Functional epitopes for site 1 of human prolactin

Human prolactin (hPRL) binds two human prolactin receptor molecules, creating active heterotrimeric complexes. Receptors bind dissimilar hormone surfaces termed site 1 and site 2 in an obligate ordered process. We sought to map the functional epitopes in site 1 of hPRL. Extensive alanine mutagenesis (102 of the 199 residues) showed approximately 40% of these mutant hPRLs changed the ΔG for site 1 receptor binding. Six of these residues are within 3.5 ? of the receptor and form the site 1 functional epitopes. We identified a set of noncovalent interactions between these six residues and the receptor. We identified a second group of site 1 residues that are between 3.5 and 5 ? from the receptor where alanine mutations reduced the affinity. This second group has noncovalent interactions with other hormone residues and stabilized the topology of the functional epitopes by linking these to the body of the protein. Finally, we identified a third group of residues that are outside site 1 (>5 ?) and extend to site 2 and whose mutation to alanine significantly weakened receptor binding at site 1 of prolactin. These three groups of residues form a contiguous structural motif between sites 1 and 2 of human prolactin and may constitute structural features that functionally couple sites 1 and 2. This work identifies the residues that form the functional epitopes for site 1 of human prolactin and also identifies a set of residues that support the concept that sites 1 and 2 are functionally coupled by an allosteric mechanism.     

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.     

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.     

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.     

Expression of the full-length rabbit prolactin receptor and its specific domains in baculovirus infected insect cells

The prolactin receptor is a membrane protein mainly involved in the development of the mammary gland and in lactation in mammals. We used specific cDNA constructs and the insect/baculovirus expression system and produced independently and in large amounts several recombinant forms of the rabbit mammary gland prolactin receptor: the full-length receptor (L1, L2), a truncated membrane form (S), a secretable form of the extracellular domain (E) and two forms of the intracellular domain (I1, I2). Of these forms, the L1 and L2 are associated with the membrane fraction, the E is predominantly secreted into the medium and the I1 and I2 are expressed as soluble proteins and surprisingly, a great portion accumulates in the culture medium. The molecular mass (94 kDa) of the expressed full-length receptor corresponds to the translation product of the entire cDNA coding region. The receptor biochemically identified in the rabbit mammary gland is however much shorter. Thus, in the mammary gland, the receptor presumably undergoes post-translational modifications. The receptor forms L1, L2 and S bind prolactin with specificity and affinity similar to those reported for the native receptor. They also interact with two monoclonal antibodies, M110 and A917, specific for the native conformation of the hormone-binding site. The I1 and I2 forms do not bind prolactin, whereas the E form does. Thus, the hormone binding site is located in the extracellular domain which can function autonomously as a PRL-binding soluble protein. However, the E form binds prolactin with a higher affinity than the native receptor and it does not bind one of the two antireceptor monoclonal antibodies, known to be hormone binding-site specific. Thus, the conformation of the native receptor and that of the E form differ.     

Development of prolactin receptor antagonists with reduced pH‐dependence of receptor binding

The cytokine hormone prolactin has a vast number of diverse functions. Unfortunately, it also exhibits tumor growth promoting properties, which makes the development of prolactin receptor antagonists a priority. Prolactin binds to its cognate receptor with much lower affinity at low pH than at physiological pH and since the extracellular environment around solid tumors often is acidic, it is desirable to develop antagonists that have improved binding affinity at low pH. The pK_a value of a histidine side chain is ～6.8 making histidine residues obvious candidates for examination. From evaluation of known molecular structures of human prolactin, of the prolactin receptor and of different complexes of the two, three histidine residues in the hormone–receptor binding site 1 were selected for mutational studies. We analyzed 10 variants by circular dichroism spectroscopy, affinity and thermodynamic characterization of receptor binding by isothermal titration calorimetry combined with in vitro bioactivity in living cells. Histidine residue 27 was recognized as a central hot spot for pH sensitivity and conservative substitutions at this site resulted in strong receptor binding at low pH. Pure antagonists were developed earlier and the histidine mutations were introduced within such background. The antagonistic properties were maintained and the high affinity at low pH conserved. The implications of these findings may open new areas of research in the field of prolactin cancer biology. Copyright © 2010 John Wiley & Sons, Ltd.     

Relationship of prolactin receptors to concanavalin A binding.

Concanavalin A, which binds to specific carbohydrate determinants on the cell surface, was used to investigate the binding of prolactin to its receptors in liver membranes from female rats. The binding of 125I-labeled ovine prolactin to receptors was sharply inhibited by concanavalin A. This effect was reversed by the competitive sugar alpha-methyl-D-mannopyranoside and thus required the presence of specifically bound lectin. Concentrations of concanavalin A of up to 50 mu/ml caused a progressive decrease in the apparent affinity of the prolactin receptor for hormone. When higher concentrations were used, the number of available binding sites decreased. Concanavalin A-resistant receptors, about 30% of the total, had the same dissociation constant (Kd) as the controls. The binding of 125I-labeled concanavalin A in the same membrane preparations showed the presence of two distinct types of concanavalin A binding. At low concentrations, the lectin bound with high affinity (Kd approximately equal to 6.6 . 10(-8) M. At high lectin concentrations, low affinity (Kd approximately equal to 6.7 . 10(-5) M) binding predominated. Since high affinity concanavalin A binding was saturated at 50 microgram/ml, this class of binding most likely alters the affinity of the prolactin receptor for hormone; low affinity concanavalin A binding may mask prolactin receptors, making them inaccessible to the hormone. Binding sites for concanavalin A and prolactin appear to be independent but closely related since (i) concanavalin A did not displace bound prolactin from its receptor, and (ii) detergent-solubilized 125I-labeled prolactin-receptor complexes bound to concanavalin A-Sepharose and were eluted by alpha-methyl-D-mannopyranoside.     

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.     

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.     

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.     

High Structural Resolution Hydroxyl Radical Protein Footprinting Reveals an Extended Robo1-Heparin Binding Interface

Interaction of transmembrane receptors of the Robo family and the secreted protein Slit provides important signals in the development of the central nervous system and regulation of axonal midline crossing. Heparan sulfate, a sulfated linear polysaccharide modified in a complex variety of ways, serves as an essential co-receptor in Slit-Robo signaling. Previous studies have shown that closely related heparin octasaccharides bind to Drosophila Robo directly, and surface plasmon resonance analysis revealed that Robo1 binds more tightly to full-length unfractionated heparin. For the first time, we utilized electron transfer dissociation-based high spatial resolution hydroxyl radical protein footprinting to identify two separate binding sites for heparin interaction with Robo1: one binding site at the previously identified site for heparin dp8 and a second binding site at the N terminus of Robo1 that is disordered in the x-ray crystal structure. Mutagenesis of the identified N-terminal binding site exhibited a decrease in binding affinity as measured by surface plasmon resonance and heparin affinity chromatography. Footprinting also indicated that heparin binding induces a minor change in the conformation and/or dynamics of the Ig2 domain, but no major conformational changes were detected. These results indicate a second low affinity binding site in the Robo-Slit complex as well as suggesting the role of the Ig2 domain of Robo1 in heparin-mediated signal transduction. This study also marks the first use of electron transfer dissociation-based high spatial resolution hydroxyl radical protein footprinting, which shows great utility for the characterization of protein-carbohydrate complexes.     

Novel mechanism of interaction of p85 subunit of phosphatidylinositol 3-kinase and ErbB3 receptor-derived phosphotyrosyl peptides

Ligand-activated and tyrosine-phosphorylated ErbB3 receptor binds to the SH2 domain of the p85 subunit of phosphatidylinositol 3-kinase and initiates intracellular signaling. Here, we studied the interactions between the N- (N-SH2) and C- (C-SH2) terminal SH2 domains of the p85 subunit of the phosphatidylinositol 3-kinase and eight ErbB3 receptor-derived phosphotyrosyl peptides (P-peptides) by using molecular dynamics, free energy, and surface plasmon resonance (SPR) analyses. In SPR analysis, these P-peptides showed no binding to the C-SH2 domain, but P-peptides containing a phospho-YXXM or a non-phospho-YXXM motif did bind to the N-SH2 domain. The N-SH2 domain has two phosphotyrosine binding sites in its N- (N1) and C- (N2) terminal regions. Interestingly, we found that P-peptides of pY1180 and pY1241 favored to bind to the N2 site, although all other P-peptides showed favorable binding to the N1 site. Remarkably, two phosphotyrosines, pY1178 and pY1243, which are just 63 amino acids apart from the pY1241 and pY1180, respectively, showed favorable binding to the N1 site. These findings indicate a possibility that the pair of phosphotyrosines, pY1178-pY1241 or pY1243-pY1180, will fold into an appropriate configuration for binding to the N1 and N2 sites simultaneously. Our model structures of the cytoplasmic C-terminal domain of ErbB3 receptor also strongly supported the speculation. The calculated binding free energies between the N-SH2 domain and P-peptides showed excellent qualitative agreement with SPR data with a correlation coefficient of 0.91. The total electrostatic solvation energy between the N-SH2 domain and P-peptide was the dominant factor for its binding affinity.     

Hormone-induced conformational changes in the hepatic insulin receptor

The insulin receptor can exist in either a lower or a higher affinity state. Hormone binding alters the equilibrium between the two states of the insulin receptor, favoring the formation of that of higher affinity (Corin, R.E., and Donner, D.B. (1982), J. Biol. Chem. 257, 104-110). After brief or extended incubations with hormone, during which the fraction of higher affinity receptors increased, 125I-insulin was covalently coupled to the alpha subunits of its receptor using disuccinimidyl suberate. Some 125I-insulin remained bound to higher affinity receptors after dissociation of hormone from lower affinity sites. This hormone could also be covalently coupled to the alpha subunit of the receptor. During extended incubations between 125I-insulin and liver plasma membranes, components of the receptor were cleaved to yield degradation products of 120,000 and 23,000 Da. The significance of this process remains undetermined. Unoccupied insulin receptors were cleaved by trypsin to produce fragments of 94,000 and 37,000 Da which remained membrane-bound and could be covalently coupled to 125I-insulin. Trypsin treatment after binding yielded an additional receptor fragment of 64,000 Da. As the incubation time between 125I-insulin and membranes was lengthened, components of the receptor became progressively less sensitive to trypsin. Higher affinity binding sites isolated after release of rapid dissociating insulin were less sensitive to trypsin than were mixtures of higher and lower affinity receptors. These observations suggest that hormone binding produces two conformational changes (alterations of tryptic lability) in the hepatic insulin receptor. The first change is rapid and exposes parts of the receptor to tryptic degradation. The second, slower conformational change renders the receptor less sensitive to trypsin and occurs with the same time course as the increase of receptor affinity mediated by site occupancy.     

Two independent histidines, one in human prolactin and one in its receptor, are critical for pH-dependent receptor recognition and activation

Human prolactin (hPRL), a member of the family of hematopoietic cytokines, functions as both an endocrine hormone and autocrine/paracrine growth factor. We have previously demonstrated that recognition of the hPRL·receptor depends strongly on solution acidity over the physiologic range from pH 6 to pH 8. The hPRL·receptor binding interface contains four histidines whose protonation is hypothesized to regulate pH-dependent receptor recognition. Here, we systematically dissect its molecular origin by characterizing the consequences of His to Ala mutations on pH-dependent receptor binding kinetics, site-specific histidine protonation, and high resolution structures of the intermolecular interface. Thermodynamic modeling of the pH dependence to receptor binding affinity reveals large changes in site-specific protonation constants for a majority of interface histidines upon complexation. Removal of individual His imidazoles reduces these perturbations in protonation constants, which is most likely explained by the introduction of solvent-filled, buried cavities in the crystallographic structures without inducing significant conformational rearrangements.     

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.     

Purification and partial characterization of a nonprimate growth hormone receptor.

Pregnant rabbit liver membranes have been shown to possess two types of receptors by displacement analysis, a growth hormone (GH) receptor which binds bovine growth hormone with an affinity constant (KA) of 3 x 10(9) M-1 and ovine prolactin with a KA of 3 x 10(8) M-1, and a prolactin (Prl)-specific receptor which binds ovine prolactin with a KA of 5 x 10(9) M-1. The prolactin-specific receptor when solubilized with Triton exhibits a 4-fold increase in the its KA while the KA of the growth hormone receptor decreases slightly to 2 x 10(9) M-1 after solubilization. The 10-fold difference in affinity which results has been exploited to facilitate the separation of these two receptors by differential affinity chromatography on human growth hormone (hGH) affinity gels. The growth hormone receptor is eluted from the gel with 4 M urea while 5 M MgCl2 is required to elute the prolactin receptor. Conditions of affinity chromatography have been optimized, and further purification of the GH receptor by preparative isoelectric focusing and Sepharose 6B gel filtration resulted in a more than 8000-fold purification of the receptor. This material had a Stokes radius of 62 A, consistent with a molecular weight of 300,000 and gave one main band (75,000 to 80,000) and two minor bands on sodium dodecyl sulfate (SDS) polyacrylamide gels, which could be interpreted as indicating a tetrameric receptor. The GH receptor was shown to be a sialoglycoprotein (or closely associated with sialoglycoprotein) by analytical isoelectric focusing with an isoelectric point of 4.6. Specificity studies with the highly purified receptor confirmed the initial hypothesis that this receptor is capable of binding bovine growth hormone (bGH) with high affinity and ovine prolactin (oPrl) with low affinity, in contrast to the prolactin-specific receptor.     

The WSXWS motif in cytokine receptors is a molecular switch involved in receptor activation: insight from structures of the prolactin receptor

The prolactin receptor (PRLR) is activated by binding of prolactin in a 2:1 complex, but the activation mechanism is poorly understood. PRLR has?a conserved WSXWS motif generic to cytokine class I receptors. We have determined the nuclear magnetic resonance solution structure of the membrane proximal domain of the human PRLR and find that the tryptophans of the motif adopt a T-stack conformation in the unbound state. By contrast, in the hormone bound state, a Trp/Arg-ladder is formed. The conformational change is hormone-dependent and influences the receptor-receptor dimerization site 3. In the constitutively active, breast cancer-related receptor mutant PRLR(I146L), we observed a stabilization of the dimeric state and a change in the dynamics of the motif. Here we demonstrate a structural link between the WSXWS motif, hormone binding, and receptor dimerization and propose it?as?a general mechanism for class 1 receptor activation.     

Manganese binding to the prion protein

There is considerable evidence that the prion protein binds copper. However, there have also been suggestions that prion protein (PrP) binds manganese. We used isothermal titration calorimetry to identify the manganese binding sites in wild-type mouse PrP. The protein showed two manganese binding sites with affinities that would bind manganese at concentrations of 63 and 200 mum at pH 5.5. This indicates that PrP binds manganese with affinity similar to other known manganese-binding proteins. Further study indicated that the main manganese binding site is associated with His-95 in the so-called "fifth site" normally associated with copper binding. Additionally, it was shown that occupancy by copper does not prevent manganese binding. Under these conditions, manganese binding resulted in an altered conformation of PrP, displacement of copper, and altered redox chemistry of the metal-protein complex. Cyclic voltammetric measurements suggested a complex redox chemistry involving manganese bound to PrP, whereas copper-bound PrP was able to undergo fully reversible electron cycling. Additionally, manganese binding to PrP converted it to a form able to catalyze aggregation of metal-free PrP. These results further support the notion that manganese binding could cause a conformation change in PrP and trigger changes in the protein similar to those associated with prion disease.