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Molecular and Cellular Biology, January 1999, p. 431-440, Vol. 19, No. 1
0270-7306/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Two Distinct Gamma Interferon-Inducible Promoters of the Major
Histocompatibility Complex Class II Transactivator Gene Are
Differentially Regulated by STAT1, Interferon Regulatory Factor 1, and Transforming Growth Factor 
Janet F.
Piskurich,
Michael
W.
Linhoff,
Ying
Wang, and
Jenny P.-Y.
Ting*
Lineberger Comprehensive Cancer Center and
Department of Microbiology and Immunology, University of North
Carolina at Chapel Hill, Chapel Hill, North Carolina
Received 11 August 1998/Returned for modification 9 September
1998/Accepted 28 September 1998
 |
ABSTRACT |
The major histocompatibility complex (MHC) class II transactivator
(CIITA) is the master regulatory factor required for appropriate expression of class II MHC genes. Understanding the expression of CIITA
is key to understanding the regulation of class II MHC genes. This
report describes the independent regulation of two distinct CIITA
promoters by cytokines with opposing functions, gamma interferon
(IFN-
) and transforming growth factor 
(TGF-). A functional
analysis of deletion mutations of the upstream promoter (promoter III)
identified an IFN--responsive region located approximately 5 kb from
the transcriptional start site. An in vivo DNase I hypersensitivity analysis detected a hypersensitive site in this area which supports the
relevance of this region. When the downstream promoter (promoter IV)
was studied by in vivo genomic footprinting, IFN--induced changes at
putative binding sites for STAT1, interferon regulatory factor 1 (IRF-1), and E-box proteins were seen. Gel shift and supershift
analyses for IRF-1 confirmed the in vivo footprint results. The role of
the IFN--inducible transcription factor STAT1 was examined
functionally. Although both promoters were controlled by STAT1,
promoter-specific regulation was exhibited. The IFN- response of
promoter III was completely dependent on STAT1 and not IRF-1, while
promoter IV was partially activated by IRF-1 in the total absence of
STAT1 expression. While both promoters were affected by TGF-,
activation of promoter III by IFN- was more severely diminished by
TGF- treatment. The differential control of CIITA promoters by
TGF-, IRF-1, and STAT1 may be important in refining regulation of
class II MHC genes in different cell types and under different
stimulatory conditions.
| |
INTRODUCTION |
The class II major
histocompatibility complex (MHC) molecules present antigenic peptides
to CD4+ T cells through interactions with both the T-cell
receptor and the CD4 molecule. Presentation of antigenic peptides by
class II MHC molecules requires coexpression of (i) invariant chain (Ii), which not only binds to the antigen-binding cleft to prevent peptide binding in the endoplasmic reticulum but also targets class II
MHC molecules to special cellular compartments where foreign peptides
are loaded, and (ii) the enzymatic HLA-DM protein, which removes the
Ii-derived peptide and facilitates loading of foreign peptides (9,
10, 13, 15, 31, 33, 48, 56). The class II MHC, Ii, and DM genes
are controlled to different extents by the master transcriptional
regulator, class II transactivator (CIITA) (3, 20).
CIITA was initially isolated by complementation cloning of RJ2.25, an
in vitro mutagenized, class II MHC-defective B-cell line
(51). CIITA not only restores class II MHC gene and antigen expression in RJ2.25 but also restores class II MHC expression in cells
of the BLS-2 cell line (complementation group A), derived from patients
suffering from the bare lymphocyte syndrome. Thus, this genetic defect
in a subset of bare lymphocyte syndrome patients resides in the CIITA
gene. Current evidence from our group shows that the BLS-2 defect,
which involves deletion of a 72-bp CIITA exon, lies in the inability of
the mutant CIITA to undergo nuclear translocation (7).
CIITA is a transcriptional coactivator that does not bind DNA yet
exhibits a potent and specific effect on class II MHC gene transcription. The CIITA protein has domains normally associated with
transcriptional activators such as acidic and proline-, serine-, and
threonine-rich domains, and also contains an unusual and important consensus GTP-binding domain (5). Recent evidence shows that lack of CIITA results in a closed chromatin structure in the class II
MHC promoter (44, 58). More importantly, reintroduction of
CIITA into G3A, a mutagenized gamma interferon (IFN-)-unresponsive cell line that lacks CIITA expression, results in the opening and
occupancy of previously closed class II MHC, Ii, and DM promoters (54, 58). The capacity of CIITA to open previously closed promoters appears to be restricted to IFN--responsive cells and not
to B cells. The biochemical mode by which CIITA functions is poorly
understood, although one report shows that CIITA can interact with RFX5
in a yeast two-hybrid system (46). Others have shown
interactions with Bob1, a B-cell factor, and with TAFII32, a subunit of the basal transcription factor TFIID (11, 12, 29). More recently, we have found that CIITA interacts with the
coactivator CREB-binding protein (17). These multiple
interactions may provide a model by which CIITA exerts its effects on
gene transcription.
The expression of CIITA coincides with class II MHC gene expression,
and this feature is distinct from other transcription factors that
control the expression of class II MHC (28). These other
transcription factors, primarily RFX and NF-Y, are ubiquitously expressed and cannot explain the restricted tissue and cell
distribution of class II MHC. In contrast, the expression of CIITA is
nearly identical to that of class II MHC genes. Two dominant regulators of class II MHC gene expression also control CIITA expression. IFN-
upregulates while transforming growth factor beta (TGF-) suppresses
CIITA (4, 6, 24, 37, 52). The physiologic roles of IFN-
and TGF- in controlling class II MHC expression are well documented.
For example, TGF-
/ gene knockout mice develop severe
autoimmune disease accompanied by the hyperexpression of class II MHC
genes (14, 36, 49). In contrast, manifestations of
autoimmunity are greatly diminished in mice that are both
TGF-/ and I-A/ (26),
which suggests that many of TGF-'s effects on the immune system are
mediated via the suppression of class II MHC expression. Hence, an
understanding of the regulation of CIITA is seminal in the definition
of events that lie between the binding of IFN- and TGF- to their
respective receptors and the downstream activation or suppression of
class II MHC genes.
Previously, we and others have found that B-cell-specific expression of
CIITA requires a small promoter region immediately upstream of the
transcriptional start site (contained in pIIIDEL4.CIITA.Luc) (see Fig.
1) (25, 35, 41). Our study further indicated that IFN-
induction of this promoter is possible in several different cell types
and requires DNA sequences located at least 2.5 kb upstream of the
start site. This IFN--inducible region was shown to be functional
both in the context of this CIITA promoter and when linked to a
heterologous promoter.
In parallel, another laboratory used RNase protection analysis to show
that the CIITA gene has multiple transcriptional start sites, a finding
indicative of multiple promoters (35). These authors
concluded that the human CIITA gene has four promoters designated by
their location from 5' (upstream) to 3' (downstream) as promoter I,
primarily expressed in dendritic cells; promoter II, expressed at
insignificant levels and functionally not well understood; promoter
III, primarily active in B cells; and promoter IV, expressed in
response to IFN- (see Fig. 1A). A comparison of their and our
published reports indicates that the promoter identified in our report
corresponds to promoter III of their report. A more careful examination
of their RNase protection data shows us that promoter III is also
IFN- inducible in a number of different cell types, including
endothelial cells and fibroblasts, although the inducibility of this
promoter is weaker than that of promoter IV. Hence, there may exist two
distinct IFN--inducible regions that reside in promoters III and IV, respectively.
The purpose of this report is to resolve the issue of two distinct
IFN--inducible promoters for the CIITA gene and to perform a series
of experiments comparing the inducibility of these promoters. This was
achieved by in vivo analyses to detect changes in the chromatin or the
binding of proteins to specific regions within each promoter. Upon
verification of modifications in the chromatin by either in vivo DNase
I hypersensitivity or genomic footprint analysis, the promoters were
studied by gel shift analyses and/or in a luciferase reporter system.
The promoters exhibited differential responses to the IFN--induced
transcription factors, STAT1 and IRF-1, as well as to TGF-. The
implications of two IFN--responsive promoters with distinct patterns
of response to cytokines and transcription factors may explain the
complex pattern of class II MHC expression in different tissues and may
have broad ramifications in tissue-specific immune responses, such as
autoimmunity and transplantation responses.
| |
MATERIALS AND METHODS |
Cell lines.
2fTGH cells are derived from HT 1080 human
fibrosarcoma cells that do not constitutively express class II MHC
antigens but express high levels of these antigens after IFN-
induction. U3A (generously provided by George Stark, Cleveland Clinic
Foundation Research Institute, Cleveland, Ohio) is a STAT1-defective
cell line derived from 2fTGH (39). U3A and 2fTGH cells were
grown in Dulbecco's modified Eagle's medium (Gibco BRL) supplemented with 10% fetal calf serum, 2 mM L-glutamine, and
penicillin and streptomycin (100 U/ml). Murine P19 embryonal carcinoma
cells (CRL-1825; American Type Culture Collection) were grown in Alpha Eagle's modified Eagle's medium (Gibco BRL) supplemented as described above. U373-MG human glioblastoma multiforme cells were grown in
McCoy's 5A medium (Gibco BRL) supplemented as described above.
Constructs.
The isolation of clones containing the promoter
regions of the human CIITA gene as well as the construction of
pIIIDEL4.CIITA.Luc (previously called p668CIITA.Luc),
pIIIDEL1.CIITA.Luc (previously p7000-2000CIITA.Luc), and pIIICIITA.Luc
(previously p7000CIITA.Luc) has been described elsewhere
(41). To obtain plasmids pIIIDEL2.CIITA.Luc and
pIIIDEL3.CIITA.Luc, 2,181-bp XbaI-SphI (for
pIIIDEL2.CIITA.Luc) and 1,068-bp XbaI-AccI (for
pIIIDEL3.CIITA.Luc) fragments from the 5' end of pIIICIITA.Luc were
cloned into the KpnI site at the 5' end of the CIITA
sequences in pIIIDEL4.CIITA.Luc by filling in using the Klenow fragment
and ligation of the blunted ends. CIITA promoter IV was generated by
PCR using Taq polymerase and standard reaction conditions
(Perkin-Elmer Cetus). Oligonucleotides 5'-TGAGTTGGAGAGAAACAGAG-3'
(sense) and 5'-CTGCTGGTGGCCTCTC-3' (antisense) were
used to amplify nucleotides 
346 to +50 of the CIITA promoter IV
sequence reported by Muhlethaler-Mottet et al. (35).
Extensions (ACGTACAAGCTT) at the 5' ends of the primers generated HindIII sites that were used to clone the
amplified fragment into the HindIII site of pGL2-Basic
(Promega) to create pIVCIITA.Luc. The template DNA for the PCR was a
human CIITA genomic clone (clone 2) that has been previously described
(41). Oligonucleotides 5'-CTCAGCGCTGCAGAAAGAActtagAAGGGAAAAAGAACTGCGGGGAG-3'
(sense; mutations shown in lowercase type) and
5'-TCGAAGTATTCCGCGTAC-3' (antisense) were used in the PCR
that was performed to create the IRF-1 site mutation in CIITA promoter
IV. The template DNA for the PCR was the pIVCIITA.Luc plasmid. The
primers were designed to amplify a region from the PstI site
(underlined in the sense primer) in promoter IV to bp 248 in
pGL2-Basic. The mutated amplified fragment was digested with
PstI-XbaI and then substituted for the nonmutated
PstI-XbaI fragment in pIVCIITA.Luc to create
pmIRF.IVCIITA.Luc. Similarly, oligonucleotide
5'-CTGCAGAACCAGGCAG T TGGGATGCCACg gagtcTAAAGCACG TGG TGGCCACAG-3'
(sense; mutations shown in lowercase type) was used with the
antisense primer described above to amplify a region from the
BstXI site (underlined) in promoter IV to bp 248 in
pGL2-Basic. The mutated amplified fragment was digested with
BstXI-XbaI and then substituted for the
nonmutated BstXI-XbaI fragment in pIVCIITA.Luc to
create pmGAS.IVCIITA.Luc. Junctions of plasmids pIIIDEL2.CIITA.Luc and
pIIIDEL3.CIITA.Luc and the inserts and junctions of pIVCIITA.Luc,
pmIRF.IVCIITA.Luc, and pmGAS.IVCIITA.Luc have been confirmed by DNA
sequencing. The pSVISGF2 plasmid, which contains the human IRF-1 cDNA,
was generously provided by Richard Pine, New York University. To
generate the IRF-1 expression plasmid, the human IRF-1 cDNA was removed
from pSVISGF2 as an XbaI-HindIII fragment and
subcloned into the XbaI-HindIII site of
pcDNA3 (Promega).
Ligation-mediated PCR DNase I hypersensitivity mapping.
The
DNase I hypersensitivity mapping technique used in this study uses
ligation-mediated PCR optimized for amplification of long PCR fragments
to detect blunt-ended DNase I-hypersensitive sites. One million cells
were plated in 10-cm-diameter dishes and either left untreated or
treated with IFN- for 5 h. Cells were permeabilized with 0.2%
saponin in DNase I buffer (15 mM Tris [pH 7.4], 15 mM NaCl, 60 mM
KCl, 3 mM MgCl2, 0.25 M sucrose, 1 mM dithiothreitol). The
permeabilized cells were then treated with DNase I buffer containing
0.05% saponin and either 20 or 40 U of DNase I (Boehringer Mannheim)
for 60 s. The buffer was removed from the dish, and the cells were
lysed and digested by incubation for 3 h at 37°C in a buffer
consisting of 0.15% sodium dodecyl sulfate, 10 mM Tris (pH 7.4), 10 mM
EDTA, RNase A (100 µg/ml), proteinase K (400 µg/ml), and 1 mM
dithiothreitol. Genomic DNA was then extracted with phenol-chloroform
and was precipitated. Five µg of DNase I-digested genomic DNA or
undigested DNA was ligated with the blunt-ended linker used in the
ligation-mediated PCR protocol (57). One-fifth of the
products of the ligation reaction was then amplified by PCR using
Expand High Fidelity DNA polymerase (Boehringer Mannheim) according to
the manufacturer's recommended conditions. The initial extension time
was 3 min. All PCRs used the linker primer
5'-GCGGTGACCCGGGAGATCTGAATTC-3' in combination with a CIITA
locus specific primer. For analysis of promoter IV, primer 104CIITA,
5'-GATTCCTACACAATGCGTTGCCTGGCTC-3' (melting temperature
[Tm] = 65°C), was used. For analysis of
promoter III, primer CIITAint, 5'-CCTTTCGGTGCTGATACATGGTTC-3'
(Tm = 63°C), was used. One-fifth of the
reaction mixture was loaded onto 1% agarose gels, and the fragments
were separated by electrophoresis, transferred to a nylon membrane
(Nytran; Schleicher and Schuell) and UV cross-linked. For detection of
the amplification products, a probe was generated by using
[
-32P]dCTP in PCRs using primers 104CIITA and CIITAint
and the human CIITA genomic clone (mentioned above) as a template. The
size of fragments was estimated by using both 1-kb and 100-bp markers (Gibco BRL), with correction for inclusion of the linker primer at the
end of each fragment.
Transfections and luciferase assay.
Transient transfections
of 2fTGH and U3A were performed by the calcium phosphate
coprecipitation method (45). Cells were plated in six-well
plates at a density of 6 × 104 cells/well and
transfected 24 h later. Three micrograms of reporter construct or
3 µg of reporter construct in combination with 3 µg of negative
control DNA (pcDNA3; Invitrogen), STAT1, or IRF-1 expression vector was
added to each well, and the dishes were incubated at 37°C in 5%
CO2. After 6 h, the precipitates were removed and the
cells were rinsed twice with phosphate-buffered saline. Culture medium
(2 ml per well) was added, and the plates were incubated for 12 h.
During this period for experiments involving TGF- treatment, the
culture medium was supplemented with 10 ng of TGF-1 (R & D
Systems)/ml. After 12 h, culture medium was removed and replaced
with fresh medium, with or without 500 U of recombinant human IFN-
(Genentech)/ml. Cells were harvested for luciferase assays 14 h
later. The STAT1 expression vector (generously provided by James
Darnell, Jr., Rockefeller University, New York, N.Y.) has been
previously described (19).
Transient transfections of P19 cells were performed by the calcium
phosphate technique described above with the following modifications:
cells were plated in 10-cm-diameter dishes at a density of 5 × 105 cells, each dish received 10 µg of reporter construct
in combination with 10 µg of control DNA or the IRF-1 expression
vector, culture medium (10 ml) was added, and cells were harvested for
luciferase assays 14 h later.
Luciferase assays were performed with an LB 953 AutoLumat (EG&G
Berthold) as previously described (
2). The protein content
of cell extracts was determined by the Bradford assay (
1).
Luciferase activity was measured as relative light units (RLU)
per
microgram of protein. Fold induction after treatments was
calculated by
dividing the luciferase activity of IFN-
-treated
samples by the RLU
of untreated
samples.
In vivo genomic footprinting.
Dimethyl sulfate (DMS)
treatment of cells and genomic DNA preparation were performed as
previously described (40). Cleaved genomic DNA was amplified
by using a ligation-mediated PCR protocol (57, 59). Ten
million cells were treated with 500 U of recombinant IFN-
(Genzyme)/ml for 4, 8, or 24 h before DMS treatment and genomic
DNA isolation. Three CIITA locus-specific primers were used to amplify
cleaved fragments from the upper strand of CIITA promoter IV: CIITA4
up1, 5'-CTACCGCTGTTCCCCG-3' (Tm=
61°C); CIITA4 up2, 5'-GCGGCAAGTCTGTGGCAGCTC-3'
(Tm = 65°C); and CIITA4 up3, 5'-GCGGCAAGTCTGTGGCAGCTCGTC-3' (Tm = 68°C). The ligation-mediated PCR procedure was also performed for the
lower strand, but no significant protections or enhancements were
observed. The primers used for the lower strand were CIITA4 lo1,
5'-GGGCCTGGGACTCTC-3' (Tm = 61°C);
CIITA lo2, 5'-GGGCTGGCCACTGTGAGGAAC-3'
(Tm = 65°C); and CIITA lo3,
5'-GGCTGGCCACTGTGAGGAACCGACTG-3' (Tm = 69°C).
Preparation of nuclear extracts and gel shift analyses.
Nuclear extracts were prepared by the method of Schreiber et al. from
2fTGH cells, uninduced and induced with 500 U of IFN-/ml for 14 h (47). The WT-IRF1/2CIITA oligonucleotide probe was as
follows: 5'-CTGCAGAAAGAAAGTGAAAGGGAAAAAGAACT-3'. The
additional oligonucleotide probes used as cold competitors were
MT-IRF1/2CIITA, 5'-CTGCAGAAAGAActtagAAGGGAAAAAGAACT-3', and
IRF-E, 5'-CGGCCGCTTTCGATTTCGCTTTCCCCTAAATGGCTG-3', an
oligonucleotide that contains an inverted IRF-1-binding site (55). Antibodies were purchased from Santa Cruz
Biotechnology. Gel shift analysis was performed as previously described
(55). Briefly, 5 µg of nuclear extract and 2.5 × 102 pmol of annealed and 32P-labeled
oligonucleotide probe (~100,000 cpm) were incubated in a reaction
mixture containing 50 mM KCl, 5 mM NaCl, 5% glycerol, 10 mM Tris (pH
7.9), 1.5 mM MgCl2, 1 mM dithiothreitol, and 2 µg of
poly(dI)(dC) for 20 min at room temperature. Antibodies were incubated
with nuclear extracts in the reaction mixture for 30 min on ice before
the addition of the probe. Complexes were resolved by electrophoresis
in 5% acrylamide-bisacrylamide (29:1) gels run in 0.5× Tris-buffered
EDTA (TBE) at 4°C and 20 mA.
| |
RESULTS |
Functional analyses of deletion mutations of promoter III map an
IFN--responsive region to the distal end of this 7-kb region.
The intent of this report was to understand the functional differences
of the two IFN--responsive promoters (promoter III and promoter IV)
of CIITA. This is important because different cell types may
selectively utilize these two promoters, resulting in distinct patterns
of immune stimulation in vivo. A previous report from our laboratory
showed that pIIICIITA.Luc, which contains a large 7-kb region upstream
of promoter III, included an IFN--responsive region. To
delineate this region, a series of internal deletion mutations (Fig.
1A) were produced. Three deletion
constructs containing the most distal 3,563, 2,181, and 1,068 bp of DNA
within the 7-kb fragment were linked to 668 bp of basal CIITA promoter
III sequence and cloned into the luciferase reporter gene vector,
pGL2-Basic. These plasmids were designated pIIIDEL1.CIITA.Luc,
pIIIDEL2.CIITA.Luc, and pIIIDEL3.CIITA.Luc, respectively. As shown in
Fig. 1B, all three constructs were IFN- inducible when transiently
transfected into human 2fTGH fibroblasts, although the inducibility
seen for plasmid pIIIDEL3.CIITA.Luc was reproducibly less. This maps
the minimal IFN--responsive region to the distal approximately 1 kb,
although the additional sequences found in pIIIDEL2.CIITA.Luc augment
the response. The pGL2-Basic vector plasmid and pIIIDEL4.CIITA.Luc, which contains the minimal B cell-promoter of CIITA promoter III, were
used as negative controls. The full-length IFN--inducible promoter
III plasmid, pIIICIITA.Luc, which was previously shown to retain full
IFN- inducibility, was used as a positive control.
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FIG. 1.
(A) Map of the 14-kb human CIITA gene fragment that
contains both IFN--inducible promoters of the CIITA gene. The
locations of the transcriptional start sites of the upstream
IFN--responsive promoter (promoter III) and the downstream promoter
(promoter IV) are shown by arrows. The location of the DNase
I-hypersensitive site that lies approximately 6 kb upstream of the
start site of promoter III is marked with an arrowhead. Locations of
the DNA fragments used in reporter constructs described in this report
are given (black boxes). Gray boxes indicate the 5' untranslated
regions in promoter III and IV constructs. A horizontally hatched box
denotes the location of the 668-bp region previously shown to be
required for constitutive basal promoter III activity in B cells
(41). Regions that confer IFN- inducibility are indicated
by diagonally and vertically hatched boxes for promoter III and
promoter IV, respectively. Open boxes show the locations of the STAT1
(GAS) and IRF-1 consensus binding motifs in promoter IV. H,
HindIII. (B) Deletion mutants that contain DNA sequences
located distant to promoter III of CIITA confer IFN- inducibility in
2fTGH cells. Transient transfections of 2fTGH cells were performed by
calcium phosphate coprecipitation. After 6 h, precipitates were
removed and culture medium was added with or without 500 U of
IFN-/ml. Cells were harvested for luciferase assays 14 h later.
Luciferase activity was measured in RLU per microgram of protein. Fold
induction after IFN- treatment was calculated by dividing the RLU of
IFN--treated samples by the RLU of untreated samples. Data shown are
the averages of three independent experiments. Error bars represent
standard errors of the means.
|
|
DNase I hypersensitivity analyses reveal sites located
approximately 5 kb upstream of the transcriptional start site of
promoter III and immediately adjacent to the start sites of both
promoter III and promoter IV.
Another way to determine the
functional importance of a DNA sequence is to examine for in vivo
hallmarks of protein-DNA interactions as revealed either by DNase I
hypersensitivity analysis or by genomic footprinting. Our group has
previously reported that a 6-kb region upstream of the transcriptional
start site of promoter III mediates the IFN- response
(41). New data presented in Fig. 1B further showed that the
most upstream 1 kb of DNA contains important regulatory sequences. The
DNase I hypersensitivity method was used to indicate the locations of
potential regulatory protein-DNA interactions, as this method can be
used to scan large regions of DNA for structural changes in chromatin.
A modified DNase I hypersensitivity method using ligation-mediated PCR
with optimization for amplification of long PCR fragments
was
established. The analysis was performed with U373-MG cells,
one of
several cell types for which we have previously shown the
IFN-
responsiveness of this region (
41). Double-stranded breaks
at hypersensitive sites were ligated to the blunt-ended linker
commonly
used in the in vivo genomic footprinting technique (
57).
Two
CIITA locus-specific primers were used in combination with
a
linker-specific primer to amplify fragments ending with a
hypersensitive
site. The CIITA-specific primers were also used to
generate a
probe for Southern blot analysis of the amplified fragments
(Fig.
2A). Amplification using an
intron-specific primer allowed detection
of hypersensitive sites 5' of
the promoter III start site. A DNase
I-hypersensitive site was
consistently observed approximately
5 kb upstream of this initiation
site (Fig.
2B, lanes 1 and 3).
This site was detectable before
induction with IFN-
, and upon
induction a slight increase in
sensitivity is observed. The location
of the hypersensitive site
correlates with the functional analysis
shown in Fig.
1B, which shows
IFN-
inducibility residing in the
furthest 1 kb of this 6-kb region
upstream of promoter III. Upon
using a higher concentration of DNase I,
the 5-kb site disappeared
and several hypersensitive sites were more
clearly visible in
the vicinity of the transcriptional start site (Fig.
2B, lanes
2 and 4). Promoter IV was analyzed by amplification in the
downstream
direction with a primer specific for sequences near the
initiation
site of promoter III (Fig.
2A). Hypersensitive sites were
detected
very close to the transcriptional start site for promoter IV
(Fig.
2C). Again, hypersensitive sites were detectable before
induction,
but an increase in DNase I sensitivity was clearly observed
after
5 h of IFN-
treatment (compare lanes 1 and 2 to 3 and 4).
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FIG. 2.
DNase I hypersensitivity analyses reveal hypersensitive
sites in the proximal promoters of both promoters III and IV and an
additional long-range hypersensitive site for promoter III. (A) Summary
of hypersensitivity analysis and graphic representation of the CIITA
genomic region showing the location of the primers and probe that were
used for detection. The hatched region represents the probe used for
Southern blot hybridization. The small arrows above (primer 104CIITA)
and below (primer CIITAint) the hatched region indicate the locations
of the primers used for the PCR. (B) Southern blot analysis of
PCR-amplified products using primer CIITAint to detect promoter
III-associated hypersensitive sites. The start site of the promoter is
designated by a filled arrow to the right of the panel. Estimated
positions of the hypersensitive sites are indicated with open arrows.
Lanes 1 and 2 represent results for uninduced cells that were treated
with 20 and 40 U of DNase I, respectively. Lanes 3 and 4 represent
results for cells that were induced with IFN- for 5 h and
treated with 20 and 40 U of DNase I, respectively. (C) Southern blot
analysis of PCR-amplified products with primer 104CIITA to detect
promoter IV-associated hypersensitive sites.
|
|
Genomic footprint analysis detects changes at putative STAT1,
IRF-1, and E-box binding sites in promoter IV.
In contrast to the
large span of endogenous DNA that is required to demonstrate IFN-
inducibility for promoter III, the IFN--responsive region of
promoter IV consists of approximately 400 bp of DNA located downstream
of promoter III (35). In addition, promoter IV uses a
different transcriptional start site (Fig. 1A). In vivo genomic
footprint analysis is the method of choice to define physiologically relevant sequences within such a relatively small region. Methylated genomic DNA was obtained from U373-MG cells that had either remained untreated or had been treated with IFN- for 4 to 24 h. IFN- treatment resulted in significant protections in promoter IV at three
predominant sites: adjacent to a putative STAT1-binding site (GAS),
within a putative IRF-1/IRF-2 site, and adjacent to an E-box motif
(Fig. 3). Protection at the guanine
residue that lies between the GAS and E-box sites was only present in
IFN--induced samples. These contacts were sustained even after
24 h of IFN- treatment. The only protections that were located
directly over a putative transcription factor binding site were found
in the IRF-1/IRF-2 site. There was a small amount of protection of this site before induction, but IFN- treatment resulted in a significant increase in the amount of protection. Analyses of methylated DNA obtained from another IFN--responsive cell line, 2fTGH, showed similar protections, while analyses of DNA from human Raji B cells showed no protections, which is consistent with B cells using promoter
III and not promoter IV (data not shown).
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FIG. 3.
The in vivo footprint of CIITA promoter IV reveals
protein-DNA contacts near the putative STAT1- and E-box-binding sites
and within the IRF-1 site. The sequence of the promoter region is shown
with the relevant cis-elements framed. Genomic footprints of
the upper strand are shown in the lower panel. Lane 1 represents
genomic DNA methylated in vitro to reveal the complete guanine ladder.
Lanes 2 through 5 show the results of a time course of IFN-
treatment using DNA from cells treated with DMS in culture. Open arrows
indicate bases that are protected from modification. Filled arrows
indicate bases for which modification is enhanced.
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|
Gel shift and supershift analyses verify the binding of IRF-1 to
its cognate binding site in promoter IV.
Gel shift and supershift
analyses were performed to identify the proteins that interact with the
in vitro-footprinted sequence. During the preparation of this
manuscript, another group also demonstrated STAT1 binding to promoter
IV in vitro (34). In the present study we examined actual
binding of IRF-1 to the putative IRF-1/IRF-2-binding site. This is
important because this site is also a potential IRF-2-binding site or
might be recognized by yet another member of the increasingly large IRF
family of DNA binding proteins (38). Furthermore, functional
analyses revealed a more significant function for the IRF site than the STAT1-binding site (see below). An in vitro gel shift analysis was
performed and demonstrated the formation of a complex on this site in
response to IFN- treatment (Fig. 4A,
compare lanes 2 and 3). Specific cold competitors consisting of either
the wild-type IRF-binding site from promoter IV (lane 4) or a consensus
IRF site (lane 6) eliminated the formation of this band, while a
competitor with a mutated IRF-1/IRF-2-binding site did not (lane 5).
Preincubation of the nuclear extracts with an anti-IRF-1 antibody
resulted in a supershifted band, while preincubation with normal serum,
isotype-matched antibodies against IRF-2, or the p52 NF-
B subunit
did not (Fig. 4B, lane 4 versus lanes 3, 5, and 6). As shown in Fig.
4B, nuclear extracts were preincubated in the reaction mixture (with or
without antibody) for 30 min. This preincubation led to a decrease
and/or slight shift in the location of nonspecific bands versus the
pattern seen in Fig. 4A, for which there was no preincubation. There
are also slight differences in the nonspecific bands between lanes shown in Fig. 4B. The difference between lanes 2 and 3 probably reflects the difference in the protein content of the mixture in lane
3, which received added protein from the normal serum. Similarly,
slight changes in nonspecific bands between lane 2 and lanes 4 to 6 probably reflect differences in protein content between the normal
serum and the antibodies. In addition, a pmIRF.CIITA.Luc plasmid bearing a mutation of this IRF-1- binding site was not inducible by IFN- in transfection experiments performed in 2fTGH fibroblasts (Fig. 4C). Together, these results provide strong evidence
that the site is required for induction and can indeed be recognized by
IRF-1.
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FIG. 4.
IRF-1 binds to the proximal IFN--inducible promoter
(promoter IV). (A) Gel shift analysis indicates that one protein
complex is induced by IFN- (lane 2 versus lane 3) (arrow). Nuclear
extracts were from 2fTGH cells induced with 500 U of IFN-/ml for
14 h (IFN-) and uninduced cells (UNT). The probe spans the
IRF-1/IRF-2 site (Fig. 1A; Materials and Methods). Lane 1 contains
probe only. Oligonucleotide competitors are designated in the top row
and are used at 200-fold molar excess (200×). Abbreviations: WT,
homologous CIITA IRF-1/IRF-2 competitor; MT, cold competitor with a
mutated IRF-1/IRF-2 site; IRF-E, cold competitor with the IRF-1-binding
site of the TAP1 gene. NUC. EX., nuclear extract. (B) Incubation with
anti-IRF-1 induces a supershifted complex (star) and reduces the
formation of the inducible complex (arrow). Antibodies are indicated at
the top. Abbreviations: AB, antibody; NS, normal serum. (C) The IRF-1
site is required for induction of promoter IV by IFN-. Transient
transfections of 2fTGH cells were performed by calcium phosphate
coprecipitation using plasmids containing wild-type CIITA promoter IV
(pIVCIITA.Luc) and promoter IV with a mutated IRF-1 site
(pmIRF.IVCIITA.Luc). After 6 h, precipitates were removed and
culture medium was added with or without 500 U of IFN-/ml. Cells
were harvested for luciferase assays 14 h later. Fold induction
after IFN- treatment was calculated by dividing the RLU of
IFN--treated samples by the RLU of untreated samples. Data shown are
the averages of three independent treatment groups. Error bars
represent standard errors of the means. This experiment has been
repeated with similar results.
|
|
A comparison of the two promoters reveals that promoter IV is
responsive to both STAT1 and IRF-1 but promoter III is not responsive
to IRF-1.
Two predominant transcription factors which mediate the
positive regulatory functions of IFN- are STAT1 and IRF-1. The STAT1 protein resides in the cytoplasm in a nonactive form. Upon IFN- binding, the chains of the IFN- receptor are cross-phosphorylated by
JAK kinases. STAT1 is recruited, undergoes phosphorylation, homodimerizes, and translocates to the nucleus where it binds a
consensus IFN- activation sequence (GAS) and induces gene
transcription. Thus, activation of STAT1 by IFN- does not require de
novo protein synthesis. In contrast, the transcription of IRF-1 is
induced by IFN- treatment and requires both de novo transcription
and protein synthesis. In fact, a GAS element is present in the
promoter of the IRF-1 gene and STAT1 is a primary activator of IRF-1
transcription (43).
To more directly assess the involvement of IRF-1 and/or STAT1 in the
regulation of CIITA promoters III and IV, mutant cell
lines that
selectively lack functional IRF-1 and STAT1 activities
were used. U3A
fibroblasts selectively lack STAT1 activity. The
lack of functional
STAT1 resulted in greatly reduced activation
by IFN-
of both
promoter III (pIIIDEL1.CIITA.Luc) and promoter
IV (pIVCIITA.Luc) (Fig.
5A, CTR data). Introduction of a vector
constitutively expressing STAT1 and IFN-
treatment resulted in
a
20-fold induction of promoter IV and a 3.3-fold induction of
promoter
III by IFN-
. Fold induction after IFN-
treatment was
calculated
by dividing the luciferase activity of IFN-
-treated
samples by the
activity of untreated samples. The induction of
pIIIDEL1.CIITA.Luc by
STAT1 has been previously reported by our
laboratory (
41).
Interestingly, a promoter IV construct (pmGAS.IVCIITA.Luc)
in which the
GAS motif (TTCTGATAAA) was mutated to the sequence
GGAGTCTAAA retained sevenfold inducibility by IFN-
(Fig.
5A,
mutGAS). This finding suggests that the GAS site per se may not
be
absolutely required for induction. Since the pmGAS.IVCIITA.Luc
construct still retains the wild-type IRF-1 site, the requirement
for
STAT1 may be related at least partly to the reliance on STAT1
for
induction of IRF-1 in these cells. An ~50% decrease in induction
by
IFN-
of the activity of pmGAS.IVCIITA.Luc vs pIVCIITA.Luc
was also
seen in 2fTGH cells (data not shown).
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FIG. 5.
Regulation of the IFN--inducible promoters by STAT1
and IRF-1. Transient transfections of U3A and P19 cells with the
indicated plasmids (pIIIDEL1.CIITA.Luc for promoter III, pIVCIITA.Luc
for promoter IV, pmGAS.IVCIITA.Luc for promoter IV-mtGAS, STAT1 for
STAT1 expression plasmid, pcDNA3 for CTR, and IRF-1 for IRF-1
expression plasmid) were performed by calcium phosphate
coprecipitation. (A) U3A is a STAT1-defective cell line derived from
2fTGH. Cultures were untreated (UNT) or treated with 500 U of human
IFN-/ml (IFN) and harvested 14 h later. Luciferase activity was
measured as RLU per microgram of protein. Error bars represent standard
errors of the means. No IFN- induction was seen for control
plasmids. These experiments have been repeated with similar results.
(B) P19 is a murine embryonal carcinoma cell line that does not express
IRF-1. Precipitates were removed after 6 h, and fresh culture
medium was added. Cells were harvested for luciferase assays 24 h
later. Luciferase activity was measured as RLU per microgram of
protein. Results shown are the averages of three cultures per group.
Error bars represent standard errors of the means. These experiments
have been repeated with similar results. (C) U3A cells were
cotransfected with the indicated plasmids. Cultures were untreated or
treated with 500 U of human IFN-/ml and harvested 14 h later.
Luciferase activity was measured as RLU per microgram of protein. Error
bars represent standard errors of the means. No IFN- induction was
seen for control or IRF-1 plasmids (data not shown). These experiments
have been repeated with similar results.
|
|
To assess the involvement of IRF-1 in the control of the two CIITA
promoters, these promoter-reporter constructs were transfected
into the
IRF-1-deficient embryonal carcinoma cell line P19 (Fig.
5B). The
luciferase activity of the promoter III plasmid, pIIIDEL1.CIITA.Luc,
was not enhanced when cotransfected with an IRF-1 expression vector
into P19 cells. In fact it was consistently less than the activity
seen
in cells cotransfected with the pcDNA3 control vector (Fig.
5B). In
contrast, cotransfection with IRF-1 resulted in a dramatic
enhancement of the luciferase activity driven by promoter IV.
This
clearly indicates that promoter IV, unlike promoter III,
requires IRF-1
for
induction.
Although data presented in Fig.
5A shows that STAT1 plays an important
role in the control of promoter IV, an extensive mutation
of the
STAT1-binding site lowered induction by only ~50%. In light
of the
important role IRF-1 plays in activating promoter IV (Fig.
5B), a
likely explanation is that the primary route by which STAT1
controls
CIITA promoter IV is indirectly through activation of
IRF-1 gene
transcription. To further investigate the dependence
of promoter IV for
IRF-1, the promoter IV luciferase constructs
were cotransfected with an
the IRF-1 expression plasmid into U3A
cells (Fig.
5C). The activity of
the promoter IV construct was
activated 3.6-fold by IRF-1 expression in
these cells, which lack
STAT1 expression. Additionally, the
pmGAS.IVCIITA.Luc was responsive
to IRF-1 expression (6.7-fold) (Fig.
5C, mtGAS), which supports
the possibility that the STAT1 activation of
IRF-1 is an important
role of STAT1 in promoter IV
activation.
The IFN- induction of CIITA promoter IV is greater than that of
promoter III.
The extent of activation by IFN- for both
promoters was examined by a comparison of reporter constructs
containing either promoter III (pIIIDEL1.CIITA.Luc) or promoter IV
(pIVCIITA.Luc) fused to the luciferase reporter gene. While both
promoters contain IFN--responsive sequences, the inducibility of
promoter IV was consistently at least twofold greater than that of
promoter III in the 2fTGH cells (Fig. 6).
The pGL2-Basic plasmid is a promoterless negative control vector.
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FIG. 6.
IFN- induction of the promoter IV is greater than
that of promoter III. Transient transfections of 2fTGH cells were
performed by calcium phosphate coprecipitation. After 6 h,
precipitates were removed and culture medium was added with or without
500 U of IFN-/ml. Cells were harvested for luciferase assays 14 h later. Luciferase activity was measured as RLU per microgram of
protein. Fold induction after IFN- treatment was calculated by
dividing the RLU of IFN--treated samples by the RLU of untreated
samples. Data shown are the averages of four independent experiments.
Error bars represent standard errors of the means.
|
|
Both CIITA promoters are suppressed by TGF-, but the suppression
of promoter III is more complete.
Suppression of CIITA
transcription by TGF- is an important route by which class II MHC
hyperexpression is prevented in physiologic conditions (24,
37). We tested the effect of TGF- on the reporter constructs
bearing promoter III (pIIIDEL1.CIITA.Luc) or promoter IV (pIVCIITA.Luc)
sequences. As shown in Fig. 7 (lanes 3 and 4), the promoter III construct was inducible by IFN- and this
induction was almost completely suppressed by TGF-. While promoter
IV was also inducible by IFN-, TGF- lowered the luciferase activity of pIVCIITA.Luc by only 50% (lanes 7 and 8). Treatment with
TGF- alone lowered the basal activity of both promoter III (41) and promoter IV, which indicates that TGF- may
interfere with promoter activity even in the absence of IFN-
(compare lanes 1 and 2 and lanes 5 and 6). The higher basal activity
seen in this experiment for the promoter III plasmid versus the
promoter IV plasmid was not a consistent finding, but the more intense suppression of promoter III by TGF- was a consistent finding.
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FIG. 7.
TGF- suppresses both promoters, but suppression of
promoter III is more pronounced. Transient transfections of 2fTGH cells
were performed by calcium phosphate coprecipitation. After 6 h,
precipitates were removed and culture medium was added with (TGF) or
without (UNT) 10 ng of TGF-/ml. After 12 h, culture medium was
changed to medium with (IFN) or without (UNT) 500 U of IFN-/ml.
Cells were harvested for luciferase assays 14 h later. Luciferase
activity was measured as RLU per microgram of protein. Data shown are
the averages of three cultures per group. Error bars represent standard
errors of the means. These experiments have been repeated with similar
results.
|
|
| |
DISCUSSION |
The induction of genes by the type I and II IFNs has been
extensively studied and remains a foundation for our understanding of
other cytokine pathways. Through elegant biochemistry, somatic mutagenesis, and gene complementation, many of the molecular mediators have been defined. For the type II IFN pathway, it is well known that
IFN- binds to its cognate receptor, resulting in receptor phosphorylation and the docking of the STAT1 protein. STAT1 is in turn
phosphorylated, and this modification leads to the formation of a
homodimer (8) (Fig. 8). The
homodimer is then translocated into the nucleus to bind DNA promoter
elements that activate gene expression. On another level, the IRF-1
transcription factor has a STAT1-binding site in its promoter and is
dependent on STAT1 for its transcriptional activation (43).
Thus, STAT1 and IRF-1 are two prominent transcriptional mediators of
the IFN- pathway.
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FIG. 8.
Model of the regulation of class II MHC genes by
IFN-. B-cell constitutive expression of CIITA is mediated by the
proximal 5'-flanking sequences of promoter III (horizontally hatched
box). In contrast, induction of this promoter by IFN- is mediated by
distal upstream sequences (diagonally hatched box). Binding of IFN-
to its receptor activates JAK kinases which results in phosphorylation
of STAT1. It is likely that STAT1 activation is accompanied by
activation of the CIITA promoter directly via STAT1 binding to
sequences in this region (black arrow). In addition, STAT1 activation
induces transcription of CIITA promoter IV both by binding directly to
sequences in this promoter (open arrow) and by inducing the
transcription of IRF-1 that is also required for promoter activation
(dashed arrow). CIITA then activates transcription of the class II MHC,
Ii, and DM genes through common sequences found in the promoter regions
of these genes. Binding of TGF- to its receptor interferes with
CIITA gene expression by attenuating the basal activity of both CIITA
promoters. It is likely that suppression by TGF- occurs by a
mechanism that is distinct from the pathway of induction by IFN-.
|
|
Although many of the players in the IFN- pathway have been defined,
one major unresolved issue in the pathway of IFN--induced gene
activation is the induction of class II MHC genes. We and others have
shown more than a decade ago that the promoter sequences that mediate
IFN- induction of class II MHC genes contain the W, X, and Y motifs
(16, 28, 53). None of these motifs resemble any other
IFN- consensus sequences that have been described. Using somatic
genetics, two other groups have identified cell lines that are
selectively defective in the IFN- induction of class II MHC genes
but not other IFN--responsive genes (27, 30). Together,
these data indicated that the induction of class II MHC genes requires
molecular mediators that are unique to this pathway. On the other hand,
the analysis of in vitro-generated cell lines indicated that the lack
of STAT1 and IRF-1 leads to the lack of and lowering of class II MHC
expression, respectively. These studies clearly demonstrated that
these classical molecules, identified in the IFN- induction pathway,
are critical for the induction of class II MHC genes by IFN-
(18, 32, 50). Therefore, class II MHC gene induction must
rely on the presence of STAT1 and IRF-1, yet its own IFN--responsive
promoter sequences do not contain apparent STAT1 or IRF-1 binding sites.
The identification of the CIITA molecular provided the crucial missing
link in the elucidation of this pathway. CIITA per se is induced by
IFN- treatment (4, 6, 52), and its expression is greatly
reduced in STAT1/ gene knockout mice (32)
and decreased in IRF-1/ gene knockout mice
(18). How STAT1 and IRF-1 control the CIITA promoter is one
of the important questions addressed by the present report. Data
presented here show that the answer is complex. The CIITA gene has two
IFN--responsive promoters: one is contiguous with the B-cell
promoter (promoter III); a second uses a different transcriptional
start site and lies downstream of the B-cell promoter (promoter IV)
(Fig. 8). The IFN- responsiveness of the former is the weaker of the
two when assayed in vitro, although it is clearly responsive to the
addition of either IFN- or STAT1 but not IRF-1. It is contained in a
region that is located as far as 6 kb away from the B-cell
transcriptional start site. In contrast, promoter IV yields a stronger
IFN- response in vitro, is well contained, responds to the addition
of IFN-, and requires STAT1 and IRF-1 for optimal gene expression.
The two promoters show differences in the vigor of their response to
IFN- in vitro, but it should be noted that many important distally
located promoter regions were not initially recognized until transgenic
mice were used in their analysis. In contrast to in vitro analyses,
such distal sequences are frequently critical for gene expression in vivo. It will be of interest to determine the respective roles of these
two promoters in vivo.
The differential strengths of these two promoters may also be related
to their dependence on the STAT1 and IRF-1 factors. While both STAT1
and IRF-1 activate promoter IV, promoter III is only activated by STAT1
(Fig. 8). A cooperatively between STAT1 and IRF-1 may be the reason for
the enhanced response of promoter IV to IFN-. Interestingly, an
examination of sequence of the IFN--responsive region of promoter
III has revealed two potential GAS sites (data not shown). The
activation of STAT1 is an immediate response and does not require
protein synthesis, while the activation of IRF-1 is a secondary
response that requires protein synthesis and prior activation of other
molecules, including STAT1. It has been shown that STAT1 mediates a
faster IFN- response, while IRF-1 mediates a slower one. The
availability of two promoters with differential responses to IRF-1 but
similar responses to STAT1 may provide a mechanism to allow the fine
tuning of class II MHC gene induction in different tissues. Prolonged
expression of class II MHC in tissues that might be prone to autoimmune
recognition would not be beneficial to the host, and these might be
prevented if the tissue favors the use of promoter III and not IV. On
the other hand, sustained class II MHC induction might be preferential in the elimination of pathogens, and both promoters might then be
utilized. It is of interest that a careful examination of a previous
report indicates to us that IFN- induces promoter III in some cells
but not others (35). It is important to determine the
differential usage of promoters III and IV by cells in various physiologic states that lead to heightened class II MHC expression, such as autoimmune disorders and immune activation by pathogenic or
allogenic foreign antigens.
During the preparation of this manuscript, another group reported the
induction of promoter IV (34). Their and our reports are in
agreement as to the induction of promoter IV by IFN-. Gel shift and
supershift analyses in this report additionally show the binding of
IRF-1 to the CIITA promoter and the critical role of IRF-1 in
activating promoter IV. In vivo footprint analyses shown in this report
lend further credence to the physiologic importance of the IRF-1 target
site of promoter IV in intact cells. The involvement of both of these
factors was further shown in the present report by the use of IRF-1-
and STAT1-negative cell lines. Our study significantly extends the
former findings by demonstrating that although the IFN--induced
response can be mediated by both promoters III and IV, the two show
differential dependency on STAT1 and IRF-1 (Fig. 8).
In contrast to the IFN- pathway, the induction or inhibition of
genes by TGF- is not well understood. Several early mediators of
this pathway have been well studied, and it is generally accepted that
the Smad2, Smad3, and Smad4 proteins are involved, as all three
molecules are required for the physiologic function of TGF- (22). More recently, two proteins termed FAST-1 and FAST-2
that also participate in this pathway have been identified
(23, 60). Although it is currently a focus of much research,
the exact mechanism(s) of TGF--induced gene expression is not yet
well defined. Some studies have shown that TGF- can activate
AP-1-containing sequences (21); however, the role of AP-1 in
the expression of genes that are biologically activated by TGF- is
less well established.
Even less understood is the process by which TGF- suppresses gene
expression, and the study of suppression of CIITA transcription by
TGF- could provide important insight into this. The impetus for
understanding the suppression of class II MHC gene expression by
TGF- is strong, attributed to the physiologic importance of this
suppression. The study of TGF/ gene knockout mice
demonstrated that the primary phenotype of these mice is the existence
of hyperactivated T-cell responses. To determine if such responses are
due to a lack of class II MHC downregulation due to the absence of
TGF-, TGF-/ I-A/ double knockout
mice were produced and found not to exhibit the hyperactivated T-cell
state (26). This finding provides strong evidence that an
important biologic role of TGF- is to reduce the level of class II
MHC expression. Uncontrolled elevation of class II MHC expression in
the absence of TGF- leads to T-cell activation and pathologic sequelae.
In light of the important physiologic context of class II MHC gene
suppression by TGF-, the present study shows that its negative
regulation of class II MHC occurs through the suppression of both CIITA
promoters III and IV (Fig. 8). The suppression of promoter III is more
complete than that of promoter IV, which likely explains the divergent
pattern of TGF- suppression of class II MHC found in different cell
types. Presumably, cells that preferentially use promoter III would be
more susceptible to TGF- suppression. Preliminary data indicates
that the basal 668-bp region within promoter III is sufficient to
mediate the suppression of basal activity by TGF- (42).
With this finding, the small region in each of these two promoters that
mediates TGF- suppression is well defined, such that detailed
mutagenesis is feasible, and should provide important insights toward
understanding how TGF- suppresses class II MHC gene expression.
Importantly, this provides a unique model for understanding how TGF-
suppresses genes that are physiologically relevant.
In conclusion, this report provides a comprehensive analysis of how two
crucial cytokines control the expression of the CIITA gene. These data
provide important information linking the binding of cytokines to
receptors at cell surfaces to the induction or suppression of CIITA,
leading ultimately to the alteration of class II MHC gene expression.
Both the activator, IFN-, as well as the repressor, TGF-, can
alter the promoter activity of CIITA. In turn, alterations in CIITA
expression control the expression of class II MHC molecules, as well as
other molecules important in class II MHC antigen presentation. The
IFN- pathway utilized for CIITA promoter activation is complex and
may reflect the nature of class II MHC gene regulation in different
tissues and under different physiologic conditions. The
TGF--mediated suppression of class II MHC may be utilized to dissect
the poorly understood process of TGF--mediated gene repression.
| |
ACKNOWLEDGMENTS |
This work was supported by grants AI029564, AI41751, AI41580, and
NS34190 to J.P.-Y.T. J.F.P. is a Postdoctoral Fellow of the
National Multiple Sclerosis Society (grant FG-1173-A-1).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Lineberger
Comprehensive Cancer Center, Department of Microbiology and Immunology, CB 7295, University of North Carolina at Chapel Hill, Chapel Hill, NC
27599. Phone: (919) 966-5538. Fax: (919) 966-3015. E-mail: panyun{at}med.unc.edu.
| |
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Abstract
Introduction
