The N-terminal Extracellular Segments of the Chemokine Receptors CCR1 and CCR3 Are Determinants for MIP-1alpha and Eotaxin Binding, Respectively, but a Second Domain Is Essential for Efficient Receptor Activation*

James E. PeaseDagger §, Juan Wangparallel , Paul D. Ponathparallel , and Philip M. Murphy§

From the Dagger  Krebs Institute, University of Sheffield, Western Bank, Sheffield S10 2TN, United Kingdom, § Laboratory of Host Defenses, NIAID, National Institutes of Health, Bethesda, Maryland 20892, and parallel  LeukoSite, Inc., Cambridge, Massachusetts 02142

    ABSTRACT
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Abstract
Introduction
Procedures
Results & Discussion
References

CCR1 and CCR3 are seven-transmembrane domain G protein-coupled receptors specific for members of the CC chemokine subgroup of leukocyte chemoattractants. Both have been implicated in the inflammatory response, and CCR3, through its expression on eosinophils, basophils, and Th2 lymphocytes, may be especially important in allergic inflammation. CCR1 and CCR3 are 54% identical in amino acid sequence and share some ligands but not others. In particular, macrophage inflammatory protein 1alpha (MIP-1alpha ) is a ligand for CCR1 but not CCR3, and eotaxin is a ligand for CCR3 but not CCR1. To map ligand selectivity determinants and to guide rational antagonist design, we analyzed CCR1:CCR3 chimeric receptors. When expressed in mouse pre-B cells, chimeras in which the N-terminal extracellular segments were switched were both able to bind both MIP-1alpha and eotaxin, but in each case, binding occurred via separate sites. Nevertheless, neither MIP-1alpha nor eotaxin were effective agonists at either chimeric receptor in either calcium flux or chemotaxis assays. These data are consistent with a multi-site model for chemokine-chemokine receptor interaction in which one or more subsites determine chemokine selectivity, but others are needed for receptor activation. Agents that bind to the N-terminal segments of CCR1 and CCR3 may be useful in blocking receptor function.

    INTRODUCTION
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Abstract
Introduction
Procedures
Results & Discussion
References

Chemokines and their seven-transmembrane domain G protein-coupled receptors constitute a large and highly differentiated signaling system involved in multiple biologic processes, including development, hematopoiesis, angiogenesis, and regulation of specific leukocyte trafficking (1-3). Together the system is capable of supporting host defense and repair functions but may also act as an amplifier of inappropriate inflammation in diseases such as asthma. Moreover, many components of the chemokine system are exploited as pro-microbial factors (3, 4). For example, diverse chemokine receptors can be exploited as cell entry factors by HIV-11 (5).

As the chemokine system expanded by gene replication, some functions were conserved, but new ones were added, allowing functional back-up to grow apace with functional diversification. This is illustrated nicely by the receptors CCR1 and CCR3. These receptors are more closely related in sequence to each other than to other chemokine receptors (54% amino acid identity) and have overlapping but nonidentical functional specificities (6-12). Both bind multiple chemokines, but only members of the CC subgroup of chemokines, including RANTES and MCP-3. However, each receptor also binds a selective ligand, eotaxin in the case of CCR3 and MIP-1alpha in the case of CCR1. Another differential feature is that CCR3 is an HIV-1 coreceptor, whereas this activity has not been found for CCR1 (13-17).

CCR3 is the only known eotaxin receptor, whereas several MIP-1alpha receptor subtypes have been identified (18-20). Eotaxin is a major activator of eosinophils, basophils, and Th2 lymphocytes, acting by binding to CCR3 (21-23), which has suggested that eotaxin and CCR3 are major factors regulating allergic inflammation. Consistent with this, mice rendered deficient in eotaxin by gene targeting exhibit reduced eosinophilic inflammation in response to both allergen challenge of the airway and cornea (24).

Compared with CCR3, CCR1 appears to be expressed at higher levels on lymphocytes and monocytes and at lower levels on eosinophils (25, 26). In mice it is an important neutrophil chemotactic receptor, but this function may not be expressed in humans (26, 27). Mice lacking CCR1 have increased susceptibility to Aspergillus infection, reduced granulomatous responses to Schistosome egg challenge, and reduced pneumonitis in a pancreatitis-induced pneumonitis model (27, 28).

Because of their roles in inflammation, identifying agents that specifically block CCR1 and CCR3 function may be therapeutically useful, and information about the ligand binding site may help to develop the most efficacious blocking agents. Also, CCR3 binding agents may be useful as anti-HIV agents. Eotaxin itself has this property, whereas RANTES and MCP-3 are much less potent (17). We have previously analyzed a series of chimeric CCR1:CCR3 receptors to map determinants of the HIV-1 coreceptor activity at CCR3(17). Here we use chimeric receptors to map chemokine selectivity determinants for CCR1 and CCR3.

    EXPERIMENTAL PROCEDURES
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Construction of Chimeric Receptors-- Construction of DNA-encoding chimeric receptors was accomplished by overlap extension polymerase chain reaction using the p4 cDNA-encoding CCR1 and the clone 3 cDNA-encoding CCR3 as templates, as described previously (7, 9, 17). The sequence encoding the FLAG epitope (Eastman Kodak Co.) was inserted between the first two codons by inclusion in the 5' oligonucleotide primer. Chimeric DNA was then ligated into the vector pcDNA3 (Invitrogen, CA) at the HindIII (5') and XhoI (3') sites, and sequences were confirmed by double-stranded DNA sequencing.

Establishment of Stable Transfectants-- The murine pre-B cell lymphoma cell line 4DE4 was generously provided by L. Staudt and maintained as described previously (29). Plasmid DNA (10 µg) was introduced into 3 × 106 cells by electroporation in 0.5 ml of Hanks' buffered saline solution (250 V, 940 µF). After 48 h in culture, the medium was supplemented with G418 (Life Technologies, Inc.) at 0.6 mg/ml until the flask achieved confluency, after which the concentration of G418 was raised to 1 mg/ml, and the cells were cloned by limiting dilution. Individual clones were then screened for receptor expression by radioligand binding and chemokine-induced calcium release assays.

Intracellular Calcium Release-- 4DE4 cells were resuspended at 107 cells/ml in phosphate-buffered saline and were loaded with 2.5 µM Fura-2 (Molecular Probes, OR) for 30 min at 37 °C in the dark. Cells were then washed twice in Hanks' buffered saline solution and resuspended at 1.5 × 106/ml. Cells were then stimulated with various doses of either eotaxin or MIP-1alpha in a continuously stirred cuvette at 37 °C in a fluorometer (Photon Technology, Inc., Piscataway, NJ). We used the recombinant BB10010 variant of human MIP-1alpha , a generous gift of L. Czaplewski (British Biotech Inc., Oxford, UK) and recombinant human eotaxin purchased from Peprotech (Rocky Hill, NJ). Data were recorded every 200 ms as the relative ratio of fluorescence emitted at 510 nm after sequential stimulation at 340 and 380 nm.

Chemotaxis Assays-- These were carried out as described previously using microchemotaxis chambers (Neuroprobe, Cabin John, MD) (29). Results obtained were expressed as a chemotactic index.

Radioligand Binding Assays-- 125I-MIP-1alpha and 125I-eotaxin were purchased from NEN Life Science Products. The specific activities were 2200 Ci/mmol. Cells were washed once in binding buffer (Hanks' buffered saline solution containing 1% bovine serum albumin and 0.05% NaN3) and resuspended in the same buffer at 2-3 × 106 cells/ml. 100 µl of this suspension were added to duplicate Eppendorf tubes containing 0.25 nM labeled ligand and varying concentrations of cold competing ligand in a final volume of 200 µl. Ligand binding was allowed to proceed at room temperature for 1 h, after which 500 µl of binding buffer adjusted to 0.5 M NaCl was added, and the cells were pelleted by centrifugation at 10,000 × g for 5 min. the supernatant was aspirated, and the cell pellet was cut from the tube and counted in a gamma counter. Nonspecific binding was typically 20-40% of the total counts. The data were fit to a curve, and the apparent binding affinity and receptor density were estimated using the program LIGAND.

    RESULTS AND DISCUSSION
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Introduction
Procedures
Results & Discussion
References

Differential Chemokine Specificities of Wild Type CCR1 and CCR3-- We have previously analyzed HIV-1 specificity determinants for CCR3 using a panel of CCR1:CCR3 chimeric receptors transiently expressed in NIH 3T3 cells. This system, which depends on vaccinia virus activation of a vaccinia promoter in the plasmid vector pSC59, allows high levels of receptor expression; however it could not be used for the present study because vaccinia interrupts G protein signaling in these cells.2 We therefore subcloned the chimeric DNA inserts into the mammalian expression vector pcDNA3 and cloned stably transfected cell lines in a mouse pre-B cell lymphoma cell line.

Untransfected cells did not exhibit specific binding of MIP-1alpha or eotaxin at the concentrations employed. However, very small calcium fluxes were observed on untransfected cells in response to MIP-1alpha but only at concentrations of 300 nM and above (data not shown). Consistent with previous reports, after transfection with the CCR1 expression plasmid, approximately 50% of clones tested responded to MIP-1alpha at low nanomolar concentrations in a calcium flux assay, but none responded to eotaxin. Likewise, after transfection with the CCR3 expression plasmid, approximately 40% of clones tested responded to eotaxin in the calcium flux assay, but none responded to MIP-1alpha . Clones that gave the most robust responses were selected for further characterization (Fig. 1). Clone 1 expressing CCR1 exhibited specific binding for MIP-1alpha (Fig. 1F), but specific eotaxin binding was not detected on the same cells using 0.25 nM 125I-eotaxin and 200 nM unlabeled eotaxin as probes (data not shown). Conversely, clone L expressing CCR3 exhibited specific binding for eotaxin (Fig. 1E), but specific MIP-1alpha binding was not detected on the same cells using 0.25 nM 125I-MIP-1alpha and 200 nM unlabeled MIP-1alpha as probes (data not shown). Scatchard analysis of competition binding data revealed that clone L expressing CCR3 expressed ~2000 eotaxin binding sites/cell with an apparent Ki = 0.5-1.0 nM (Table I). The EC50 for calcium release by eotaxin in these cells was 1-5 nM (Fig. 1A and Table I). Eotaxin binding was insensitive to competition with excess MIP-1alpha , and MIP-1alpha did not antagonize eotaxin induction of calcium release (data not shown). Receptor parameters for clone 1 expressing CCR1 were similar: ~2200 MIP-1alpha binding sites/cell, an apparent Ki = 1-5 nM, and an EC50 for calcium release by MIP-1alpha of 1-5 nM (Table I). Also, MIP-1alpha binding to clone 1 was insensitive to competition with excess eotaxin, and eotaxin did not antagonize MIP-1alpha induction of calcium release (data not shown). These parameters are consistent with those previously reported for wild type CCR1 and CCR3 expressed in other cell types (6, 11, 12).


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Fig. 1.   Differential specificity of CCR1 and CCR3 for MIP-1alpha and eotaxin. Results in each panel correspond to the receptor indicated at the top of the column in which it is found. A and B, calcium flux assay. Pre-B cells stably expressing CCR1 or CCR3 were stimulated with the indicated concentrations of eotaxin (open circles) or MIP-1alpha (closed circles), and calcium flux was monitored in real time by Fura-2 fluorescence. The maximum of the fluorescence change observed at each concentration is plotted on the y axis. Results are from a single clone for each construct and are representative of 2-3 clones each tested 3 times. C and D, chemotaxis assay. Each panel gives the results of chemotaxis assays in response to various concentrations of eotaxin (open circles) or MIP-1alpha (closed circles). E and F, binding assay. Each panel gives the results of homologous competition for 0.25 nM radioligand indicated using increasing concentrations of the same unlabeled chemokine. B/T, bound chemokine/total chemokine. In each panel of the figure, the results denoted are from representative experiments performed on a single clone at least 3 times.

                              
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Table I
Binding and signaling parameters for wild type CCR1 and CCR3 and CCR1:CCR3 chimeric receptors
Data are derived from 2-3 separate experiments for each construct. ND, not detectable.

Clone L cells expressing CCR3 also exhibited chemotaxis to eotaxin, with the maximal response observed at a concentration of 100 nM (Fig. 1C). No background chemotaxis was observed with eotaxin using untransfected cells, even at concentrations of 1 µM. In contrast, MIP-1alpha was a poor chemoattractant, eliciting a chemotactic response only when employed at 1 µM, which represented a background response on these cells (Fig. 1C and data not shown). Clone 1 cells expressing CCR1 were unable to chemotax in response to eotaxin, as may have been inferred by the calcium release data in panel B, but surprisingly, MIP-1alpha was also a poor attractant, eliciting only background chemotactic activity when tested at 1 µM (Fig. 1D). Similar chemotaxis results were obtained when the same constructs were tested in transiently transfected L1.2 cells (data not shown).

It is interesting that two similar receptors expressed in the same cellular background can exhibit potent efficacy in mobilizing intracellular calcium to key ligands, yet have such different chemotactic profiles to the same ligands. Similar but converse findings have been observed for CCR2B, where chemotaxis to MCP-1 was observed in the absence of a calcium flux, suggesting that the two events can occur independently of each other (30).

Staining of both clones with the anti-FLAG monoclonal antibody M5 revealed a small 2-fold shift relative to staining of untransfected cells, consistent with the low levels of expression determined by Scatchard analysis of the binding data.

Mapping of Ligand Specificity Determinants to the N-terminal Extracellular Segments of CCR1 and CCR3-- Having established the receptor parameters for wild type CCR1 and CCR3 in our system, we next tested the importance of the N-terminal segments of each receptor in determining differential ligand selectivity. We focused on this region because the corresponding region has been shown to be a ligand selectivity determinant for several other chemokine receptors, including CXCR1, CXCR2, Duffy and CCR2 (31-37).

One chimera contained amino acids 1-32 from CCR1 joined to amino acids 33-355 of CCR3 and was named CHI1. The reciprocal chimera contained amino acids 1-32 of CCR3 fused to amino acids 33-356 of CCR1 and was named CHI2. The junctions were based on the hydropathy plot of the receptors. When expressed in pre-B cells, both chimeras exhibited chimeric ligand recognition, specifically binding both 125I-MIP-1alpha and 125I-eotaxin (Fig. 2).


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Fig. 2.   Importance of the N-terminal extracellular segment of CCR1 and CCR3 for chemokine specificity. Results in each panel correspond to the receptor construct indicated at the top of the column in which it is found. Black indicates CCR1 sequence; white indicates CCR3 sequence. A-D, ligand binding assay. Each panel gives the results of homologous competition for 0.25 nM radioligand shown in each box using increasing concentrations of the same unlabeled chemokine. Results are from representative experiments performed on a single clone, tested 2-3 times. B/T, bound chemokine/total chemokine.

Scatchard analysis of competition binding data revealed that clone A6 for CHI1 coexpressed both eotaxin and MIP-1alpha binding sites (apparent Ki = 5-10 nM and 10-50 nM, respectively, and 6,000-10,000 sites/cell for each). Likewise, Scatchard analysis of competition binding data revealed that clone 5.5 for CHI2 coexpressed both eotaxin and MIP-1alpha binding sites (apparent Ki = 0.5-1.0 nM and 50-75 nM, respectively, and 6,000-10,000 sites/cell for each).


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Fig. 3.   Importance of the third extracellular loop of CCR1 and CCR3 for chemokine specificity. Results in each panel correspond to chimeric receptor CHI3 whose composition is given at the upper right. Black indicates CCR1 sequence; white indicates CCR3 sequence. A, calcium flux assay. Pre-B cells stably expressing CHI3 were stimulated with eotaxin (open circle) and MIP-1alpha (closed circle) at the indicated concentrations, and the peak changes in Fura-2 fluorescence were plotted on the y axis. Results are from a single clone for each construct and are representative of two clones each tested three times. B and C, ligand binding assay. Each panel gives the results of homologous competition for 0.25 nM radioligand shown in each box using increasing concentrations of the same unlabeled chemokine. Results are from a single clone for each construct tested 2-3 times. B/T, bound chemokine/total chemokine.

A role for the N-terminal segment of CCR1 as a MIP-1alpha binding selectivity determinant is supported by the gain of MIP-1alpha binding in CHI1 relative to wild type CCR3 and the ~50-fold reduction in apparent binding affinity for MIP-1alpha in CHI2 relative to wild type CCR1. A role for the N-terminal segment of CCR3 as an eotaxin binding selectivity determinant is supported by the gain of eotaxin binding in CHI2 relative to wild type CCR1 and the ~10-fold reduction in apparent binding affinity for eotaxin in CHI1 relative to wild type CCR3. That other receptor domains are also involved in ligand binding selectivity is apparent from the preserved ability of CHI1 to bind eotaxin and CHI2 to bind MIP-1alpha , albeit at reduced affinity.

Independence of MIP-1alpha and Eotaxin Binding Sites in CCR1:CCR3 Chimeric Receptors-- Heterologous competition binding was carried out to examine the relationship of the MIP-1alpha and eotaxin binding sites on CHI1 and CHI2. Neither chemokine could compete for binding to the site labeled by the other on either chimera, even when 1 µM heterologous chemokine was used (data not shown), suggesting that the sites are independent, as they are on wild type CCR1 and wild type CCR3. Independence of binding sites has also been reported for interleukin-8 and GROalpha on CXCR1:CXCR2 chimeric receptors and for MCP-1 and MIP-1alpha on chimeric receptors (33-36). In the case of CCR2, a pseudo-tethered N-terminal domain binds MCP-1 with affinity similar to the full-length wild type receptor, suggesting that the bulk of the binding energy between CCR2 and MCP-1 is conferred by interactions occurring solely between MCP-1 and this domain (36). Also, there is direct structural evidence from spectroscopy studies for binding of interleukin-8 to the N-terminal segment of CXCR1 (38). Ligand selectivity determinants have been mapped to the second extracellular loop of CCR5 using CCR2:CCR5 chimeras and to the third extracellular loop of CCR1 using CCR1:CCR2 chimeras; however, direct binding sites have not been identified yet (39, 40). Thus, in some cases chemokines may bind to receptors at a single extracellular domain, and this domain could differ for different chemokines binding to the same receptor. However, in other cases, ligands appear to share sites on the same receptor.

It is important to point out that, in contrast to our results with CCR1:CCR3 chimeras, MIP-1alpha selectivity did not map to the N-terminal segment of CCR1 in CCR1:CXCR2 or CCR1:CCR2 chimeras reported previously (33, 35). Our data suggest that a revised interpretation of these negative results may be warranted: that the CCR1 N-terminal segment complements other domains to determine MIP-1alpha recognition specificity. From this perspective, CCR3 contains complementary domains, whereas CXCR2 and CCR2 do not.

Requirement for Other Receptor Domains for Receptor Activation-- With several exceptions, there is a fairly good correlation between the rank order of chemokine binding affinity for individual receptors and among different receptors versus the rank orders when the same chemokines are evaluated as agonists. Creation of chimeric receptors allows one to test whether chemokine binding specificity determinants and chemokine receptor activation determinants map to the same domains.

Unlike wild type CCR1 and wild type CCR3, we did not observe activation of either CHI1- or CHI2-expressing stable cell lines in calcium flux and chemotaxis assays when stimulated with either MIP-1alpha or eotaxin, even at concentrations 10-100-fold greater than the apparent binding constant. The cells were capable of signaling as shown by robust calcium flux responses to the CXC chemokine SDF-1 via an endogenous pre-B cell receptor that is probably the chemokine receptor CXCR4 (not shown; Refs. 41 and 42). Moreover, the results could not be explained by low receptor expression, since levels of chimeric receptors were actually 3-fold higher than wild type receptor levels in the clones tested. Nor could they be explained completely by reduced ligand binding affinity, since eotaxin binding affinity for CHI2 and wild type CCR3 were equivalent. In the case of MIP-1alpha , affinity for CHI1 and CHI2 was substantially reduced (~10-fold) compared with wild type CCR1. However, a third chimeric receptor named CHI3, in which the third extracellular loop of CCR1 was replaced with that of CCR3, was expressed at levels similar to CHI1 and CHI2, exhibited an affinity for MIP-1alpha only 5-fold higher than values for CHI1 and CHI2, and supported MIP-1alpha signaling at a potency and efficacy equivalent to wild type CCR1 (EC50 = 1-5 nM for calcium release, Fig. 3). Cells expressing CHI3 were able to bind eotaxin with an apparent affinity ~3-fold lower than for wild type CCR3 (~20 nM). However, no response to eotaxin was observed at concentrations up to 200 nM. The reciprocal of CHI3 was not informative in fluorescence-activated cell sorter, ligand binding, or calcium flux assays (data not shown). Note that the present CHI3 is a different structure from a construct named CHI3 in a previous paper (17).

Similar results were obtained when the same constructs were transiently expressed in L1.2 pre-B cells, with one exception. CHI1-transfected cells responded chemotactically to eotaxin, although the efficacy was typically ~25% that of wild type CCR3 in the same system, despite equivalent levels of expression as determined by the monoclonal antibody 7B11 (data not shown). Thus the results from the stably and transiently transfected cells with respect to chemotaxis are qualitatively similar.

Conclusions-- The results of the present study are consistent with a multi-site model for chemokine-chemokine receptor interaction in which one or more subsites determine chemokine selectivity, but others are needed for receptor triggering. In this model, ligand is envisioned to bind first via a docking domain, which may be the N-terminal segment for eotaxin and MIP-1alpha in the case of CCR3 and CCR1, respectively, and then to be presented to a second activation site on the receptor. The first well documented example in support of this model was the C5a receptor, which binds a peptide chemoattractant similar in size to the chemokines (43). Since then, additional examples have been reported based on the study of chimeric CCR1:CXCR2, CCR2:CCR5, and CXCR1:CXCR2 receptors (33-36).

Analysis of chimeric receptors only allows statements about selectivity determinants and does not give direct information about the location of ligand binding sites or sites important in receptor activation. In the case of CCR2 and CXCR1, the importance of the N-terminal segment in binding MCP-1 and IL-8, respectively, which had been suggested from chimeric receptor studies, was later validated by more direct experimental approaches (36, 38). In the case of CCR1 and CCR3, direct identification of functional sites has not yet been accomplished. Nevertheless, since the N-terminal segments of CCR1 and CCR3 appear to be important ligand binding selectivity determinants, agents that bind there could perturb receptor recognition of MIP-1alpha and eotaxin, respectively, and act as effective blocking agents, either directly or allosterically. Point mutagenesis of these regions should enable a more detailed understanding of the functional sites on CCR1 and CCR3 and may further assist the development of specific antagonists.

    ACKNOWLEDGEMENT

We are grateful to the British Heart Foundation for their financial support of this project.

    FOOTNOTES

* 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.

To whom correspondence should be addressed: Leukocyte Biology, Imperial College School of Medicine, Division of Biomedical Sciences, Exhibition Road, London, SW7 2AZ, UK. Tel.: 0171-594-3124; E-mail: j.pease{at}ic.ac.uk.

The abbreviations used are: HIV, human immunodeficiency virus; MIP, macrophage inflammatory protein 1alpha .

2 G. Alkhatib, M. Locati, P. M. Murphy, and E. A. Berger, unpublished observations.

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Abstract
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Results & Discussion
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