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CHEMOKINES
From the Departments of Microbiology and Internal
Medicine III, Kinki University School of Medicine, Department of
Neurology, Tohoku University School of Medicine, Department of
Laboratory Medicine, Nagasaki University School of Medicine, Department
of Molecular Preventive Medicine, Tokyo University School of Medicine,
Department of Internal Medicine, Ehime University School of Medicine,
Japan.
Chemokines and chemokine receptors play important roles in
migration and tissue localization of various lymphocyte subsets. Here,
we report the highly frequent expression of CCR4 in adult T-cell
leukemia (ATL) and human T-cell leukemia virus type 1 (HTLV-1)-immortalized T cells. Flow cytometric analysis revealed that
ATL and HTLV-1-immortalized T-cell lines consistently expressed CCR4.
Inducible expression of HTLV-1 transcriptional activator tax in a human
T-cell line Jurkat did not, however, up-regulate CCR4 mRNA. In vitro
immortalization of peripheral blood T cells led to preferential
outgrowth of CD4+ T cells expressing CCR4. We further
demonstrated highly frequent expression of CCR4 in fresh ATL cells by
(1) reverse transcriptase-polymerase chain reaction (RT-PCR) analysis
of CCR4 expression in peripheral blood mononuclear cells (PBMCs) from
patients with ATL and healthy controls; (2) flow cytometric
analysis of CCR4-expressing cells in PBMCs from patients with ATL and
healthy controls; (3) CCR4 staining of routine blood smears from
patients with ATL; and (4) an efficient migration of fresh ATL cells to
the CCR4 ligands, TARC/CCL17 and MDC/CCL22, in chemotaxis assays.
Furthermore, we detected strong signals for CCR4, TARC, and MDC in ATL
skin lesions by RT-PCR. Collectively, most ATL cases have apparently
derived from CD4+ T cells expressing CCR4. It is now
known that circulating CCR4+ T cells are mostly polarized
to Th2 and also contain essentially all skin-seeking memory T
cells. Thus, HTLV-1-infected CCR4+ T cells may have growth
advantages by deviating host immune responses to Th2. CCR4 expression
may also account for frequent infiltration of ATL into tissues such as
skin and lymph nodes.
(Blood. 2002;99:1505-1511) Human T-cell leukemia virus type 1 (HTLV-1) is the
causative agent of adult T-cell leukemia (ATL), a unique malignancy of mature CD4+ T cells with characteristic lobular nuclei and
surface activation markers such as CD25.1,2 In vitro,
HTLV-1 efficiently immortalizes CD4+ T cells into
continuously growing T-cell blasts.3 HTLV-1 is vertically
transmitted from mother to child through breast feeding and also
horizontally by sexual contact. Asymptomatic carriers contain a large
number of HTLV-1-infected cells which are mostly CD4+CD45RO+ T cells.4 With about
5% life risk, ATL develops in HTLV-1 carriers after 40 to 50 years of
latency.2 This implies that ATL develops from
HTLV-1-infected T cells after accumulation of multiple critical
mutations.5 HTLV-1 is also etiologically associated with
various chronic inflammatory diseases such as HTLV-1-associated
myelopathy/tropical spastic paraparesis, HTLV-1-associated uveitis,
HTLV-1-associated bronchopneumopathy and HTLV-1-associated arthrophathy.2
Chemokines are a group of structurally related cytokines that induce
directed migration of various leukocyte populations.6 In
humans, more than 40 chemokines have been identified. Based on the
arrangement of the N-terminal conserved cysteine residues, chemokines are classified into 4 subfamilies: CC, CXC, C, and CX3C. All
chemokines transduce signals through 7 transmembrane G protein-coupled
receptors. At present, 18 chemokine receptors have been
identified.6 It is now known that chemokines are crucially
involved in migration and tissue localization of various lymphocyte
subpopulations, which express specific chemokine receptors in
accordance with their differentiation pathways and maturation stages.6 In ATL, leukemic cells frequently infiltrate into organs such as lymph nodes, spleen, liver, and skin.2
Various HTLV-1-associated inflammatory diseases are also commonly
characterized by infiltration of HTLV-1+ T cells into
target organs.2 It is thus conceivable that chemokines and
their receptors play important roles in tissue infiltration of ATL
cells and HTLV-1+ T cells. Previously, we have shown that
increased surface expression of CCR7, the shared receptor for SLC/CCL21
and ELC/CCL19, which are both expressed in the secondary lymphoid
organs,7,8 correlates well with lymphoid organ involvement
in ATL.9 In the present study, we have extended this
observation and demonstrated highly frequent expression of CCR4 in
HTLV-immortalized T cells and fresh ATL. It is now known that
peripheral blood T cells expressing CCR4 are mostly polarized to Th2
and also include essentially all skin-seeking memory T cells
positive for cutaneous lymphocyte antigen (CLA).10-12
Thus, our findings may provide new clues to understanding various
aspects of ATL and HTLV-1-associated diseases such as suppression of
cell-mediated immunity and frequent involvement of tissues such as skin
and lymph nodes.
Chemokines and monoclonal antibodies
Cells and tissues
Flow cytometry Cells were washed with phosphate buffered saline (PBS) containing 2% fetal calf serum (FCS) and incubated for 30 minutes with mAbs or control isotype-matched murine IgG. The primary antibodies were detected by FITC-conjugated sheep (Fab')2 antimouse IgG (Sigma, St Louis, MO). For double staining, cells were incubated with FITC-labeled anti-CCR4 and PerCP-labeled anti-CD4 or PE-labeled anti-CD25. If necessary, dead cells were stained with propidium iodide (PI) and gated out. Cells were analyzed on a FACS Calibur (Becton Dickinson, Mountain View, CA), and the data were collected in the log mode. In each sample, 10 000 cells were analyzed.In vitro immortalization Immortalization of peripheral blood T cells with HTLV-1 was carried out by the coculture method.3 In brief, PBMCs from adult donors and MT-2 cells pretreated with mitomycin C (Sigma) at 50 µg/mL at 37°C for 1 hour were cocultured in 96-well microtest plates at 100 cells/well and 2 × 104 cells/well, respectively. After 10 days, interleukin 2 (IL-2) was added to each culture at 100 U/mL. After about a month, growing cultures were individually expanded and examined for expression of surface molecules by flow cytometry.CCR4 staining in blood smear Routine blood smears were fixed with ice-cold acetone and blocked with PBS containing 3% normal horse serum. After washing, slides were incubated first with anti-CCR4 (KM2160) or isotype-matched control mouse IgG and then with biotinylated horse anti-mouse IgG (Vector, Burlingame, CA). After treatment with 0.3% H2O2, slides were incubated with avidin-biotin complex (Vector) and developed with diaminobenzidine (DAB) (Sigma). Slides were counterstained by Gill hematoxylin.RT-PCR analysis Total RNA was prepared from cells or tissues by using Trizol reagent (GIBCO-BRL, Gaithersburg, MD). RNA was further purified by using RNeasy (Qiagen, Hilden, Germany). Genome DNA was also prepared from the same tissues following the instruction manual for Trizol reagent. Total RNA (1 µg) was reverse transcribed using oligo(dT)18 primer and SuperScript II reverse transcriptase (GIBCO-BRL). Resulting first-strand DNA (20 ng total RNA equivalent), original total RNA (20 ng), and genome DNA (200 ng) were amplified in a final volume of 20 µL containing 10 pmol of each primer and 1 unit of Ex-Taq polymerase (Takara Shuzo, Kyoto, Japan).The primers used were: +5'-ACTGCTCCAGGGATGCCATCGTTTTT-3' and -5'-ACAAGGGGATGGGATCTCCCTCACTG-3' for TARC; +5'-AGGACAGAGCATGGCTCGCCTACAGA-3' and -5'-TAATGGCAGGGAGGTAGGGCTCCTGA-3' for MDC; +5'-AAGAAGAACAAGGCGGTGAAGATG-3' and -5'-AGGCCCCTGCAGGTTTTGAAG-3' for CCR4; +5'-GTGCCCGCGTCCTTCTCATCAG-3' and -5'-GGCCAGGACCACCCCATTGTAG-3' for CCR7; +5'-AAAAAGCGGGTCACTCTATATGCTC-3' and -5'-CCACTGCTACCTGGTACTCTGTTGT-3' for IL-2R (CD25);
+5'-ATCCCGTGGAGACTCCTCAA-3' and -5'-AACACGTAGACTGGGTATCC-3' for Tax;
+5'-GCCAAGGTCATCCATGACAACTTTGG-3' and -5'-GCCTGCTTCACCACCTTCTTGATGTC-3' for glyceraldehyde 3-phosphate dehydrogenase (G3PDH). Amplification conditions were denaturation at 94°C for 30 seconds (5 minutes for
the first cycle), annealing at 60°C for 30 seconds and extension at
72°C for 30 seconds (5 minutes for the last cycle) for 34 cycles for
MDC and TARC, 35 cycles for CCR4 and CCR7, 37 cycles for IL-2R, 38 cycles for Tax, and 27 cycles for G3PDH. Amplification products (10 µL each) were subjected to electrophoresis on 2% agarose and stained
with ethidium bromide.
Chemotaxis assay Chemotaxis assay was carried out using Transwell plates with 3-µm pore size (Coster, Cambridge, MA). Cells were suspended at 2 × 107/mL in RPMI-1640 containing 1 mg/mL bovine serum albumin (BSA) and 20 mM HEPES, pH 7.4. Cells were applied to upper wells (200 µL/well). Lower wells contained chemokines at various concentrations (600 µL/well). After 3 hours at 37°C, cells migrated into lower chambers were counted by flow cytometry.
Flow cytometric analysis on surface expression of chemokine receptors Using a panel of 24 human T-cell lines, we examined the surface expression of CXCR4, CCR4, and CCR7 by flow cytometry. The results are summarized in Table 1. Based on the expression of CD4 and CD8, HTLV-1 leukemic T-cell lines
were further divided into 3 groups: double-negative, double-positive
and CD4+.13 On the other hand, ATL-derived
leukemic cell lines and HTLV-1-transformed T-cell lines were
consistently CD4+. CXCR4 was consistently expressed in all
HTLV-1 T-cell lines (15/15) and HTLV-1-immortalized
T-cell lines (5/5). However, only a fraction of ATL-derived leukemic
cell lines were positive for CXCR4 (2/4). CCR7 was mostly negative in
HTLV-1 T-cell lines (4/15). On the other hand, most
ATL-derived leukemic cell lines (3/4) and all HTLV-1-immortalized
T-cell lines were positive for CCR7 (5/5). Concerning CCR4, some
double-negative T-cell lines were clearly positive (2/4), whereas
double-positive T-cell lines were all negative (0/6). Some
HTLV-1 CD4+ T-cell lines were marginally
positive (3/5). However, HUT78, a mature T-cell line derived from a
patient with cutaneous T-cell lymphoma (Sezary syndrome), was strongly
positive. Rather strikingly, ATL-derived leukemic T-cell lines and
HTLV-1-immortalized T-cell lines were consistently found to express
CCR4 at high levels (4/4 and 5/5, respectively).
No induction of CCR4 or CCR7 by Tax Consistent expression of CCR4 in HTLV-1+ T-cell lines may be due to induction of CCR4 by the viral transactivator tax. To test this possibility, we used JPX-9, a Jurkat subline carrying HTLV-1 tax under the control of the metallothionine gene promoter.14 This cell line has been widely used to demonstrate induction of various cellular target genes by tax.14 As shown in Figure 1, JPX-9 constitutively expressed CCR4 and CCR7 mRNA. Upon treatment with Cd2+, tax mRNA was induced in JPX-9. Accordingly, IL-2R
(CD25), a tax-responsive cellular gene,2 was induced.
However, there was no up-regulation of CCR4 or CCR7 mRNA even after 7 days of treatment. In fact, CCR4 mRNA was slightly down-regulated upon induction of tax with Cd2+. Thus, at least in the cellular
background of Jurkat, tax does not up-regulate expression of CCR4
or CCR7.
Preferential outgrowth of CCR4+ T cells upon immortalization with HTLV-1 We next examined whether T cells freshly immortalized by HTLV-1 expressed CCR4. For this purpose, we carried out immortalization of PBMCs by HTLV-1 at a limiting cell concentration (100 PBMCs cocultured with MMC-treated MT-2/well). By this way, rare outgrowing cultures might be mostly monoclonal. A total of 17 immortalized CD4+ T-cell lines were thus obtained starting with 960 wells, and all turned out to be positive for CCR4 by flow cytometric analysis (data not shown). Thus, CD4+ T cells expressing CCR4 may be either preferentially infected by HTLV-1 and/or, upon HTLV-1 infection, may have some in vitro growth advantages over CCR4 T cells.
Expression of CCR4 on fresh ATL We next examined expression of CCR4 in fresh leukemic cells from patients with ATL. We first carried out RT-PCR analysis on CCR4 expression in PBMCs from a total of 13 healthy adult donors and 24 patients with ATL (16 acute and 8 chronic cases) (Table 2). Representative results are shown in Figure 2. Whereas PBMCs from healthy donors gave only weak signals for CCR4, strong signals were consistently observed for PBMCs from most patients with ATL (22/24). In the case of CCR7, however, no such consistent differences between healthy donors and patients with ATL were observed (Figure 2). Since peripheral blood samples from all these patients with ATL contained leukemic cells at high frequencies (15%-97%, average 62%), these results supported that leukemic cells from most ATL cases were positive for CCR4. Two patients with ATL (one acute and one chronic), however, gave only weak CCR4 signals. Since PBMCs from these 2 patients also contained leukemic cells at high frequencies (60%-70%), their ATL cells were likely to be negative for CCR4. Table 2 summarizes the results together with the clinical profiles of each patient.
We next carried out CCR4 staining and flow cytometric analysis of PBMCs
from a total of 4 healthy adult donors and 10 patients with ATL.
Representative results are shown in Figure
3 (A, ATL; B, healthy). Compared with
PBMCs from healthy adult donors, PBMCs from most ATL cases (8/10)
indeed contained a large fraction of cells expressing CCR4 (right upper
panel). Double staining with anti-CD25 or anti-CD4 demonstrated that
CCR4-expressing cells were largely positive for CD25 (right lower
panel) and CD4 (left lower panel). Thus, the majority of
CCR4-expressing cells in PBMCs from patients with ATL were likely to be
leukemic cells. However, 2 patients showed little significant increases
in CCR4-expressing cells in their peripheral blood. These 2 patients
also gave only a weak signal for CCR4 by RT-PCR analysis (data not
shown). Thus, ATL cells from these 2 patients were likely to be
negative for CCR4.
Since ATL cells have characteristic flowerlike nuclei, it is rather
easy to identify ATL cells in blood smears. We therefore further
carried out immunologic staining of CCR4 using routine blood smears
from a total of 7 patients with ATL. Representative results are shown
in Figure 4. Again, most ATL cases (6/7)
were clearly stained positive for CCR4 (A, B, C: positive; D:
negative).
Collectively, a total of 40 ATL cases were examined by at least one of the 3 different techniques described above and 36 cases were concluded to be positive for CCR4. Chemotactic response of fresh ATL cells to CCR4 ligands We next examined whether fresh ATL cells were capable of responding to the CCR4 ligands, TARC/CCL17 and MDC/CCL22,15,16 in a chemotactic assay using a Transwell plate. A total of 8 ATL cases (4 acute and 4 chronic) were studied. Representative results are shown in Figure 5. We observed an efficient migration of PBMCs from all patients with ATL (8/8) toward TARC and MDC with a typical bell-shaped dose-response curve and an optimal concentration of about 1 nM. No such vigorous migration was observed by using fresh PBMCs from healthy adult donors in the present conditions. Thus, it is likely that the responding cells were mostly leukemic cells. To confirm this, we carried out a cytologic evaluation of cells migrated into the lower chambers. As shown in Figure 6, Giemsa staining of cytospin samples confirmed that migrated cells from PBMCs of patients with ATL were indeed mostly abnormal cells with characteristic flowerlike nuclei. Thus, fresh ATL cells expressing CCR4 are capable of efficiently responding to the CCR4 ligands TARC and MDC.
ATL skin lesions ATL frequently invades skin.2,17 Accumulating evidence supports that CCR4 and its ligands TARC and MDC play important roles in T-cell infiltration into skin.12,18-20 It is thus possible that frequent skin invasion in ATL may be facilitated by expression of CCR4 on ATL cells and production of TARC and/or MDC in lesional skin tissues. To test this notion, we examined expression of CCR4, TARC, and MDC in normal skin tissues from 3 donors and lesional skin tissues from 4 patients with ATL by RT-PCR. As shown in Figure 7, normal skin tissues hardly contained mRNA for TARC, MDC, or CCR4. On the other hand, ATL skin lesions gave strong signals of TARC, MDC, and CCR4. Detection of tax DNA by PCR supported that these ATL skin lesions were indeed invaded by cells carrying HTLV-1. Thus, expression of CCR4 by ATL cells and production of the CCR4 ligands in local skin tissues may facilitate invasion of ATL cells into lesional skin tissues.
Besides cell adhesion molecules, chemokines and chemokine
receptors are likely to play important roles in in vivo spread and tissue localization of various tumors.21 Therefore, it is
of great interest to determine the patterns of chemokine receptor expression in various types of leukemia and lymphoma. Jones et al have
reported that all types of B-cell lymphoma express CXCR5 whereas
certain distinct subtypes of B-cell lymphoma (ie, chronic lymphocytic
leukemia/small lymphocytic lymphoma and splenic marginal zone lymphoma)
also express CXCR3.22 Trentin et al have also demonstrated
frequent expression of CXCR3 in malignant B cells, especially chronic
lymphocytic leukemia.23 CXCR5 is the receptor for an
important B-cell attractant, BLC/CXCL13, which is expressed in the
lymphoid follicles.24,25 During normal B-cell
differentiation and maturation, CXCR5 has been shown to be expressed by
pro-B cells and all stages of mature B cells.26 On the
other hand, CXCR3 is the shared receptor for IP-10/CXCL10, Mig/CXCL9,
and I-TAC/CXCL11, all commonly induced by interferon gamma
(IFN- ATL is a malignancy of mature T cells and is particularly notorious for
its highly frequent invasion into various organs.2 Previously, various cell adhesion molecules have been implicated in
tissue infiltration of ATL cells.32-35 Recently, we have
shown that high levels of expression of CCR7 in ATL, the receptor for SLC/CCL21 and ELC/CCL19 commonly expressed in the secondary lymphoid organs,7,8 correlates positively with lymphoid organ
involvement.9 In the present study, we have further shown
that HTLV-1-immortalized T cells and fresh ATL cells frequently
express CCR4. The HTLV-1-encoded transactivator tax is a potent
inducer of cellular target genes including various cell adhesion
molecules and chemokines.34,36-40 However, it does not
up-regulate CCR4 or CCR7 at least in the cellular background of Jurkat
(Figure 1). Thus, highly frequent expression of CCR4 in ATL and
HTLV-1-immortalized T cells may be due to preferential infection of
HTLV-1 to CCR4+ T cells and/or some growth advantages of
HTLV-1-infected CCR4+ T cells in vivo as well as in vitro.
Since CCR4+ T cells are considered to be mostly polarized
to Th2,10,11 the production of Th2-type cytokines by
HTLV-1-infected T cells may help them to avoid immunologic attacks in
vivo by shifting the host Th1/Th2 balance to Th2. In fact, suppression
of cell-mediated immunity has been well documented in HTLV-1 carriers
and patients with ATL.41-43 Even though previous studies
on the cytokine profiles of ATL cell lines and HTLV-1-immortalized T
cells do not particularly support a shift to Th2,44,45
similar studies using freshly isolated cells from carriers and patients
with ATL may be necessary to test this possibility. It should also be
noted that not all ATL cases are CCR4+. This may be due to
down-regulation of CCR4 during development of ATL in some patients or
development of ATL from CCR4 As stated above, CCR4 is the receptor for TARC/CCL17 and
MDC/CCL22.15,16 Consistent with Th2-selective expression
of CCR4,10,11 TARC has been shown to be produced by
epidermal keratinocytes in atopic dermatitis and by bronchial
epithelium in asthma, both typical Th2-type diseases.18,46
On the other hand, MDC has been shown to be produced by dermal
dendritic cells and also by mature dendritic cells in draining regional
lymph nodes.18,20,47 Furthermore, Campbell et al have
reported that essentially all CLA+ skin-seeking memory T
cells are CCR4+, whereas microvascular endothelium in
inflammed skin tissues express TARC.12 Andrew et al have
also demonstrated that CCR4 is expressed by the majority of circulating
nonintestinal ( In spite of highly frequent expression of CCR4 on ATL cells, however, only a fraction of patients have skin lesions (Table 2). It is thus evident that CCR4 positivity of leukemic cells per se is not sufficient for skin invasion. Other factors such as expression of CLA by leukemic cells and inflammatory responses in lesional skin leading to up-regulation of TARC and MDC are also likely to contribute to skin involvement of ATL.20,48 It should also be pointed out that together with CCR7,9 CCR4 may also facilitate ATL cells to invade the secondary lymphoid organs where mature dendritic cells are known to produce MDC.20,47 In conclusion, we have demonstrated a highly frequent expression of CCR4 on ATL and HTLV-1-infected T cells. This suggests that HTLV-1 is preferentially transmitted to CCR4-expressing Th2 cells and/or HTLV-1-infected Th2 cells have certain growth advantages. Our findings may also provide a new clue to understand certain aspects of ATL and HTLV-1-associated diseases such as frequent tissue involvement and suppression of Th1-mediated immune responses.
We are grateful to Kazuyuki Sugahara and Kazuto Tsuruda for their excellent technical assistance.
Submitted June 26, 2001; accepted October 17, 2001.
Supported by Grants-in-Aid for Science Research from the Ministry of Education, Culture, Sports, Science and Technology, Japan.
The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked "advertisement" in accordance with 18 U.S.C. section 1734.
Reprints: Osamu Yoshie, Department of Microbiology, Kinki University School of Medicine, 377-2 Ohno-Higashi, Osaka-Sayama, Osaka 589-8511, Japan; e-mail: o.yoshie{at}med.kindai.ac.jp.
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Abstract
Introduction
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