(Received for publication, December 12, 1996, and in revised form, April 2, 1997)
From the Shionogi Institute for Medical Science, 2-5-1 Mishima, Settsu-shi, Osaka 566, Japan
Thymus and activation-regulated chemokine (TARC)
is a recently identified CC chemokine that is expressed constitutively
in thymus and transiently in stimulated peripheral blood mononuclear cells. TARC functions as a selective chemoattractant for T cells that
express a class of receptors binding TARC with high affinity and
specificity. To identify the receptor for TARC, we produced TARC as a
fusion protein with secreted alkaline phosphatase (SEAP) and used it
for specific binding. By stably transfecting five orphan receptors and
five known CC chemokine receptors (CCR1 to -5) into K562 cells, we
found that TARC-SEAP bound selectively to cells expressing CCR4.
TARC-SEAP also bound to K562 cells stably expressing CCR4 with a high
affinity (Kd = 0.5 nM). Only TARC and
not five other CC chemokines (MCP-1 (monocyte chemoattractant protein-1), RANTES (regulated upon activation, normal T cells expressed
and secreted), MIP-1 (macrophage inflammatory protein-1
), MIP-1
, and LARC (liver and activation-regulated chemokine)) competed with TARC-SEAP for binding to CCR4. TARC but not RANTES or MIP-1
induced migration and calcium mobilization in 293/EBNA-1 cells stably
expressing CCR4. K562 cells stably expressing CCR4 also responded to
TARC in a calcium mobilization assay. Northern blot analysis revealed
that CCR4 mRNA was expressed strongly in human T cell lines and
peripheral blood T cells but not in B cells, natural killer cells,
monocytes, or granulocytes. Taken together, TARC is a specific
functional ligand for CCR4, and CCR4 is the specific receptor for TARC
selectively expressed on T cells.
Chemokines are small secreted polypeptides that play important
roles in a wide range of inflammatory and immunological processes by
recruiting selected subsets of leukocytes (1, 2). The known chemokines
are divided into two major subfamilies based on the spacing of the
first two cysteines in the conserved motif. The CXC chemokine
subfamily, which includes IL-81 (3) and
IP-10 (4), is characterized by the presence of a single amino acid
separating the first two cysteines. The two cysteines are adjacent in
the CC chemokine subfamily, which includes RANTES (5), MCP-1 (6, 7),
MCP-2 (8), MCP-3 (9), MCP-4 (10), MIP-1 (11), MIP-1
(12), I-309
(13), eotaxin (14, 15), HCC-1 (16), TARC (17), and LARC (18). The CXC
chemokines preferentially attract and activate neutrophils, whereas the
CC chemokines usually attract and activate monocytes and also
basophils, eosinophils, or lymphocytes with variable selectivity (19).
Recently, lymphotactin/single C motif 1 that carries only the second
and the fourth of the four cysteine residues conserved in other
chemokines has been identified, suggesting the existence of the C type
chemokine subfamily (20, 21). The human genes for the CXC, CC, and C
chemokines are clustered on human chromosomes 4, 17, and 1, respectively (1, 22, 23). Recent studies indicate that genes for
certain chemokines are present outside these clusters. For example, a
CXC chemokine SDF-1/PBSF has been mapped to human chromosome 10 (24),
and CC chemokines TARC and LARC have been mapped to human chromosomes
16 and 2, respectively (18, 25). In addition to chemotactic activity, some chemokines have a regulatory activity on hematopoiesis and angiogenesis (26-28). Recently, it has been shown that three CC chemokines, MIP-1
, MIP-1
, and RANTES, block infection of
macrophage-tropic strains of human immunodeficiency virus type 1, while
a CXC chemokine, SDF-1/PBSF, blocks infection of T cell line-tropic
human immunodeficiency virus type 1 strains (29, 30).
The specific effects of chemokines on target cells are mediated by
seven-transmembrane G-protein-coupled receptors (31). To date, at least
five human CC chemokine receptors have been defined for ligand
specificity. CCR1 is a receptor for MIP-1, RANTES, and MCP-3
(32-35); CCR2 is a receptor for MCP-1 and MCP-3 (35, 36); CCR3 is a
receptor for eotaxin, RANTES, and MCP-3 (14, 37, 38); CCR4 is a
receptor for MIP-1
, RANTES, and MCP-1 (39); and CCR5 is a receptor
for MIP-1
, MIP-1
, and RANTES (40-42). The specific ligands for
CCR1, CCR2, CCR3, and CCR5 were demonstrated by specific binding and
functional assays such as chemotaxis and calcium flux using
cDNA-transfected mammalian cells. In the case of CCR4, however,
only marginal levels of binding of MIP-1
and RANTES were shown with
HL-60 cells transfected with CCR4 (43), while a chloride current
induction in response to MIP-1
, RANTES, and MCP-1 was demonstrated
in CCR4 cRNA-injected oocytes (39). Except for CCR3 that is almost
exclusively expressed on eosinophils (38, 44), other receptors were
reported to be expressed on monocytes and lymphocytes. Notably, CCR4
that was originally cloned from a human basophilic cell line was shown to be expressed selectively in thymus besides peripheral blood mononuclear cells (PBMCs) (39).
Recently, we have isolated a novel CC chemokine, TARC
(thymus and activation-regulated
chemokine) by an efficient signal sequence trap using an
Epstein-Barr virus vector (17). TARC is expressed transiently in
phytohemagglutinin-stimulated PBMC and constitutively and selectively
in thymus. TARC induces chemotaxis in certain human T cell lines but
not in monocytes or granulocytes. Pretreatment of cells with
Pertussis toxin abolishes cell migration induced by TARC.
Radiolabeled recombinant TARC specifically binds to T cell lines and
peripheral blood T cells but not to monocytes or granulocytes. The
binding of radiolabeled TARC to T cells is competed by TARC but not by
other chemokines such as IL-8, MIP-1, RANTES, or MCP-1. These
results indicate the existence of a class of highly specific
Pertussis toxin-sensitive G-protein-coupled receptors for
TARC on T cells. In the present study, we have demonstrated that CCR4
is the specific high affinity functional receptor for TARC that is
expressed selectively on T cells.
Human hematopoietic cell lines were maintained in
RPMI 1640 supplemented with 10% fetal calf serum (FCS). The murine
pre-B cell line L1.2 was kindly provided by Dr. Craig Gerard (Harvard Medical School, Boston, MA) and maintained in RPMI 1640 supplemented with 10% FCS. 293/EBNA-1 cells were purchased from Invitrogen (San
Diego, CA) and maintained in Dulbecco's modified Eagle's medium
supplemented with 10% FCS. PBMCs were isolated from venous blood
obtained from healthy adult donors using Ficoll-Paque (Pharmacia, Uppsala, Sweden). Monocytes were stained with fluorescein
isothiocyanate-conjugated anti-CD14 and positively selected by MACS
(Miltenyi Biotec, Bergisch, Germany). B cells were stained with
fluorescein isothiocyanate-conjugated anti-CD19 and positively selected
by MACS. T cells were stained with fluorescein
isothiocyanate-conjugated anti-CD3 and positively selected by MACS.
Natural killer (NK) cells were sorted by FACStar Plus (Beckton
Dickinson, Mountain View, CA) as CD16+ or CD56+
and CD3 cells with appropriate forward and side scatters.
Purification of CD4+ and CD8+ T cells from
PBMCs was carried out by negative selection using Dynabeads (Dynal,
Oslo, Norway) after incubation of PBMCs with anti-CD16, anti-CD14,
anti-CD20, and anti-CD8 or anti-CD4, respectively. Granulocytes were
obtained from the pellet fraction of Ficoll-Paque gradient by dextran
sedimentation and hypotonic lysis of erythrocytes. The purity of each
cell population was always in the range of 95-99% as determined by
flow cytometric analysis or by staining with Diff-Quik (Baxter
Scientific Products, McGaw Park, IL).
The cDNA fragments covering the open reading frames for various chemokine receptors and orphan receptors were obtained as follows. Cloning of CCR3 cDNA was described previously (14). EBI1 and BLR1 cDNA were isolated by screening a phytohemagglutinin-stimulated human PBMC cDNA library. Other receptors were cloned from a human PBMC cDNA library or human genomic library by polymerase chain reaction (PCR). The primers were designed using the sequences from the following GenBankTM submissions: CCR1 (L09320[GenBank]), CCR2B (U03905[GenBank]), CCR4 (X85740[GenBank]), CCR5 (X91492[GenBank]), CXCR4 (M99293[GenBank]), V28 (U20350[GenBank]), GPR-CY4 (U45984[GenBank]), GPR-9-6 (U45982[GenBank]), EBI1 (L31581[GenBank]), BLR1 (X68149[GenBank]). The fragments were cloned into an expression vector pDREF-Hyg (17) for efficient expression in 293/EBNA-1 cells and Raji cells, or pCAGG-Neo (kindly provided by T. Nakajima) for expression in K562 cells and L1.2 cells.
Stable TransfectionFor stable expression in Raji cells, cells were transfected by electroporation as described previously (17). For stable expression in 293/EBNA-1 cells, 1 × 106 cells were plated onto 100-mm dishes. After 12-20 h, cells were transfected with recombinant plasmids (10 µg each) using LipofectAMINE (Life Technologies, Inc.). After selection with 250 µg/ml hygromycin for 1-2 weeks, drug-resistant cells were pooled and used for experiments. For stable expression in K562 cells and L1.2 cells, 1 × 107 cells in 500 µl of phosphate-buffered saline were electroporated with 10 µg of linearized plasmid at 260 V, 960 microfarads using a Gene Pulser (Bio-Rad). After selection with 800 µg/ml of G418 for 1-2 weeks, cells expressing transfected receptors at high levels were identified by binding assays and/or Northern blot analysis and cloned by limiting dilution.
Production of TARC-SEAP Fusion ProteinThe DNA fragment
encoding TARC was amplified from clone D3A (17) by PCR using 5
SalI-TARC primer (+5
-CGCGTCGACAAAACCATGTGCTGTACCAAG-3
) and
3
TARC-XbaI primer
(
5
-CGCTCTAGACATGTTCTTGACTTTTTTACT-3
). After digestion with
SalI and XbaI, the TARC cDNA was subcloned into SalI-XbaI sites of
pDREF-SEAP(His)6-Hyg vector (18) to express TARC as a
soluble fusion protein linked through five amino acid residues
(Ser-Arg-Ser-Ser-Gly) with secreted placental alkaline phosphatase
(SEAP) tagged with six histidine residues ((His)6). 293/EBNA-1 cells were transfected with the expression vector
pDREF-TARC-SEAP(His)6 using LipofectAMINE (Life
Technologies, Inc.). The transfected cells were incubated for 3-4 days
in Dulbecco's modified Eagle's medium supplemented with 10% FCS. The
supernatant containing TARC-SEAP(His)6 was collected by
centrifugation, filtered (0.45 µm), and stored at 4 °C after
adding 20 mM Hepes (pH 7.4) and 0.02% sodium azide. For
one-step affinity purification of TARC-SEAP(His)6, the
supernatant was applied to 1 ml of Hisbond resin (Qiagen, Hilden,
Germany). After washing, bound TARC-SEAP(His)6 was eluted
with 100 mM imidazol. The concentration of
TARC-SEAP(His)6 was determined by a sandwich type
enzyme-linked immunosorbent assay as described previously (18).
Briefly, 96-well microtiter plates (Nunc Maxsorb) were coated with
antiplacental alkaline phosphatase monoclonal antibody (Medix Biotech,
Foster City, CA). After blocking with 1 mg/ml bovine serum albumin
(BSA) in phosphate-buffered saline, the samples were titrated and
incubated for 1 h at room temperature. After washing, plates were
incubated with biotinylated rabbit antiplacental alkaline phosphatase
diluted 1:500 for 1 h at room temperature, washed again, and
incubated with peroxidase-conjugated streptavidin (Vector) for 30 min.
After washing, bound peroxidase was reacted with
3,3
-5,5
-tetramethylbenzidine. Reaction was stopped by adding 1 N H2SO4, and absorbance at 450 nm
was measured. Alkaline phosphatase activity was determined by a
chemiluminescent assay using the Great EscApe detection kit
(CLONTECH). Purified antiplacental alkaline
phosphatase (Cosmo Bio) was used to generate a standard curve. The
enzymatic activity was expressed as relative light units/s. The
SEAP(His)6 and TARC-SEAP(His)6 used in the
present study had a specific activity of approximately 8.88 × 107 relative light units/s and 1.23 × 108
relative light units/s per pmol, respectively.
For displacement experiments, cells were
incubated for 1 h at 16 °C with 1 nM of
SEAP(His)6 or TARC-SEAP(His)6 in the presence of increasing concentrations of unlabeled chemokines in 200 µl of
RPMI 1640 containing 20 mM Hepes (pH 7.4), 1% BSA, and
0.02% sodium azide. For saturation experiments, cells were incubated for 1 h at 16 °C with increasing concentrations of
TARC-SEAP(His)6 in the presence or absence of 1 µM unlabeled TARC. After incubation, cells were washed
five times and lysed in 50 µl of 10 mM Tris-HCl (pH 8.0),
1% Triton X-100. Samples were heated at 65 °C for 10 min to
inactivate cellular phosphatases. Lysates were collected by
centrifugation, and alkaline phosphatase activity in 25 µl of lysate
was determined by the chemiluminescent assay described above. For
direct binding experiments, cells were incubated for 1 h at
16 °C with 0.1 nM of 125I-RANTES,
125I-MCP-1, 125I-MIP-1, or
TARC-SEAP(His)6 without or with 200 nM of
unlabeled chemokines in 200 µl of low salt binding buffer (50 mM Hepes, pH 7.5, 1 mM CaCl2, 5 mM MgCl2, 0.5% BSA, and 0.05% sodium azide). The cells were then washed five times with low salt binding buffer containing 0.5 M NaCl. All assays were done in duplicate.
Binding data were analyzed by the LIGAND program (45).
Cell migration was assayed by using a 48-well microchemotaxis chamber as described previously (17, 34). In brief, chemoattractants were diluted in Hepes-buffered RPMI 1640 supplemented with 1% BSA and placed in lower wells (25 µl/well). Cells were suspended in the same medium at 2 × 106 cells/ml and added to upper wells (50 µl/well). The upper and lower wells were separated by a polyvinylpyrrolidone-free polycarbonate filter with 8-µm pores that was precoated with type IV collagen (34). The chamber was incubated for 4 h at 37 °C in 5% CO2, 95% air. Filters were removed and stained with Diff-Quik. Each sample was assayed in triplicate, and migrated cells were counted in five randomly selected high power fields (× 400) per well.
Calcium Mobilization AssayCells were suspended at 3 × 106 cells/ml in Hank's balanced salt solution
supplement with 1 mg/ml BSA and 10 mM HEPES, pH 7.4. Cell
were incubated with 1 µM fura-PE3-AM (Texas Fluorescence Labs) at room temperature for 1 h in the dark. After washing
twice, cells were resuspended at 2.5 × 106 cells/ml.
To measure intracellular calcium, cells in 2 ml were placed in a quartz
cuvette in a Perkin-Elmer LS 50B spectrofluorimeter. Fluorescence was
monitored at 340 nm (ex1), 380 nm (
ex2), and 510 nm (
em) every
200 ms. A dose-response curve was generated in each experiment, and
results were expressed as percentage of maximum response.
Total RNAs were prepared from
various subsets of peripheral blood leukocytes using Trizol (Life
Technologies, Inc.). RNA samples (5 µg each) were fractionated by
electrophoresis on a 1% agarose gel containing 0.66 M
formaldehyde. Gels were blotted onto a filter membrane (Hybond
N+) (Amersham Japan, Tokyo). The probe was the
SmaI-PstI fragment of clone D3A (17).
Hybridization was carried out at 65 °C in QuickHyb solution
(Stratagene) with probes labeled with 32P using Prime it II
(Stratagene). After washing at 55 °C with 0.2 × SSC and 0.1%
SDS, filters were exposed to x-ray films at 80 °C with an
intensifying screen.
Chemokines often have a tendency for
self-aggregation at physiological pH and tonicity that interferes with
their receptor studies (46, 47). To circumvent this problem, Luster
et al. generated IP-10 fused with SEAP and showed that the
fusion protein retained its ability to interact specifically with cell
surface receptors without self-aggregation in physiological buffers
(46). To prepare labeled TARC convenient for receptor binding
experiments, we decided to adopt this method and expressed TARC as a
fusion protein with SEAP with the (His)6 tag (Fig.
1A). The alkaline phosphatase activity
allowed quantitative determination of specific binding, whereas the
(His)6 tag in the C terminus was used for one-step affinity
purification with a nickel agarose column. TARC-SEAP(His)6 was expressed in 293/EBNA-1 cells and purified as a single major protein with an apparent molecular mass of 74 kDa (Fig. 1B).
Previously, we showed that 125I-labeled TARC specifically
bound to a single class of receptors expressed on a human T cell line
Jurkat with a Kd of 2.1 nM (17).
Importantly, the binding was competed only by TARC and not by any other
chemokines so far tested. To verify specificity and affinity of
TARC-SEAP(His)6 for TARC receptors, we carried out
TARC-SEAP(His)6 binding experiments using another human T cell line Hut78. The binding of TARC-SEAP(His)6 was fully
competed by unlabeled TARC with an IC50 of 0.5 nM (Fig. 2A). CC chemokines such
as MCP-1, MIP-1, or MIP-1
did not show any significant competition with TARC-SEAP(His)6 (Fig. 2B).
RANTES and LARC, however, partially (<30%) inhibited
TARC-SEAP(His)6 binding. Such partial inhibition by
heterologous chemokines was not, however, seen with Jurkat using either
125I-labeled TARC (17) or TARC-SEAP(His)6 (data
not shown). These results may indicate that Hut78 expresses at least
two types of TARC receptors, one highly specific for TARC and another
shared by RANTES and LARC. At any rate, the present results were highly consistent with those obtained previously by using
125I-labeled TARC. Thus, TARC-SEAP(His)6 was
proven to retain its ability as a specific high affinity ligand for
TARC receptors.2
CCR4 Is a High Affinity Specific Receptor for TARC
Since TARC
was shown not to share the major class of its high affinity binding
sites on T cells with other CC chemokines that are known to bind to one
or more CCRs (17), we first tested the binding of
TARC-SEAP(His)6 to orphan receptors such as EBI1 (48), BLR1
(49), V28 (50), GPR-9-6 (GenBank accession number: HSU45982), GPR-CY4
(GenBank accession number: HSU45984), and LESTR/fusin (51). LESTR/fusin
is now known as the receptor for SDF-1/PBSF (CXCR4) (52, 53).
TARC-SEAP(His)6 showed no significant binding to Raji,
293/EBNA-1, or K562 cells stably transfected with any of these orphan
receptors (data not shown). In parallel experiments, we also examined
the binding of TARC-SEAP(His)6 to the five CC chemokine
receptors that are known to be shared by several CC chemokines (CCR1 to
-5). Surprisingly, TARC-SEAP(His)6 specifically bound to
CCR4 expressed on K562 (Fig. 3), Raji, and 293/EBNA-1 (not shown). To further characterize the binding of TARC to CCR4, experiments were performed using K562 cells stably expressing CCR4.
When the binding was performed with increasing concentrations of
TARC-SEAP(His)6 (Fig. 4A), a
single class of receptors with a Kd of 0.5 nM and 29,000 sites/cell was demonstrated (Fig.
4B). Competition experiments showed that unlabeled TARC fully competed with TARC-SEAP(His)6 for CCR4 (Fig.
4C). In contrast, other CC chemokines such as RANTES, MCP-1,
MIP-1, MIP-1
, and LARC showed no significant competition with
TARC-SEAP(His)6 for CCR4 (Fig. 4D). Similar
results were obtained using Raji or 293/EBNA-1 cells stably transfected
with CCR4 (data not shown). Collectively, the binding characteristics
of TARC-SEAP(His)6 to CCR4 were highly consistent with
those obtained with the major class of the endogenous TARC receptors
expressed on T cells (Fig. 2) (17).
We next compared direct binding of TARC-SEAP(His)6, RANTES,
MCP-1, and MIP-1 to CCR4-transfected cells (Fig. 5).
In these experiments, murine L1.2 cells transfected with CCR4 were used (38). As expected, TARC-SEAP(His)6 specifically bound to
CCR4-transfected L1.2 cells at levels about 20-fold higher than those
obtained with Hut78 cells that express endogenous TARC receptors at
1000-2000 sites/cell (Fig. 2). In contrast, RANTES, MCP-1, or MIP-1
bound to CCR4-transfected L1.2 cells at marginal levels, if any,
although these chemokines efficiently bound to THP-1 cells that express endogenous receptors at 1000-5000 sites/cell (1). These results further strengthen the possibility that TARC is the physiological ligand for CCR4.
TARC Induces Chemotaxis in CCR4-transduced Cells
Previously,
we showed that TARC induced chemotaxis in certain human T cell lines
(17). We therefore examined whether TARC also induced migration of
cells expressing transfected CCR4. 293/EBNA-1 cells were stably
transfected with CCR4 or CCR1, and migration of these cells to TARC,
MIP-1, and RANTES was examined. As shown in Fig. 6,
TARC induced migration of cells transfected with CCR4 but not those
transfected with CCR1. On the other hand, MIP-1
and RANTES induced
migration of cells transfected with CCR1 but not those transfected with
CCR4. Parental 293/EBNA-1 cells or those transfected with the vector
alone did not respond to TARC, MIP-1
, or RANTES (data not shown).
Migration of CCR4-transfected 293/EBNA-1 cells to TARC was
concentration-dependent, being promoted at concentrations
from 10 to 1000 ng/ml. Desensitization was observed at 10 µg/ml (not
shown). A checkerboard analysis indicated that the migration of
CCR4-transfected 293/EBNA-1 cells toward TARC was mostly chemotactic
but partly (~40%) chemokinetic (data not shown). Collectively, TARC
but not MIP-1
or RANTES is a functional ligand for CCR4.
TARC Induces Calcium Mobilization in CCR4-transduced Cells
We
next examined induction of calcium mobilization in K562 cells
expressing CCR4, CCR1, or CCR2B (Fig. 7A).
TARC induced calcium flux in K562 cells expressing CCR4, whereas
RANTES, MIP-1, or MCP-1 did not. In addition, TARC, but not RANTES,
MIP-1
, or MCP-1, was able to desensitize the cells expressing CCR4
for subsequent stimulation with TARC (Fig. 7A and data not
shown). On the other hand, K562 cells expressing CCR1 responded to
MIP-1
but not to TARC, whereas K562 cells expressing CCR2B responded
to MCP-1 but not to TARC. Parental K562 cells or those transfected with
the vector alone did not show any response to TARC, RANTES, MIP-1
, or MCP-1 (data not shown). Responses to TARC were detectable above 1 nM, and maximum values were obtained at 100 nM
with an EC50 of 8 nM (Fig. 7B). We
further confirmed that TARC at 100 nM did not induce
calcium fluxes in CCR1, CCR2B, CCR3, or CCR5-transfected K562 cells,
while MIP-1
induced calcium fluxes in CCR1- and CCR5-transfected cells, MCP-1 in CCR2B-transfected cells, and eotaxin in
CCR3-transfected cells (data not shown). Similar results were obtained
by using 293/EBNA-1 cells. These observations again demonstrated that
TARC is a functional ligand for CCR4.
CCR4 Is Expressed Mainly in CD4+ T Cells
Previously, we showed that high levels of binding sites for
TARC were detected on certain T cell lines and peripheral blood T cells
but not on peripheral monocytes or granulocytes (17). To determine the
cell types that express CCR4, we performed Northern blot analysis. As
shown in Fig. 8A, CCR4 mRNA was strongly
expressed in T cell lines such as Hut78, Hut102, and Jurkat, all having been shown to display high levels of TARC binding sites (17). A
basophilic cell line KU812 that was originally used to clone CCR4
cDNA (39) and a megakaryocytic cell line MEG-1 were also found to
express CCR4 mRNA. On the other hand, CCR4 mRNA was
undetectable in THP-1, U937, Raji, K562, and HL-60, all having been
shown to possess negligible, if any, binding sites for TARC (17). In normal peripheral blood mononuclear cells (Fig. 8B), CCR4
mRNA was expressed in T cells, especially CD4+ T cells,
but not in B cells, NK cells, monocytes, or granulocytes. The
expression pattern of CCR4 is thus highly consistent with the T
cell-selective expression of the endogenous TARC receptor described
previously (17).
Although a number of chemokines are known to act on T cells (54-61), TARC appears to be the first CC chemokine highly selective for T cells (17). High levels of constitutive expression of TARC have been detected only in thymus and not in spleen. High levels of specific binding sites for TARC have been detected on some T cell lines and peripheral blood T cells but not on monocytes or granulocytes. TARC has been shown to induce chemotaxis in certain human T cell lines. Furthermore, a class of TARC receptors expressed on T cells is highly specific for TARC and not shared by any other CC or CXC chemokines that are known to act on T cells (17). Here we have presented several lines of evidence indicating that CCR4 is the major class of receptors for TARC that is selectively expressed on T cells and not shared by other CC or CXC chemokines.
CCR4 was originally cloned by Power et al. from a human
basophilic cell line KU-812 (39). The CC chemokines, MIP-1, RANTES, and MCP-1, were presumed to be the functional ligands for CCR4, because
among various chemokines, only these were able to activate a
calcium-dependent chloride channel in Xenopus
laevis oocytes injected with CCR4 cRNA. However, induction of
chemotaxis or calcium flux in CCR4-transfected mammalian cells by
MIP-1
, RANTES, MCP-1, or any other chemokines has not been
demonstrated. Here we have shown that introduction of the CCR4 cDNA
into Raji, 293/EBNA-1, and K562 cells induced a class of high affinity
binding sites for TARC (Figs. 3 and 4). Binding of TARC to CCR4 was
competed only by TARC and not by any other chemokines including
MIP-1
, RANTES, and MCP-1 (Fig. 4). Binding of
125I-labeled RANTES, MCP-1, or MIP-1
to CCR4 were
marginal, if any, while they bound to endogenous receptors expressed on
THP-1 cells efficiently. (Fig. 5). Furthermore, only TARC but not
RANTES, MCP-1, or MIP-1
induced chemotaxis in CCR4-transfected
293/EBNA-1 and induced calcium flux in CCR4-transfected 293/EBNA-1 and
K562 (Figs. 6 and 7). Collectively, these results have clearly
demonstrated that TARC is the specific functional ligand for CCR4. The
discrepancy between Power et al. (39) and the present study
is probably due to the assay system used in the former study,
i.e. activation of a calcium-dependent chloride
channel in Xenopus laevis oocytes injected with CCR4 cRNA.
Besides CCR4, however, some T cells may also express a class of
receptors for TARC that is shared by RANTES and LARC (Fig. 2).
Compared with the high affinity value obtained from binding of TARC-SEAP(His)6 to CCR4 (Kd = 0.5 nM), the potency of TARC in induction of chemotaxis in CCR4-transfected 293/EBNA-1 (EC50 = 10 nM) or in calcium flux in CCR4-transfected K562 cells (EC50, 8 nM) appeared to be considerably less. Previously, we observed that TARC induced chemotactic responses in two human T cell lines Hut78 and Hut102 with an EC50 of about 2 nM (17). Types and/or efficiency of G-proteins coupling to CCR4 may be different depending on the cell background. SDF-1/PBSF is another chemokine that was reported to require high concentrations in induction of chemotaxis in lymphocytes and monocytes (53). Recently, Monteclaro and Charo proposed a two-step mechanism for activation of the MCP-1 receptor CCR2 in which high affinity binding of MCP-1 with the receptor amino terminus allows subsequent low affinity interactions with the extracellular loops/transmembrane domains that lead to receptor activation and signaling (62). A similar two-step mechanism may apply to high affinity binding versus relatively low potency in activation of CCR4 by TARC. Furthermore, like I-309 that was shown to be much more potent in inhibition of glucocorticoid-induced apoptosis of murine T cell lymphomas than in induction of chemotaxis in human THP-1 monocytic cells (63), TARC may be more potent in some biologic activities other than induction of chemotaxis or calcium mobilization.
Although several chemokine receptors are known to be expressed on T cells, CCR4 appears to be the first CC chemokine receptor highly selective for T cells. By Northern blot analysis, CCR4 mRNA was detected highly selectively in some T cell lines and peripheral blood T cells, especially CD4+ T cells, but not in B cells, NK cells, monocytes, or granulocytes (Fig. 8). Previously, Power et al. (39) also demonstrated by Northern blot analysis that CCR4 was expressed strongly in thymus and peripheral blood leukocytes but very weakly in spleen. However, they further demonstrated by reverse transcriptase-PCR analysis that CCR4 was expressed not only in T cells but also in B cells and monocytes. Taken together, T cells are the cells that express CCR4 at high levels, but other types of leukocytes may also express CCR4 at low levels detectable by reverse transcriptase-PCR. The selective expression of CCR4 on T cells is thus consistent with the fact that T cells are the major target of TARC. Furthermore, the fact that TARC and CCR4 are both constitutively and strongly expressed in thymus further supports their important roles in trafficking and education of thymocytes within the thymus.
Notably, we also detected expression of CCR4 in a basophilic cell line KU812 and a megakaryocytic cell line MEG-1 (Fig. 8). In fact, CCR4 was originally cloned from KU812, and, by using reverse transcriptase-PCR, Power et al. (39) demonstrated expression of CCR4 in fresh basophils, especially after brief treatment with IL-5. They also mentioned that platelets contain high levels of CCR4 mRNA (39, 64). We have also detected high levels of TARC-binding sites on platelets (data not shown). Thus, it is clear that cells of the megakaryocyte/platelet lineage also express CCR4. It remains to be seen whether TARC affects differentiation and/or function of basophils and megakaryocytes/platelets besides T cells.
It is also noteworthy that high levels of CCR4 expression are observed only in certain human T cell lines and peripheral blood T cells of especially the CD4 type. CCR4 may thus be expressed selectively in particular subsets of T cells and/or in particular stages of differentiation and/or activation of T cells. Cultured CD45RO+ T cells were shown to express CCR1 and CCR2 in a strictly IL-2-dependent manner (65). Both CD4+ and CD8+ T cells were shown to constitutively express CCR5 (41). Activated T cells were shown to express CXCR3, the first T cell-selective CXC chemokine receptor shared by IP-10 and Mig (66). It is thus important to determine phenotypes of T cells that express CCR4 and conditions that regulate CCR4 expression. Obviously, elucidation of the physiological roles of the TARC/CCR4 system will be greatly facilitated by generation of mutant mice lacking the respective genes.
We thank Dr. Craig Gerard for providing L1.2, and T. Nakajima and M. Kitaura for valuable help. We also thank Dr. Y. Himuna and Dr. M. Hatanaka for constant support.