Human growth hormone binds to lactogenic receptors in bovine, ovine and rat adrenals

The distribution of 125I radioactivity in the liver, kidneys, adrenals and serum of male rats was measured 10 minutes after an intravenous bolus of 125I-labelled human growth hormone (hGH) was administered in the presence or absence of a large excess of ovine growth hormone or ovine prolactin. The hGH binding sites in the adrenals had displacement properties characteristic of lactogenic receptors, whereas those in the liver had displacement properties characteristic of somatogenic receptors. Bovine and ovine adrenal microsomal membrane fractions contained high affinity (Ka = 1.4-3.3 nM-1) binding sites for hGH which showed ligand specificity typical of lactogenic receptors. It is concluded that the hGH binding site in the adrenal gland is a classical lactogenic receptor and that this tissue is a convenient and rich (42.6 +/- 6.4 fmol hGH specifically bound/mg protein) source of receptor suitable for further characterization.     

The specificity of binding of growth hormone and prolactin to purified plasma membranes from pregnant-rabbit liver.

The binding of 125I-labelled human growth hormone (hGH) to a purified plasma membrane preparation from the liver of pregnant rabbit, and to receptors solubilized from this fraction with Triton X-100, was dependent on time, temperature, the cations used and the receptor concentration. Solubilization did not affect the binding properties of the receptors at low concentrations of Triton X-100. Some somatogenic hormones, such as bovine GH, and some lactogenic hormones, such as ovine prolactin, displaced 125I-labelled hGH from purified plasma membranes and solubilized receptor preparations, but GHs and prolactins from various other species were rather ineffective. The results indicate that although there are binding sites for hGH in these pregnant rabbit liver membranes, few of these are specifically somatogenic or lactogenic. The binding properties of the purified plasma membranes are similar to those of a microsomal preparation studied previously, suggesting that the complex nature of the binding of hGH is not due to the heterogeneity of cellular membranes used to study binding, but is a property of the receptors associated with plasma membranes.     

Species variation in the binding of hGH to hepatic membranes

The binding of 125I-labeled human growth hormone (hGH) to liver membranes from several different species was studied to determine the lactogenic or somatotropic hormone nature of the receptors. Liver membranes from several species of the class of Mammalia bound significant quantities of 125I-hGH. Goat, sheep, rat, mouse, and rabbit liver membranes exhibited the highest binding with cow, pig, human, and hamster liver membranes exhibiting severalfold less binding. The binding of the dog and cat liver membranes exhibited relatively high nonspecific binding. Fish and chicken liver membranes did not bind appreciable quantities of 125I-hGH. In all species except for dog and cat in which 125I-hGH bound to the membranes, hGH was the most effective competitor for binding. The mean ID50 for hGH and all membranes was 2.4 X 10(-9) M. Human liver membranes exhibited the smallest ID50, 4.9 X 10(-10) M. In sheep liver membranes, bovine growth hormone (bGH) was equipotent to hGH in competing for 125I-hGH binding. bGH also demonstrated significant competition for 125I-hGH binding in pig and cow membranes. Ovine prolactin (oPrl) exhibited significant competition for 125I-hGH only in rodent membranes. The ID50 for oPrl was 3- to 10-fold greater than for hGH in the rat, hamster, and mouse liver membranes. The ID50 for oPrl in the sheep liver membranes was 13-fold greater than that of hGH. We conclude the following: (1) There appears to be a species specificity of hGH binding that may be phylogenetically significant and may result from variations in the structure of the hormone or the receptor. (2) The competitive binding properties of hGH are fairly consistent within phylogenetic orders. (3) The simple designation of lactogenic or somatotropic for hormones and receptors is insufficient to characterize the binding properties of this group of hormones.     

Growth hormone binding and stimulation of amino acid uptake in epithelial cells of rat ventral prostate

The binding of [125I]-human growth hormone (hGH) was studied in epithelial cells isolated from rat ventral prostate. Binding and degradation were dependent on time and temperature. The effect of a lysosomotropic agent suggested internalization and lysosomal degradation of the hormone. Dissociation and stoichiometric studies indicated the existence of a single class of GH receptors with a Kd of 0.7 nM and a binding capacity of 46 fmol hGH bound mg-1 cell protein. The receptor appeared to possess a somatotrophic nature since lactogenic hormones such as human placental lactogen and rat prolactin exhibited a very low degree of competition (whereas a variety of unrelated hormones and neuropeptides showed no effect). GH-stimulated leucine uptake by the cells in a time- and dose-dependent manner, half maximal effect being observed at 0.32 nM GH thus suggesting a direct relationship with the binding step.     

Zinc binding to human lactogenic hormones and the human prolactin receptor

Zinc half sites are present in all human lactogenic hormones: human prolactin (hPRL), growth hormone (hGH), placental lactogens (hPL) and the hPRL receptor (hPRLr). The influence of divalent zinc (Zn(2+)) as measured by intrinsic fluorescence or FRET in each of these hormones is unique and is affected by the presence of varying stoichiometries of hPRLr. These data show that both Zn(2+) and hPRLr binding influence hPRL conformers in an interdependent fashion. Although each of these three lactogenic hormones bind hPRLr and induce a biological response that is sensitive to the presence of increasing concentrations of Zn(2+), each hormone is unique in the mechanistic details of this process.     

Proteins associated with somatogenic and lactogenic receptors in microsomal membranes and intact rat hepatocytes

Lactogenic and somatogenic receptors present in rat liver have been examined by cross-linking with a derivative of human somatotropin (AP-hGH1) followed by SDS-polyacrylamide gel electrophoresis. AP-hGH1, which has a content of 2.2 azidophenacyl groups per molecule, mainly linked to half Cys-182 and half Cys-189, exerted a specificity similar to that of the native hormone (hGH), with an ability of 46% with respect to hGH to compete with the radiolabelled hormone for the binding sites of microsomal preparations. Photolysis of the 125I-labelled derivative bound to the lactogenic receptors present in either microsomal membranes or Triton X-100 solubilized preparations gave rise to a 63 kDa species. In addition, 30% of the covalent complexes formed in microsomal membranes belonged to a species with a molecular mass of 70 kDa. Incubation of viable rat hepatocytes with the radiolabelled derivative at either 0 degrees C for 3 h or 15 degrees C for 1.5 h and subjection to irradiation, yielded covalent complexes of molecular masses estimated at 130, 73, 63, 45 and 35 kDa. Experiments performed in the presence of 1 mM NaCN, gave rise to the previous species in a similar yield as that obtained in the absence of cyanide. The 130 kDa complex is related to the somatogenic binding sites, since it was not visualized in the presence of unlabelled bovine somatotropin, while the 70-73, 63, 45 and 35 kDa bands disappeared when the incubations were performed in the presence of unlabelled ovine prolactin.     

Obligate Ordered Binding of Human Lactogenic Cytokines

Class 1 cytokines bind two receptors to create an active heterotrimeric complex. It has been argued that ligand binding to their receptors is an ordered process, but a structural mechanism describing this process has not been determined. We have previously described an obligate ordered binding mechanism for the human prolactin/prolactin receptor heterotrimeric complex. In this work we expand this conceptual understanding of ordered binding to include three human lactogenic hormones: prolactin, growth hormone, and placental lactogen. We independently blocked either of the two receptor binding sites of each hormone and used surface plasmon resonance to measure human prolactin receptor binding kinetics and stoichiometries to the remaining binding surface. When site 1 of any of the three hormones was blocked, site 2 could not bind the receptor. But blocking site 2 did not affect receptor binding at site 1, indicating a requirement for receptor binding to site 1 before site 2 binding. In addition we noted variable responses to the presence of zinc in hormone-receptor interaction. Finally, we performed Förster resonance energy transfer (FRET) analyses where receptor binding at subsaturating stoichiometries induced changes in FRET signaling, indicative of binding-induced changes in hormone conformation, whereas at receptor:hormone ratios in excess of 2:1 no additional changes in FRET signaling were observed. These results strongly support a conformationally mediated obligate-ordered receptor binding for each of the three lactogenic hormones.     

Ovine prolactin and human growth hormone derivatives. Specific modification of their alpha-amino groups

The alpha-amino group of ovine prolactin (oPRL) and human growth hormone (hGH) was selectively modified by transamination with glyoxylic acid. No difference was found in the binding capacity of transaminated oPRL to rat liver lactogenic receptors with respect to its control, although both samples showed a decrease in its binding capacity with reference to the native hormone. This decrease was due to conformational changes caused by the reaction conditions and not by the transamination itself, as shown by the circular dichroism spectra. Transaminated hGH retained the full binding capacity of the hormone. These results suggest that the alpha-amino group is not relevant for the binding to lactogenic liver receptors in both lactogenic hormones.     

Homology modeling of rabbit prolactin hormone complexed with its receptor

The pituitary hormone prolactin (prl) is implicated in a number of biological functions, especially lactation, which is mediated through specific lactogenic receptors (PrlR). Human growth hormone (hGH) is also a pituitary hormone responsible for linear growth. While the growth hormone receptor (hGHR) binds only hGH, hPrlR can interact with both hGH and hPrl. Using structural information from the human growth hormone (hGH)/receptor (hGHR) complex, we modeled by homology a complex between rabbit prolactin hormone (rbPrl) and its receptor (rbPrlR). While the somatogenic hormone/somatogenic receptor (hGH/hGHR) and somatogenic hormone/lactogenic receptor (hGH/hPrlR) interactions are now known and well studied, here we propose a model for the interaction of the lactogenic hormone with its receptor (rbPrl/rbPrlR), and compare these three kinds of ligand/receptor interaction. We identified residues contributing to the active site and tested the potential dimerization of the receptor. Biochemical studies and information deduced from the modeled complex do not exclude a homodimeric form but point to a functional heterodimeric complex. Proteins 27: 459–468, 1997. © 1997 Wiley-Liss, Inc.     

Identification of somatogenic binding sites in liver microsomes from normal mice and transgenic mice expressing human growth hormone gene.

Somatogenic binding sites were detected and characterized in microsomal preparations from livers of normal mice and mice expressing metallothionein-I/hGH (mMT/hGH) hybrid gene, using 125I-labelled bovine or human GH, or a photoreactive derivative of hGH (125I-AP-hGH1). Specific binding of 125I-bGH was detected in liver microsomes from both normal and transgenic mice with an apparent Kd of 2 nM. 125I-hGH was partially displaced by bGH. 125I-AP-hGH1 was covalently bound to the microsomal preparations, and bGH prevented the formation of the 130 kDa species with no appreciable effect on 63 kDa and 70 kDa lactogenic complexes.     

Mutational analysis and protein engineering of receptor-binding determinants in human placental lactogen

Human placental lactogen (hPL) shares 85% sequence identity to human growth hormone (hGH) yet has some very different receptor-binding properties. For example, hPL binds 2300-fold weaker than hGH to the hGH receptor, yet these two hormones have similar affinities for prolactin receptors. We have expressed hPL in Escherichia coli, and we show that, like hGH, hPL requires zinc for tight binding to the extracellular domain of the human prolactin receptor (hPRLbp). In fact, hPL contains virtually the same receptor-binding determinants and zinc ligands (His-18, His-21, and Glu-174) that hGH uses for coordinating zinc in the hGH.hPRLbp complex. As with hGH, mutation of Glu-174 to Ala in hPL reduces the affinity for the hPRLbp by 1400-fold. We can increase the affinity of hPL by over 200-fold for the hGHbp by installing four hGH receptor determinants that are not conserved in hPL. By simultaneously introducing E174A, we produced a pentamutant whose binding affinity for the hGHbp is only 1.6-fold weaker than hGH, but whose binding affinity for the hPRLbp is weaker by greater than 1000-fold relative to wild-type hPL. Thus, we have identified an hPRLbp epitope in hPL, "recruited" an hGHbp epitope into hPL, and produced receptor selective analogs of hPL that are designed to bind tightly to either, neither, or both receptors. Such variants should be important molecular probes to link specific receptor-binding, activation, and biological events.     

Selecting high-affinity binding proteins by monovalent phage display

Variants of human growth hormone (hGH) with increased affinity and specificity for the hGH receptor were isolated using an improved phage display system. Nearly one million random mutants of hGH were generated at 12 sites previously shown to modulate binding to the hGH receptor or human prolactin (hPRL) receptor. The mutant hormones were displayed in a monovalent fashion from filamentous phage particles as fusions to the gene III product of M13 packaged within each particle. After three to six cycles of enrichment for hGH-phage particles that bound to hGH receptor beads, we isolated hGH mutants that exhibited consensus binding sequences for the hGH receptor. Residues previously identified as important for hGH receptor binding by alanine-scanning mutagenesis were more highly conserved by this selection method. However, other residues nearby were not optimal, and by mutating them, hormone variants having greater affinity and selectivity for the hGH receptor were isolated. This approach should be useful for those who wish to modify and understand the energetics of protein-ligand interfaces.     

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.     

Induction of specific human growth hormone binding sites in rat liver by human growth hormone.

125I-Labeled hGH was bound to liver plasma membranes which were obtained from female rats. The binding was displaced by hGH, hPRL, bPRL, rPRL and bGH but not by rGH. This result indicated that hGH was bound to lactogenic binding sites in rat livers. After hypophysectomy, the binding was markedly decreased. Treatment of hypophysectomized rats with hGH (80 micrograms/day) for 10 days increased the binding sites for hGH. These binding sites were different from those found in normal female rat livers because of their high affinity and specificity for hGH. These results indicate that hGH induces specific binding sites for hGH in rat livers.     

Reaction of the histidines of prolactin with ethoxyformic anhydride. A binding site modification.

The seven histidines of bovine prolactin were modified with ethoxyformic anhydride and two classes of reactivity were apparent: 5 histidines were in the more reactive class (k = 0.097 min-1) and 2 histidines were less reactive (k = 0.011 min-1). The activity of the modified prolactins was determined by measuring their ability to bind to prolactin receptors from rabbit mammary glands. This assay showed that prolactin was fully active when 0 to 5 histidines were modified. If all 7 residues were modified, the hormone was unable to bind to its receptor. Circular dichroism studies indicated no significant differences in conformation for prolactins which had 2 to 7 histidines modified. Modification of human growth hormone and human placental lactogen with ethoxyformic anhydride resulted in a loss of the ability of these lactogenic hormones to bind to the prolactin receptor. For all three hormones, essentially full activity was recovered when the modifying group was removed by treatment with hydroxylamine. Sequence comparisons indicate that only 2 of the 3 growth hormone histidines and 2 of 7 placental lactogen histidines were homologous with histidines in bovine prolactin and that, in each case, they correspond to His-27 and His-30 in bovine prolactin. It is postulated that these residues serve to identify a portion of the binding domain of bovine prolactin.     

Identification of the mRNA coding for prolactin in the human decidua

Total RNAs extracted from amnion, chorion and decidua of the human second trimester placentas were translated in the cell-free translation system, followed by immunoprecipitation with antiserum to human prolactin (Prl) and electrophoresis in sodium dodecyl sulfate slab gel. A single immunospecific protein with an apparent molecular weight of approximately 25,500, about 3000 daltons larger than authentic Prl, was formed only with RNA from decidua, and it competed with unlabeled Prl but not with unlabeled human placental lactogen (hPL) for binding to the antibody. The electrophoretic patterns of the fragments formed by partial enzymatic proteolysis of it and authentic Prl were similar.     

Differential effects of zinc on functionally distinct human growth hormone mutations

Human growth hormone (hGH) binds and activates lactogenic receptors by a sequential receptor dimerization mechanism. The affinity for the first lactogenic receptor is increased due to one zinc molecule linking hGH residues H18 and E174, located in helices 1 and 4, respectively, with two adjacent residues in the lactogenic receptor (D187 and H188). Two functionally unique groups of mutant hGHs have been identified. Addition of 25 microM zinc to lactogenic bioassays differentially affects mutant activities based on which group they belong to. One mutation (G120R) is located within the binding surface of hGH that interacts with the second lactogenic receptor. In the presence of endogenous zinc, G120R reduces the maximal activity of hGH without altering either the agonist or antagonist phases of the bell-shaped dose-response curve. Addition of zinc to this assay further reduces the activity of this protein. In contrast, mutations within a hydrophobic motif in hGH that functionally couples the two lactogenic receptor binding sites decrease the sensitivity (right-shift) of the agonist phase of the dose-response curve without similarly affecting the antagonist phase. The addition of zinc to these lactogenic assays increases the sensitivity (left-shifts) of the dose-response curves, largely negating the effect of these mutations. The effects of zinc differentiate between mutations within these two distinct functional motifs by limiting the pool of potential conformations that are available for binding within either of the receptor binding sites of this ligand.     

Binding and structural characteristics of a soluble lactogen-binding protein from rabbit mammary-gland cytosol.

Specific receptors for prolactin (PRL) are known to be present on plasma membranes and intracellular membranes of mammary gland. We now report, however, the detection and characterization of a soluble lactogen-specific binding protein in high-speed (200,000 g) cytosolic preparations from pregnant- and non-pregnant-rabbit mammary gland. The binding protein was not detectable by poly(ethylene glycol) precipitation; instead, bound and free 125I-labelled human growth hormone (hGH; a potent lactogen) was separated using a mini-gel filtration technique. Specific binding of 125I-hGH reached an apparent equilibrium between 10 and 14 h at 21-23 degrees C. It was dependent on mammary-gland protein concentration and, partially, on Ca2+ or Mg2+ concentrations. Scatchard analysis revealed steep curvilinear plots, the high-affinity component having a KA of approximately 3 X 10(10) M-1. Gel filtration on calibrated Ultrogel AcA34 columns of 125I-hGH-cytosol complexes or of cytosol alone, followed by measurement of 125I-hGH binding in each eluted fraction, indicated that the binding protein had an Mr of 33,000-43,000. A specific binding protein of the same size was observed when 125I-ovine or -human PRL, but not 125I-bovine GH, was used as ligand. The apparent lactogenic specificity was confirmed by a lack of cross-reactivity of the binding protein with an anti-[GH receptor (rabbit liver)] monoclonal antibody. Polyacrylamide-gel electrophoresis of 125I-hGH covalently cross-linked to cytosol with disuccinimidyl suberate revealed binding proteins of Mr 35,000 (non-reduced) and 37,000 (reduced), results comparable with those obtained by gel filtration and indicating an absence of inter-subunit disulphide bonds. These studies have shown the presence of an apparently naturally soluble lactogen-binding protein in the cytosolic fraction of rabbit mammary gland. The relationship between this binding protein and the membrane PRL receptor is not yet known.     

Allosteric effects of monoclonal antibodies on human growth hormone

We have previously shown that a monoclonal antibody (MAb) recognizing the human growth hormone (hGH) antigenic domain left exposed after binding to lactogenic receptors enhanced hGH binding probably through allosteric effects on the hormone binding site. Since receptors displaying different specificities would not recognize exactly the same hGH region, we explored whether some of our MAb could affect hGH binding to somatogenic receptors from rabbit liver and to human liver hGH-specific receptors.The effect of MAbAE5, AC8 and F11 on hGH binding was measured by determining the formation of¹²⁵I-MAb:hGH:receptor complexes using two different experimental approaches. Results from procedure A, which involved the previous binding of the hormone to microsomes before adding¹²⁵I-MAb, indicated that the hGH domain defined by epitopes AE5, AC8 and F11 is uncovered in the various hormone:receptor complexes.Procedure B was devised to reveal any alteration in the hGH molecule induced by the MAb. In this case preformed¹²⁵I-MAb:hGH complexes were added to microsomes. Data showed that¹²⁵I-MAb AE5:hGH complexes bound better to the various receptors than¹²⁵I-MAb AE5 to hGH:receptor complexes. On the contrary, hGH previously bound to¹²⁵I-MAb AC8 or¹²⁵I-MAb F11 was less recognized by the receptors than the free hormone. Furthermore, binding of MAb AE5 or MAb F11 to hGH 20 K (a natural hGH variant lacking residues 32–46) also enhanced its affinity to the various receptors whereas MAb AC8 did not inhibit hGH 20 K binding.Results indicated that MAb recognizing the hGH antigenic area that remains unmasked after binding to different membrane-bound receptors are able to affect hormone binding site. MAb would induce either positive or negative allosteric changes in the hormone region involved in its binding to lactogenic, somatogenic and hGH-specific receptors.