Characterization of the prolactin receptor in cell fractions from rat liver

The usefulness of CHAPS as a non-cytotoxic stabilizing agent in purification of growth factors

Among several detergents, a zwitterionic detergent, 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulfonate (CHAPS), was found to be least cytotoxic for cultured mammalian cells. CHAPS improved the activity recovery and elution profile of crude and purified fibroblast growth factors (FGFs) during chromatographies. Diluted preparations of FGFs were stabilized by CHAPS against the loss during storage. Amino acid sequence analysis was not disturbed by CHAPS. CHAPS was removable by reversed-phase high-performance liquid chromatography. These results indicate that CHAPS is useful as a non-cytotoxic stabilizing agent in purification of various kinds of bioactive polypeptides.

A membrane protein associated with the prolactin receptor. Studies with a photoactivatable human growth hormone derivative

Prolactin receptor from rat liver (PRL-R, 42 kDa) was cross-linked to a radiolabeled azidophenacyl derivative of human growth hormone ([125I]AP-hGH) to yield a 63 kDa adduct. In addition, a protein of Mr 50-52 K was detected as a 73 kDa complex. Microsomes incubated with either (a) increasing amounts of [125I]AP-hGH, or (b) a fixed amount of photoprobe and increasing concentrations of unlabeled hGH, showed that the 73/63 kDa band intensity ratio remains constant (0.71-0.77). Once transferred onto nitrocellulose membranes, only the 42 kDa protein is able to bind [125I]AP-hGH or [125I]hGH. Two anti-PRL-R monoclonal antibodies fail to cross-react with proteins of Mr 50-52 K. In membranes solubilized with 3-[(3-cholamidopropyl)-dimethylammonio]-1-propanesulfonate (CHAPS), a significantly lower amount of the 73 kDa complex is detected. Thus, the 50-52 kDa protein appears to be structurally unrelated to, but is presumably associated with the PRL-R. The 73 kDa complex is also detected under low membrane fluidity conditions (1 degree C), indicating that PRL-R associates to this 50-52 kDa protein prior to hormone binding. Perfusion of rat liver with [125I]AP-hGH shows that this associated protein accompanies the receptor along its intracellular pathway.

Solubilization and characterization of a lactogenic receptor from human placental chorion membranes

Prolactin has a wide range of actions, including osmoregulation and the control of mammary gland development and lactation. These effects are mediated through a high-affinity cell surface receptor, which has been well characterized in a number of animal tissues. The molecular characteristics of the human receptor are unknown, however. The present studies were initiated, therefore, to determine the binding and molecular characteristics of the lactogenic receptor of human placental chorion membranes. Subcellular fractionation studies showed that the bulk of the receptor sedimented in the microsomal fraction at 45,000gav. Endogenous ligand was dissociated from the receptor with 3.5 M MgCl2 or 0.05 M acetate buffer (pH 4.8) with preservation of binding activity. The microsomal receptor bound human growth hormone (hGH), human prolactin (hPRL), ovine prolactin (oPRL), and human placental lactogen (hPL) but not non-primate growth hormones, indicating a narrow specificity for lactogenic hormones. The binding was only partially reversible in agreement with the known binding kinetics of animal lactogenic receptors. The receptor was solubilized with 45% yield from the microsomes using 16 mM 3-[(3-cholamidopropyl)dimethylammonio]-1-propane sulphonate (CHAPS) detergent-250 mM NaCl, and the binding activity was fully restored by a two-fold dilution in the binding reaction to reveal a KD of 0.8 nM for hGH and a binding capacity of 200 fmol of specifically bound hGH per mg of microsomal protein. Gel filtration chromatography indicated the minimum molecular weight of the ligand-receptor complex was approximately 60,000 daltons, and sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) of covalently cross-linked 125I-hGH-receptor complexes revealed a molecular size of 58,000 daltons. When account was taken of the contribution of the ligand, a molecular weight of 36,000 for the receptor's binding domain was obtained. These data indicate that the chorion lactogenic receptor has very similar binding and molecular characteristics to the lactogenic receptors from other mammalian species. Chorion membranes are thus a convenient source of material for the further purification and characterization of the human lactogenic receptor.

Characterization of hepatic lactogen receptor. Subcellular distribution and characterization of N-linked carbohydrate chains

The types of carbohydrate chains present in a rat liver lactogenic hormone-binding receptor species with an Mr of 82,000, and in its hormone-binding subunits with Mr values of 40,000 and 35,000, were characterized using carbohydrate-chain-cleaving enzymes and affinity cross-linking. The subcellular distribution of lactogenic hormone-binding species was studied in organelle-enriched fractions. The monomeric Mr-40,000 and Mr-35,000 species contain N-linked tri- or tetra-antennary complex and high-mannose chains respectively. The Mr-82,000 species exists in two forms, where the Mr-40,000 and Mr-35,000 subunits are each combined with unglycosylated and, with the technique used, unlabelled subunit(s). Studies with organelle-enriched fractions revealed that the Mr-35,000 species was found in an endoplasmic reticulum-enriched fraction. The Mr-40,000 species was the predominant monomeric binding species in Golgi/endosome- and plasma membrane-enriched fractions. It is suggested that the Mr-35,000 species is a precursor to the Mr-40,000 species. In lysosome/endosome- or lysosome-enriched fractions, a broad distribution in Mr (35,000-40,000) was characteristic of the hormone-binding species. The Mr-82,000 species was only found in a Golgi/endosome-enriched fraction. Labelling of endosome lactogen receptor by injection of 125I-labelled ovine prolactin in vivo and cross-linking yielded only the Mr-40,000 species. Thus, the Mr-40,000 and Mr-35,000 lactogenic hormone-binding species each appear to be combined with the unglycosylated receptor subunit(s) in the Golgi complex to form Mr-82,000 heterodimeric complexes.

Variations of liver prolactin receptors during the estrous cycle in normal rats and in the genetically hypoprolactinemic IPL nude rat

Ovine prolactin (oPRL) binding to liver membranes was studied during the estrous cycle in normal and in genetically hypoprolactinemic rats. Serum levels of hormones were measured by radioimmunoassay and prolactin (PRL) binding was determined using 125I-ovine PRL in the 100,000 X g pellet. Scatchard plots obtained were curvilinear throughout the estrous cycle in the normal rat. They were analyzed in reference to the co-operativity model and to the Hill model which give the factor delta and Hill's coefficient (nH), respectively. During the estrous cycle, delta values varied from 3.77 +/- 0.66 on the day of estrous to 13.48 +/- 1.34 on the day of proestrus at 16.00 h. At the same time, nH were 0.97 +/- 0.033 on the day of estrus and 0.72 +/- 0.025 on the day of proestrus at 16.00 h. On the other hand, the number of PRL receptors did not change significantly throughout the estrous cycle. Moreover, the dissociation of 125I-oPRL from its receptor was accelerated by the presence of native ovine oPRL. These results suggest the presence of a negative co-operativity which reached a maximum on the day of proestrus in the normal rat. This co-operativity during the estrous cycle was not found in liver from genetically hypoprolactinemic (IPL nude) rats, which present a total absence of lactation. The delta values did not vary significantly and were 6.52 +/- 1.30 on the day of estrus and 4.41 +/- 0.52 on the day of proestrus at 16.00 h. The difference between the two rat strains was statistically significant on the day of proestrus at 16.00 h for both delta and nH values.(ABSTRACT TRUNCATED AT 250 WORDS)

Lactogenic and somatogenic binding sites in intact and detergent-solubilized membrane preparations of female rat liver

The presence of lactogenic and somatogenic binding sites in intact microsomal membranes and in detergent-solubilized microsomal membrane preparations of female rat liver has been studied by affinity cross-linking-SDS/polyacrylamide-gel electrophoresis. In microsomal membrane preparations an Mr 40,000 lactogenic binder is present which is not disulphide-linked to another protein. Triton X-100 solubilization of membranes results in the appearance of three lactogenic 125I-human growth hormone (125I-hGH) binders with Mr values of 87,000, 40,000 and 35,000, and one somatogenic 125I-hGH binder with Mr 32,000. Treatment of rats with oestrogen increased the amount of lactogenic and somatogenic binding species in liver. The lactogenic binding sites are present as one entity in Triton X-100-solubilized preparations, clearly separated from the somatogenic binder as analysed by gel chromatography. Furthermore, 125I-hGH interacts with an Mr 95,000 somatogenic binder in membrane preparations to which the hormone can be cross-linked only following Triton X-100 solubilization.

A comparison of lactogenic receptors from rat liver and Nb2 rat lymphoma cells by using cross-linking techniques

Lactogenic receptors were analysed with the use of the cross-linking agent disuccinimidyl suberate to attach covalently 125I-labelled ovine prolactin or human growth hormone to binding sites from (1) liver from pregnant rats and (2) the rat-derived Nb2 lymphoma cell line. Analysis by SDS/polyacrylamide-gel electrophoresis of the proteins cross-linked to labelled hormone in rat liver indicated a major specifically-labelled complex with an Mr of 68,000-72,000, when run under reducing or non-reducing conditions. With Nb2 cells a major specifically-labelled complex with an Mr of 97,000-110,000 was identified, but only when electrophoresis was run using reducing conditions. Assuming one hormone molecule (Mr 22,000-24,000) per hormone-receptor complex, then the receptor proteins have an Mr of 44,000-50,000 for rat liver and 73,000-88,000 for the Nb2 cells. For both cell types the receptors were of lactogenic specificity; lactogenic hormones competed for binding whereas somatogenic hormones did not. These studies suggest that the lactogenic receptors in rat liver membranes and Nb2 cells differ in two respects. Firstly, the Mr of the labelled receptor protein in Nb2 cells is greater than that of the corresponding receptor protein in rat liver membranes; secondly, the Nb2 cell receptor appears to exist as a disulphide-linked oligomer whereas the receptor in rat liver membranes does not.

Separation of rabbit mammary-gland prolactin receptors by ion-exchange chromatography, h.p.l.c.-gel filtration and ultracentrifugation

Rabbit mammary-gland prolactin (Prl) receptors in the microsomal fraction were solubilized in 7.5 mM-Chaps) or 1% Triton X-100 and analysed by ion-exchange chromatography using DEAE-Bio-Gel A. Prl receptors in the presence of 7.5 mM-Chaps were separated into two different fractions (Fr. A and B), both of which showed identical specificity of binding to peptide hormones as those in the Chaps or Triton extract. oPrl and human growth hormone (hGH) bound to the same site, but other non-lactogenic hormones (follicle-stimulating hormone, oGH, luteinizing hormone and insulin) failed to bind to the Prl receptors. The dissociation constant (Kd) for Prl binding to the receptors in Fr. A was about 50% of those in Fr. B, suggesting that the rabbit mammary gland contains two types of Prl receptors, one with a high, and one with a low, Kd for Prl binding. A decrease in the concentration of Chaps in the column buffer to 4 mM caused aggregation of the receptors in Fr. A. H.p.l.c.-gel filtration, using Shim pack 150 and 300 columns connected in series, separated the receptor as a protein with an Mr of 74,000 +/- 4,900 (mean +/- S.D.) in the presence of 5 mM-Chaps, or of 36,800 +/- 2,100 in the presence of 7.5 mM-Chaps. Sucrose-gradient-centrifugation analysis showed that the Prl-receptor complexes in the presence of 5 mM-Chaps were sedimented between gamma-globulin and bovine serum albumin (5.56 +/- 0.22 S). As the Chaps concentration was increased to 7.5 mM, a further peak of the Prl-receptor complexes (4.01 +/- 0.23 S) appeared below ovalbumin. The present data suggest that the binding subunit causes the monomeric subunit to aggregate with itself or with another specific associated protein of similar Mr.

Short-term regulation of prolactin receptors in the liver, mammary gland and kidney of pregnant and lactating rats infused with ovine prolactin or human growth hormone

Short-term regulation of prolactin (PRL) receptors was studied in ketamine-anaesthetized 18-day pregnant or 7-day lactating female rats, by infusing them with various doses of oPRL or human growth hormone (hGH) for 0-3 h and measuring the binding of [125I]oPRL of [125I]hGH to the microsomal fractions prepared from the liver, mammary gland and kidneys of animals sacrificed at various states of infusion. Our main findings are: In pregnant rats, only 30% of liver receptors are unoccupied and infusion with 25 micrograms/h for 3 h of either oPRL of hGH decreased both free and total receptors by 22-30% while infusion with 250 micrograms/ml caused an additional decrease only in the free receptors. In the mammary gland and the kidney of pregnant rats, all receptors seem to be unoccupied; infusion with 25 micrograms/ml had none or a slight elevating effect on the number of both free and total receptors in the mammary gland but caused a significant 3-fold increase in the kidney; infusion with 250 micrograms/ml, however, resulted in a slight decrease in the mammary gland and a significant decrease in the kidney in both total and free receptors. In the liver of the lactating rats, there was no significant difference between the number of free and total receptors, but in mammary gland, specific binding to the total receptor was higher than to the free ones indicating partial occupancy; infusion with 25 micrograms/ml caused a significant decrease in free and total liver receptors without a remarkable change in the mammary gland and some decrease (by infusion with hGH only) in the kidney. In all cases, the changes in the specific binding resulted from the increase or decrease in receptor number and not from the change in receptor-hormone affinity. In almost all cases, infusion with oPRL or hGH yielded similar results. Infusion with both hormones did not affect the level of the endogenous rat prolactin. In conclusion, our results indicate the short-term regulation of PRL receptors by exogenous hormones is a complicated process which is affected by the level of the infused hormone, physiological state of the animal and may yield, simultaneously, different or even opposite changes in receptor number in various organs.