Báo cáo Y học: Repression of FasL expression by retinoic acid involves a novel mechanism of inhibition of transactivation function of the nuclear factors of activated T-cells pptx
RepressionofFasLexpressionbyretinoicacidinvolvesa novel
mechanism ofinhibitionoftransactivationfunctionofthe nuclear
factors ofactivated T-cells
Mi-Ock Lee
1,
*, Hyo-Jin Kang
1,
*, Young Mi Kim
1
, Ji-Hyun Oum
2
and Jungchan Park
2
1
Department of Bioscience and Biotechnology, Institute of Bioscience, Sejong University, Seoul, Korea;
2
Department of Bioscience
and Biotechnology, Hankuk University of Foreign Studies, Kyounggi-do, Korea
Retinoids are potent immune modulators that inhibit Fas
ligand (FasL) e xpression and t hereby repress t he activation -
induced apoptosis of immature thymocytes and T-cell
hybridomas. In this study, we demonstrate that all-trans-
retinoic acid ( all-trans-RA) directly represses t he transcrip-
tional activity ofthenuclearfactorsofactivated T-cells
(NFAT), which is an important transactivator ofthe FasL
promoter. The analysis of reporter constructs containing the
FasL promoter and wild-type or mutant NFAT binding-
sites indicated that all-trans-RA repression was mediated via
an NFAT binding element located in the promoter. A
reporter construct comprising the NFAT binding sequence
linked to a heterologous SV-40 promoter showed that
NFAT transc riptional activity was significantly inhibited by
all-trans-RA. Furthermore, all- trans-RA inhibited a ctiva-
tion ofthe distal NFAT binding motif present in the inter-
leukin (IL)-2 p romoter, s uggesting that t he inhibition of
NFAT functionby all-trans-RA was not specific to the FasL
promoter. Gel shift assays corroborated the results of the
gene reporter studies by showing that all-trans-RA decreased
the NFAT binding to DNA. All-trans-RA blocked trans-
location of NFATp from the cytosol into the nucleus, which
was induced by PMA/ionomycin treatment in HeLa cells
transfected with a Flag-tagged NFATp. Taken together, our
results indicate that FasLinhibitionby all-trans-RA involves
a novelmechanism whereby the transcriptional function of
NFAT is blocked.
Keywords: r etinoic acid; NFAT; FasL.
The CD95 (Fas) ligand (FasL) is a type-II transmembrane
protein expressed on highly activated T-lymphocytes [1,2].
Activated T-lymphocytes undergo apoptosis following
homotypic interaction of F asL and its receptor, Fas [3–5].
Thus, the elimination of highly activatedT-cellsbythe Fas/
FasL system is critical for the downregulation of immune
responses, the homeostasis of lymphocytes, and the main-
tenance of peripheral tolerance. Retinoids, vitamin A and its
natural and synthetic derivatives, regulate a wide array of
biological processes, includin g cellular proliferation, differ-
entiation, and immune modulation. All-trans-retinoic acid
(RA) and 9 -cis-RA inhibit FasL e xpression, and thereby
suppress the activation-induced apoptosis of immature
thymocytes and T -cell hybridomas [ 6–9]. The inhibitory
effects o f RA are mediated through two classes of nuclear
receptors, retinoica cid receptors (RARs) and retinoid X
receptors (RXRs), both of which are ligand-dependent
transcriptional factorsofthe steroid/thyroid hormone
receptor superfamily [9–11]. However, the molecular details
of RA-mediated repressionofFasL gene expression have
not been elucidated.
Nuclear factorsofactivatedT-cells (NFAT) is a family of
related transcription factors that play a c entral role in
regulating the immune response by modulating the expres-
sion of important cytokines such as interleukin (IL)-2 in the
activated T-cells [12]. Five members ofthe NFAT family are
currently known, NFATp ( NFAT1, NFATc2), NFATc
(NFAT2, NFATc1), NFAT3 (NFATc4), NFAT4
(NFATc3, NFATx), and NFAT5, which share homology
within a region of t he DNA binding domain that is distantly
related to the Rel domain [13–17]. Moreover, various lines
of biochemical evidence, including knock-out studies and
tissue distribution patterns of t he proteins, indicate that
three ofthe NFAT family members, NFATp, NFATc, and
NFAT4, play important roles in the modulation and
development ofthe immune system [12,18]. Although
NFAT5 appears to be constitutively localized in the nucleus
and under t he regulation of osmotic shock, the other NFAT
family members are primarily controlled by their subcellular
localization depending on their phosphorylation status. In
resting T-cells, NFAT proteins are present in the cytoplasm
in a phosphorylated state. Activation via the T-cell receptor
(TCR) o r other stimulus results in an influx of calcium and
induces the dephosphorylation of NFAT, and r apid trans-
location ofthe protein into the nucleus [19,20]. D ephos-
phorylated NFAT binds to specific response elements and
thereby a ctivates a number o f genes, including those
Correspondence to M O. Lee, Department of Bioscience and
Biotechnology, Sejong University, 98 Kunja-dong, Kwangjin-gu,
Seoul 143-747, Korea. Fax: + 82 2 3408 3768,
Tel.: + 82 2 3408 3768, E-mail: molee@sejong.ac.kr
Abbreviations: FasL, Fas ligand; RA, retinoic acid; RARs, retinoic
acid receptors; RXRs, retinoid X receptors; NFAT, nuclear factors
of activated T-cells; TCR, T-cell receptor; CsA, cyclosporin A;
PBMCs, peripheral blood mononuclear cells; PMA, 4b-phorbol
12-myristate 13-acetate; b-gal, b-galactosidase; IL, interleukin; VDR,
vitamin D receptor.
*Note: both authors co ntributed equally to this work.
(Received 30 July 2001, revised 18 December 2001, accepted 19
December 2001)
Eur. J. Biochem. 269, 1162–1170 (2002) Ó FEBS 2002
encoding cytokines, cell surface receptors, signaling mole-
cules, and other, as y et unidentified, targets. As NFAT
dephosphorylation is mediated bythe Ca
2+
/calmodulin-
dependent phosphatase, calcineurin, NFAT-regulated genes
are sensitive to inhibitionby immunosuppressive agents that
inhibit calcineurin, such as cyclosporin A (CsA) and FK506
[21].
Recently, several studies have demonstrated the in volve-
ment of NF AT in the t ranscriptional activation of F asL
[22–25]. Therefore, w e speculated that N FAT inhibition
might be an important mechanism through which RA
inhibited theexpressionof FasL. In this study, we show that
all-trans-RA inhibits FasLexpressionby blocking tran-
scriptional activation by NFAT. Our r esults suggest t he
therapeutic potential of targeting NFAT function with RA
to achieve immunosuppression.
EXPERIMENTAL PROCEDURES
Cells and reagents
The Jurkat human T-cell leukemia (ATCC, CRL1990), and
HeLa human cervical carcinoma (ATCC, CCL-2) cell lines
were obtained from the American Type Culture Collection.
Cells were maintained in RPMI 1640 medium containing
10% fetal bovine serum. Human peripheral blood mono-
nuclear cells (PBMCs) were isolated from healthy donors by
density gradient centrifugation of heparinized blood on a
layer of Ficoll/Hypaque (Sigma, St. Louis, MO, USA). All-
trans-RA, 9-cis-RA, 4b-phorbol 12-myristate 13-acetate
(PMA) and CsA were purchased from Sigma. Ionomycin
was obtained from Calbiochem (La Jolla, CA, USA). All
other chemicals used were ofthe purest grade available from
Sigma.
RT-PCR for FasL
Jurkat cells (2 · 10
6
cells) were treated with a mixture of
PMA (10 ngÆmL
)1
) and ionomycin (0.5 l
M
) for 6 h with or
without a 24-h pretreatment with various concentrations of
all-trans-RA. Total R NA w as prepared using Q iagen
RNeasy kit (Qiagen Inc., Chatsworth, CA, USA) following
the m anufacturer’s instructions. RT-PCR was performed
essentially as described previously [26]. cDNA was synthe-
sized from 4 lg total RNA using 100 ng random hexamer
(Pharmacia, Uppsala, Sweden). The PCR primer sequences
used were as follows. FasL (forward: 5¢-ATGTTTCAGC
TCTTCCACCTACAGAAGGA-3¢,reverse:5¢-CAGAGA
GAGCTCAGATACGTTGAC-3¢); and b-actin (forward:
5¢-CGTGGGCCGCCCTAGGCACCA-3¢,reverse: 5¢-TTG
GCCTTAGGGTTCAGGGGGG-3¢. PCR cycling condi-
tions were: de-naturation at 94 °C for 30 s, annealing at
52 °C for 30 s and extension at 72 °C for 30 s. Twenty-eight
cycles were carried out for amplification ofFasL and 22
cycles for b-actin.
Plasmids and reporter gene assay
The luciferase reporter constructs containing a 2 .3-kb
fragment (from n ucleotide s )2365 to )2) and a 320-bp
fragment (nucleotides )318 to )2) of genome region located
5¢ upstream oftheFasL translation initiation s ite, and the
luciferase reporters containing mutatio ns in the NFAT
(DNFAT) or SP1 (DSP-1) sites, were previously described
[22]. The luciferase reporter constructs containing deleted
promoter fragments (nucleotides )1783 to )2) and (nucleo-
tides )1703 to )2), were constructed b y r estricting the
2.3-kb full promoter using XhoIandNcoI/XhoI, respectively.
The NFAT-Luc reporter was constructed by inserting an
oligonucleotide en coding the NFAT binding site of the
FasL promoter (5¢-ATTGTGGGCGGAAACTTCCAG-3¢)
with additional GATC motifs at the 5¢ endintotheBglII site
of the pGL2-promoter (Promega, Madison, WI) that
carries an SV40 promoter. The eukaryotic expression
vectors carrying Flag-NFATp, RARa,RARb, RARc,
and RXRa have been reported previously [27,28]. Jurkat
cells (1–2 · 10
7
cells) were transfected with reporter plas-
mids (7.5 lg) or with a b-galactosidase (b-gal) expression
vector (2.5 lg) by electroporation. CV-1 cells were seeded in
a 24-well culture p late at 5 · 10
4
cells per well, and
transfected with DNA mixtures (1 lg per well) containing
reporter plasmids (0.1 lg), the eukaryotic expression vector
encoding Flag-NFATp (25 ng), the retinoid receptor
expression plasmid (25 ng), or the b-gal expression vector
(0.15 lg) with carrier DNA (pBluescript). The cell cultures
were incubated for 6 h with PMA (10 ngÆmL
)1
)and
ionomycin (0.5 l
M
), in the presence or a bsence of all-
trans-RA. At the end ofthe incubation period, luciferase
activity was determined using a luminometer according to
the manufacturer’s instructions. The luciferase activity was
normalized for transfection efficiency using the correspond-
ing b-gal activity.
To examine the effects of all-trans-RA on IL-2 NFAT
site-dependent transcription, we employed a Jurkat cell line
that was s tably transfected with the NFATZH reporter
construct (Oum, J H. & Park, J., unpublished r esults). The
reporter construct contained three copies ofthe distal
NFAT binding site in the human I L-2 promoter and a
minimal IL-2 promoter, upstream ofthe b- gal gene [29]. The
Jurkat-NFAT cells (1 · 10
5
cells per well) were cultured in a
24-well plate and stimulated for 6 h with PMA
(10 ngÆmL
)1
) and ionomycin (0.5 l
M
), in the presence or
absence ofa ll-trans-RA (2.0 l
M
). The b-gal activity was
determined using t he fluorogenic substrate 4-methyl-lum-
bellifery-b-galactoside, and was normalize d for protein
content [30]. A one-way analysis of variance was performed
using GraphPad
INSTAT
Ò (GraphPad Software, San Diego,
CA, USA). A value of P < 0.05 was considered statistically
significant.
Electrophoretic mobility shift assay (EMSA)
PBMCs (7 · 10
6
cells) obtained from healthy dono rs were
stimulated in a 100-cm
2
plates precoated with anti-CD3 Ig
(100 lgÆmL
)1
) for 4 h with or without various concentra-
tions of all-trans-RA p retreatment. A mouse antibody
against human C D3 was prepared from the supernatants of
OKT3 hybridoma cell cultures [28]. Nuclear extracts were
prepared from the PBMCs and gel-shift assays were carried
out using p reviously desc ribed meth ods [28]. Nuclear
extracts (5 lg) were incubated for 20 min at 25 °Cwith
32
P-labeled oligonucleotides encoding either t he NFAT or
SP-1 binding sequences in a 20-lL reaction mixture
containing 10 m
M
Tris buffer ( pH 7.5), 1 00 m
M
KCl,
1m
M
dithiothreitol, 1 m
M
EDTA, 0.2 m
M
phenyl-
methanesulfonyl fluoride, 1 mgÆmL
)1
BSA, and 5%
Ó FEBS 2002 Repressionof NFAT byretinoicacid (Eur. J. Biochem. 269) 1163
glycerol. The sequences of oligonucleotides used as probe in
the experiments were: NFAT, 5¢-GATCATTGTGGGCG
GAAACTTCC AG-3¢; and SP-1, 5¢-GATCGATCGGGG
CGGGGCGAG-3¢.
Immunofluorescence studies
For the subcellular localization studies, HeLa cells (1 · 10
6
per well) were transie ntly transfected with 4 lg Flag-
NFATp using LipofectaminePlus
TM
(Gibco BRL, Grand
Island, NY, USA) according to t he manufacturer’s instruc-
tions. The transfected HeLa cells were cultured for 24 h on
poly
L
-lysine-coated 11-mm coverslips. Th e cells were
stimulated with PMA (10 ngÆmL
)1
) and ionomycin
(0.5 l
M
), in the presence or absence of all-trans-RA
(1.0 l
M
). Following treatment, the cells were fixed overnight
at )20 °C in a methanol/acetone (1 : 1) solution. The cells
were then stained with an anti-(Flag M 2) Ig (Upstate
Biotech., Lake Placid, NY, USA) a t a co ncentration of
1 lgÆmL
)1
in NaCl/P
i
and 1% bovine serum albumin,
followed bya biotin-labeled, anti-(mouse Ig) Ig (1 : 1000,
Vector Laboratories, I nc., Burlingame, CA, USA), and
streptavidin–fluorescein isothiocyanate (1 : 200, Vector
Laboratories). Fluorescent cells were washed with NaCl/P
i
and visualized by confocal microscopy (Nikon, Japan).
RESULTS
All-
trans
-RA represses FasL expression
As RA has been shown to inhibit theexpressionofFasL in
the immature thymocytes and T-cell hybridomas [6–8], we
confirmed these data using a human leukemia cell line,
Jurkat. The addition of PMA and ionomycin into culture
media remarkably induced theexpressionofFasL in Jurkat
cells and the induction was r epressed by all-trans-RA
treatment in a dose-dependent manner (Fig. 1A). FasL
transcription was decreased at all-trans-RA concentrations
as low as 0.01 l
M
, and was almost completely abolished at
1.0 l
M
. To further establish the inhibitory effect of all-trans-
RA on FasL gene expression, we employed a luciferase
reporter system containing the 2 .3-kb genomic DNA
fragment that is sufficient for transcriptional activation of
the FasL gene [22]. Transient transfection ofthe reporter
into Jurkat cells produced a 3.25-fold increase in reporter
gene activity in response to PMA and iono mycin treatmen t,
a finding that was consistent with previously rep orted results
[22]. Approximately 80% ofthe reporter gene activity was
repressed i n the presence of all- trans-RA (Fig. 1B). In
summary, the results f rom R T-PCR and r eporter g ene
analyses clearly showed that RA decreased the transcrip-
tional expressionofFasL in Jurkat cells.
The NFAT binding motif in theFasL promoter
confers responsiveness to all-
trans
-RA
We studied the RA-responsive, cis-regulatory elements in
the FasL promoter, in order to elucidate t he molecular
mechanism through which RA represses FasL expression.
First, we tested the responsiveness to all-trans-RAoffour
reporter constructs c ontaining serially deleted FasL pro-
moters (Fig. 2A). As shown in Fig. 2B, all-trans-RA
significantly repressed the transcriptional induction of the
four reporter genes that were induced by PMA a nd
ionomycin treatment. These results suggested that the
putative R A-responsive elements were located w ithin the
nucleotides )318 to )2 region oftheFasL pro moter.
The FasL promoter (nucleotides )318 to )2) contains
several potential cis-acting r egulatory ele me nts, including
binding sites for NFAT and SP-1 [22–25]. However, there
are no consensus retinoid-responsive elements prese nt in
this region, suggesting that retinoid receptors may not bind
directly to this portion oftheFasL promoter. Therefore, it is
possible that the activities of RA are m ediated through
transcriptional modulation by other nuclear transcriptional
factors, such as NFAT and SP-1. To test this hypothesis, we
employed reporters encoding mutated DNA-bind ing
sequences fo r NFAT o r SP-1 (Fig. 3A). When the wild-
type or SP-1-mutated reporter was transfected into Jurkat
cells, PMA and ionomycin treatment induced an approxi-
mately 3.5-fold increase in reporter gene activation
(Fig. 1 B). Co-treatment with all-trans-RA of cells carrying
either of these reporter constructs repressed the PMA and
ionomycin-induced reporter gene a ctivity by approximately
80% (Fig. 3B). In contrast, neither PMA and ionomycin
nor all-trans-RA treatment meaningfully modulated the
transcriptional activity ofa reporter g ene c ontaining the
Fig. 1 . All-trans-RA represses the induction ofFasL expression. (A)
The effects of all-trans-RA on FasL transcription were examined using
RT-PCR. Jurkat cells were incubated with the indicated concentra-
tions o f all- trans -RA f or 24 h a nd then treated with PMA
(10 ngÆmL
)1
)andionomycin(0.5l
M
) for 6 h. T h e expression of
b-actin was monitored as a co ntrol. (B) TheFasL (nucleotides )2306
to )2)-Luc reporter, together with the b-gal expression vector, was
transiently transfected into Jurkat cells as described in the Experi-
mental p rocedu res. Transfected cells were trea ted with PMA
(10 ngÆmL
)1
) and ionomycin (0.5 l
M
) in t he presence or absence of
1.0 l
M
RA for 6 h. The luciferase activity was measured and nor-
malized by b-gal activity. Data are shown as the mean ± S E of three
independent measurements.
1164 M O. Lee et al. (Eur. J. Biochem. 269) Ó FEBS 2002
mutated NFAT sequence. These results indicated that all-
trans-RA repressed theFasL promoter, mainly through the
inhibition of NFAT a ctivity. T o further c onfirm t he
involvement of NFAT, we generated a reporter construct,
NFAT(FasL)-Luc, in w hich an NFAT binding site from the
FasL promoter was subcloned upstream ofa heterologous
SV40 promoter and luciferase. When t his construct was
transfected into Jurkat cells, the reporter gene activity was
increased about threefold by P MA and ionomycin treat-
ment; approximately 60% a nd 70% ofthe P MA and
ionomycin-induced reporter gene activity was repressed by
the addition of all-trans-RA and 9-cis-RA, respectively
(Fig. 3C). We then tested whether all-trans-RA inhibited the
transcriptional activation driven b y NFAT binding
sequences present in other NFAT target genes. F or this
purpose, we employed a Jurkat cell line in which b-galacto-
sidase expression was under the control of three copies of
the distal IL-2 NFAT site upstream ofthe minimal IL-2
promoter. As shown in Fig. 3D, approximately 65% and
85% ofthe reporter gene transcriptional activity induced by
PMA and ionomycin was repressed by treatment with all-
trans-RA and 9-cis-RA, respectively (Fig. 3 D), indicating
that all-trans-RA-induced repressionof NFAT binding
motifs was not specific for theFasL promoter, and further
supporting our contention that RA modulates the transac-
tivation functionof NFAT.
We also cotransfected the NFAT(FasL)-Luc reporter,
along with the retinoid receptor expression plasmid, into
CV-1 cells, in order to investigate whether the modulatory
activities of all-trans-RA were mediated by retinoid recep-
tors. As shown in Fig. 4, NFAT-Luc was strongly induced
by PMA and ionomycin in the p resence of NFATp.
Although all-trans-RA d id not induce a significant repres-
sion ofthe reporter g ene a ctivity in t he absence o f
cotransfection with the retinoid receptor plasmid, repression
was greater when plasmids containing RARa,RARb,
Fig. 2 . Delineation of all-trans-RA-responsive cis-actingelementsinthe
FasL promoter. (A) Schematic representation ofthe deletions in the
5¢ term inus oftheFasL promoter that were cloned upstream of a
luciferase report er gene. The 3¢ end oftheFasL promoter contains
nucleotide )2, counted from the translation initiation site, and tran-
scription s tarts from nucleotide )181 [22]. (B) Each reporter construct
was transiently transfected into Jurkat cells. Transfected cells were
stimulated with PMA (25 ngÆmL
)1
)andionomycin(0.5l
M
)inthe
absence (empty bar) or presence (filled bar) of all-trans-RA ( 2.0 l
M
)
for 6 h. Luciferase activity was measured and normalized by b-gal
activity. To establish the reporter construct basal expression, pTK-luc,
which contains a minimal promoter of thymidine kinase, was also used
in the transfection assay.
Fig. 3 . The effect of all-trans-RA is mediated by an NFAT binding motif
present in theFasL promoter region. (A ) S chema tic representation of
the FasL promoter (nucleotides )318 to )2) reporter construct, along
with NFAT and SP-1 binding sites. The nucleotide sequences of the
NFAT- and SP-1- bindin g sites and of mutations in these sites are
shown. (B) The indicated rep orter constructs together with a b-gal
expression vector were transiently t ransfected into Jurkat cell s as
described in the E xperimental procedures. Transfected c ells were
treated with PMA (10 ng ÆmL
)1
) and iono mycin (0.5 l
M
)inthepres-
ence or absence of R A (1.0 l
M
) for 6 h. Luciferase activity was mea-
sured and normalized by b-gal activity. (C) The NFAT(FasL)-Luc
construct was transfected into Jurkat cells and incubated for 6 h with
PMA (10 ngÆmL
)1
)andionomycin(0.5l
M
) in the absence or presence
of all-trans-RA (1.0 l
M
). Luciferase activity was measured and nor-
malized by b-gal act ivity. (D) Jurkat-NFAT cells were treated with
PMA (25Æng mL
)1
)/ionomycin (0.5 l
M
), CsA (1 lgÆmL
)1
), and RA
(2.0 l
M
)for6h,asindicated.b-Gal activity was measured and nor-
malized with the protein concentrations of cell extracts. All data from
the reporter gene assays are shown as the mean ± SE of more than
three indepen dent me asurem ents.
Ó FEBS 2002 Repressionof NFAT byretinoicacid (Eur. J. Biochem. 269) 1165
and/or RXRa were cotransfected (Fig. 4 ). Interstingly,
ligand-dependent repression was observed when RXRa or
RARa/RXRa was c otransfected, i mplicating that RXR
plays an important role in repressing NFAT activity.
However, RARc expression did not induce a significan t
change in the reporter gene activity. These results indicated
that the i nhibition ofFasLexpressionby RA involves a
novel mechanismof NFAT blockage that is mediated by a
subset ofthe r etinoid receptors.
All-
trans
-RA inhibits the DNA binding activity of NFAT
To understand the molecular m echanism of RA-induced
inhibition of NFAT activity, we investigated whether the
DNA-binding activity o f N FAT w as changed b y R A
treatment. When PBMCs were stimulated with anti-CD3
Ig, binding to the NFAT binding sequence from t he FasL
promoter was s ignificantly increased (Fig. 5A). However,
the induced NFAT binding activity was significantly
inhibited by all-trans-RA t reatment, whereas binding to
the consensus S P-1 b inding seq uence was unchanged. A
100-fold excess of unlabeled probe or of an unlabeled
oligonucleotide encompassing the NFAT binding sequence
from the I L-2 promoter, completely abolished the protein–
DNA complexes, whereas a 100-fold excess ofa nonspecific
oligonucleotide had no effect, indicating that the complex
was specific. As shown in Fig. 5B, therepressionof NFAT–
DNA b inding by all-trans-RA was dose-dependent; the
repression was observed with all-trans-RA concentrations
as low as 0 .1 l
M
, and NFAT binding was abolished in the
presence of 1.0 l
M
all-trans-RA. In contrast, SP-1 binding
was similar at all co ncentrations of all-trans-RA tested.
All-
trans
-RA blocks NFAT translocation to the nucleus
Activation via the T-cell receptor (TCR) or stimuli suc h as
ionomycin results in the rapid dephosphorylation of
NFAT and its translocation into t he nucleus [ 19,20].
Therefore, we spec ulated that the observed d ecrease in
NFAT–DNA binding might be due to a decrease i n the
amount of NFAT proteins translocated from the cytosol
into the nucleus. To test this hypothesis, we analyzed the
effects of all-trans-RA on thenuclear s huttling of
NFATp. We performed immunocytochemistry on HeLa
cells that had b een t ransiently transfected with Flag-
tagged recombinant NFATp. The Flag-tagged NFATp
was found in the cytoplasm of unstimulated cells, a nd
all-trans-RA treatment did not induce significant changes
in the recombinant protein localization (Fig. 6). Following
stimulation with PMA and ionomycin, NFATp was
translocated to the nucleu s in t he majority ofthe cells.
PMA and ionomycin-induced translocation was reduced
by approximately 70% when the cells received cotreat-
ment with all-trans-RA, and was almost completely
inhibited bythe addition of CsA.
Fig. 4 . Retinoid r eceptors repres s the transcriptional activity of the
NFAT response element. The NFAT(FasL)-Luc was cotransfected,
along with the indicated retinoid receptor expression vector (25 ng)
and NFATp (25 ng), into CV-1 cells, as described in the Experimental
procedures. Transfected cells w ere incubated for 6 h with PMA
(10 ngÆmL
)1
) and ionomycin (0.5 l
M
) in the absence or presence of all-
trans-RA ( 1.0 l
M
)or9-cis -RA (1.0 l
M
). Lu ciferase activity was
measured and normalized by b-gal activity. Data are shown as the
mean ± S E of three independen t measurements.
Fig. 5 . All-trans-RA represses the DNA-binding activity of NFAT. A,
PBMCs (7 · 10
6
cells) obtained from a healthy donor were stimulated
in a 100-cm
2
plate that was precoated with anti-CD3 Ig for 4 h with or
without 1.0 l
M
all-trans-RA. B, Jurkat cells (3 · 10
6
cells) were treated
with PMA ( 10 ngÆmL
)1
) and ionomycin (0.5 l
M
)for4h,inthe
presence or a bsence ofa 24 -h pretreatment with all-trans-RA, as
indicated. The reaction mixture co ntaining 5 lg nuclear extract was
incubated with
32
P-labeled oligonucleotide and analyzed by gel shift
assay, as d escribed in the Experimental procedures. The designations
for cNFAT(FasL), cNFAT(IL-2), and cSP-1 indicate a 100-fold excess
of the competing unlabeled oligonucleotides.
1166 M O. Lee et al. (Eur. J. Biochem. 269) Ó FEBS 2002
DISCUSSION
Although i t h as been convincingly d ocumented that RA
induces therepressionof T-cell apoptosis and FasL gene
expression, the underlying molecular mechanism has not
been clarified. In this study, we demonstrated that the
repression ofFasL transcription by RA w as mediated
through the i nhibition of NFAT f unction. Both r eporter
gene analyses and DNA binding assays indicated that all-
trans-RA mediated t his r epression through the NFAT
binding sequence in theFasL promoter. In addition, we
showed that all-trans-RA inhibited NFAT–DNA binding,
as well as NFAT entry into the nucleus from the cytosol.
Therefore, our results indicate that FasLexpression inhibi-
tion by RA involvesanovelmechanismof NFAT
transcription inhibition.
The biolo gical functions o f RA are mainly mediated by
the ligand-depend ent transcriptional factors RAR a nd
RXR, which belong to the steroid/thyroid receptor super-
family [7–9]. Several studies ind icate that protein–protein
interactions between nuclear retinoid receptors mediate
cellular cross-talk, thus generating diverse gene-regulatory
pathways. For instance, it was found that RXR could
physically interact with either NF-jBorIjBb, resulting in
the repression o f IL-12 production in macrophages or
altered LPS responses, respectively [31,32]. Furthermore, it
has been shown t hat PPARc, a nother member of t he
steroid/thyroid receptor superfamily, interacts with NFAT
at the protein level in T-lymphocytes, resulting in d ecreased
IL-2 production [33]. Another potential mechanism involves
competition for DNA binding at the NFAT site in the FasL
promoter. In t his regard, RXR w as reported to play a
crucial role in immunosuppression induced by 1 a,25
(OH)
2
D
3
, the active metabolite of vitamin D, by forming
heterodimers with the vitamin D r eceptor (VDR), wh ich
can compete with NFAT-AP-1 binding on the IL-2
promoter NFAT site [ 34,35]. In addition, it has recently
been reported that the activity ofthe inducible N-terminal
transactivation domain of NFATc was coactivated by CBP/
p300, well-characterized coactivators of RAR/RXR [36].
Therefore, competition for CBP/p300 between these tran-
scriptional factors might result i n theinhibitionof the
NFAT activity. Similarly, the cross-talk between retinoid
receptors and NFAT might take place at the protein level,
as NFAT inhibitionby all-trans-RAwasgreaterinthe
presence of retinoid receptors (Fig. 4). Therefore, further
investigations into each of these potential mechanisms are
warranted, in o rder to further understand the retinoid
receptor-induced inhibitionof NFAT. Interestingly, Szondy
and others have shown that RARa stimulation inhibited,
whereas RARc enhanced, activation-induced apoptosis
[37,38]. Similarly, we showed that RAR a repressed NFAT
function, while RARc did not (Fig. 4). Th us, b alanced
RARa/RARc stimulation may decide whether all-trans-RA
enhances or inhibits the transcriptional activity of NFAT
and thereby FasL expression, which controls activation-
induced apoptosis.
Activation via the TCR or some other stimulus ind uces
calcium influx and leads to th e dephosphorylation and rapid
translocation into the nucleus of NFAT, where it activates a
number of target genes. The dephosphorylated NFAT may
be rephosphorylated at serine residues by either removing
the s timulus or treating cells with a c alcineurin i nhibitor
such as CsA, whereby it i s translocated back to the
cytoplasm [19,39]. While NFAT dephosphorylation is
mediated by calcineurin, rephosphorylation is catalyzed by
a variety of serine kinases, such as glycogen synthase kinase-
3, ERK, p38, casein kinase-2, and c-Jun N-terminal kinase
[40–43]. These enzymatic activities may b e targeted by RA
in order t o block NFAT dephosphorylation by repressing
calcineurin and/or activating the specific serine kinases. For
example, dithiocarbamate, a powerful inhibitor of NF-jB,
inhibited NFAT dephosphorylation b y i nducing a pro-
longed activation ofthe c-Jun N-terminal kinase [44]. O ur
preliminary results indicated that all-trans-RA inhibited
dephosphorylation of NFAT, which could be an important
Fig. 6 . All-trans-RA blocks nuclear translocation of NFAT. A, HeLa cells, transfected with an expression vector encoding the Flag epitope-tagged
NFATp, were cultured on poly
L
-lysine-coated coverslips for 24 h. Cells were treated with PMA and ionomycin or vehicle for 30 min in the
presence or absence of all-trans-RA or CsA. The cells were fixed and stained with anti-Flag Ig, followed by mouse-biotin and streptavidin–FITC, as
described in the Experimental procedures. (A) no treatment; (B) all-trans-RA (1.0 l
M
); (C) PMA (10 ngÆmL
)1
) and ionomycin (0.5 l
M
); (D) all-
trans-RA (1.0 l
M
) with PMA (10 n gÆmL
)1
) and ionomycin (0.5 l
M
); E, CsA (1 lgÆmL
)1
) with PMA (10 ng ÆmL
)1
) and ionomycin (0.5 l
M
).
Ó FEBS 2002 Repressionof NFAT byretinoicacid (Eur. J. Biochem. 269) 1167
mechanism for RA-induced repressionofnuclear translo-
cation of NFAT (Kang, H J. & Lee, M O., unpublished
results). Therefore, further studies are required to e stablish
whether RA modulates the activities ofthe enzymes that
affect nuclear translocation and transcriptional activity of
NFAT.
The NFAT proteins regulate theexpressionofFasL and
a discrete set of cytokines involved in the regulation of
immune responses, such as proliferation and differentiation,
as well as in multiple effector functions of immune cells. The
promoters ofthe IL-2, GM-CSF, IL-3, IL-4 a nd tumor
necrosis factor alpha genes contain different types of NFAT
binding elements that are independently active or combine
with AP-1 binding sites [12]. The previous observations that
all-trans-RA repressed IL-2 production and IL-2 gene
transcription [45,46] correlate with our present findings
(Fig. 3 D). Currently, CsA and FK506 are the most
powerful i mmunosuppressive drugs available t hat target
calcineurin function. However, their clinical use is limited
because ofthe toxic s ide-effects caused byinhibitionof the
many biological pathways controlled by calcineurin. There -
fore, there is considerable therapeutic interest in drugs that
directly target NFAT and allow reductions in CsA/FK506
dosage. In this regard, RA, o r its more potent and receptor
subtype-selective analogues, may sub serve the role of such
agents.
Recently, the physiological importance of NFAT in
cells other t han t hose o f the immune system has been
uncovered. The widespread distribution of NFAT
mRNA and/or proteins in nonlymphoid tissues, including
the heart, testis, brain, ovary, small intestine, prostate,
colon, muscle, placenta, lung, and kidney, as well as in
skin [47–50], suggests that NFAT f amily members might
control cellular differentiation programs in these organ
systems. Indeed, recent evidence s uggests t hat NFAT
may participate in a dipogenesis and m yogenesis [49,50].
Interestingly, retinoid receptor expression has been
implicated in cardiomyopathy and congestive heart
failure [51–53], sugge sting a potential link between
RA-induced repressionof NFAT and the pathophysiol-
ogy of these diseases. Given the importance of NFAT in
fundamental physiology, the i nhibition of NFAT func-
tion by retinoids may be a critical factor in NFAT-
mediated biological signaling.
ACKNOWLEDGEMENTS
We thank Dr Carlos V. Paya (The Mayo Clinic, Rochester, MN, USA)
for t he luciferase reporter constructs. We also thank Dr Crabtree
(Stanford University, Stan ford, CA, USA) for F lag-NFATp and
NFATZH. This work w as supported bya grant (KRF-99–015-
DP0398) from the Korea Research Foundation to M O. L . and J. P.
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