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Blood, Vol. 96 No. 1 (July 1), 2000:
pp. 288-296
NEOPLASIA
AML1-MTG8 leukemic protein induces the expression of
granulocyte colony-stimulating factor (G-CSF) receptor through the
up-regulation of CCAAT/enhancer binding protein epsilon
Kimiko Shimizu,
Issay Kitabayashi,
Nanao Kamada,
Tatsuo Abe,
Nobuo Maseki,
Kazumi Suzukawa, and
Misao Ohki
From the Radiobiology Division, National Cancer Center Research
Institute, Tsukiji, Chuo-ku, Tokyo 104-0045, Japan.
 |
Abstract |
The t(8;21) translocation is one of the most frequent chromosomal
abnormalities associated with acute myeloid leukemia (AML). In this
translocation, the AML1 (CBFA2/PEBP2aB) gene is
disrupted and fused to the MTG8 (ETO) gene. The ectopic
expression of the resulting AML1-MTG8 fusion gene product in
L-G and 32Dcl3 murine myeloid precursor cells stimulates cell
proliferation without inducing morphologic terminal differentiation
into mature granulocytes in response to granulocyte-colony stimulating
factor (G-CSF). This study found that the ectopic expression of
AML1-MTG8 elevates the expression of the G-CSF receptor (G-CSFR).
Analysis of the promoter region of the G-CSFR gene revealed
that up-regulation of G-CSFR expression by AML1-MTG8 does not depend on
the AML1-binding sequence, but on the C/EBP (CCAAT/enhancer binding
protein) binding site. The results suggest that the overproduction of
G-CSFR is at least partly mediated by C/EBP , whose expression is
activated by AML1-MTG8. The ectopic expression of G-CSFR in L-G cells
induced cell proliferation in response to G-CSF, but did not inhibit
cell differentiation into mature neutrophils. Overexpression of
C/EBP in L-G cells also stimulated G-CSF-dependent cell
proliferation. High expression levels of G-CSFR were also found in the
leukemic cells of AML patients with t(8;21). Therefore,
G-CSF-dependent cell proliferation of myeloid precursor cells may be
implicated in leukemogenesis.
(Blood. 2000;96:288-296)
© 2000 by The American Society of Hematology.
| |
Introduction |
The molecular analyses of the recurrent chromosomal
translocations associated with leukemia or lymphoma have provided
insights into the mechanism of malignant transformation and have led to the identification of several transcription factors that participate in
the regulation of normal hematopoiesis.1,2 We previously showed that the AML1 gene3 is located at the
translocation breakpoint of chromosome 21 in the t(8;21) translocation,
which is frequently found in a subtype of acute myeloid leukemia (AML) (M2 according to the French-American-British
classification)4 but rarely in myelodysplasia.5
Biallelic and heterozygous point mutations in the Runt domain of the
AML1 gene are suggested to be responsible for AML.6
AML1 directly binds the enhancer core DNA (cDNA)
sequence TGT/cGGT, which is present in several viral and cellular
promoters and enhancers, and AML1 DNA binding activity is stabilized by
heterodimerization through the Runt domain with CBF /PEBP2.7 Studies on AML1-deficient mice have
suggested that AML1-regulated genes are essential for the definitive
hematopoiesis of all lineages,8,9 and that AML1 functions
as a transcriptional regulator at a high level of hierarchy in
hematopoietic lineages.10 It is also believed that AML1
requires cooperative transcription factors to regulate expression of
its target genes. AML1 interacts with many transcription factors or
modulates the activities of those known to be important for
hematopoiesis, including ETS1, c-MYB, ALY, PU.1, TLE, YAP, and
C/EBP .7 We also found that AML1 specifically interacts
and functionally cooperates with p300, a transcriptional coactivator
possessing histone acetyltransferase activity.11 AML1 also
interacts with mSin3A and represses expression of
p21/WAF1/CIP1.12
The AML1/CBF transcription factor complex is most frequently
targeted in leukemia-associated chromosomal aberrations such as
t(8;21), t(12;21), t(3;21), t(16;21), and inv(16).7 These translocations result in the expression of chimeric transcription factors such as AML1-MTG8/ETO, TEL-AML1, AML1-EVI1, AML1-MTG16, and
CBF-SMH11. AML1-MTG8 can function as a complex with other MTG8
family members, such as MTGR113 or MTG16 (I. Kitabayashi, unpublished data). The recent finding that the MTG8 portion of AML1-MTG8 interacts with the histone deacetylase complex involved in
transcriptional repression of target genes is consistent with the idea
that AML1-MTG8 interferes with AML1-dependent
transactivation.7 However, the mechanism of gene regulation
by AML1-MTG8 varies depending on the target gene. AML1-MTG8 was also
shown to induce expression of the BCL2 gene.14
Several experiments of ectopic expression of AML1-MTG8 were
done to demonstrate the transforming activity of the AML1-MTG8
chimeric protein. AML1-MTG8 induces granulocyte colony-stimulating
factor (G-CSF)-dependent cell proliferation of murine
hematopoietic precursor L-G or 32D cells and inhibits their terminal
differentiation into segmented neutrophils.13,15,16 These
results provide a sound basis for further studies on the function of
AML1-MTG8. However, in these experiments, the mechanism of
G-CSF-dependent proliferation was not revealed. At present, the target
genes of AML1-MTG8 responsible for leukemogenic transformation remain
to be identified.
G-CSF stimulates both the proliferation and differentiation of
neutrophilic precursor cells. It also stimulates a variety of responses
in mature neutrophils, including prolonged survival, phagocytosis, and
superoxide production.17-19 G-CSF binds to its receptor
(G-CSFR) on the cell surface to form a homodimeric receptor complex.20 The membrane-proximal region of G-CSFR has been
shown to be essential for the transmission of growth
signals21,22 via JAK2 activation, STAT3 and STAT5
phosphorylation, and MAP kinase
phosphorylation.23,24 Because point mutations in the G-CSFR gene were identified in some patients with
AML25,26 and in severe congenital
neutropenia,27 the signal transduction pathway via G-CSFR
is likely to be important for normal hematopoiesis. In addition,
because of the huge production (120 billion/d) and rapid turnover (48 hours) of neutrophils, tight regulation of this signaling pathway is
probably critical.21 Thus, the accumulated evidence
indicates that G-CSF and its receptor are essential for hematopoietic
development and that G-CSF may be implicated in malignant disease.
However, the precise role played by these proteins in the early
commitment to a particular cell lineage, whether it be to direct
multipotent cells down a particular cellular pathway or to merely
support the survival of cells that have intrinsically selected a
specific hematopoietic lineage, remains controversial.28,29
We show here that AML1-MTG8 induces the expression of G-CSFR that
accompanies G-CSF-dependent cell proliferation in murine myeloid
precursor cell lines by activating the promoter of the G-CSFR
gene. We also show that this activation is indirectly mediated by
AML1-MTG8 up-regulation of C/EBP .
| |
Materials and methods |
Cells, viruses, and expression plasmids
The L-G30 and 32Dcl331 cells were cultured
in RPMI1640 medium supplemented with 10% fetal calf serum (FCS) and
recombinant mouse interleukin-3 (IL-3; 0.25 ng/mL; a generous gift from
Kirin Brewery) with or without 50 mmol/L -mercaptoethanol,
respectively. BOSC2332 cells were cultured in Dulbecco's
modified Eagle's medium (DMEM) supplemented with 10% FCS. Leukemic
cell fractions of bone marrow or of peripheral blood from AML-M2
patients were prepared by centrifugation with Ficol Paque. Granulocytic
fractions from healthy individuals were prepared with Mono-poly
Resolving Medium. LNSX and LXSH retrovirus vectors33 were
generously provided by Dr D. Miller. AML1b cDNA,34
AML1-MTG8 cDNA35 and mouse G-CSFR cDNA36 (a
generous gift from Dr S. Nagata) were inserted between the Stu
I site and Cla I site of the LNSX vector as described previously.13 C/EBP cDNA with the HA-tag sequence was
generated by the polymerase chain reaction (PCR) with specific primers; 5'-TGAATTCACCATGGCATACCCATACGACGTGCC- TGACTACGCCTCCTCCCCAGGGGACCTA-3' and 5'-TTCGGCCGTCAGCTGCAACCCCCCAC-3' to generate cDNA
encoding 32-kd protein37 and cloned into the LNSX vector.
All of the viruses were transiently produced in BOSC23 cells after
transfection of each vector by the calcium phosphate precipitation
method. After L-G cells were infected with LNSX viruses for 2 days, the cells were transferred to G418 (1 mg/mL) containing medium and used for
analyses. For LXSH virus infection, cells were selected with hygromycin
B (2.5 mg/mL). The 32Dcl3 cells were transfected with the expression
plasmid pRc/CMV (Invitrogen) carrying murine G-CSFR by
electroporation, and after 2 days, the cells were transferred to medium
containing 400 µg/mL G418. For time-course experiments, L-G
infectants maintained in the presence of IL-3 were washed once with
IL-3-free medium and incubated in medium containing human recombinant
G-CSF (10 ng/mL) (a generous gift from Chugai Pharmaceutical Company).
Viable cells were counted at the indicated times by the trypan blue
exclusion method or with a Coulter counter. For cell morphology, cells
were stained with May Gruenwald-Giemsa solution.
Northern blotting
Procedures for Northern blotting were the same as those described
previously.38 Poly (A) + RNA (1 µg) or total RNA (5 µg) was denatured and fractionated on a 1.0% agarose gel containing formaldehyde. The probe used was mouse or human G-CSFR cDNA (generous gifts from Dr S. Nagata), mouse or human myeloperoxidase (MPO) cDNA
(generous gifts from Dr K. Morishita), or human
glyceraldehyde-3-phosphate-dehydrogenase (G3PDH) cDNA. The probe for
C/EBP cDNA was a generous gift from Dr A. D. Friedman. The probe for
mouse C/EBP was generated by PCR. Primers used for C/EBP were
F5'-ACATGTGTGAGCATGAGGCC-3') and
R5'-TGTGCCACTTGGTACTGCAG-3').37
Western blotting
Cell lysates were fractionated on sodium dodecyl sulfate-10%
polyacrylamide gels (SDS-PAGE) and transferred to a membrane filter by
electroblotting. Immunodetection using an anti-HA antiserum was
performed as described elsewhere13 except that all of the washing and hybridization procedures were performed in tris-buffered saline (TBS) containing 0.2% Tween-20. The immune
complexes were visualized by an alkaline phosphatase detection system
(Bio-Rad).
Ligand-binding assay for G-CSFR
Specific G-CSFR activity was determined as the difference between
total and nonspecific binding.20 The cells were incubated, with rotation, for 4 hours at 4°C with [125I]G-CSF
(Amersham) in the presence (nonspecific binding) or absence (total
binding) of 50 nM unlabeled G-CSF. One arbitrary unit is defined as 1 active site bound by 1 G-CSF molecule per cell in the presence of 1.5 nmol/L radiolabeled G-CSF.
Isolation of the human G-CSFR promoter and C/EBP promoter
On the basis of the published sequence,39 the sequences
of the 5' promoter region of the human G-CSFR gene were amplified and cloned from human genomic DNA by the PCR with primers F
5'-AACGCGTCCAAAGGGCTTTGACTTTG-3') and R 5'
GAAGCTTACTCACGTTGGCACCTCT-3'). This PCR fragment was sequenced
and confirmed to be identical to the published sequence. The
synthesized fragment represents bp  1360 to +10, with the major
transcription start site designated +1. Deletion mutants were
constructed by PCR to generate fragments containing nucleotides +10 to
60, +10 to 188, +10 to 243. The forward primers
were 5'-AGCTTTGAGCTCAGGAAATC-3' and R,
5'-TAAGACCCCCAAGGCAGGAA- 3' and R, and
5'-CGGAAGGTGTTGCAATCC-3 and R, respectively. The mutant carrying
2 base substitutions in the consensus site for AML1 binding at
390 to 385 was also constructed by PCR. The PCR products were sequenced and cloned into the luciferase reporter plasmid pGL3-Basic (Promega).
For isolation of the promoter region of C/EBP gene, human
PAC library was screened. C/EBP genomic primers,37 F:
5'-CTACAATCCCCTGCAGTAC-3' and R:
5'-CATTTCACAGAGCGACACCA-3' were used for screening by
PCR. An EcoRI fragment of approximately 12 kb
containing the C/EBP gene was subcloned into a plasmid
vector and the C/EBP gene promoter region was sequenced. A
region of 1280 bp from the promoter region was cloned into pGL3-Basic.
Transcriptional analysis
For the analysis of G-CSFR promoter activity, L-G cells infected
with AML1b or AML1-MTG8 were transiently transfected by
diethylaminoethanol (DEAE)-dextran treatment (300 µg/mL, 30 minutes).
Cells were cultured in the presence of IL-3 for 66 to 72 hours. Cells
were harvested by centrifugation. Activity in cell lysates (10 µL)
was detected with the Dual Luciferase Assay Kit (Promega) and
luciferase activity was measured by Lumat LB9507 (Berthold). In all
assays of luciferase activity, pRL-TK (Promega) (0.2 µg) was
cotransfected as an internal control.
Electrophoretic mobility shift assays
The L-G cells were infected either with LNSX, LNSA-AML1b, or
LNSX-AML1-MTG8. Whole cell lysates were prepared as described elsewhere.40 The cells were washed in cold
phosphate-buffered saline (PBS) and suspended in cold buffer (10 mmol/L
HEPES-KOH, pH7.9, 1.5 mmol/L MgCl2, 10 mmol/L KCl, 0.5 mmol/L DTT, 0.2 mm phenylmethylsulfonyl fluoride [PMSF]). The cells
were allowed to swell on ice for 10 minutes and vortexed for 10 seconds. After centrifugation at 12 000 rpm for 10 seconds, the pellet
was resuspended in a buffer containing 20 mmol/L HEPES-KOH, pH7.9, 25%
glycerol, 420 mmol/L KCl, 1.5 mmol/L MgCl2, 0.2 mmol/L
EDTA, 0.5 mmol/L DTT, and 0.2 mmol/L PMSF. The suspension was incubated
on ice for 20 minutes and centrifuged at 12 000 rpm for 20 minutes.
The supernatant was used for the assays. For synthesis of C/EBP
protein, the cDNA was cloned into the pSP64poly(A) vector. In vitro
transcription/translation reactions were carried out with the TnT SP6
quick coupled transcription/translation system (Promega).
Electrophoretic mobility shift assays (EMSA) were performed in 20 mL of
binding buffer (20 mmol/L HEPES, pH 7.9, 0.1 M KCl, 5 mmol/L
MgCl2, 2 mmol/L EDTA, 1 mmol/L DTT, 20% glycerol)
containing 1 µg of poly(dI-dC), 32P-labeled
oligonucleotide (5 × 103 cpm) and the cell extract
on ice for 30 minutes. DNA-protein complexes were resolved on 5%
polyacrylamide gels.
| |
Results |
AML1-MTG8 induces and AML1b represses the expression of G-CSFR
The murine IL-3-dependent hematopoietic precursor cell lines L-G
and 32Dcl3 differentiate into mature neutrophils in response to
G-CSF.30,31 We previously reported ectopic expression of AML1b, a wild-type full-length protein of AML1 and AML1-MTG8, in the
L-G cell line using a retrovirus vector. In these experiments, cells
were not cloned after selection with drugs to avoid clonal diversity of
the cells. Like the parental L-G cells, the cells infected with
LNSX-AML1b or the control LNSX-vector did not proliferate in the
presence of G-CSF during the 7-day culture period and underwent terminal differentiation into mature neutrophils. In contrast, cells
that expressed AML1-MTG8 proliferated exponentially in response to
G-CSF without differentiating into mature granulocytes, as judged from
the changes in cell morphology.13
These results suggest that AML1-MTG8 might modulate cell responses to
G-CSF. To identify the molecule responsible for this modulation, we
initially measured the expression of G-CSFR in L-G infectants
expressing either AML1b or AML1-MTG8. A ligand-binding assay using
radiolabeled recombinant G-CSF showed elevated levels of G-CSFR
activity (about 6-fold) after infection of the cells with a retrovirus
containing AML1-MTG8 (Figure 1C).
On the other hand, the number of functional G-CSFRs slightly decreased
in infectants expressing AML1b (Figure 1C). Northern blot analyses
showed consistently that the G-CSFR transcript level was also
increased in cells expressing AML1-MTG8 (about 3-fold), whereas slight
decreases were observed in cells expressing AML1b (Figure 1D). We
previously found that the NHR2 region of AML1-MTG8, which is required
to form complexes with MTG8 family members, is essential for the
induction of G-CSF-dependent cell proliferation.13 To
clarify the relationship between G-CSF-dependent proliferation and the
G-CSFR transcript level, Northern blot analysis was carried out using
cells infected with a series of C-terminal deletion mutants of
AML1-MTG8 (Figure 1E). The C-terminal deletion mutant D538 containing
NHR2 (Figure 1A) as well as wild-type AML1-MTG8 stimulated the
synthesis of G-CSFR transcripts. However, further deletion to residue
487 eliminated this activity. These results indicated that the
activation of G-CSFR expression coincided well with the proliferation
response of L-G cells to G-CSF.
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| Fig 1.
Up-regulation of G-CSFR by AML1-MTG8 and down-regulation
by AML1b in L-G infectants.
(A) Schematic representation of AML1b protein, AML1-MTG8 protein, and
deletion mutants of AML1-MTG8 proteins, D538 and D487. Runt indicates
the runt homology region; PST, proline, serine, threonine-rich region;
NHR, nervy homology region; Zn, zinc finger motifs. Note that AML1-MTG8
retains the runt homology region and most of the MTG8 protein. (B)
Expression of AML1b and AML1-MTG8 protein in L-G cells detected by
Western blot analyses. Proteins from the L-G infectants with viruses
encoding AML1b and AML1 MTG8 or with a control virus were analyzed by
immunodetection using anti-HA antibody. The positions of AML1 and
AML1-MTG8 are indicated by arrows. (C) Ligand binding assay for G-CSFR
activity of L-G infectants. The activity was measured as described in
"Materials and methods." (D) Northern blot analyses showing the
expression of G-CSFR mRNA. Total RNAs (5 µg of RNA) were prepared
from L-G infectants cultured with IL-3, blotted, and hybridized with
32P-labeled mouse G-CSFR cDNA and human G3PDH cDNA. (E)
Northern blot analyses showing the expression of G-CSFR mRNA in
deletion mutants of AML1-MTG8. Total RNAs were prepared from L-G
infectants cultured with IL-3, blotted, and hybridized with
32P-labeled mouse G-CSFR cDNA and human G3PDH.
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The effect of AML1-MTG8 on cell proliferation and the differentiation
block in response to G-CSF can be completely rescued by overexpressing
AML1b.11 This suggests that the induction of G-CSFR
expression by AML1-MTG8 might be due to AML1-MTG8 alleviation of the
repressive activity of AML1b on G-CSFR expression. The AML1b-dependent
decrease in the level of G-CSFR was apparent when the cells expressing
AML1-MTG8 were further infected with a virus expressing
AML1b. Up-regulated expression of G-CSFR by
AML1-MTG8 was almost completely inhibited by overexpressing AML1b
(Figure 2).
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| Fig 2.
Inhibition of AML1-MTG8-induced up-regulation of G-CSFR
by AML1b.
(A) Expression of AML1b and AML1-MTG8 protein detected by Western blot
analyses. L-G cells infected with LXSH or LXSH-AML1-MTG8 were further
infected with LNSX-AML1b viruses and the protein extracts from the
infectants were analyzed by immunodetection using anti-HA antibody. The
positions of AML1 and AML1-MTG8 are indicated by arrows. (B) Northern
blot analyses showing the expression of G-CSFR mRNA. Total RNAs (5 µg
of RNA) were prepared from L-G infectants cultured with IL-3, blotted,
and hybridized with 32P-labeled mouse G-CSFR cDNA, mouse
MPO cDNA, and human G3PDH cDNA.
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AML1-MTG8 activates and AML1b represses the promoter of
G-CSFR
To understand the molecular mechanism of transcriptional regulation
of the G-CSFR gene by AML1-MTG8, fusion reporter constructs comprising about 1.4-kb of DNA from the 5' upstream region of the
human G-CSFR promoter and the luciferase gene
(pGRP1400n) were transfected into L-G cells ectopically expressing
AML1b, AML1-MTG8, or a deletion mutant of AML1-MTG8, D478. The
G-CSFR promoter was significantly activated in cells expressing
AML1-MTG8 (about 4-fold) (Figure 3B). On
the other hand, the activity in cells expressing AML1b was suppressed
(about 1/2-fold) compared to cells infected with the vector. In
addition, the activation was not induced by a deletion mutant of
AML1-MTG8, D478, which did not induce expression of G-CSFR. Because a
consensus sequence for AML1-binding (391 to 385) is
present in the upstream region of the G-CSFR gene, we initially
constructed a mutant reporter with 2 base substitutions in this
sequence (pGRP1400m). However, these mutations in the AML1 site did not
affect the transactivation of the promoter by AML1-MTG8 or AML1b. This
suggests that up- or down-regulated expression is not mediated by
direct binding of AML1-MTG8 or AML1b to the AML1 site (Figure 3B).
Compared to the native promoter, the mutant promoter pGRP1400m was
slightly activated in all infectants, suggesting that the AML1 site
might function as a negative regulatory element. Cotransfection of the G-CSFR promoter with effector plasmids expressing AML1b or
AML1-MTG8 or both also consistently showed that AML1-MTG8 activates the G-CSFR promoter and that AML1 inhibits the AML1-MTG-8
activation effect in a dose-dependent manner (Figure 3C).
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| Fig 3.
Activation of the G-CSFR promoter by AML1-MTG8.
(A) Schematic representation of the promoter region of G-CSFR
and its deletion mutants. (B) Activation of the G-CSFR promoter
by AML1-MTG8. LG cells expressing either vector, AML1b, AML1-MTG8 or a
deletion mutant of AML1-MTG8, D487, were transfected with
G-CSFR-luciferase (pGL3) using DEAE-dextran. Transfection efficiency
was normalized by cotransfection with pRL-TK as an internal control.
pGRP1400n; normal 1370 bp promoter, pGRP1400m; a mutant (2 base
substitution) of the AML1 consensus site of pGRP1400n. (C) AML1b
interferes with the enhancing activity of AML1-MTG8 on the
G-CSFR promoter. Cells were cotransfected with pGRP1400n and
either LNSX, LNSX-AML1b, or LNSX-AML1-MTG8. LNSX-AML1b was added in
addition to the effector plasmid AML1-MTG8 at 0.3 µg, 1 µg, and 3 µg in lanes 2, 3, and 4, respectively. The total amount of effector
DNA was 6 µg each. LNSX was used to adjust the total amount of DNA.
(D) Activity of 5' deletion mutants of the G-CSFR
promoter in L-G cells. Cells were cotransfected with each mutant and
either 3 µg of LNSX, LNSX-AML1b, or LNSX-AML1-MTG8. The activity of
the control vacant reporter with LNSX was designated as being equal to
1.
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The C/EBP binding site is required for activation of the G-CSFR
promoter by AML1-MTG8
To determine the functionally critical regions of the G-CSFR
promoter for up-regulation by AML1-MTG8, we created a series of
5' truncation mutants by PCR. As shown in Figure 3D, AML1-MTG8 significantly activated the constructs pGRP1400n, pGRP7 (243 to
+100), pGRP15 (243 to +10), pGRP16 (188 to +10) and
pGRP17 (60 to +10). The shortest construct pGRP17 contains no
other transcriptional factor binding site besides the potential sites for C/EBPs and Sp1. The C/EBP family, especially C/EBP and C/EBP, are important for myeloid cell proliferation and differentiation and
for the regulation of myeloid-specific proteins.25,41-43
C/EBP activates promoters for the cytokine receptors of
granulocyte/macrophage colony-stimulating factor (GM-CSF), macrophage
colony-stimulating factor (M-CSF) and G-CSF.44-46 C/EBP
activates G-CSFR37 and myeloperoxidase.47 We
created mutants of the C/EBP binding site and Sp1 binding site in
pGRP16 (Figure 4A). AML1-MTG8 stimulation of G-CSFR promoter activity was significantly reduced by
mutations of the C/EBP site (pGRP16M1) but not by mutations of the Sp1
site (pGRP16M2/M3) (Figure 4B).
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| Fig 4.
Requirement for the C/EBP binding site for activation of
the G-CSFR promoter by AML1-MTG8.
(A) Schematic representation of the base substitution of the mutants
around the C/EBP site in the G-CSFR promoter. GRP16M1 is a
mutant of the C/EBP consensus site. GRP16M2 is a mutant of the putative
Sp1 site. GRP16M3 is a mutant of the Sp1 consensus site. (B) Effects of
AML1-MTG8 on the activity of GRP16 mutants in L-G cells. Cells were
cotransfected with each mutant reporter and either LNSX, LNSX-AML1b, or
LNSX-AML1-MTG8.
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AML1-MTG8 induces expression of C/EBP
Analysis of the G-CSFR promoter using mutated sequences
indicated the possible involvement of C/EBPs in the regulation of G-CSFR expression. Among C/EBP family members, C/EBP,
C/EBP, and C/EBP were shown to be important for hematopoiesis. We
therefore examined their expression levels to determine which one was
responsible for the stimulation of the G-CSFR promoter by
AML1-MTG8. Northern analysis indicated that the expression of C/EBP
was significantly up-regulated in the cells ectopically expressing
AML1-MTG8 (Figure 5A), whereas the
expression of C/EBP and C/EBP were neither detected in L-G
cells expressing AML1-MTG8 nor in the parental L-G cells
(data not shown). No significant change was observed in the expression
level of PU.1 (Figure 5A), a transcription factor known to be important
for the activation of G-CSFR.46
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| Fig 5.
Induced expression of C/EBP by AML1-MTG8.
(A) Northern blot analyses showing the expression of C-EBP mRNA.
Total RNAs (5 µg of RNA) were prepared from L-G infectants cultured
with IL-3, blotted, and hybridized with 32P- labeled human
C/EBP cDNA, mouse PU.1 cDNA, and human G3PDH cDNA. (B) Northern blot
analyses of poly(A)+RNAs from hematopoietic cell lines. Northern blots
were hybridized with human C/EBP cDNA and human C/EBP cDNA. (C)
Gel mobility shift assay showing the binding activities of cell
extracts from L-G infectants and in vitro synthesized C/EBP protein.
(D) AML1-MTG8 activates the promoter of the C/EBP gene.
Cells were cotransfected with pGL3-C/EBP (1280 bp) and either 0.2 µg of LNSX, 0.2 µg of LNSX-AML1b, or various concentrations of
LNSX-AML1-MTG8. LNSX-AML1-MTG8 was added at 0.05 µg, 0.1 µg, and
0.2 µg in lanes 2, 3, and 4, respectively.
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Expression of C/EBP was observed in leukemia cell lines carrying
t(8;21), SKNO1 and Kasumi-1, and in HL60 cells established from the M2
AML patients (Figure 5B). No detectable transcripts were seen in the
other hematopoietic cell lines tested. These observations corroborate a
report that showed the expression of C/EBP is restricted to the
granulocytic lineage and the T-cell lineage and that C/EBP is
induced along with granulocytic differentiation.37,48 C/EBP is expressed in ML1 and U937, but weakly in K562, and not at
all in cells expressing C/EBP (Figure 5B).
To confirm the involvement of C/EBP in the regulation of
the G-CSFR expression, EMSA was carried out using a 23-mer
oligonucleotides probe N1 that contains the C/EBP binding sequence
(62 to 39) of the G-CSFR promoter and lysates
from L-G cells overexpressing AML1b or AML1-MTG8. Complex A (Figure 5C)
was found to be more abundant in the lysate from AML1-MTG8 expressing
cells. Because complex A migrated at the same position as the complex
formed with in vitro translated C/EBP, complex A is likely to
contain C/EBP. The differences in the amount of complex A between
the lysates were compatible with the variations in the messenger RNA (mRNA) levels of C/EBP in the infectants used to make the lysates. These results suggested that C/EBP was involved in the regulation of
G-CSFR transcription by AML1-MTG8. Band B was considered to be a
nonspecific complex, because its intensity was not diminished by adding
excess competitor (Figure 5C). These results indicated that C/EBP
mediates the transcriptional regulation of G-CSFR by
AML1-MTG8.
To determine the possible mechanism of enhanced expression of
C/EBP by AML1-MTG8, a PAC clone containing genomic DNA coding for
the human C/EBP gene was isolated and sequenced. The
promoter region of 1280 bp, which contains the 130 bp reported
sequence37 of C/EBP was fused to the luciferase
gene and the reporter was cotransfected into L-G cells with either
AML1b or AML1-MTG8. As shown in Figure 5D, AML1-MTG8 significantly
activated the promoter of the C/EBP gene in a dose-dependent
manner. In contrast, AML1b did not affect the promoter. These results
suggest that AML1-MTG8 stimulates transcription of the C/EBP
gene. However, no consensus binding motif for AML1 is present in the
1280 bp promoter region, suggesting that additional steps might be
involved in transcriptional activation of G-CSFR by AML1-MTG8.
Overexpression of C/EBP induces expression of G-CSFR and
G-CSF-dependent cell proliferation
To confirm the finding that AML1-MTG8 enhanced expression of
C/EBP, L-G cells were infected with a C/EBP-carrying retrovirus. Northern blot analysis showed that the expression of G-CSFR was induced
by C/EBP as in the case of AML1-MTG8 (Figure
6B). The introduction of C/EBP also
induced MPO expression like that observed after the introduction of
AML1-MTG8, although induction by C/EBP was stronger than that by
AML1-MTG8. The similar effects of AML1-MTG8 and C/EBP on MPO
expression suggest that the induction of MPO expression by AML1-MTG8 is
also mediated by C/EBP. The cells expressing C/EBP proliferated
in response to G-CSF for at least 8 days after exposure to G-CSF
(Figure 6C). However, after 7 days of culture in the presence of G-CSF,
a significant percentage of the cells (about 80%) showed
morphologic differentiation into mature neutrophils with segmented
nuclei (data not shown).
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| Fig 6.
Induced expression of G-CSFR and growth stimulation by
C/EBP.
(A) Expression of C/EBP protein in L-G cells detected by Western
blot analyses. Proteins from the L-G infectants with viruses encoding
AML1b, AML1-MTG8, or C/EBP were analyzed for immunodetection using
anti-HA antibody. The positions of AML1b, AML1-MTG8, and C/EBP are
indicated by arrows. (B) Total RNAs (5 µg of RNA) were prepared from
L-G infectants cultured with IL-3, blotted, and hybridized with
32P-labeled mouse G-CSFR cDNA, mouse MPO cDNA, and human
G3PDH cDNA. (C) Growth curves of L-G cells infected with LNSX
retroviruses carrying human C/EBP cDNA or AML1-MTG8 cDNA in the
presence of G-CSF.
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The effect of overexpression of G-CSFR on G-CSF-induced cell
proliferation and differentiation
The high levels of G-CSFR expression and the high
proliferative responses to G-CSF in the cells expressing AML1-MTG8
suggest that the proliferative responses of these cells may be
associated with the up-regulation of G-CSFR. To evaluate this notion,
the murine G-CSFR gene was introduced into L-G cells and 32Dcl3
cells by virus infection and transfection, respectively. L-G
infectants, which overexpressed G-CSFR (about 20 000
sites/cell) proliferated in response to G-CSF for at least
10 days after exposure to G-CSF (Figure
7A). To test the relationship between
G-CSFR levels and G-CSF-dependent cell proliferation, 13 clones, which
stably expressed various levels of G-CSFR (900~15 000 sites/cell),
were isolated after transfection of 32Dcl3 cell. The transfectants also
showed growth response to G-CSF, and their growth rate over a period of
5 days in the presence of G-CSF was well correlated with the level of
G-CSFR expression (Figure 7B). These results indicate that the elevated
expression of G-CSFR stimulates cell proliferation in response to
G-CSF. However, the growth rate of L-G and 32Dcl3 transformants
overexpressing G-CSFR gradually decreased with time. After 9 to 12 days
of culture in the presence of G-CSF, a significant percentage of the
cells (20-80%) showed morphologic differentiation into mature
neutrophils with segmented nuclei. However, other cells were still
present that continued to grow without terminal differentiation (Figure
7C). In contrast, the cells expressing AML1-MTG8 proliferated
continuously in response to G-CSF without terminal
differentiation.13 This difference in response to G-CSF between AML1-MTG8-expressing cells and G-CSFR-expressing cells suggests that additional factor(s) may be required for the continuous proliferation of cells and for the inhibition of morphologic terminal differentiation.
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| Fig 7.
Overexpression of G-CSFR stimulates cell proliferation in
response to G-CSF.
(A) Growth curves of L-G cells infected with LNSX retroviruses carrying
mouse G-CSFR cDNA or AML1-MTG8 cDNA in the presence of G-CSF. (B)
Correlation between G-CSFR activity and the rate of proliferation in
the presence of G-CSF. The 32Dcl3 transfected cells were inoculated
into medium supplemented with 10 ng/ml of G-CSF at a cell density of
2 × 104 cells/mL, and cell numbers were counted
with a Coulter counter after 5 days of incubation. (C) Cell morphology
of G-CSFR transformed GR8 cells when cultured with G-CSF for 10 days.
GR8 is a representative clone that expresses G-CSFR at a high level.
Cells were stained with May-Gruenwald-Giemsa solution.
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t(8;21) leukemic cells express G-CSFR
Case reports have shown that high expression levels of
G-CSFR can be found in leukemic cells from M2 AML
patients.49,50 To determine the relationship between AML
with a t(8;21) translocation and G-CSFR expression, we measured G-CSFR
activity in leukemic cells from M2 AML patients who were positive or
negative for t(8;21). A ligand-binding assay showed that elevated
levels of G-CSFR (1000~3500 sites/cell) were present in leukemic
cells from all of the AML patients positive for t(8;21), but not in the
cells of AML patients negative for t(8;21), except for 1 case (about
1500 sites/cell) (Figure
8A). G-CSFR is
mainly expressed during the differentiation of myeloblasts into mature
neutrophils, and its expression level increases during granulocytic
differentiation.22 The increased activity of G-CSF binding
seen in t(8;21) cells was not due to contamination by mature
granulocytes because large numbers of G-CSF receptors were not detected
in fractions enriched with granulocytes from healthy volunteers.
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| Fig 8.
High expression levels of G-CSFR in leukemic cells from
patients with t(8;21) and hematopoietic cell lines with t(8;21).
(A) Ligand binding assays for G-CSFR activities in leukemic cells with
or without t(8;21) in M2, and in normal granulocytes. (B) Northern blot
analyses of poly(A)+RNAs from hematopoietic cell lines. Northern blots
were hybridized with human G-CSFR, MPO, and G3PDH cDNA.
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| Fig 9.
Model for the regulation of G-CSFR expression, cell
proliferation, and cell differentiation by AML1-MTG8.
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High expression levels of the G-CSFR transcript were also observed in
leukemia cell lines carrying t(8;21), SKNO1 and Kasumi-1 cell lines
(Figure 8B). None of the other hematopoietic cell lines tested, which
did not carry t(8;21), expressed such a high level of G-CSFR. These
results indicate that AML with t(8;21) is specifically accompanied by
high levels of G-CSFR expression, and the results are consistent with
those obtained using the L-G cell system.
| |
Discussion |
Transcription factor genes are frequently involved in the
chromosomal translocations associated with human leukemia. The
resulting deregulation of downstream target genes probably contributes
to differentiation arrest and the aberrant proliferation of
hematopoietic progenitor cells. Accordingly, studies to identify the
downstream gene products that confer the neoplastic nature are a
prerequisite for a full understanding of the mechanism of
leukemogenesis. However, reports identifying the target genes of
chimeric transcription factors are rare, and so far the genes directly
responsible for the leukemogenetic process have not been identified for
AML1-MTG8 or for other chimeric transcription factors resulting from
various chromosome translocations. In the present study, we identified the G-CSFR gene as a candidate downstream target gene involved in the leukemogenic process induced by the chimeric transcription factor AML1-MTG8.
AML1-MTG8 induces expression of G-CSFR through a transcription
cascade
To understand the tumorigenic potential of these chimeric proteins,
the most commonly accepted explanation is that AML1 chimeric proteins
retain the ability to interact with the enhancer core DNA sequence,
thereby interfering with AML1-dependent transactivation in a dominant
negative manner.7 Here we demonstrated that deregulation, caused by AML1-MTG8, is indirect and mediated by C/EBP synthesis (Figure 9). It has been reported that PU.1 and C/EBP are involved in
the positive regulation of G-CSFR expression.46 However, our results indicate that the expression of PU.1 and C/EBP are unlikely to be involved in this regulation, because no changes in the
PU.1 transcript or C/EBP transcript level were observed in L-G
cells. The C/EBP family is assumed to be important for hematopoiesis.
C/EBP is almost exclusively expressed in the granulocytic lineage
and preferentially up-regulated during granulocytic
differentiation.37,48 C/EBP / mice fail to
generate functional neutrophils and eosinophils.42 C/EBP
can activate the MIM-1, neutrophil elastase, and G-CSFR promoters.47 C/EBP and C/EBP have similar affinity
for the consensus binding sites within G-CSFR promoter. C/EBP is
able to repress the transactivation of proteinase 3 by C/EBP and
c-MYB in a dose-dependent manner.51 These findings show
that C/EBP can act either as a transcriptional activator or a
repressor depending on the target promoter.
AML1 also functions as both an activator and repressor depending on the
presence of cooperative factors. Analysis of the truncated promoter
suggested that AML1 might be involved in the regulation of G-CSFR in 2 different ways. First, it directly inactivates the G-CSFR
promoter by binding to an AML1 sequence locating at 391 to
385. Second, it inactivates the promoter by repressing the
expression of C/EBP that is essential for the activation of
G-CSFR. Although the molecular basis of the regulation of the C/EBP expression has not been well elucidated, the present data show
that AML1-MTG8 activated the promoter of the C/EBP gene. This activation again seems to be indirect, because the AML1 binding motif is not present in the promoter region analyzed.
Aberrant recruitment of the nuclear receptor corepressor-histone
deacetylase complex by AML1-MTG8 is suggested to be responsible for
leukemogenesis. However, the mechanism through which the histone deacetylase complex represses the expression of the target genes, which
seems to be important for myeloid cell growth and differentiation, is
still unknown. The preliminary gene expression profiles obtained by
mRNA differential display analyses showed that AML1-MTG8 rather than
AML1 up-regulates many genes relating to myeloid cell differentiation in L-G myeloid precursor cells.57 If AML1-MTG8 always acts
as a transcriptional repressor, it might repress the expression of possible repressors that might be under the positive control of AML1.
Alternatively, up-regulation by AML1-MTG8 could depend on changes in
AML1 or AML1-MTG8 complexes that occur during certain stages of
differentiation. The changes in AML1 or AML1-MTG8 complexes may
specifically regulate the target genes.
Up-regulation of G-CSFR induces cell proliferation of myeloid
precursor cells
We found the overexpression of G-CSFR can mimic certain leukemogenic
activities of AML1-MTG8. However, the overexpression of G-CSFR does not
completely explain all the effects of AML1-MTG8. Unlike
AML1-MTG8-expressing cells, G-CSFR-expressing cells could differentiate into mature neutrophils. It is possible that additional factors, whose expression would be deregulated by AML1-MTG8, are required to fully express the transforming activity of AML1-MTG8.
We also showed that the number of functional G-CSFRs is high in
leukemic specimens from AML patients with t(8;21). There are several
possible explanations of how elevated G-CSFR levels might contribute to
leukemogenesis. First, high levels of G-CSFR expression might provide
leukemic cells with a growth advantage. Our results show that growth
stimulation is proportional to the level of G-CSFR expression.
Supporting evidence shows that overexpressed G-CSFR may activate STAT3
and induce self-renewal of hematopoietic stem cells. Self-renewal of
pluripotent embryonic stem cells is mediated via ectopic expression of
STAT3.52 The stimulation of cell proliferation induced by
the overexpression of G-CSFR may provide a clue about malignant
transformation. Second, a high level of G-CSFR may suppress apoptosis,
which may contribute to leukemogenesis. In fact, ectopic expression of
G-CSFR inhibits apoptosis of L-G cells in the presence of G-CSF. When
parental L-G cells are cultured in the presence of G-CSF, a significant
proportion of the cell population dies before and after maturation.
However, the L-G cells that ectopically expressed high levels of G-CSFR
did not die before maturation (data not shown). Third, the high level
of G-CSFR might specify the phenotype of leukemic cells with t(8;21).
AML with t(8;21) represents a unique phenotype with features of
granulocytic differentiation.53 Elevated expression of
G-CSFR may induce commitment of leukemic cells to the granulocytic
lineage and may be associated with this unique differentiation
phenotype. However, in contradiction to this notion, G-CSF stimulates
the development of primitive multipotential progenitors both in vitro
and in vivo in transgenic mice ubiquitously expressing G-CSFR, but does
not induce exclusive commitment to the myeloid lineage.54
Other reports indicate that ectopic expression of G-CSFR in
hematopoietic progenitor cells permits multilineage differentiation.29 Thus, overexpression of G-CSFR is not
sufficient for commitment to the myeloid lineage. The present results
suggest that other factors such as C/EBP may mediate induction of
the differentiated phenotype of t(8;21).
AML1-MTG8 might induce functional differentiation through
C/EBP
We showed that cells expressing AML1-MTG8 induce the expression of
MPO when cultured in the presence of IL-3 and that this induction is
likely to be due to up-regulation of C/EBP. Morphologic analysis
showed that many granules were present in cells expressing AML1-MTG8
(data not shown). The expression of G-CSFR, C/EBP, and MPO are
up-regulated as the cell differentiates into the granulocytic lineage.
Thus, AML1-MTG8 may induce some of the phenotypes of granulocytic
differentiation. These considerations seem to run contrary to the
results obtained with L-G cells, where AML1-MTG8 blocked terminal
differentiation into segmented neutrophils in response to G-CSF.
However, the induced expression of C/EBP might enhance the
functional differentiation of t(8;21)-positive precursor cells. In
addition, because C/EBP is critical for eosinopoeisis and
granulopoiesis, the increased number of eosinophils in t(8;21) leukemia
could be explained by enhanced synthesis of C/EBP. It is probable
that the nature of the fusion gene in this unique type of leukemia
specifies the tumor phenotype. Because t(8;21) is exclusively
associated with M2 AML, AML1-MTG8 might not block the differentiation
of pluripotent stem cells, but rather specify them for the myeloid
lineage. In the case of chimeric mice harboring knocked-in embryonic
stem cells expressing MLL-AF9, the resulting acute
myeloid leukemias were preceded by effects on differentiation, which
resulted in myeloproliferation and the accumulation of Mac-1/Gr-1 double-positive mature myeloid cells.55,56 AML1-MTG8 might have a potential analogous to that of MLL-AF9. At prese |
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Abstract
Introduction