with the GH-R (residues 245-267) abolished the functional activity of PRL-R, whereas deletion of the second region of homology (residues 322-333) was without effect. These results indicate that a critical cytoplasmic region of 23 residues proximal to the transmembrane domain is essential for PRL signal transduction. There is strong homology within an 8-residue segment of this region with other members of the cytokine receptor superfamily, suggesting it contains a sequence necessary for signal transduction.

Distinct Cytoplasmic Regions of the Prolactin Receptor Are Required for Prolactin-induced Calcium Entry

Two cytoplasmic regions of the prolactin (PRL) receptor are well documented for their participation in PRL signal transduction, the membrane proximal box 1 and the COOH-terminal region. In order to study the role of these regions in PRL-induced Ca2+ increase, we use Chinese hamster ovary (CHO) cells stably transfected with mutated PRL receptor cDNA. These cells express the long form of PRL receptor deleted from box 1 (CHO Δ1 cells) or the 141 amino acids of the COOH-terminal region (CHO H3 cells). The patch-clamp technique in “whole-cell” configuration and microfluorimetric techniques were used singly or in combination. Data obtained for these cells were compared with those we have recently published using CHO cells expressing the wild-type long form of the PRL receptor (CHO TSE32). In contrast to CHO TSE32 cells, exposure of CHO Δ1 or H3 cells to PRL (0.05–50 nm) did not modify [Ca2+] i . We have previously shown that the PRL-induced calcium influx via voltage-insensitive, Ca2+ channels was due to the activation of tyrosine kinase-dependent K+ channels that hyperpolarize the CHO TSE32 cell membrane (hyperpolarization-driven Ca2+influx). Therefore, two events are involved in PRL-induced Ca2+ changes (i) JAK2-activation of K+ channels and (ii) intracellular messenger-opening of Ca2+ channels. In CHO Δ1 cells, PRL (0.05–50 nm) neither hyperpolarized the membrane potential nor stimulated the JAK2-dependent K+ current, confirming the pivotal role played by box 1/JAK2 in the PRL-induced activation of K+ channels. However, when these cells were voltage-clamped below the resting membrane potential, application of 5 nm PRL resulted in an increase in Ca2+ influx. Therefore, box 1/JAK2 was not involved in the opening of these Ca2+ channels. In CHO H3 cells, 5 nm PRL activated the K+ current and hyperpolarized the membrane potential without any effect on [Ca2+] i . Moreover, PRL was also ineffective on CHO H3 cells voltage-clamped below the resting membrane potential. Therefore, the COOH-terminal region is involved in the production of the intracellular messenger that opens voltage-independent Ca2+ channels. We conclude from these findings that box 1 and COOH-terminal regions are both needed for PRL-induced Ca2+ changes.

Expression by Transgenesis of a Constitutively Active Mutant Form of the Prolactin Receptor Induces Premature Abnormal Development of the Mouse Mammary Gland and Lactation Failure

Abstract Prolactin (PRL) initiates signal transduction by inducing homodimerization of PRL receptor (PRL-R). We have previously developed a mutant form of the PRL-R in which a part of the extracellular domain is deleted. This receptor constitutively activates protein gene transcription. We examined the oligomerization of the mutant PRL-R using two differently epitope-tagged receptors in a coimmunoprecipitation assay. It was shown that mutant receptor dimers were formed in a ligand-independent manner, which may explain the constitutive activity on milk protein gene expression. To study the biological activity of this mutant PRL-R on mammary gland development, we generated two lines of transgenic mice expressing the corresponding cDNA specifically in the mammary epithelial cells. For both transgenic lines, the mammary gland of 8-wk-old virgin mice was overdeveloped with numerous dilated ductal and alveolar structures, whereas only a limited duct network was present in wild-type animals at the same age. During pregnancy, the ducts and alveoli of transgenic mice were more developed than those of control animals. At parturition, the transgenic animals failed to lactate and nourish their offspring, and the involution of the mammary gland was strongly delayed. In conclusion, the expression of a constitutively active PRL-R by transgenesis induces a premature and abnormal mammary development and impairs terminal differentiation and milk production at the end of pregnancy.

Effect of PRL on MAPK activation: negative regulatory role of the C-terminal part of the PRL receptor

Prolactin induces cell proliferation and cell differentiation through well-known MAPK Erk, and JAK2/STAT5 pathways depending on the cell line. The aim of the present study was to delineate the functional domains of the PRL receptor involved in PRL induced MAPK regulation. Using various PRL-R mutants of the cytoplasmic domain we found, that the membrane proximal domain is necessary for PRL induced MAPK activation and that the C-terminal part of the receptor exerts a negative regulatory role. A pharmacological approach, using different types of inhibitors, provided evidence that PRL induced MAPK activation requires both a MEK dependent pathway and a PI3K dependent pathway. The negative regulation induced by the carboxy-terminal part of the receptor involves a combination of tyrosine phosphatases and serine/threonine phosphatases as concluded from the actions of the phosphatase inhibitors: pervanadate, PAO and okadaic acid. The mechanism by which these phosphatases are recruited or are induced by the last 141 cytoplasmic residues of the receptor remains to be determined. Finally the negative regulatory role of the carboxy-terminal part of the receptor, first demonstrated in the present study, is discussed in terms of the regulation of different effects of PRL on growth and differentiation.

Introduction of a Proximal Stat5 Site in the Murine α-Lactalbumin Promoter Induces Prolactin Dependency In Vitro and Improves Expression Frequency In Vivo

In order to establish a possible correlation between in vitro prolactin induction and the transcriptional activity of mammary gene promoters in transgenic mice, a functional Stat5-binding site was created by means of site-directed mutagenesis at position −70 on a 560 bp murine α-lactalbumin promotor linked to a CAT reporter gene. Surprisingly, the wild-type promoter was constitutively active in vitro and could not be induced by prolactin. Introducing the proximal Stat5 site abolished this constitutive activity and resulted in prolactin dependence in both CHO-K1- and HC11-transfected cells. In transgenic mice, both the frequency of lines expressing the transgene and the prevalence of mid to late pregnancy expression were increased.

PROLACTIN RECEPTOR AND SIGNAL TRANSDUCTION TO MILK PROTEIN GENES

Abstract After cloning of the mammary gland prolactin (PRL) receptor cDNA, a functional assay was established using co-transfection of PRL receptor cDNA together with a milk protein promoter/chloramphenicol acetyl transferase (CAT) construct in Chinese hamster ovary (CHO) cells. Different mutants of the PRL receptor were tested in this CAT assay to delimit the domains in the receptor necessary for signal transduction to milk protein genes. In CHO cells stably transfected with PRL receptor cDNA, high numbers of PRL receptor are expressed. By metabolic labeling and immunoprecipitation, expressed PRL receptor was identified as a single species of 100 kDa. Using these cells, we analyzed the effects of PRL on intracellular free Ca++ concentration. PRL stimulates Ca++ entry and induces secondary Ca++ mobilization. The entry of Ca++ is a result of an increase in K+ conductance that hyperpolarizes the membranes. We have also analyzed tyrosine phosphorylation induced by PRL. In CHO cells stably transfected with PRL receptor cDNA, PRL induced a very rapid and transient tyrosine phosphorylation of a 100-kDa protein which is most probably the PRL receptor. The same finding was obtained in mammary membranes after PRL injection to lactating rabbits. Whereas tyrosine kinase inhibitors genistein and lavendustin were without effect, PRL stimulation of milk protein gene promoters was partially inhibited by 2 μM herbimycin in CHO cells co-transfected with PRL receptor cDNA and the β lactoglobulin CAT construct. Taken together these observations indicate that the cytoplasmic domain of the PRL receptor interacts with one or several tyrosine kinases, which may represent early postreceptor events necessary for PRL signal transduction to milk protein genes.

INVOLVEMENT OF BOTH CALCIUM INFLUX AND CALCIUM MOBILIZATION IN GROWTH HORMONE-INDUCED CA2+I INCREASES IN CHINESE HAMSTER OVARY CELLS

This study reports rapid effects of growth hormone (GH) on the intracellular free calcium concentration ([Ca2+]i) in Chinese hamster ovary (CHO) cells stably expressing rabbit GH receptor. [Ca2+]i was measured by spectrofluorimetric methods in single cells and membrane Ca2+ currents by patch clamp techniques in the whole-cell configuration. In individual CHO cells, bathed in a standard saline solution containing 2 mM Ca2+, basal [Ca2+]i was 191 +/- 27 nM (mean +/- S.D.; n=83). Short term administration of GH (100 ng/ml, 30 s) induced a [Ca2+]i increase in 54% of cells tested (n = 398 of 743). Responses were clearly heterogeneous. Maximum calcium increase varied from 16 to 853 nM and time to peak varied from 4 to 320 s. On examination of the [Ca2+]i increases, it was possible to define two different types of calcium responses to GH. Experimental manipulations of extracellular and intracellular calcium concentrations demonstrated that GH-induced calcium increases involved both calcium influx and calcium mobilization. Calcium influx, a long lasting, small amplitude (63 +/- 34 nM) response, was observed in 121 out of 398 cells (30%) whereas calcium mobilization, a transient, large amplitude (263 +/- 175 nM) response, was observed in 277 out of 398 cells (70%). Moreover, patch clamp data show that influx did not involve the dihydropyridine-sensitive calcium channels.