Mechanism for ordered receptor binding by human prolactin

Prolactin, a lactogenic hormone, binds to two prolactin receptors sequentially, the first receptor binding at site 1 of the hormone followed by the second receptor binding at site 2. We have investigated the mechanism by which human prolactin (hPRL) binds the extracellular domain of the human prolactin receptor (hPRLbp) using surface plasmon resonance (SPR) technology. We have covalently coupled hPRL to the SPR chip surface via coupling chemistries that reside in and block either site 1 or site 2. Equilibrium binding experiments using saturating hPRLbp concentrations show that site 2 receptor binding is dependent on site 1 receptor occupancy. In contrast, site 1 binding is independent of site 2 occupancy. Thus, sites 1 and 2 are functionally coupled, site 1 binding inducing the functional organization of site 2. Site 2 of hPRL does not have a measurable binding affinity prior to hPRLbp binding at site 1. After site 1 receptor binding, site 2 affinity is increased to values approaching that of site 1. Corruption of either site 1 or site 2 by mutagenesis is consistent with a functional coupling of sites 1 and 2. Fluorescence resonance energy transfer (FRET) experiments indicate that receptor binding at site 1 induces a conformation change in the hormone. These data support an "induced-fit" model for prolactin receptor binding where binding of the first receptor to hPRL induces a conformation change in the hormone creating the second receptor-binding site.     

Contribution of individual histidines to the global stability of human prolactin

A member of the family of hematopoietic cytokines human prolactin (hPRL) is a 23k kDa polypeptide hormone, which displays pH dependence in its structural and functional properties. The binding affinity of hPRL for the extracellular domain of its receptor decreases 500‐fold over the relatively narrow, physiologic pH range from 8 to 6; whereas, the affinity of human growth hormone (hGH), its closest evolutionary cousin, does not. Similarly, the structural stability of hPRL decreases from 7.6 to 5.6 kcal/mol from pH 8 to 6, respectively, whereas the stability of hGH is slightly increased over this same pH range. hPRL contains nine histidines, compared with hGH's three, and they are likely responsible for hPRL's pH‐dependent behavior. We have systematically mutated each of hPRL's histidines to alanine and measured the effect on pH‐dependent global stability. Surprisingly, a vast majority of these mutations stabilize the native protein, by as much as 2–3 kcal/mol. Changes in the overall pH dependence to hPRL global stability can be rationalized according to the predominant structural interactions of individual histidines in the hPRL tertiary structure. Using double mutant cycles, we detect large interaction free energies within a cluster of nearby histidines, which are both stabilizing and destabilizing to the native state. Finally, by comparing the structural locations of hPRL's nine histidines with their homologous residues in hGH, we speculate on the evolutionary role of replacing structurally stabilizing residues with histidine to introduce pH dependence to cytokine function.     

Analysis of site-specific histidine protonation in human prolactin

The structural and functional properties of human prolactin (hPRL), a 23 kDa protein hormone and cytokine, are pH-dependent. The dissociation rate constant for binding to the extracellular domain of the hPRL receptor increases nearly 500-fold over the relatively narrow and physiologic range from pH 8 to 6. As the apparent midpoint for this transition occurs around pH 6.5, we have looked toward histidine residues as a potential biophysical origin of the behavior. hPRL has a surprising number of nine histidines, nearly all of which are present on the protein surface. Using NMR spectroscopy, we have monitored site-specific proton binding to eight of these nine residues and derived equilibrium dissociation constants. During this analysis, a thermodynamic interaction between a localized triplet of three histidines (H27, H30, and H180) became apparent, which was subsequently confirmed by site-directed mutagenesis. After consideration of multiple potential models, we present statistical support for the existence of two negative cooperativity constants, one linking protonation of residues H30 and H180 with a magnitude of approximately 0.1 and the other weaker interaction between residues H27 and H30. Additionally, mutation of any of these three histidines to alanine stabilizes the folded protein relative to the chemically denatured state. A detailed understanding of these complex protonation reactions will aid in elucidating the biophysical mechanism of pH-dependent regulation of hPRL's structural and functional properties.     

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.     

Functional impact of manipulation on the relative orientation of human prolactin receptor domains

Hormone binding creates active receptor dimers for class 1 cytokine receptors; however, the detailed molecular mechanism by which these receptors are activated by their ligands is not well characterized, and it is unknown if these receptors share common mechanisms. A rotation model has been proposed for the activation of human erythropoietin receptor and human growth hormone receptor and is supported by evidence showing that additions of alanine at the junction of the transmembrane (TM) and intracellular (IC) domains and/or within the TM domain influenced receptor activities. This evidence suggests that alanine additions changed the relative orientations of the IC domains and their subsequent activation. We wished to determine if a similar mechanism was at play with human prolactin receptor (hPRLr). Up to four alanines were added between the TM and either the IC or extracellular (EC) domains to extend the TM helix and to rotate the IC or EC domains. Also, up to four glycines were placed between the TM and IC domains to provide increased flexibility between these two domains. Wild-type hPRLr or various mutant receptors were expressed in human embryonic kidney 293T cells that express endogenous Janus kinase 2. In the absence of human prolactin (hPRL), none of the alanine or glycine additions increased the level of receptor phosphorylation above that of wild-type hPRLr. In the presence of hPRL, both wild-type hPRLr and each of the mutant receptors were successfully phosphorylated. These data do not support a rotation mechanism for hPRLr activation or a requirement of a fixed spatial relationship between the TM and IC domains for hPRLr activation. In a second set of experiments, both wild-type hPRLr and either alanine- or glycine-extended receptors were coexpressed in 293T cells. In the absence of hPRL, there was no detectable phosphorylation of hPRLr. Such data do not support a piston movement between the hPRLr pair in their activation.     

Structural and thermodynamic bases for the design of pure prolactin receptor antagonists: X-ray structure of Del1-9-G129R-hPRL

Competitive antagonists of the human prolactin (hPRL) receptor are a novel class of molecules of potential therapeutic interest in the context of cancer. We recently developed the pure antagonist Del1-9-G129R-hPRL by deleting the nine N-terminal residues of G129R-hPRL, a first generation partial antagonist. We determined the crystallographic structure of Del1-9-G129R-hPRL, which revealed no major change compared with wild type hPRL, indicating that its pure antagonistic properties are intrinsically due to the mutations. To decipher the molecular bases of pure antagonism, we compared the biological, physicochemical, and structural properties of numerous hPRL variants harboring N-terminal or Gly(129) mutations, alone or combined. The pure versus partial antagonistic properties of the multiple hPRL variants could not be correlated to differences in their affinities toward the hPRL receptor, especially at site 2 as determined by surface plasmon resonance. On the contrary, residual agonism of the hPRL variants was found to be inversely correlated to their thermodynamic stability, which was altered by all the Gly(129) mutations but not by those involving the N terminus. We therefore propose that residual agonism can be abolished either by further disrupting hormone site 2-receptor contacts by N-terminal deletion, as in Del1-9-G129R-hPRL, or by stabilizing hPRL and constraining its intrinsic flexibility, as in G129V-hPRL.     

Human growth hormone site 2 lactogenic activity requires a distant tyrosine164.

Comparison of crystallographic structures of human growth hormone, either bound to the prolactin receptor or free of receptors, reveals that human growth hormone binding to the prolactin receptor at site 1 is associated with a structural change in human growth hormone that influences the organization of residues which constitute site 2. We have identified Tyr164 as a residue that is critical for the propagation of this structural rearrangement. Tyr164 is a structural epitope for site 1 and is distal to site 2. Mutation of Tyr164 to glutamic acid (Y164E) does not affect the somatotrophic activity, absorption or fluorescence spectra or binding to the human prolactin receptor when compared to wild-type human growth hormone, indicating the subtle effects of the mutation. Lactogenic assays using extended concentrations of Y164E human growth hormone produce dose-response curves that are characterized by a right-shifted agonist phase and an unchanged antagonist phase when compared to wild-type human growth hormone. These results indicate that Tyr164 is required for the lactogenic activity of human growth hormone and that mutation to glutamic acid disrupts the lactogenic function of site 2.     

Prolactin-inducible proteins in human breast cancer cells

The mechanism of action of prolactin in target cells and the role of prolactin in human breast cancer are poorly understood phenomena. The present study examines the effect of human prolactin (hPRL) on the synthesis of unique proteins by a human breast cancer cell line, T-47D, in serum-free medium containing bovine serum albumin. [35S]Methionine-labeled proteins were analysed by sodium dodecyl sulfate-polyacrylamide slab gel electrophoresis and fluorography. Treatment of cells with hPRL (1-1000 ng/ml) and hydrocortisone (1 microgram/ml) for 36 h or longer resulted in the synthesis and secretion of three proteins having molecular weights of 11,000, 14,000, and 16,000. Neither hPRL nor hydrocortisone alone induced these proteins. Of several other peptide hormones tested, only human growth hormone, a hormone structurally and functionally similar to hPRL, could replace hPRL in causing protein induction. These three proteins were, therefore, referred to as prolactin-inducible proteins (PIP). Each of the three PIPs was purified to homogeneity by preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis, and specific antibodies were generated to them in rabbits. By immunoprecipitation and immunoblotting (Western blot) of proteins secreted by T-47D cells, it was demonstrated that the three PIPs were immunologically identical to one another. In addition, the 16-kDa and 14-kDa proteins (PIP-16 and PIP-14), and not the 11-kDa protein (PIP-11), incorporated [3H]glycosamine. Furthermore, 2-deoxyglucose (2 mM) and tunicamycin (0.5 micrograms/ml), two compounds known to inhibit glycosylation, blocked the production of PIP-16 and PIP-14, with a concomitant increase in the accumulation of PIP-11. These results indicate PIP-16 and PIP-14 are glycosylated variants of PIP-11. Finally, in vitro translation of poly(A)+ messenger RNA followed by immunoprecipitation revealed a 12.5-kDa protein, possibly the precursor form of PIPs. In addition, T-47D cells treated with hPRL plus hydrocortisone contained 10-fold more mRNA for PIPs than control cells, suggesting that the hormones' action is at the level of gene expression. Our finding represents a first demonstration of prolactin regulation of gene expression in human target cells. The human breast cancer cells, T-47D, appear to be an excellent model to afford future studies on the molecular action of prolactin and on the possible role of prolactin in human breast cancer.     

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.     

Alanine-scanning mutagenesis of human prolactin: importance of the 58-74 region for bioactivity.

We have generated 10 alanine mutants of human PRL (hPRL), a member of the PRL/GH family, to investigate the involvement of the highly conserved 58-74 region in the biological behavior of the protein. When treated with polyclonal anti-hPRL antibodies, all mutants were immunologically indistinguishable from the unmodified hPRL, and circular dichroism analyses indicated that their alpha-helix content was similar to that of the unmodified hormone. Mutations C58A, K69A, and, to a lesser extent, P66A affected drastically the ability of hPRL first to bind to the lactogenic receptor and second to stimulate the proliferation of Nb2 lymphoma cells, proving the importance of the 58-74 peptide segment for hPRL bioactivity. Binding affinities of these mutants to the Nb2 lactogenic receptor have been compared to lactogenic binding data previously obtained for several mutants of hGH. The comparison reveals that the residues involved in the biological properties of the two proteins are not at topologically equivalent positions. Hence, we suggest that the binding of these hormones to the lactogenic receptors occurs through a different molecular mechanism having distinct requirements at the residue level.     

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 and characterization of the prolactin-binding protein in human serum and milk

The actions of prolactin (PRL) are mediated by its receptor, a member of the superfamily of single transmembrane cytokine receptors. High affinity binding proteins for the closely related growth hormone have been found in the sera of several species including humans and are generated by alternative splicing or proteolysis of the growth hormone receptor extracellular domain (ECD). In contrast, no conclusive evidence has been presented that an analogous prolactin-binding protein (PRLBP) is expressed in human serum. Using both monoclonal and polyclonal antibodies generated against hPRL and the ECD of the human prolactin receptor, co-immunoprecipitation analyses of human serum identified a 32-kDa hPRLBP capable of binding both hPRL and human growth hormone. A measurable fraction of circulating PRL (36%) was associated with the hPRLBP. Despite well documented sex differences in serum hPRL levels, there were no significant differences in the levels of hPRLBP found in the sera of normal adult males and females (15.3 +/- 1.3 ng/ml versus 13.4 +/- 0.8 ng/ml, respectively (mean +/- S.E.)). Immunoprecipitation studies also detected the PRLBP in human milk albeit at lower concentrations than found in sera. Deglycosylation did not alter its electrophoretic mobility, indicating an absence of carbohydrate moieties and suggesting that the hPRLBP spans most of the PRLR ECD, a result confirmed by limited proteolysis and mass spectrometry. The potential function of this serum chaperone was assessed in vitro by the addition of recombinant hPRLBP to the culture medium of the PRL-dependent Nb2 T-cell line. These studies revealed that the hPRLBP antagonizes PRL action, inhibiting PRL-driven growth in a dose-dependent manner.     

Radioreceptor assay for lactogenic hormones based on membranes from rat mammary tumour

A highly sensitive radioreceptor assay (RRA) for human prolactin (hPRL) based on membrane preparations obtained from chemically induced rat mammary tumour is described. The binding of 125I-labelled, highly purified pituitary human prolactin was specific for lactogenic hormones and depending on time, temperature, and concentration of receptor protein. Optimal specific receptor binding (18-20%) was obtained by incubation at 21 degrees C for 18 h. The prolactin receptor was shown to have a single "class" of binding sites with an affinity constant (Ka) of 6.0 X 10(10) mol-1. The binding capacity was 8-33 fmol/mg membrane protein. The sensitivity of the radioreceptor assay was 0.5 ng/ml ovine prolactin (NIH-PS-10) or 0.84 ng/ml human prolactin (NIH-VLS-4). The receptor binding activity of various purified prolactin preparations from different species was comparable to the biological hormone activities, indicating that this in vitro assay system measures values which are biologically relevant.     

Surface plasmon resonance-based highly sensitive immunosensing for brain natriuretic peptide using nanobeads for signal amplification

Site-specific metal-catalyzed oxidation (MCO) was applied to characterize the metal-binding site (MBS) of recombinant human prolactin (hPRL), which belongs to the hematopoietic cytokine family. Copper and ascorbate of various concentrations were used to initiate the oxidation of hPRL, and the oxidation-sensitive motifs were characterized and quantitated by mass spectrometry. Based on the results obtained with 10 microM Cu(2+) and 0.3-2.0mM ascorbate, we propose that the MBS in hPRL is composed of His27, His30, and His173. This result shows the similarity of hPRL to human growth hormone (hGH), a member of the same family as hPRL, where the MBS is composed of His18, His21, and Glu174.     

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.     

Culture of human pituitary prolactin and growth hormone cells

Summary Fragments of pituitary tissue obtained from a total of 37 patients with either breast cancer, diabetic retinopathy, galactorrhea, or acromegaly were dissociated into single cell suspensions prior to cell culture. Release of human growth hormone (hGH) and human prolactin (hPRL) into the culture medium was measured by radioimmunoassay. During a 3-week culture period, prolactin cells released 9–13 times the intracellular levels of hPRL at the time of seeding, whereas hGH release from growth hormone cells was only 1–2 times that of their initial intracellular level during this same time. Both growth hormone and prolactin cells retained distinctive ultrastructural features during culture. The prolactin cells responded to TRH stimulation by elevated release of PRL into the medium. No evidence for mitotic division of prolactin cells in vitro was found.This work was supported by NCI Contract NO 1-CB-23863     

The kinetics of binding human prolactin, but not growth hormone, to the prolactin receptor vary over a physiologic pH range

A member of the family of hematopoietic cytokines, human prolactin (hPRL) serves a dual role both as an endocrine hormone and as an autocrine/paracrine cytokine or growth factor. During investigation of the solution structural properties of hPRL, we have noted a surprising pH dependence of its structural stability over a range from approximately pH 6.0 to pH 8.0. An analysis of backbone atom NMR chemical shift changes and backbone amide hydrogen-deuterium exchange rates due to titration of the solution pH over this same range, along with calculations of protein surface electrostatic potential, suggests the possible involvement of a localized cluster of three His residues (27, 30, and 180), which comprise a portion of the high-affinity receptor-binding epitope. Surface plasmon resonance analysis of the interaction between hPRL and the extracellular domain (ECD) of the hPRL receptor reveals a selective 500-fold change in the dissociation rate between pH 8.3 and pH 5.8. In comparison, the interaction of hGH with the same receptor ECD did not demonstrate any significant dependence on pH. We also present an initial investigation of the pH dependence of hPRL function in rat Nb2 cell proliferation assays and a STAT5 luciferase gene reporter assay in the T47D human breast cancer cell line, whose results are consistent with our biophysical studies. The potential implications of this variation in hPRL's structural stability and receptor-binding kinetics over this physiologic range of pH are discussed.     

Functional Differences of Invariant and Highly Conserved Residues in the Extracellular Domain of the Glycoprotein Hormone Receptors

Multiple interactions exist between human follicle-stimulating hormone (FSH) and the N-terminal hormone-binding fragment of the human FSH receptor (FSHR) extracellular domain (ECD). Binding of the other human glycoprotein hormones to their cognate human receptors (luteinizing hormone receptor (LHR) and thyroid-stimulating hormone receptor (TSHR)) was expected to be similar. This study focuses on amino acid residues in β-strands 2 (Lys⁷⁴), 4 (Tyr¹²⁴, Asn¹²⁹, and Thr¹³⁰), and 5 (Asp¹⁵⁰ and Asp¹⁵³) of the FSHR ECD identified in the human FSH·FSHR ECD crystal structure as contact sites with the common glycoprotein hormone α-subunit, and on noncontact residues in β-strands 2 (Ser⁷⁸) and 8 (Asp²²⁴ and Ser²²⁶) as controls. These nine residues are either invariant or highly conserved in LHR and TSHR. Mutagenesis and functional characterization of these residues in all three human receptors allowed an assessment of their contribution to binding and receptor activation. Surprisingly, the six reported α-subunit contact residues of the FSHR ECD could be replaced without significant loss of FSH binding, while cAMP signaling potency was diminished significantly with several replacements. Comparative studies of the homologous residues in LHR and TSHR revealed both similarities and differences. The results for FSH/FSHR were analyzed on the basis of the crystal structure of the FSH·FSHR ECD complex, and comparative modeling was used to generate structures for domains, proteins, and complexes for which no structures were available. Although structural information of hormone-receptor interaction allowed the identification of hormone-receptor contact sites, functional analysis of each contact site was necessary to assess its contribution to hormone binding and receptor activation.     

Identification of ligand binding determinants of the prolactin receptor.

The prolactin (PRL) receptor, a lactogen- and primate somatogen-binding protein, is a member of an expanding superfamily (cytokine/growth hormone (GH)/PRL) of single membrane-spanning receptors. Two features commonly shared among this group of proteins are the presence of two pairs of cysteines, generally found in the N-terminal region of the extracellular domain, and a WSxWS (WS) motif, frequently located proximal to the transmembrane domain. We have recently shown the 4 cysteines to be critical to the maintenance of the structural and functional integrity of the PRL-receptor. In the present study, we prepared a set of eight chimeric rat PRL/human GH receptors and several alanine mutants, to assess the importance of the Cys-rich domain (residues 12-68) in confering specificity to PRL binding. The role of the WS motif in high affinity binding was also investigated. Binding of 125I-labeled ovine PRL or human GH to membrane preparations from COS-7 cells transiently expressing the mutant receptors have defined a region within the first disulfide loop (residues Arg13, Asp16, Glu18) and the set of lactogen-specific sequences between the two pairs of cysteines as key determinants of PRL-binding specificity, which converge to form a patch on a two-dimensional model of the PRL receptor. We also demonstrate that, although PRL- and GH-specific determinants overlap in certain areas, they are not identical. Finally, substitution of the WS motif with alanine residues precludes high affinity binding to ovine PRL and human GH and suggests that this structural element may provide a target site for the interaction of an accessory protein necessary for the formation of a high-affinity receptor complex.