The Unique Ligand-binding Pocket for the Human Prostacyclin Receptor

SITE-DIRECTED MUTAGENESIS AND MOLECULAR MODELING*

Jeremiah Stitham, Aleksandar Stojanovic, Bethany L. Merenick, Kimberley A. O'Hara, and John HwaDagger

From the Department of Pharmacology & Toxicology, Dartmouth Medical School, Hanover, New Hampshire 03755

Received for publication, July 24, 2002, and in revised form, November 18, 2002

    ABSTRACT
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

The human prostacyclin receptor is a seven-transmembrane alpha -helical G-protein coupled receptor, which plays important roles in both vascular smooth muscle relaxation as well as prevention of blood coagulation. The position of the native ligand-binding pocket for prostacyclin as well as other derivatives of the 20-carbon eicosanoid, arachidonic acid, has yet to be determined. Through the use of prostanoid receptor sequence alignments, site-directed mutagenesis, and the 2.8-Å x-ray crystallographic structure of bovine rhodopsin, we have developed a three-dimensional model of the agonist-binding pocket within the seven-transmembrane (TM) domains of the human prostacyclin receptor. Upon mutation to alanine, 11 of 29 candidate residues within TM domains II, III, IV, V, and VII exhibited a marked decrease in agonist binding. Of this group, four amino acids, Arg-279 (TMVII), Phe-278 (TMVII), Tyr-75 (TMII), and Phe-95 (TMIII), were identified (via receptor amino acid sequence alignment, ligand structural comparison, and computer-assisted homology modeling) as having direct molecular interactions with ligand side-chain constituents. This binding pocket is distinct from that of the biogenic amine receptors and rhodopsin where the native ligands (also composed of a carbon ring and a carbon chain) are accommodated in an opposing direction. These findings should assist in the development of novel and highly specific ligands including selective antagonists for further molecular pharmacogenetic studies of the human prostacyclin receptor.

    INTRODUCTION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
REFERENCES

Vascular smooth muscle relaxation and inhibition of platelet aggregation are two key physiological processes mediated by human prostacyclin. Dysfunctional prostacyclin activity has been implicated in the development of a number of cardiovascular diseases including thrombosis, myocardial infarction, stroke, myocardial ischemia, atherosclerosis, and systemic and pulmonary hypertension (1). In contrast to other members of the rhodopsin-like G-protein coupled receptor (GPCR)1 subfamily such as the adrenergic receptors or other members of the prostanoid family, there are currently no high affinity selective antagonists for the prostacyclin receptor. This finding suggests that the prostacyclin receptor may possess a unique ligand-binding pocket.

Receptor activation is contingent upon ligand binding interactions, which initiate a conformational change in protein structure that is subsequently transmitted to the G-protein. Determining the exact nature and location of receptor-ligand binding interactions at the molecular level is essential for understanding the functions of prostanoid receptor physiology. Moreover, such insights would lend to the development of novel and highly specific modes of treatment for prostanoid-related disorders. Based upon the position of the chromophore (covalently bound 11-cis-retinal) within the binding pocket of rhodopsin along with the location of other ligands within similar rhodopsin-type GPCRs (2), the putative binding pocket for GPCRs with small nonpeptide ligands is believed to be located predominantly within the hydrophobic core of the transmembrane domain in close proximity to the extracellular boundary of the receptor. However, the crucial anchoring points that comprise the fundamental structure of the binding pocket, securing important receptor-ligand associations between prostacyclin and its receptor, have yet to be determined.

As is the case with all prostanoids, prostacyclin (PGI2) is a derivative of the C20 unsaturated fatty acid arachidonic acid (5,8,11,14-eicosatetraenoic acid) (Fig. 1). The general structure of prostanoid molecules consists of a centralized cyclopentane ring (thromboxane has an oxane ring) flanked by two hydrocarbon chains, the alpha - and omega -chains, whose configuration and functional groups determine further classification (Fig. 1). In particular, the prostacyclin molecule contains an additional oxolane (cyclic ether) ring fused to the cyclopentane ring as well as two hydroxyl groups located at C11 and C15. A characteristic terminal carboxylate group is present at the C1 position as well as carbon-carbon double bonds linking C5 to C6 and C13 to C14. Similar molecular features can be seen in synthetic prostacyclin analogues such as iloprost, a stable high affinity agonist that substitutes a secondary cyclopentane ring in place of the PGI2 oxolane ring, carries an additional C16-methyl group and a omega -chain triple bond (Fig. 1). Side chains of certain amino acids have been shown in receptors to interact directly with substituents of ligands, conferring binding affinity (3, 4) through major forces such as hydrogen bonding, hydrophobic interactions, and ionic interactions. Thus, structural similarities and differences between both prostanoid receptors and prostanoid ligands play an important role in determining sites of interaction between receptor and ligand. For example, conserved serine residues found in TMV of the adrenergic receptors have been shown to interact with the conserved hydroxyl groups extending from the catechol ring of the biogenic amines (4).

Recent studies have begun to identify generalized regions within the prostacyclin receptor and other prostanoid receptors that appear crucial for ligand-binding specificity and affinity. Studies using chimeric combinations of mouse prostaglandin D and prostaglandin I receptors have shown that protein segments within transmembrane domains VI and VII (TMVI and TMVII) are involved in distinct binding interactions with prostacyclin side chains, whereas TMI along with a portion of the first extracellular loop confers broader binding functions, incorporating recognition and interaction with the cyclopentane ring (5, 6). Additionally, glycosylation at Asn-7 and Asn-78 (7) and proline residues within the transmembrane domains (8) have also been shown to be essential for proper binding and activation. Although neither of the two recently identified naturally occurring polymorphisms (i.e. V25M and R212H) have revealed inherent effects on binding, R212H in the third intracellular loop has been shown to exclusively effect activation and exhibits defective binding only under acidic conditions (9).

Using site-directed mutagenesis, prostanoid ligand and receptor comparisons, and a three-dimensional computer-generated homology model of the hIP receptor derived from the recently published crystal structure of bovine rhodopsin (10), four crucial points of interaction between prostacyclin and the upper perimeter of the transmembrane domain of the hIP were identified. These crucial points include Arg-279 (TMVII), Phe-278 (TMVII), Tyr-75 (TMII), and Phe-95 (TMIII), which interact with the C1-COOH, oxalane ring and alpha -tail, C11-OH, and omega -tail of prostacyclin, respectively. This agonist-binding pocket is quite distinct from that of the biogenic amine receptors and rhodopsin.

    EXPERIMENTAL PROCEDURES
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
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Materials-- Iloprost ligands, radiolabeled [3H]iloprost (17.0 Ci/mmol) and non-radiolabeled iloprost, were purchased from Amersham Biosciences. Oligonucleotide primers were purchased from Sigma, whereas the hIP cDNA was a generous gift from Dr. Mark Abramovitz (Merck Frosst, Quebec, Canada).

Approach to Elucidating the hIP-binding Pocket-- Initially, criteria were established to identify potentially important residues within the upper half of the transmembrane domain (i.e. the proposed locale of the putative prostacyclin-binding pocket) whose side-chain functional groups may interact with prostacyclin via electrostatic interactions, hydrogen bonding, or hydrophobic associations. Thus, candidate hIP residues with probable implications on ligand binding were targeted for site-directed mutagenesis, initially changing each residue to alanine. A series of competition binding assays were performed using iloprost, a stable high affinity analogue of prostacyclin. For those mutations eliciting a notable change in binding affinity, further appropriate residue replacements (catering to more specific size and/or polarity changes) were made to determine the specific characteristics of the amino acid with adverse effects on ligand binding. The influence on binding affinity was postulated to be the result of: 1) direct molecular interactions among critical binding-related residues and ligand side chains within the immediate binding pocket; 2) indirect molecular interactions among receptor residues involved in local preservation of the proximal binding domain; or 3) outlying interactions among alpha -helix-maintaining amino acids. To further define the receptor amino acids that interacted with ligand, sequence alignments for all prostanoid receptor transmembrane domains were obtained from GPCRDB Prostanoid (www.gpcr.org). Forty-two prostanoid receptor sequences including multiple PE21, PE22, PE23, PE24, PF2R, TA2R, PD2R, and PI2R from different species were internally compared with each other as well as with rhodopsin. Similar principles were applied in comparing functional groups of prostacyclin (as well as its analogues) to other prostaglandin ligands. Conservation of amino acids at equivalent positions on corresponding receptors along with the maintenance of certain functional groups on other prostaglandins suggested probable functional correlations and importance. Residues identified within the putative binding pocket and exhibiting substantial influence on ligand binding affinity were reconstructed on a computer-generated hIP model based upon the crystal structure of rhodopsin. A structural-based prostacyclin molecule was then inserted (bound) onto the model receptor comparing multiple positions. Taking into account all of the aforementioned features, a theoretical three-dimensional model of the prostacyclin-binding pocket was developed.

Construction of Mutant Receptors-- Human IP cDNA was cloned into the plasmid vector pMT4, and point mutations were generated using conventional methods of PCR mutagenesis. Complementary oligonucleotide primers were designed extending 10-12 nucleotides 3' and 5' from the desired mutation site. The PCR reaction mixture contained 1× Pfu reaction buffer, 200 ng of DNA construct, 150 ng of each primer (sense and antisense), 10 mM dNTPs, and 2.5 units of Pfu DNA polymerase (Stratagene, Austin, TX) and was heated and cooled at 95 °C for 30 s, 55 °C for 1 min, and 68 °C for 10 min for 16 cycles. The products were then digested with DpnI restriction enzyme (Promega, Madison, WI) for 3 h to remove any parental wild-type strands of DNA. Ten microliters of PCR product was used to transform competent DH5alpha Escherichia coli cells (~2 × 109 cells) followed by DNA extraction from selected clones. Large plasmid preparations were performed using Wizard® Plus Maxiprep kits (Promega), and all mutant constructs were confirmed via PCR DNA dideoxynucleotide chain termination sequencing (Molecular Biology Core Facility, Dartmouth Medical School, Hanover, NH).

Transfection of COS-1 Cells-- Transient transfections were performed on COS-1 cells as follows: the initial wash of cells with Cellgro® Dulbecco's modified Eagle's medium (DMEM, Mediatech, Inc., Herndon, VA) was followed by addition of mutant DNA (20 µg/plate) in diethylaminoethyl-Dextran (DEAE-Dextran, Sigma) and DMEM. Cells were then incubated at 37 °C with 5% CO2 for 6 h after which 0.1 mM chloroquine solution was added. Cells were subsequently incubated for 1 h, and chloroquine was removed through washes with DMEM. Cells were harvested 72 h post-transfection.

Membrane Preparations-- Preparations of COS-1 cell membranes were carried out as follows: cells were washed in phosphate-buffered saline and harvested using cell scrapers. Vortexing (providing shear forces) for 3 min in sucrose (0.25 M) was followed by low speed spin (~1260 × g) for 5 min, and the supernatant collected. After a high speed centrifugation (~30,000 × g for 15 min), the pellet was then washed twice in 1× HEM (20 mM Hepes, pH 7.4, 1.5 mM EGTA, and 12.5 mM MgCl2) followed by resuspension in 1× HEM containing 10% glycerol and stored at -70 °C. A Bradford protein assay was performed to quantitate membrane proteins.

Ligand Binding-- Ligand-binding characteristics for the expressed receptors were determined through a series of competition binding assays using the radiolabeled ligand [3H]iloprost. An analysis involved the construction of reaction mixtures (in duplicate wells) containing 50 µg of membrane protein, HEM buffer, and 15 nM [3H]iloprost along with 1 of 11 different concentrations of cold (non-radiolabeled) iloprost ranging from 10 µM to 0.1 nM. After 1.5 h of incubation at 4 °C, reactions were stopped by the addition of ice-cold 10 mM Tris/HCl buffer, pH 7.4, and filtered onto Whatman® GF/C glass-fiber filters using a Brandel® cell harvester. The filters were washed five times with ice-cold Tris/HCl buffer, and radioactivity was measured in the presence of 5 ml of EcoscintTM H scintillation fluid (National Diagnostics, Atlanta, GA). Nonspecific binding was determined by the addition of a 500-fold excess of non-radiolabeled iloprost. The concentration of [3H]iloprost was varied from 1 to 100 nM for saturation binding studies. Data were analyzed using GraphPad Prism software (GraphPad Software, Inc., San Diego, CA). IC50 values were converted to Ki using the Cheng-Prusoff equation, and Ki values were expressed as a mean ± S.E. An analysis of variance (ANOVA) and Student's t tests were used to determine significance differences (p < 0.05).

Western Blot Analysis-- The presence of mutant protein with low affinity to iloprost was determined through Western blot analysis using monoclonal antibodies targeting the 1D4 epitope tag (8). Thirty microliters of membrane preparation containing 30 µg of membrane protein was subjected to 10% SDS-polyacrylamide gel electrophoresis. This was transferred to a nitrocellulose membrane, immunoblotted using a 1D4 monoclonal antibody and horseradish peroxidase-conjugated anti-mouse secondary antibody, and detected with enhanced chemiluminescence reagents.

Modeling of Prostacyclin Ligand-- Because of the instability of the native ligand (prostacyclin), a synthetic analogue (iloprost) (Fig. 1) was used in all experimental assays. However, seeing that both structures are virtually identical and share the same reactive components that confer binding specificity with the hIP (e.g. C1-COOH, C11-OH, C15-OH, bicyclic ring, alpha -chain, and omega -chain) in addition to identical binding affinities, it was our feeling that the endogenous prostacyclin molecule would be more appropriate and biologically relevant within our modeling system. Computer-assisted molecular modeling of the prostacyclin ligand (native agonist to the hIP receptor) was performed using Swiss PDB Viewer (GlaxoSmithKline, Geneva, Switzerland) (11). A three-dimensional PGI2 molecule was modeled based upon the known chemical structure as well as a previously predicted conformation of a receptor-associated PGI2 (12). Initial modeling constraints required the adjustment of individual atoms such that they would conform to the chemically acceptable limits of the ligand structure. This included the adjustment of all covalent bonds to agree with standard lengths and angles: sp3-hybridized C-C single bond = 1.54 Å and 109.5°; sp2-hybridized C=C double bond = 1.33 Å and 120.0°; sp3-hybridized C-O single bond = 1.40 Å and 108.0°; and sp2-hybridized C=O double bond = 1.20 Å and 120.0°. Because of substantial torsional strain, all interior angles for both five-membered rings were approximated at 108.0° with the exception for the C-O-C bond angle of the oxane ring, which was set closer to 112.0°. The root mean square deviation for all bonds and angles was calculated at 0.006 Å and 0.4°, respectively, compared with the standard numbers referenced above. Furthermore, the two rings were constructed to assume the common envelope configuration with the characteristic four co-planar atoms combined with a fifth member out of plane. The structural conformation of our receptor-bound prostacyclin molecule is similar to that of previous investigations in modeling conformations of receptor-associated PGI2 (12) where the alpha -chain is maintained in a bent conformation (back upon the two centralized rings), whereas the long hydrophobic omega -chain is in an extended configuration. This configuration was independently confirmed using MacSpartan Pro software where the energy-minimized conformations (-7 to -10 kcal/mol) all exhibited such a ring and alpha -chain conformation with the major variances being in position of the omega -chain (data not shown).


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Fig. 1.   Structures of prostanoid precursor and selected prostanoid ligands. An illustration comparing the structural similarities and differences of some representative prostanoid ligands is shown. A, arachidonic acid (5,8,11,14-eicosatetraenoic acid) serves as the precursor molecule for all native prostaglandin and thromboxane ligands. B, three native prostanoids (PGI2, PGE1, and TXA2) showing common features: the C1-COOH, the alpha -chain; the C11-OH, the omega -chain; and the C15-OH. There are distinct variances within the centralized ring structure with prostacyclin having two rings. C, the structure of iloprost (stable, high affinity synthetic PGI2 analogue) is shown. It has the four common structural features described in B. However, a cyclopentane ring replaces the oxalane ring, there is a C16-methyl substitution, and there is a C18-triple bond.

Modeling of hIP Receptor-- A theoretical three-dimensional homology model of the seven-transmembrane alpha -helices of the hIP receptor was constructed using the internet-based protein-modeling server Swiss Model (GlaxoSmithKline) (11). Amino acid sequences from all prostanoid receptors were obtained from the GPCR data base (42 sequences in total, GPCRDB Prostanoid) and aligned with those of the bovine rhodopsin receptor. Based upon this alignment, seven distinct peptide segments (each containing 26 amino acids) corresponding to the seven-transmembrane domains of the hIP were determined, and a homology model was generated using the 2.8-Å resolution x-ray crystallographic structure of the bovine rhodopsin receptor as the template (Protein Data Bank code 1HZX). Receptor residues were tethered by harmonic constraints to their corresponding rhodopsin transmembrane templates and assembled into helical conformations by successive manipulations of selected degrees of freedom (rigid body rotational/translational followed by torsional). Once assembled, the transmembrane domains were energy-minimized utilizing the Gromos96 force field to improve the stereochemistry of the model and remove unfavorable clashes (Swiss Model). Visualization and evaluation of the model as well as insertion of the prostacyclin ligand was performed using the Swiss PDB Viewer. Additional amino acids were added to the extracellular transmembrane domain region and allowed to adopt an alpha -helical conformation (where appropriate) using the crystal structure of rhodopsin as a template. From the crystal structure of the rhodopsin, some of the transmembrane alpha -helices extend beyond 26 amino acids (e.g. TMIII). Furthermore, the binding of prostacyclin may extend into the extracellular domain. The complete interhelical loops were intentionally excluded from our model as they are known in rhodopsin to be flexible with areas missing from the crystal structure. In addition, they share no homology with the loops of the hIP. Thus, our study focuses exclusively on the putative binding pocket within the transmembrane domain of the hIP.

    RESULTS AND DISCUSSION
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ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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The prostacyclin receptor serves important roles in vascular smooth muscle relaxation, platelet aggregation, and inflammation (13-16). Prostacyclin agonists are now widely used for the treatment of pulmonary hypertension (17-20). More recently, it has also been suggested that prostacyclin may also be useful as a therapeutic agent in treating lung (21) and colon cancers (22, 23). Our current knowledge of the hIP receptor is very limited with only a handful of studies addressing the structure-function characteristics of this important receptor. Currently, there are no commercially available high affinity antagonists and only a few stable high affinity agonists. An understanding of the particular residues that constitute the ligand-binding pocket would be useful in determining any unusual features this receptor may contain and assist in the development of more functionally specific hIP ligands, particularly selective antagonists.

11 of 29 Candidate Residues When Mutated to Alanine Had a Significant Decrease in Binding Affinity for Iloprost-- Candidate residues were first individually mutated to alanine (alanine scanning) to determine those that had an affect on binding affinity (Table I). These amino acids were selected based upon their potential to interact with prostacyclin side chains. To avoid preconceived bias with regard to the binding pocket position within the seven-transmembrane domains, all prospective binding pocket residues such as charged, polar, and large side-chain amino acids (e.g. phenylalanines and tyrosines) in the upper half of the TM domain were mutated. The wild-type prostacyclin receptor expressed well (1.8 pmol/mg membrane protein) with a binding affinity (Ki) for iloprost of 7.9 ± 1.7 nM (n = 9) (Table I). The competition binding best fitted to a one-site competition binding curve. In the absence of a high affinity antagonist, the labeled agonist iloprost was used for competition binding. Further studies were performed on the wild-type receptor in the presence of Gpp(NH)p, a non-hydrolyzable form of GTP, to effectively uncouple G-protein from the receptor. The presence of 100 µM Gpp(NH)p had no significant effect on binding affinity for wild-type protein (7.9 ± 0.1 nM (n = 3)), establishing that this affinity was not the result of G-protein coupling. Of the 29 residues mutated, 11 had a significant effect on binding (Table I) (Fig. 2, squares). These were located in TMII (D60A, S68A, and Y75A), TMIII (F95A and F97A), TMIV (F150A), TMV (S185A and Y188A), and TMVII (D274A, F278A, and R279A). In the absence of a high affinity antagonist for ligand binding, only those mutant receptors with significant differences of 0.5-1.7 log in binding affinity (S68A, F95A, F97A, S185A, and F278A) compared with wild-type receptor were able to yield a competition binding curve (Fig. 3). For those remaining mutants with extremely low binding affinity (>500 nM) (D60A, Y75A, F150A, Y188A, D274A, and R279A), little iloprost binding was observed despite adequate amounts of protein being present. Both Western analysis (Fig. 4) and saturation binding (Table I) showed detectable yet significantly reduced amounts of protein expression for these severely affected mutant receptors. Moreover, Western analysis also revealed the complex-glycosylated states (multiple bands) that are typically observed with these receptors (8).

                              
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Table I
Competition binding and saturation binding experiments for the initial 29 transmembrane mutations to alanine
Shown are the mean Ki ± S.E. from at least three separate experiments (number of repetition indicated by n) performed in duplicate. Saturation binding results are the mean ± S.D. of at least two experiments (in picomole/milligram of membrane protein).


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Fig. 2.   Mutation sites on secondary structure of the hIP receptor. Diagram highlighting the positions for all 31 (29 original plus 2 latter mutations) putative binding pocket residues within the upper half of the seven-transmembrane helical domains (shaded boxes) is shown. Shown in bold squares are the residues that showed a significant difference in iloprost binding when mutated to alanine as compared with the wild-type hIP1D4 protein. The circles are the residues that are unaffected by such an alanine mutation. Extracellular, transmembrane, and cytoplasmic regions are designated based on the structure of rhodopsin with approximate membrane boundaries numbered. The conserved disulfide bond found in the extracellular domain is indicated with a dashed line as are the two palmitoylation sites located along the cytoplasmic domain. The two glycosylation sites are indicated by the small circles. The C terminus has been tagged with a 1D4 epitope (bold). A shaded box highlights the region for the putative ligand-binding pocket.


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Fig. 3.   Competition binding for hIP1D4 and mutations that exhibited a significant decrease in binding affinity. Competition-binding curves (15 nM [3H]iloprost versus 12 different concentrations of non-radiolabeled iloprost 10 µM-0.1 nM) are shown. Shown are the mutant constructs (S68A, F95A, F97A, S185A, and F278A) that had significantly reduced binding affinity as compared with wild-type hIP1D4. All of them show a significant and parallel shift to the right as compared with the wild-type curve.


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Fig. 4.   Western analysis for hIP1D4 and mutants with very low binding affinity. Western analysis was performed as described under "Experimental Procedures" using the high affinity 1D4 monoclonal antibody to the C-terminal epitope tag. Those mutations, D60A, Y75A, F150A, Y188A, D274A, F278A, and R279A, resulting in significant binding deficits were compared (all transfected in parallel using 20 µg of DNA/15-cm plate). Thirty micrograms of membrane-prepared protein was loaded/well with the exception of WT (hIP1D4), which only contained 15 µg of membrane protein.

Evidence from Sequence Alignments, Ligand Comparisons, and Modeling Supporting Four Residues as Having Direct Agonist Receptor Interactions-- Receptor configuration and TM helices were based upon sequence homology and alignment with the crystal structure of the rhodopsin receptor. Highly conserved ligand substituents on prostaglandins are likely to interact with conserved amino acids on the prostaglandin receptor. This principle has been used and confirmed in the investigation of many GPCRs including the adrenergic receptors (4) and rhodopsin (24). Independently, the computer-generated homology model of the hIP transmembrane domain (minus ligand) was evaluated and visualized using the Swiss PDB Viewer program. Initial superimposition of the model with the crystal structure of rhodopsin yielded significant structural similarity. To further determine the validity of our hIP model, a Ramachandran plot analysis was employed. Of the 182 amino acids formulating the transmembrane helices, 180 (99%) were within the allowable region for a right-handed alpha -helix, whereas 171 (94%) were within the preferred region. This corresponded well with the expected seven-transmembrane alpha -helical secondary structure of the hIP receptor. It was also determined (via Swiss PDB Viewer) that none of the residues was involved in any intramolecular or intermolecular clashes with the protein backbone or other side-chain constituents, nor were there any signs of global inconsistencies. By inserting prostacyclin into the model of the hIP, identification of distinct receptor-ligand interactions was possible. The major determinant for the final receptor-bound position of prostacyclin was based upon the experimentally observed requirement for the C1-carboxylate to interact with Arg-279.

Arg-279 (TMVII) Forms Ionic Interaction with the C1-Carboxylate Group-- The most significant binding pocket amino acid is the highly conserved (100%) Arg-279 found within the seventh transmembrane domain (TMVII) of the hIP receptor. Upon mutation to alanine (R279A), a significant decrease in agonist binding affinity was observed (Ki > 500 nM iloprost, p < 0.001) (Table I) as compared with the hIP1D4 wild-type receptor (Ki = 7.9 ± 1.7 nM iloprost). In addition, R279A protein expression was decreased greater than 3-fold in comparison with the wild-type construct (R279A Bmax = 0.5 pmol/mg membrane protein versus hIP1D4 Bmax = 1.8 pmol/mg membrane protein). Previous mutagenesis studies performed on the EP3 (25, 26) and EP2 (27) receptors have highlighted the impact of this residue in both ligand binding as well as receptor activation. Moreover, it has been shown that this residue has the capacity to not only form an ionic bond with the C1-carboxylate group of various ligands but serves as a hydrogen donor for carbonyl groups as well. EP1 receptor studies have confirmed that the primary interaction between this residue and ligand constituents is ionic (electrostatic) rather than hydrogen bonding since modification to various esters resulted in a greatly reduced affinity and potency (28). Thus, the complete level of conservation of Arg-279 across all of the prostanoid receptors, marked effect on ligand binding (when mutated to alanine), and complete conservation of the C1-carboxylate among all of the native prostanoid agonists strongly supports a direct ionic interaction between Arg-279 and the C1-carboxylate of prostacyclin (Fig. 5).


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Fig. 5.   Molecular model of receptor-bound prostacyclin and important binding pocket residues. Homology-based model of hIP receptor transmembrane domains with bound prostacyclin ligand is shown. An extracellular view of the critical contacts made between receptor residues within transmembrane domains II, III, and VII, and prostacyclin is shown. Green-dashed lines represent interactions, either hydrogen bonding or electrostatic attractions. The major sites of interactions are electrostatic interaction (green-dashed lines) between Arg-279 and the negatively charged C1-carboxylate group of prostacyclin; hydrophobic ring-ring interaction between Phe-278 and the oxolane ring of prostacyclin; and hydrogen bond (green-dashed line) and hydrophobic interactions between Tyr-75 and the C11-hydroxyl group of prostacyclin and hydrophobic stabilizations among Phe-95, Leu-67, and the omega -chain of prostacyclin. Phe-97, although not directly interacting with the ligand, forms an important interhelical interaction with TMIV.

Phe-278 (TMVII) Provides Supplemental Hydrophobic Interaction with Oxolane Ring and alpha -Chain-- Directly adjacent to the crucial Arg-279 residue is Phe-278, an exclusive residue found only in the IP receptor at this position. The distinctiveness of this residue seems to directly correlate with unique structural features found on IP receptor ligands, in particular the additional oxolane (cyclic ether) ring found on the native prostacyclin ligand. Some synthetic IP ligands such as iloprost and carbacyclin contain secondary cyclopentane rings at this position, whereas other naturally occurring prostaglandins (e.g. PGE1) do not (Fig. 1). A drastic reduction in binding affinity was observed in the F278A mutation with Ki = 351.3 ± 88.9 nM (n = 5) iloprost (p < 0.001) (Table I). Expression was also diminished as indicated by the lowered Bmax value of 0.8 pmol/mg membrane protein. Unlike the positively charged Arg-279, the Phe-278 residue contains a completely non-polar side chain. Thus, the most likely association between this residue and prostacyclin involves a hydrophobic ring-ring interaction between the oxolane ring of prostacyclin (cyclopentane ring of iloprost) and the Phe-278 phenyl constituent. As observed with our model (Fig. 5), there may be an additional interaction with the alpha -chain. It is our belief that both of these ring structures serve as unique yet corresponding elements that are crucial for proper ligand binding and help to supplement the main electrostatic bond at Arg-279. The combination of Phe-278 and Arg-279 facilitate key anchoring points at the C1-carboxylate chain and secondary oxolane ring of prostacyclin, accommodating the alpha -chain such that it remains in a "bent" state (Fig. 5) as observed with the energy-minimized configurations of prostacyclin.

Tyr-75 (TMII) Exhibits Functional Duality with C11-Hydroxyl and Cyclopentane Ring-- The Tyr-75 residue on TMII is conserved throughout the majority of the prostanoid receptors with the exception of the thromboxane receptors, which contain a histidine residue. Interestingly, a C11-hydroxyl group is present on all native prostanoids with the exception of thromboxane. In the prostaglandins, this hydroxyl is attached to C11, a member of a cyclopentane ring; however, in thromboxane, the equivalent oxygen is incorporated as part of a six-membered oxane ring (Fig. 1). Furthermore, from energy minimization, the C11-hydroxyl group on prostacyclin is in close proximity with the C1-carboxylate moiety. This is closely paralleled by the close proximity between Arg-279 and Tyr-75, adding further support for our model. Thus, our mutagenesis and modeling results predict a direct interaction between Tyr-75 and the C11-hydroxyl group as binding of agonist with the Y75A mutant revealed a greater than 50-fold decrease in affinity (p < 0.001) with little specific binding (Ki > 500 nM iloprost) (Table I) as compared with the hIP1D4 wild-type receptor (Ki = 7.9 ± 1.7 nM iloprost). To determine the precise structural features involved in this residue-ligand interaction (i.e. the presence of a phenyl ring, a hydroxyl group, or both), further mutagenesis (Y75F and Y75S) was performed. Unexpectedly, no significant defects in binding were observed with either of the additional mutations with Ki values comparable with wild type (Y75F Ki = 10.5 ± 4.1 nM iloprost (n = 5) and Y75S Ki = 13.3 ± 2.8 nM iloprost (n = 4)). Expression was decreased to roughly 30% for all three mutations with Bmax values of 0.5, 0.4, and 0.5 pmol/mg membrane protein for Y75A, Y75F, and Y75S, respectively. From our modeling, hydrogen bonding appears to be the major means for interaction (Fig. 5); however spatial flexibility (by angstroms) in either the ligand or the receptor may allow for the formation of hydrophobic ring-ring interactions between the centralized (non-oxolane) cyclopentane ring of prostacyclin and the Tyr-75-phenyl ring. Thus, either interaction alone (i.e. Y75F hydrophobic ring-ring association or Y75S hydrogen bond) is sufficient in maintaining efficient receptor-ligand affinity. Possessing a high level of conservation across all prostanoid receptors (apart from the thromboxane receptor), shared common structural C11-hydroxyl groups with ligands (apart from thromboxane), close proximity to the critical Arg-279 residue, and reduced affinity upon mutagenesis to alanine supports Tyr-75 as an anchoring point to the C11-hydroxyl of prostacyclin.

Phe-95 (TMIII) Is a Key Element in Accommodating the omega -Chain-- The Phe-95 residue is part of a phenylalanine-rich area within TM domain III. According to our model and binding analyses, Phe-95 plays a crucial role in accommodating the mainly hydrophobic omega -chain of prostacyclin. A cluster of hydrophobic residues is present in TMIII on all prostanoid receptors in the region of the putative binding pocket. The binding affinity for the F95A mutation differed significantly from the wild-type hIP1D4, revealing a considerable binding deficit (F95A Ki = 143.6 ± 98 nM iloprost (n = 6); p < 0.05) (Table I). The Bmax value for F95A was 0.8 pmol/mg membrane protein. The Phe-95 side chain provides a planar hydrophobic "sidewall" that helps to secure the freely rotating omega -chain constituent (Fig. 5). Previous chimera studies have shown this entire TM region to be interchangeable between mouse prostaglandin I and mouse prostaglandin D receptors (6). Furthermore, TMIII is one of two critical regions required for GPCR activation (29-31). We have previously shown that this region is also likely to be similarly important in the hIP (8). Thus, with attachments for the alpha -chain carboxylate group (Arg-279, TMVII) and both centralized rings (Phe-278 (TMVII) and Tyr-75 (TMII)) accounted for, the large hydrophobic region of TMIII, which includes Phe-95, comprises the fourth fundamental point of attachment-interaction between receptor and ligand, accommodating the omega -chain.

Residues That Affect Binding but Are Predicted to Have Indirect Ligand-Receptor Interactions-- Despite significant effects on binding affinity, amino acid residues Asp-60, Ser-68, Phe-97, Phe-150, Ser-185, Tyr-188, and Asp-274 are not predicted by our model to be directly involved in receptor-ligand binding (Table I). Asp-60 (TMII), although highly conserved (100%) across all prostanoid receptors, lies too far (12.3 Å) from our proposed ligand-binding pocket. Similarly, Ser-68 in TMII, although moderately conserved (~40%), is not predicted to be directly involved in binding. Phe-97 contributes to the largely hydrophobic region found in TMIII. Although it is very close to its Phe-95 counterpart, Phe-97 is oriented away from the receptor-bound prostacyclin molecule and thus has no direct impact on ligand binding. When mutated to alanine (F97A), a marked decrease in affinity suggests a potential role as a TMIII position stabilizer through interhelical interactions with the adjacent TMIV. Phe-150 is also an important binding-related residue as indicated by the marked reduction in binding affinity upon mutation to alanine (Ki > 500 nM iloprost (n = 4); p < 0.001) (Table I). However, contributions to ligand binding are indirect due to the increased distance (~ 8.5 Å) from the bound ligand as predicted by our model. Ser-185 in TMV is found in only 29% of all prostanoid receptors and has been shown to moderately affect ligand-binding affinity upon mutation to alanine. According to our model, Ser-185 is in close proximity to both Phe-150 (TMIV) and Tyr-188 (TMV). The Tyr-188 position is conserved only in mass (across the prostanoid receptors) with the majority of amino acids at this position being phenylalanine. Unlike Tyr-75, the Tyr-188 residue is not predicted to be directly involved in receptor-ligand interactions but rather may serve as a structural contributor, participating in potential hydrophobic (ring-ring) interactions with F146 (TMIV). Asp-274 in TMVII is conserved in ~40% of all prostanoid receptors. Within our proposed model, no direct residue-ligand interaction was evident; however, the proximity to the ligand combined with a gamma -carbon carboxylate group (negative charge) suggests that Asp-274 is an essential structural contributor near the binding domain, possibly through the formation of a salt bridge. Therefore, these indirect binding-related residues are important in supporting the fundamental binding pocket and anchoring points established for the receptor-bound prostacyclin model (i.e. Arg-279, Phe-278, Tyr-75, and Phe-95). Further model refinements were pursued.

Model Based Identification of Additional Interactions and Compensatory Mutations-- With the receptor-bound prostacyclin molecule in place and the structure refined, the ability to probe for other receptor-ligand interactions was now possible using the Swiss PDB Viewer as an exploratory device. Two additional residues, namely Leu-67 (TMII) and Met-99 (TMIII), were initially identified as being potential binding pocket contributors, affording probable receptor-ligand associations within the omega -chain area of prostacyclin. An additional residue, Val-71, was targeted as a possible compensatory mutation candidate for the binding deficit created by F95A. The prognostic capability and succeeding results achieved with our working model lend to both its internal validity and accuracy.

L67A and L67W (TMII)-- A probable binding pocket contributor, Leu-67, is found in only a small number of prostanoid receptors including the hIP. Normally, such a small and comparatively unreactive (non-polar) molecule would not be sought out as a direct contributor to ligand binding as was corroborated by an L67A mutation, which exhibited wild-type-like affinity (Ki = 4.8 ± 1.1 nM iloprost (n = 3)) (Fig. 5). However, when converted to a much larger amino acid (i.e. tryptophan, L67W), a significant decrease in binding affinity was observed (Ki > 500 nM iloprost; p < 0.001 (n = 3)). A steric repulsion between the larger L67W side chain and the omega -chain of prostacyclin is predicted by our model (Fig. 5). Therefore, with accommodating position, size, and side-chain neutrality, Leu-67 seemingly complements other hydrophobic residues in containing the omega -chain of prostacyclin as it is bound to the hIP receptor.

M99L (TMIII)-- Another prospective binding pocket residue with potential direct interaction with ligand constituents was Met-99 (TMIII), which is highly conserved and present in ~88% of all prostanoid receptors. In reviewing our model (Fig. 5), it was our belief that Met-99 may contribute to binding affinity through hydrogen bond formation with the C15-hydroxyl group of prostacyclin, which is a highly preserved feature in all prostaglandin ligands. However, a methionine-to-leucine change (M99L) at this position exhibited no significant change in binding affinity (Ki = 2.7 ± 0.7 nM iloprost (n = 3)) as compared with wild type. This is consistent with previous studies on the EP2, EP3, and EP4 receptor subtypes, which showed that the conserved C15-hydroxyl group may not play an important role in agonist affinity (28, 32).

F95A (TMIII) in Combination with V71L or V71F (TMII)-- As both the above results added marginal support to our model, we directed our focus toward producing compensatory mutations that might help counteract one of the more destructive binding pocket changes examined earlier, namely the important Phe-95 residue (TMIII) that (upon mutation to alanine) disrupted the hydrophobic interaction with the omega -chain. Upon examination of our model, Val-71 in TMII appeared to be a good candidate for compensation of the F95A-induced binding deficit when changed to phenylalanine (V71F) (Fig. 6). Thus, we investigated both V71L and V71F mutations in conjunction with the original F95A mutation. The combined F95A/V71L mutation exhibited a very poor binding affinity (Ki > 500 nM (n = 3)) in comparison with F95A/V71F of 7.2 ± 3.0 nM (n = 3). Despite this rescue in binding, no improvement in expression was observed (0.2 pmol/mg membrane protein). The validity of our model was supported by this compensatory mutation.


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Fig. 6.   Compensatory mutation of F95A with V71F. Model of hIP shows proximity of both Phe-95 (TMIII) and Val-71 (TMII) to the omega -chain of prostacyclin. The other points of ligand receptor interactions (i.e. Arg-279, Phe-278, and Tyr-75) have been removed for clarity. A, the wild-type protein with Phe-95 and Val-71 residues. Phe-95 interacts with the omega -chain of prostacyclin. B, mutating Phe-95 to alanine removes hydrophobic interaction with the omega -chain, leading to a drop in binding affinity. C, in the presence of F95A, a co-mutation of V71F restores binding affinity by substituting for the lost hydrophobic interaction between Phe-95 and the omega -chain.

Model-based Prediction of hIP Activation by Prostacyclin-- It should be noted here that our model is a static image of the initial binding of ligand to receptor. Such an interaction in reality is dynamic with significant changes in both receptor and ligand conformation. Being an agonist, prostacyclin and iloprost within the binding pocket would result in conformational changes initiating receptor activation. It has been observed for rhodopsin as well as other GPCRs including our hIP studies that poor receptor expression occurs upon mutation of residues critical for ligand binding (33, 34). This observation strongly suggests that, in addition to binding, these residues may also serve as important structural stabilizers in the empty state (no ligand). Moreover, these binding pocket residues may contribute to the constraining influence on receptors that when broken by ligand (e.g. salt bridges) leads to receptor activation (33). As a consequence of prostacyclin or iloprost binding, such stabilizing factors may be disrupted, leading to both ligand and receptor conformational changes. Given the position of prostacyclin in the binding pocket, we would predict that TMIII and TMVII would rotate and move apart upon agonist binding. There is precedence for such movements as biochemical and EPR assays on rhodopsin upon photoisomerization of 11-cis-retinal to all-trans-retinal have shown movements in TMIII and TMVII (29, 35-38). These major changes are most probably induced by ligand chain movements (e.g. alpha -chain moves TMVII and omega -chain TMIII). Thus, the first piece of evidence substantiating this hypothesis has now been provided; however, further studies are required for definitive confirmation.

The Unique IP Agonist-binding Pocket-- This study pinpoints specific residues that comprise the fundamental structure of the hIP-binding pocket, securing crucial receptor-ligand associations as well as those amino acids in close proximity to the general binding domain. Our findings support a structural model of receptor-bound prostacyclin in which four distinct anchoring sites (comprised by seven TM amino acids) link ligand to receptor. These observations were somewhat unexpected because they placed the prostacyclin-binding pocket at the same level but in an opposing direction to the ligands of rhodopsin and the biogenic amine receptors, both of which also have ligands consisting of a carbon ring with a hydrocarbon chain (catecholamine and 11-cis-retinal, respectively). For rhodopsin, the beta -ionone ring of 11-cis-retinal (20 carbons in size) faces TMV and TMVI, and the carbon chain is covalently attached via a Schiff base to TMVII (10). With the biogenic amines (9 carbons), hydroxyl groups from the catechol rings interact with serines on TMV and the amine group with an acidic residue in TMIII (4, 39). Prostacyclin like 11-cis-retinal and the biogenic amines has similarly important interactions with TMVII and TMIII; however, the bicyclic rings face TMI and TMII rather than TMV and TMVI (Fig. 7). We hypothesize that this may be a unique feature of the prostacyclin receptor that has reduced the availability of high affinity selective ligands. This insight may assist in the development of unique and highly specialized agents including additional agonists and, more notably, selective antagonists for the treatment and study of prostanoid-related disorders.


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Fig. 7.   Positions of three ligands: 11-cis-retinal, epinephrine, and prostacyclin in the agonist binding pocket. Homology modeling was performed as described under "Experimental Procedures" using the rhodopsin crystal structure as the template. Extracellular view of the homology-based prostacyclin receptor transmembrane alpha -helices with bound prostacyclin ligand (red) is shown. Also superimposed in the IP receptor is the configuration of 11-cis-retinal (green) in rhodopsin and epinephrine (yellow) in the adrenergic receptors.


    ACKNOWLEDGEMENTS

We wish to thank Dr. Kathleen Martin (Dartmouth Medical School, Hanover, NH), Professor Robert Graham (Victor Chang Cardiac Research Institute, Sydney, Australia), and Dr. Peter Reik (Victor Chang Cardiac Research Institute, Sydney, Australia) for critically reviewing the paper. We thank Dr. Bernard Trumpower (Department of Biochemistry, Dartmouth Medical School) for assistance and advice in the energy minimization of prostacyclin.

    FOOTNOTES

* This work was supported by a start-up grant provided by the Department of Pharmacology & Toxicology and an American Heart Association Scientist Development Grant 0235260N.The costs of publication of this article were defrayed in part by the payment of page charges. The article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

Dagger To whom correspondence should be addressed: Dept. of Pharmacology & Toxicology, 7650 Remsen, Dartmouth Medical School, Hanover, NH 03755. Tel.: 603-650-1813; Fax: 603-650-1129; E-mail: John.Hwa@Dartmouth.edu.

Published, JBC Papers in Press, November 21, 2002, DOI 10.1074/jbc.M207420200

    ABBREVIATIONS

The abbreviations used are: GPCR, G-protein coupled receptor; PGI2, prostacyclin; Gpp(NH)p, 5'-guanlyl-imidodiphosphate; ANOVA, analysis of variance; hIP, human prostacyclin receptor; TM, transmembrane.

    REFERENCES
TOP
ABSTRACT
INTRODUCTION
EXPERIMENTAL PROCEDURES
RESULTS AND DISCUSSION
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