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Molecular and Cellular Biology, January 2000, p. 713-723, Vol. 20, No. 2
0270-7306/0/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
A GATA Box in the GATA-1 Gene
Hematopoietic Enhancer Is a Critical Element in the Network of GATA
Factors and Sites That Regulate This Gene
Shigeko
Nishimura,1
Satoru
Takahashi,1
Takashi
Kuroha,1
Naruyoshi
Suwabe,1
Toshiro
Nagasawa,2
Cecelia
Trainor,3 and
Masayuki
Yamamoto1,*
Center for Tsukuba Advanced Research Alliance
and Institutes of Basic Medical Sciences1 and
Clinical Medicine,2 University of
Tsukuba, Tsukuba 305-8577, Japan, and Laboratory of Molecular
Biology, National Institute of Diabetes and Digestive and Kidney
Diseases, National Institutes of Health, Bethesda, Maryland
208923
Received 5 April 1999/Returned for modification 18 May
1999/Accepted 18 October 1999
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ABSTRACT |
A region located at kbp 
3.9 to 2.6 5' to the first
hematopoietic exon of the GATA-1 gene is necessary to
recapitulate gene expression in both the primitive and definitive
erythroid lineages. In transfection analyses, this region activated
reporter gene expression from an artificial promoter in a position- and
orientation-independent manner, indicating that the region functions as
the GATA-1 gene hematopoietic enhancer (G1HE). However,
when analyzed in transgenic embryos in vivo, G1HE activity was
orientation dependent and also required the presence of the endogenous
GATA-1 gene hematopoietic promoter. To define the
boundaries of G1HE, a series of deletion constructs were prepared and
tested in transfection and transgenic mice analyses. We show that G1HE
contains a 149-bp core region which is critical for GATA-1
gene expression in both primitive and definitive erythroid cells but
that expression in megakaryocytes requires the core plus additional
sequences from G1HE. This core region contains one GATA, one GAT, and
two E boxes. Mutational analyses revealed that only the GATA box is
critical for gene-regulatory activity. Importantly, G1HE was active in
SCL
/ embryos. These results thus demonstrate the
presence of a critical network of GATA factors and GATA binding sites
that controls the expression of this gene.
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INTRODUCTION |
GATA-1 gene expression is
essential for hematopoietic cell differentiation (reviewed in reference
33). The transcription factor GATA-1 is expressed in
erythroid cells, megakaryocytes, eosinophils, and mast cells (9,
20, 36), as well as in Sertoli cells in the testis (6,
35). Two promoters, or first exons, exist in the
GATA-1 gene (6). The distal (IT) promoter specifies the expression of the GATA-1 gene in Sertoli
cells, whereas the proximal (IE) promoter, located between the IT exon and the common coding exons, directs GATA-1 gene expression
in the hematopoietic lineages (6). Gene ablation experiments
of GATA-1 demonstrate that GATA-1 is required for the
differentiation of erythroid cells and also for platelet formation in
the final stage of megakaryopoiesis (18, 23-26). GATA-1 is
also important for the formation of connective tissue type mast cells
(4).
We previously identified critical regulatory regions for expression of
the GATA-1 gene in erythroid-lineage cells with a
-galactosidase (lacZ) reporter gene in a transgenic-mouse
analysis (17). Transgenic mouse lines bearing a DNA fragment
beginning at kbp 3.9 5' to the IE exon and extending through the
second exon, when fused to a lacZ gene (IE3.9intLacZ),
recapitulated GATA-1 gene expression in both primitive and
definitive erythroid cells. LacZ activity was abolished in transgenic
mouse lines bearing a smaller fragment extending from kbp 2.6 (5' to
IE) through the second exon (IE2.6intLacZ), indicating that the 1.3-kbp
region acts as an upstream activating element (UE) (17). UE
contains a region corresponding to a DNase I-hypersensitive site 1 (21). In transgenic mice with a 3.9-kbp fragment, including
UE but lacking the first intron (IE3.9LacZ), the LacZ reporter was
expressed only in primitive erythroid cells, not in definitive
erythroid cells. As before, deletion of UE from the construct
(IE2.6LacZ) ablated this primitive cell-specific LacZ expression. These
results suggest the existence of at least two regulatory regions in the
GATA-1 gene, i.e., UE and the first intron element
(17). In a rescue experiment with our GATA-1 gene
knockdown mouse (26), we have demonstrated that the DNA fragment extending from UE through the second exon is sufficient to
recapitulate the physiological level of GATA-1 gene expression (S. Takahashi and M. Yamamoto, unpublished data). Thus the UE fragment is
one of the regions required for complete GATA-1 gene regulatory activity.
Upstream activating sequences such as UE frequently contain enhancers
that can activate transcription from core promoters in a position- and
orientation-independent manner and can activate transcription from
heterologous promoters (1, 2). These characteristics of
enhancers have been established in vitro, in transfection analyses with
tissue culture cells (for example, see reference
12). We speculated, however, that novel
characteristics of enhancers would be revealed when these elements were
tested in vivo in transgenic-mouse assays, leading to the development of new concepts in gene regulation. Indeed, in this study we compared the activity of UE in transgenic mice and in a transfection assay with
K562 cells. UE was found to satisfy the classic criteria of an enhancer
in the transfection assay and consequently was renamed the
GATA-1 gene hematopoietic enhancer (G1HE). However, when
G1HE was integrated into the mouse genome, its activity was more
restricted. We also performed a detailed dissection of G1HE to
delineate a core region, using both the reporter transfection and
transgenic-mouse assays, and assessed the importance of each cis-acting element in the core region for stage- and
lineage-specific expression of GATA-1. The results of these analyses
demonstrate that a network of GATA factors regulates the expression of
the GATA-1 gene during hematopoietic cell differentiation,
through the GATA box in G1HE, and that G1HE consists of two elements
which determine erythroid or megakaryocyte lineage specificity.
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MATERIALS AND METHODS |
Construction of plasmids and generation of transgenic mice.
Various reporter genes were constructed by using restriction enzyme
sites in the GATA-1 gene regulatory regions. The
lacZ gene in pSV (Clontech) was used as a reporter gene
for the transgenic-mouse analysis. An EcoRI site in the
first intron was deleted (delE) from pIE3.9intLacZ (17). A
series of G1HE deletion constructs and all the point mutant constructs
were made with the delE construct. To make pHE-SV40-LacZ and
pHE-TK-LacZ, a genomic BamHI (kbp 3.9)-EcoRI (kbp 2.6) restriction fragment (G1HE) was inserted into pSV and
pTK (Clontech), respectively. The firefly luciferase
(LUC) gene was used as a reporter gene for the transfection
analysis. To make pHE-SV40 and inverted HE-SV40, the
BamHI-EcoRI fragment was inserted into the pGL3
promoter vector in both orientations (Promega). Transgenic mice were
generated by standard methods (5).
Transfection analysis.
LUC reporter plasmids were
transfected into K562 cells (5 × 106 cells/sample) by
the DEAE-dextran procedure as described previously (7), and
the cells were grown for 24 h. In each experiment, plasmid (10 µg) was transfected in triplicate. Preparation of cell lysates and
measurement of LUC activity were carried out with a LUC assay kit (TOYO
INK) as specified by the supplier. LUC activity was normalized by the
transfection efficiency, determined by using control sea pansy
luciferase activity. Cotransfection of pEF-SP (13) did not
interfere with the activity of our reporter constructs.
Analysis of transgenic mouse embryos and yolk sacs.
For
whole-mount 5-bromo-4-chloro-3-indolyl--D-galactoside
(X-Gal) staining, embryos at embryonic day 8.5 (E8.5) or E9.5 were fixed at room temperature for 30 min in 1% formaldehyde-0.2%
glutaraldehyde-0.02% Nonidet P-40 in phosphate-buffered saline (PBS,
pH 7.3). After being washed with PBS, the embryos were incubated
overnight at 37°C in PBS containing 2 mM MgCl2, 5 mM
K3Fe(CN)6, 5 mM
K4Fe(CN)6 and 1 mg of X-Gal per ml. For section
staining, embryos at E15.0 were fixed and incubated overnight at 4°C
in PBS-20% sucrose. Samples were embedded in Tissue-Tek OCT compound
(Sakura Finetechnical, Tokyo, Japan) and rapidly frozen. Cryosections
were stained at 37°C for 8 h with X-Gal. Genomic DNA was
purified from the yolk sacs and embryos, and integration of transgenes
was verified by PCR with a set of primers (primers 2 and 3) described
previously (17). Another set of primers, beta-gal1 and
beta-gal2, corresponding to the sequences in the lacZ gene,
were also used; their sequences are 5'-ACCGACTACACAAATCAGCG-3'
and 5'-CAACCACCGCACGATAGAGA-3', respectively.
Preparation of nuclear extract.
Mouse erythroleukemia (MEL)
cells were used for detection of DNA binding proteins. Also, GATA-1,
GATA-2, or GATA-3 proteins were individually overexpressed in 293T
cells. To prepare nuclear extract, MEL cells were washed twice and
collected by centrifugation to measure the packed-cell volume (PCV).
The cells were then washed twice in 5 PCV of buffer A (10 mM HEPES [pH
8.0], 1.5 mM MgCl2, 10 mM KCl, 0.5 mM dithiothreitol,
protease inhibitors), resuspended in buffer A (3 PCV), and incubated on
ice for 15 min. They were then homogenized. Nuclei were collected by
centrifugation, and the packed-nucleus volume (PNV) was measured. The
nuclei were resuspended in 2 PNV of buffer C (20 mM HEPES [pH 8.0],
1.5 mM MgCl2, 420 mM KCl, 0.2 mM EDTA, 25% [vol/vol]
glycerol, 0.5 mM DTT, protease inhibitors). The suspension was mixed
gently for 30 min at 4°C and centrifuged, and aliquots of the
supernatant were frozen immediately in liquid nitrogen and stored.
EGMSA.
Electrophoretic gel mobility shift assay (EGMSA) was
performed as described previously (32, 34). MEL and 293T
cell nuclear extracts were incubated at room temperature with a
32P-labeled consensus E-box-GATA oligonucleotide (9-bp
spacing) (32), GGE, GGmE, or GGEm probe (see Fig. 7A).
Competitor oligonucleotides or specific antibodies raised against
GATA-1 (N6) or E2A (SC-349X Santa Cruz) were added to the reaction
mixture 15 min after the start of incubation. After an additional
15-min incubation, DNA-protein complexes were separated from the free
probe by nondenaturing polyacrylamide gel electrophoresis (4%
polyacrylamide) and analyzed by autoradiography.
Analysis of SCL homozygous mutant mice.
Transgenic mice
bearing pIE3.9intGFP were newly prepared. SCL knockout mutant mice
(22) were obtained from Jackson Laboratory. The heterozygous
SCL mutant mice were mated with GFP transgenic mice. The
SCL/+::GFP+ mice were
then intercrossed to generate mice with the
SCL/::GFP+ genotype.
Because the SCL homozygous mutant mice die by E10.5, embryos were
analyzed at E9.5. For genotype screening, the neomycin resistance gene
and wild-type allele were analyzed by PCR. The SCL mutant allele was
amplified with a set of primers for the neo gene
(27). The PCR conditions were denaturation for 30 s at
94°C, annealing for 30 s at 55°C, and extension for 30 s
at 72°C (30 cycles). Amplification of wild-type allele was performed with primers TALS1 (5'-CACCAGACAAGAAACTAAGC-3') and TALAS1
(5'-ATAGGAAGGCAAGTCTCAGT-3'). The PCR conditions were
denaturation for 30 s at 94°C, annealing for 30 s at
56°C, and extension for 1 min at 72°C (35 cycles). The GFP gene was
amplified with primers GFPS (5'-AGCAAGGGCGAGGAGCTGTTCACC-3') and GFPAS (5'-TGCCGTCGTCCTTGAAGAAGATG-3'). The PCR
conditions were the same as for neo gene amplification (30 cycles).
| |
RESULTS |
G1HE functions in an orientation-dependent manner in an
F0 assay.
To examine whether UE of the
GATA-1 gene (17) actually fulfills the criteria
for an enhancer, we fused the 1.3-kbp UE fragment to the simian virus
40 (SV40) promoter and LUC gene. This reporter construct was
transfected into K562 cells. The addition of the UE fragment stimulated
expression from this reporter 16-fold (data not shown). When UE was
tested in the opposite orientation from that of the normal gene, it
activated LUC reporter gene expression eightfold. Thus, UE
can enhance reporter gene transcription from a heterologous promoter
regardless of orientation and distance, satisfying the classical
criteria for an enhancer; it is subsequently referred to as G1HE (see above).
To examine whether G1HE also functions as an enhancer in vivo after
integration into chromatin, we used a transgenic "blue" mouse
system with the lacZ reporter gene. We previously detected G1HE activity by comparing transgenic mouse lines carrying the IE3.9intLacZ construct with lines containing IE2.6intLacZ, which lacks
G1HE (17). Whereas erythroid cell-specific expression of the
reporter was reproduced in the former mice, there was no significant
blue staining in E8.5 yolk sac cells or E12.5 fetal liver cells of the
latter transgenic mouse embryos. Since making a large number of
transgenic mouse lines was technically not feasible, we examined
transgenic founder mice (F0 or G0 for
generation 0) to analyze lacZ reporter gene expression
during primitive-stage hematopoiesis in the yolk sac. The yolk sacs of
mouse embryos at E8.5 or E9.5 were stained directly with X-Gal. A
typical whole-mount staining pattern of IE3.9intLacZ at E8.5 is shown
in Fig. 1 (17). Intense blue
staining was seen in the transgenic-mouse yolk sacs (Fig. 1A and data
not shown), whereas normal yolk sacs and embryos contained essentially
no positively stained cells under these assay conditions (Fig. 1B).
Only embryos with more than 10 blue-stained blood islands in the yolk
sac were scored positive.
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FIG. 1.
Whole-mount LacZ staining of an E8.5 yolk sac of a
IE3.9intLacZ transgenic mouse. (A) Typical positively stained yolk sac
blood islands, in which the blue area indicates LacZ activity.
Primitive erythroid cell-specific expression of LacZ activity is
observed. (B) A transgene-negative littermate.
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In the IE3.9intLacZ transgenic F
0 embryos, six of nine yolk
sacs were positive (Fig.
2A). Position
effects due to the integration
site are commonly observed in
transgenic-mouse analyses and are
probably responsible for the three
negative cases. This result
is in agreement with our previous
transgenic-mouse analysis (see
above). When G1HE was moved 2 kbp 5' of
the original position,
two of nine yolk sacs still stained positively
(Fig.
2A). Similarly,
six out of six yolk sacs were positive when G1HE
was moved 500
bp closer to the reporter gene. While the magnitude of
the stimulation
varies, G1HE can obviously activate transcription from
multiple
locations. The position independence of G1HE clearly indicated
that this element itself is sufficient for enhancer activity.
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FIG. 2.
Functional analysis of G1HE activity by a transgenic
mouse assay. (A) The mouse GATA-1 locus is shown at the top;
exons are depicted as solid boxes, and G1HE is shown as HE.
Abbreviations of the restriction enzyme sites: B, BamHI; E,
EcoRI. Arrows indicate whether G1HE is cloned in the sense
or antisense orientation relative to the promoter. A reporter
lacZ gene was fused to exon II of the GATA-1
gene. In the IE3.9intLacZ, IE5.9intLacZ, IE3.4intLacZ, and inverted HE
constructs, an EcoRI site in intron I was deleted (delE).
The number of embryos staining positive for LacZ [LacZ(+)] and the
total number of transgenic embryos [Tg(+)] are shown. (B) Ectopic
LacZ expression in an embryo with a HE-TK-lacZ transgene. In this
embryo, LacZ activity was observed in the rhombomere and heart.
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We then tested a construct in which G1HE was inverted. In contrast to
results obtained with the parent IE3.9intLacZ, no positively
stained
yolk sacs were observed with this construct in a total
of eight samples
(Fig.
2A). This indicates that G1HE works in
vivo in an
orientation-dependent manner. In addition, the G1HE
fragment (normal
orientation) failed to activate transcription
from the SV40 or
thymidine kinase promoters, since no positively
stained yolk sacs were
observed. Since G1HE is able to activate
SV40 promoter in K562 cells,
the transgenic-mouse assay detects
a fundamentally different gene
regulatory activity from that detected
by the transient-transfection
assay. The mice carrying the thymidine
kinase promoter construct showed
ectopic blue staining at high
frequency (13 of 16 [81.3%]). However,
the staining patterns differed
among embryos, and the blood islands
remained completely unstained.
For instance, one F
0 embryo
showed rhombomere staining but no
yolk sac blood cell staining (Fig.
2B) (see Discussion). We conclude
that these signals were all ectopic.
Thus, G1HE is not sufficient
to confer tissue specificity on the
GATA-1 gene in vivo, but additional
regulatory sequences are
necessary. The orientation dependence
and promoter selectivity of G1HE
were observed only in transgenic
mice, not in transient-transfection
analyses.
A core sequence exists near the 5' end of G1HE.
The 1,174-bp
nucleotide sequence of G1HE is shown in Fig.
3, and potential transcription factor
binding sites are underlined. We have numbered the first nucleotide of
the BamHI site +1, and this is the 5' end of the fragment.
This sequence has been deposited in DDBJ/GenBank Database under
accession no. AB000965 and agrees in general with the partial sequence
reported by Ronchi et al. (21). The differences between the
two sequences probably reflect variation of mouse strains.
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FIG. 3.
Structure of the G1HE region. The sequence is numbered
from the BamHI site at kbp 3.9, which is the 5' end of
G1HE. Binding sites for transcription factors are underlined. Note that
E box 1, GAT, GATA, and E box 2 are mutated in the later analysis.
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To identify a core region, we prepared various truncated forms of G1HE.
We first inserted these into IE2.6intLUC and analyzed
the mutants by
transfection into K562 cells. When 137 bp was deleted
from the 5' end
of G1HE (
BamHI site), the LUC activity was notably
reduced
to the level of the IE2.6intLUC construct, indicating
that this 137-bp
sequence contains part of the core (Fig.
4).
Because a 91-bp deletion mutant
showed markedly more LUC activity
than the 137-bp deletion mutant did,
at least one important
cis-acting
element appeared to be
located between nucleotides (nt) 92 and
137. Similar results were
observed when the same series of deletions
was tested in a vector with
an SV40 promoter-driven reporter gene
(data not shown).
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FIG. 4.
Deletion analysis of G1HE in a transfection assay with
K562 cells. LUC activity of pIE2.6intLUC was set to 1, and the relative
LUC activities of other constructs are shown.
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We then tested the G1HE deletion mutants in a transgenic-mouse assay.
The yolk sac expression of LacZ in E8.5 or E9.5 transgenic
F
0 embryos was examined and scored as above. Approximately
65%
of embryos harboring the reporter plasmid with complete G1HE (Fig.
2) or with nt 29 through 1174 (Fig.
5A)
(6 of 9 and 7 of 11, respectively),
showed positively stained yolk
sacs. Similarly, 33% of embryos
with nt 40 to 1174 and 92 to 1174 constructs (2 of 7 and 3 of
8, respectively) were positive (Fig.
5A).
In contrast, no positively
stained yolk sacs were observed in embryos
with nt 138 to 1174
or shorter constructs. These results coincide very
well with those
of the transfection assay and confirm the importance of
the region
between nt 92 and 137. In addition, the decrease in the
frequency
of positive embryos from 65% to 33% suggests that the
region between
nt 29 and 92 may also contain some important regulatory
elements
(see below).
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FIG. 5.
Deletion analysis of G1HE activity in a transgenic-mouse
assay. (A and B) A series of 5' deletion constructs (A) and a series of
3' deletion constructs (B) were prepared and analyzed. F0
embryos were analyzed at E8.5 (or E9.5) or E14.5 (or E15.5) for LacZ
activity in primitive erythroid cells and definitive erythroid
cells/megakaryocytes, respectively. The numbers are the number of
embryos staining positive for LacZ/the total number of transgenic
embryos. (C and D) E14.5 livers of transgenic-mouse embryos bearing 3'
deletion constructs were stained with X-Gal. Embryonic livers with the
149-bp core region (C) and the 235-bp fragment (D) of GIHE,
respectively, are shown. Arrowheads indicate megakaryocytes.
Magnification, ×140.
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Meanwhile, we made three reporter constructs that truncate G1HE from
the 3' end. The smallest construct contained only the
5' 149 bp of G1HE
adjacent to the IE2.6intLacZ reporter gene (Fig.
5B). This construct
consequently lacked most of the G1HE sequence.
When tested in the
transgenic-mouse F
0 assay, the 149-bp fragment
alone could
activate transcription of the
lacZ reporter gene in
yolk sac
hematopoietic cells. Thus, the 149-bp region contains
the core enhancer
sequence of G1HE, which is sufficient to direct
specific GATA-1 gene
expression in primitive erythroid
cells.
We also carried out similar F
0 experiments for E14.5 or
E15.5 embryos to determine the activity of G1HE in definitive erythroid
cells and in megakaryocytes. As expected, the core 149-bp region
stimulated expression of the
lacZ reporter gene in
definitive
erythroid cells (Fig.
5B). Surprisingly, however, the 149-bp
region
failed to induce LacZ activity in megakaryocytes (Fig.
5C). In
contrast, a longer region of G1HE (1 to 235 bp) enhanced LacZ
expression both in definitive erythroid cells and in megakaryocytes
(Fig.
5D). These results suggest that in addition to the 149-bp
core
region, G1HE contains another regulatory region that specifies
GATA-1
gene expression in the megakaryocyte
lineage.
The consensus GATA box is essential for G1HE activity.
In
the region between nt 92 and 137, there is a
GATnnnnTTATCT (the underline indicates GATA) sequence
(Fig. 3). An E box (E box 2) resides 10 bp 3' to this GATA box. This
sequence arrangement is close to the binding site for a model
transcription complex, which includes the GATA-1, SCL, Lmo2, E2A, and
Ldb1 proteins (32). If a similar protein complex was formed
on the GATA and E boxes of G1HE, it might play an important role in
GATA-1 gene expression. To test the functional importance of
the GATA-box-E-box combination in vivo, we prepared several
lacZ transgene constructs that contain mutations in each
motif and tested their expression during both primitive and definitive
hematopoiesis. While mutations in the atypical GAT and in E box 2 did
not affect the enhancer activity at all, no positively stained
erythroid cells and megakaryocytes were observed in the yolk sacs or
fetal livers of the embryos containing mutations in the consensus GATA
box (Fig. 6). These results clearly
demonstrate that only the GATA box, and not E box 2, is essential for
G1HE activity in both primitive and definitive hematopoiesis.
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FIG. 6.
A GATA site in the core of G1HE is essential for the
GATA-1 gene expression in primitive erythroid cells,
definitive erythroid cells, and megakaryocytes. There are two E boxes,
an atypical GAT, and a consensus GATA box in the core of G1HE.
Mutations in each cis-acting element were tested in the
transgenic-mouse system. F0 indicates the transient transgenic assay,
and "line" indicates the F1 or F2 assay.
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We also noticed another E box (E box 1; CAAATG) between nt 29 and 39 of
G1HE. Deletion of this region reduced transcriptional
activity in the
transgenic-mouse analysis (see above). We therefore
mutated the E-box 1 sequence and examined this transgene construct
similarly. No decrease
in the frequency of the LacZ-positive embryos
was observed (Fig.
6),
indicating that E box 1 is also dispensable
for reporter gene
expression in this in vivo
analysis.
GATA factors bind to the GATA box.
To identify the molecule(s)
binding to the consensus GATA box in G1HE, EGMSA was performed. To this
end, we prepared three probes from the G1HE core region that contain
various combinations of the GATA boxes and the E box (Fig.
7A). These are GGE (wild-type sequence),
GGmE (mutation in the second GATA sequence), and GGEm (mutation in
E-box-2). We first tested three hematopoietic GATA factors for binding
to the wild-type GGE probe. GATA-1, GATA-2, and GATA-3 proteins were
expressed individually in 293T cells, and nuclear extracts were
prepared from these cells. All three hematopoietic GATA factors were
found to bind the GGE probe (Fig. 7B). Supershift experiments with
antibodies confirmed the identity of each GATA factor. These analyses
thus demonstrated that GATA-1, GATA-2, or GATA-3 could occupy the GATA
box in the core of G1HE.
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FIG. 7.
GATA factors can bind to the core GATA sequence of G1HE.
(A) Sequences of the consensus GE probe (9-bp spacing) (32)
and GGE probe of G1HE. The G1HE sequence is shown in bold type. The
GAT, GATA, and E-box sequences are boxed. The GGmE probe indicates the
GATA motif mutant of GGE probe, whereas the GGEm probe indicates the
E-box mutant of the GGE probe. Underlines show mutated sequences. (B)
GATA-1, GATA-2, and GATA-3 can bind to the GGE probe. Nuclear extracts
from 293T cells transfected with GATA-1 (lanes 3 to 5), GATA-2 (lanes 6 to 8), or GATA-3 (lanes 9 to 11) expression plasmids were examined.
Lanes 3, 6, and 9 show shifted bands with 0.2 µl of each extract,
while lanes 4, 7, and 10 show bands with 1.0 µl of each extract. The
bands in the latter condition were supershifted with specific
monoclonal antibodies against each GATA factor (lane 5, anti-GATA-1;
lane 8, anti-GATA-2; lane 11, anti-GATA-3). Lane 1 contains probe
alone. Lanes 2 and 12 show binding of 293T cell and MEL cell nuclear
extract, respectively, to the GGE probe. Of the hematopoietic GATA
factors, MEL cells express predominantly GATA-1, so that lane 12 serves
as a marker lane for GATA-1. (C) EGMSA with MEL cell nuclear extract.
The labeled consensus GE probe was incubated alone (lane 1) or with MEL
cell nuclear extract (lanes 2 to 5) for 15 min. Then cold consensus GE
oligonucleotide (lane 3), anti-GATA-1 antibody (lane 4), or anti-E2A
antibody (lane 5) was added to the reaction mixture. An asterisk in
lane 4 marks a band that was supershifted by the anti-GATA-1 antibody.
(D) Lanes 1 to 5 show EGMSA with the GGE probe. Labeled GGE probe was
incubated alone (lane 1) or with MEL cell nuclear extract (lanes 2 to
5) for 15 min. Then a 100-fold excess of cold GGE probe (lane 3),
anti-GATA-1 antibody (lane 4), or anti-E2A antibody (lane 5) was added
to the reaction mixture. Note that the high-molecular-weight complex
was not affected by the addition of anti-E2A antibody. GGmE probe (lane
6) or GGEm probe (lane 7) was used in the reaction instead of GGE
probe. An asterisk in lane 4 shows a band that was supershifted by the
anti-GATA-1 antibody.
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We also prepared a probe with the consensus GATA-box-E-box motif
(consensus GE), which was shown to mediate the formation
of a
high-molecular-weight complex (Fig.
7A) (
32). In good
agreement
with the previous analysis (
32), a GATA-1 band was
observed
with the consensus GE probe and nuclear extract from MEL cells
(Fig.
7C, lanes 2 and 5). Considering the results shown in Fig.
7B,
this band is most likely to represent monomeric GATA-1 binding
to the
consensus GE probe. Upon overexposure of the gel, we also
detected a
high-molecular-weight complex (Fig.
7C, lane 2), of
much reduced
intensity relative to the GATA-1 band. Both the GATA-1
and
high-molecular-weight bands were abolished in the presence
of an excess
of cold consensus GE competitor (Fig.
7C, lane 3),
indicating specific
binding. Inclusion of anti-GATA-1 antibody
in the reaction mixture
resulted in a large reduction of the high-molecular-weight
complex, as
well as in the appearance of a supershift of the GATA-1
band (Fig.
7C,
lane 4). Similarly, addition of anti-E2A antibody
destroyed the
high-molecular-weight complex with the consensus
GE probe (Fig.
7C,
lane 5), indicating that this complex contains
both GATA-1 and
E2A.
With the GGE probe, we also detected a high-molecular-weight band (Fig.
7D, lane 2), which was competed with a 100-fold excess
of cold GGE
(lane 3). The high-molecular-weight complex was disrupted
specifically
with an anti-GATA-1 antibody (lane 4) but not with
anti-E2A antibody
(lane 5). Importantly, whereas the amount of
high-molecular-weight
complex was markedly decreased with the
GGmE probe (a GATA site mutant
probe [lane 6]), the complex was
formed normally with the GGEm probe
(an E box 2 mutant probe [lane
7]). These results suggest that the
high-molecular-weight complex
with the GGE probe is distinct from that
formed on the consensus
GE probe, in that E2A may not be a major
constituent of the GGE
complex. The observation that the E box 2 in
G1HE is not important
for the high-molecular-weight complex formation
in gel shift analyses
is consistent with the results of
transgenic-mouse analyses (see
above).
G1HE is active in SCL-null primitive erythroid cells.
The
results thus far suggest that the consensus GATA box at nt 133 is
essential for the G1HE activity whereas the E box 2 at nt 147 is not.
This conclusion is somewhat unexpected, since SCL, one of the E-box
binding transcription factors, is indispensable for hematopoiesis.
GATA-1 expression could not be detected in SCL-deficient embryos
(19). However, SCL may regulate GATA-1 gene
expression through interactions with GATA factors or with other
transcription factors, rather than by direct binding to the GATA-1 gene
promoter/enhancer. In this scenario, SCL does not necessarily bind the
G1HE E box directly but can still regulate GATA-1 gene expression. This
possibility was tested by mating heterozygous SCL knockout mice
(22) with IE3.9intGFP transgenic mice. The latter transgenic
mice express green fluorescence protein (GFP) reporter gene in yolk sac
hematopoietic cells under G1HE regulation.
Yolk sac hematopoietic cells in the
SCL+/::GFP+ E9.5 embryos
show clear green fluorescence (Fig.
8B;
panel A shows the yolk sac
and embryo proper), indicating that G1HE is
active in primitive
erythroid cells. The yolk sacs of wild-type
littermates with the
SCL+/+::GFP genotype did
not contain any green fluorescence-positive cells
(Fig.
8C and D). The
SCL/::GFP+ embryos
were very small and were not well developed (Fig.
8E).
However,
although the number was significantly decreased, some
green
fluorescence-positive cells were clearly visible in the
yolk sac (Fig.
8F). This result was quite reproducible. We found
green
fluorescence-positive cells in five
SCL/::GFP+ yolk sacs
from three independent litters. This result indicates
that G1HE can
support the initiation of transcription from the
GATA-1 promoter
without SCL, so that SCL is not the essential
constituent of
GATA-1 gene transcription initiation.
View larger version (73K):
[in this window]
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|
FIG. 8.
G1HE can activate transcription in SCL-null primitive
erythroid-cell progenitors. (A and B) Appearance of SCL heterozygous
and IE3.9intGFP transgene-positive
(SCL+/::GFP+) E9.5
embryo (A) and yolk sac (B). Green fluorescence-positive cells were
seen in the yolk sac. (C and D) A wild-type littermate without the GFP
transgene (SCL+/+::GFP)
did not show any GFP-positive cells. (E and F) An
SCL/::GFP+ embryo (E)
is severely anemic and has developmental defects, but a small number of
GFP-positive cells are clearly visible in the yolk sac (F).
|
|
| |
DISCUSSION |
The GATA-1 gene hematopoietic enhancer, G1HE, is a
powerful activator of transcription in a transgenic-mouse assay in vivo (17). In this study, we have demonstrated that G1HE acts as a classic enhancer element in a reporter transfection assay. Results of
a deletion analysis with both the transfection and transgenic-mouse systems indicate that the core 149-bp region within G1HE contains a
strong GATA-1 gene regulatory activity for the erythroid
lineage. A consensus GATA box, an atypical GAT box, and two E boxes
reside within the core region. Mutational analyses of these
cis-acting elements have revealed that while the consensus
GATA box is critical for the activity of G1HE in both primitive and
definitive hematopoiesis, the other elements are not. Hematopoietic
GATA factors GATA-1, GATA-2, and GATA-3 were all demonstrated to bind
to the consensus GATA box of G1HE. This result is quite intriguing,
since duplicated GATA boxes have been found in the IT promoter
(16) and the upstream region of the IE promoter (3, 15,
29). These GATA boxes are required for reporter gene expression
in transfection analyses. Taken together, these results demonstrate
that a network of GATA factors and binding sites regulate
GATA-1 gene expression in hematopoietic cells and suggest
that GATA-1 and/or other GATA factors work as key regulators in this
network through direct interaction with the cis-acting GATA
boxes in multiple regulatory regions. This network seems to be the
molecular basis for the erythroid cell-specific expression of the
GATA-1 gene.
We also found that while the core 149-bp region of G1HE was sufficient
to drive lacZ reporter gene expression in erythroid cells,
the region was inadequate to generate reporter gene expression in
megakaryocytes of E15 fetal liver. To attain megakaryocytic expression
of the reporter gene, a slightly longer region of G1HE (i.e., bp 1 to
235) was required. Since disruption of the GATA box at nt 133 in the
G1HE reporter resulted in loss of megakaryocytic expression of the
reporter gene, the core region was also required for the enhancer
activity of G1HE in the fetal liver megakaryocytes. These results thus
indicate that G1HE consists of multiple cis-acting elements
and that these elements have distinct functions in erythroid and
megakaryocytic lineage-specific gene expression.
G1HE can activate transcription in a position-independent manner from a
cognate promoter in both the transfection and transgenic-mouse assays.
Unlike in the transfection assay, however, the presence of the IE
promoter was necessary for the reporter genes to recapitulate the
endogenous GATA-1 gene expression profile in the
transgenic-mouse assay. Whereas G1HE activated the SV40 promoter in the
transfection analysis, it could not do so in the transgenic mice. These
discrepancies in G1HE function between the transfection and
transgenic-mouse assays may be due to the transgene configuration. In
the reporter transfection assay, the reporter gene exists transiently
in the nucleus as an episome outside the host genome. In contrast, the reporter gene is integrated into the transgenic mouse genome, where
chromatin structure and the influences of regulatory sequences surrounding the integration site can affect reporter gene expression. Thus, the transgenic-mouse assay is a more stringent test for correct
gene-regulatory activity than is the DNA transfection assay.
While inversion of G1HE relative to the IE promoter had only a
quantitative effect on reporter gene transcription in the transfection assay, proper orientation of G1HE is absolutely required for its activity in the transgenic mice. We do not know the basis for the
strict orientation dependence of the G1HE activity in vivo. One
plausible explanation is that the three-dimensional structure of the
protein complex interacting with the core enhancer (and/or promoter)
region may be crucial for transcriptional activation in a chromatin
configuration. In fact, a high-molecular-weight complex containing
GATA-1 was detected in nuclear extracts of MEL cells with the GGE probe
of G1HE. An alternative explanation is to assume that transcription
initiation at the GATA-1 locus is regulated by a tracking
mechanism and that the inverted G1HE may disturb the synthesis of long
RNA transcripts initiated from far upstream. These issues remain to be resolved.
A transcription factor complex containing GATA-1, SCL, and E2A
assembled by Lmo2 and Lbd1 was proposed to associate with DNA through
an E box and then to be stabilized by interaction with a GATA box in an
in vitro reconstitution analysis (32). Importantly, in G1HE,
E box 2 resides 10 bp 3' to the consensus GATA box, similar to the
arrangement of the DNA binding site used in the reconstitution assay.
Because this model has never been tested in vivo, we examined the
activity of each cis element in G1HE in detail. While
mutation of E box 2 did not affect the enhancer activity at all,
mutations in the consensus GATA box severely affected reporter gene
expression in yolk sacs, definitive erythrocytes, and megakaryocytes,
demonstrating that the GATA box is essential for the activity of G1HE
but E box 2 is not. In addition, a high-molecular-weight complex was detected with the GGE probe and the GGEm (E-box-mutated) probe in MEL
cell nuclear extracts, while its level was markedly decreased when the
GGmE (GATA box-mutated) probe was used. Our results also suggest that
the high-molecular-weight complex generated with the GGE probe may be
distinct from the complex formed with the consensus GE probe, in that
E2A is not involved in the GGE-based high-molecular-weight complex.
Thus, GATA-1 or other hematopoietic GATA factors bind to the GATA box
in G1HE and serve as an anchoring factor, as well as contributing to
the formation of the high-molecular-weight protein complex which
regulates GATA-1 gene expression.
An attractive model proposes that GATA-2 binds the GATA motif in the
early stage of differentiation whereas GATA-1 replaces GATA-2 in the
late stage. Three lines of evidence support this notion. First, we
previously demonstrated that G1HE is active in the GATA-1 knockdown
environment (26), suggesting that some other GATA factors
can substitute at the GATA box. Second, our recent experiment shows
that the GATA-1 knockdown mice can be rescued by GATA-2, and the GATA
box in G1HE is indeed occupied by GATA-2 in the mouse cells (Takahashi
and Yamamoto, unpublished). This indicates that other GATA factors can
actually substitute for GATA-1 in vivo. Third, GATA-1, GATA-2, and
GATA-3 can bind to the GATA boxes in the G1HE core (C. D. Trainor,
unpublished observation; see above); these sequences actually form a
GATA-pal configuration similar to other double GATA sites, to which
both GATA-1 and GATA-2 can bind (28). It has also been shown
that the expression of GATA-2 precedes that of GATA-1 in the
hematopoietic lineage (8, 11, 14, 30).
SCL-null mice were reported to die by E10.5 due to severe anemia
(19). mRNAs for GATA-1 and EKLF were not detected in E9.5 yolk sacs and embryos, suggesting that SCL is necessary for
GATA-1 gene expression. These findings thus appear
inconsistent with the results of our E-box mutation. To resolve this
discrepancy, we carried out an additional experiment, in which
SCL/ mice were crossed with IE3.9intGFP
transgenic mice. The latter mice express GFP reporter in yolk sac
hematopoietic cells under the regulatory influence of G1HE. The results
unequivocally demonstrated that GFP reporter is expressed in yolk sac
cells in the absence of SCL, thus excluding the possibility that SCL is
essential for initiation of G1HE activity. This data is in good
agreement with the recent rescue experiment of
SCL/ embryos by using a transgene that
expresses SCL under the influence of regulatory sequences from the
GATA-1 gene (31). In the latter mouse embryos,
the GATA-1 gene regulatory region drove the expression of
SCL cDNA in the absence of endogenous SCL protein, proving that SCL is
not required for transcription from the GATA-1 enhancer/promoter.
The reason for the marked decrease in the number of GFP-positive cells
in the yolk sacs of
SCL/::GFP+ embryos is
not clear. One plausible explanation is that SCL is essential for the
growth and/or differentiation of early primitive myeloerythroid
progenitors, so that without SCL, the hematopoietic compartment cannot
expand in the yolk sac. If this is the case, the GFP-positive cells may
correspond to the yolk sac progenitors of hematopoiesis. However, it is
technically not feasible to analyze the properties of the GFP-positive
cells in SCL/::GFP+ embryos,
and this point remains to be addressed.
Recently, the zebrafish GATA-1 gene-regulatory region was
examined in a transgenic-fish assay, and distal double GATA sites were
found to promote and maintain GATA-1 transcription (10). In
the zebrafish GATA-1 gene, a proximal CACCC box is also
critical for the initiation of GATA-1 gene expression in
hematopoietic cells. However, since the zebrafish GATA-1
gene sequence has diverged substantially from those of the mouse and
human GATA-1 genes, the cis-acting regulatory
elements are difficult to compare. For instance, we previously
identified a regulatory region in the first intron that specifies
GATA-1 gene expression in definitive erythroid cells
(17), but this intronic regulatory element does not appear
to be conserved in the zebrafish GATA-1 gene.
Our preliminary data suggests that the erythroid-cell specificity of
the GATA-1 gene also depends on the contribution of a regulatory element in the upstream promoter region (S. Nishimura, S. Takahashi, and M. Yamamoto, unpublished observation). Identification of
cis-acting elements that organize the lineage specificity of GATA-1 gene expression and elucidation of the intricate
relationships among the factors interacting with these elements are
apparently the focus of our future research.
| |
ACKNOWLEDGMENTS |
We thank N. Kajiwara, N. Kaneko, Y. Kikuchi, N. Kasai, K.-C. Lim,
J. Ohta, H. Motohashi, F. Sugiyama, N. Suzuki, and K. Yagami for help
and discussion.
This work was supported in part by Grants-in-Aids from the Ministry of
Education, Science, Sports and Culture, Core Research for Evolutional
Science and Technology (CREST), the Japanese Society for Promotion of
Sciences (JSPS), and NIH.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Center for TARA,
University of Tsukuba, 1-1-1 Tennoudai, Tsukuba 305-8577, Japan. Phone: 81-298-53-6158. Fax: 81-298-53-7318. E-mail:
masi{at}tara.tsukuba.ac.jp.
| |
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Molecular and Cellular Biology, January 2000, p. 713-723, Vol. 20, No. 2
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Abstract
Introduction
