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Previous Article | Next Article 
Molecular and Cellular Biology, March 2000, p. 1970-1981, Vol. 20, No. 6
0270-7306/00/$04.00+0
Regulation of the Resident Chromosomal Copy of
c-myc by c-Myb Is Involved in Myeloid
Leukemogenesis
M.
Schmidt,1
V.
Nazarov,1,
L.
Stevens,2
R.
Watson,3 and
L.
Wolff1,*
Laboratory of Cellular
Oncology1 and Laboratory of
Genetics,2 National Cancer Institute, Bethesda,
Maryland, and Ludwig Institute for Cancer Research, Imperial
College School of Medicine at St. Mary's, London, United
Kingdom3
Received 13 October 1999/Returned for modification 12 November
1999/Accepted 16 December 1999
 |
ABSTRACT |
c-myb is a frequent target of retroviral insertional
mutagenesis in murine leukemia virus-induced myeloid leukemia.
Induction of the leukemogenic phenotype is generally associated with
inappropriate expression of this transcriptional regulator. Despite
intensive investigations, the target genes of c-myb that
are specifically involved in development of these myeloid lineage
neoplasms are still unknown. In vitro assays have indicated that
c-myc may be a target gene of c-Myb; however, regulation of
the resident chromosomal gene has not yet been demonstrated. To address
this question further, we analyzed the expression of c-myc
in a myeloblastic cell line, M1, expressing a conditionally active
c-Myb-estrogen receptor fusion protein (MybER). Activation of MybER
both prevented the growth arrest induced by interleukin-6 (IL-6) and
rapidly restored c-myc expression in nearly terminal
differentiated cells that had been exposed to IL-6 for 3 days.
Restoration occurred in the presence of a protein synthesis inhibitor
but not after a transcriptional block, indicating that
c-myc is a direct, transcriptionally regulated target of
c-Myb. c-myc is a major target that transduces Myb's proliferative signal, as shown by the ability of a c-Myc-estrogen receptor fusion protein alone to also reverse growth arrest in this
system. To investigate the possibility that this regulatory connection
contributes to Myb's oncogenicity, we expressed a dominant negative
Myb in the myeloid leukemic cell line RI-4-11. In this cell line,
c-myb is activated by insertional mutagenesis and cannot be
effectively down regulated by cytokine. Myb's ability to regulate c-myc's expression was also demonstrated in these cells,
showing a mechanism through which the proto-oncogene c-myb
can exert its oncogenic potential in myeloid lineage hematopoietic cells.
| |
INTRODUCTION |
myb was originally
identified as an oncogene following its transduction into the avian
retroviruses avian myeloblastosis virus and E26 (16, 32),
which cause acute myeloblastic leukemia or erythroblastosis. Its
oncogenic potential was further demonstrated in animal models, where
the cellular proto-oncogene c-myb was shown to be a target
of retroviral insertional mutagenesis, causing T- and B-cell lymphomas
in chickens (28, 52, 53, 55) and myeloid leukemias in mice
(21, 46, 60, 61, 72). Despite many reports over the last
several years that described potential target genes of the
transcription factors v-Myb and its cellular counterpart c-Myb, little
is known about the regulatory pathways through which c-myb
exerts its oncogenic potential.
The product of the c-myb gene is a highly conserved
transcription factor of 75 kDa (4, 37). In hematopoietic
cells of all types, it is expressed in the immature phase (29,
62) and is down regulated during terminal differentiation
(15, 22, 69). Functions assigned to this gene regulator are
apoptosis, differentiation, and proliferation (reviewed in references
70 and 71). Its role in apoptosis
was impressively demonstrated by inactivation of its function in
transgenic mice using a dominant interfering Myb, targeted specifically
to T cells; thymocytes from these mice died from apoptosis at a higher
rate than normal. It was shown that the antiapoptotic role of c-Myb in
both T cells and myeloid cells is connected to Myb's ability to
regulate expression of bcl-2 (19, 65). Its
function in differentiation is evident from studies which have
identified, as c-Myb targets, genes like mim-1,
TCR
, CD4, and the neutrophil elastase gene
(reviewed in reference 48), all of which are markers
of mature cell phenotypes. Furthermore, the detection of the homeobox
gene GBX2 as a direct target gene of c-Myb demonstrates how
Myb can be responsible, in a more global way, for lineage commitment in
differentiation (31).
Myb's involvement in maintaining proliferation is thought to be an
important function in regard to its oncogenic potential. This function
also has been clearly demonstrated for normal cell development. For
example, homozygous knockout mice were shown to have an embryonic
lethal phenotype due to a severe reduction in the number of progenitor
cells (44). In addition, in vitro experiments in both
erythroid and myeloid cells have demonstrated that constitutive
expression of exogenous c-myb blocks growth arrest
associated with terminal differentiation (7, 12, 42, 58).
Genes implicated as targets of c-Myb and involved in its role in
proliferation are the cell cycle regulator gene cdc2
(31), the DNA polymerase 
gene (64),
c-kit (27, 54, 68), and c-myc
(13, 17, 73). These genes were implicated primarily in
studies using in vitro transactivation assays, where reporter gene
constructs containing the given promoters were transfected into
different cell types. More conclusive data were obtained recently for a
role of c-kit in transducing c-Myb's signal to proliferate
in fetal liver-derived primitive myeloid cells when it was shown that
the endogenous chromosomal copy of the gene was regulated directly by
c-Myb (27). In contrast, in the case of c-myc,
recent studies have raised doubts as to whether it is regulated by
c-Myb, because analysis of its expression in lymphoid, erythroid, or
primitive myeloid cells, in response to conditional expression of an
active c-Myb or a dominant negative Myb, failed to show effects on the
resident chromosomal gene (27, 35, 65).
Despite the fact that recent studies have raised doubts concerning
whether c-myc is a gene regulated by c-Myb, experimental observations from leukemogenesis studies have led us to further investigate this topic in cells of the myeloid lineage. Myeloid leukemias resulting from inoculation of retroviruses into young adult
mice fall into two categories. One type, monocyte-macrophage leukemias
induced by a retrovirus expressing c-myc, do not express c-myb (2, 3, 72). In contrast, promonocytic
leukemias, which have been induced following retroviral insertion of
the c-Myb locus and have inappropriate expression of c-myb,
have constitutively up regulated c-myc
(72; L. Wolff, unpublished data). These leukemias are called MML, for murine leukemia virus-induced myeloid leukemia (71). Interestingly, expression of c-myc is not
observed in normal cells of this late stage of differentiation. These
examples suggested the intriguing possibility that c-myc is
a downstream target of c-Myb in myeloid leukemogenesis.
| |
MATERIALS AND METHODS |
Cells and viruses.
The murine myeloid cell line M1
(33) was maintained in RPMI 1640 medium supplemented with
10% heat-inactivated horse serum. The murine leukemia cell line
RI-4-11 (45) was maintained in Dulbecco modified Eagle
medium containing 10% fetal bovine serum, as were the murine ecotropic
GP + E-86 (38) and murine amphotropic envAM12 (39) packaging cell lines. For activation
of the estrogen receptor (ER) fusion proteins, 4-hydroxytamoxifen
(4-OHT; Sigma) was added to the medium at a concentration of 1 to 2 nM;
for induction of the metallothionein (MT) promoter, ZnCl2
was used at a concentration of 50 to 85 µM.
Retroviruses were prepared as previously described (7) by
transfecting LXSN-based (43) recombinant retrovirus DNA into the amphotropic packaging cell line GP + envAM12 by the
calcium phosphate method. The ecotropic packaging cell line GP + E-86 was infected 48 h later, in the presence of Polybrene (4 µg/ml; Sigma), with conditioned, virus-containing supernatant of the transfected GP + envAM12 culture. Infected cells were
selected in medium containing G418 (400 µg/ml; GIBCO-BRL). Selected
cells producing recombinant retroviruses were treated with mitomycin C
(10 ng/ml; Sigma) for 3 h and used to infect M1 or RI-4-11 cells by cocultivation. The infected M1 or RI-4-11 cells were subsequently selected for neomycin resistance with 400 or 800 µg respectively, of
G418 per ml.
Electroporation was used for transfection of M1 cells. Briefly, 5 × 106 cells in 500 µl of phosphate-buffered saline (PBS)
were electroporated with a Bio-Rad Gene Pulser II (400 V, 50 µF).
After transfection, M1 cells containing recombinant vectors were
selected in medium containing G418 (400 µg/ml) or puromycin (2 µg/ml).
For M1 cell differentiation, cells were seeded at a concentration of
1 × 105 to 2 × 105/ml in medium
containing interleukin-6 (IL-6). Stocks of secreted murine recombinant
IL-6 were prepared from SF9 cells infected with PVL 6A8 mouse IL-6
baculovirus (a kind gift of J. Van Snick, Ludwig Institute for Cancer
Research, Brussels, Belgium). SF9 cells grown in Grace's insect medium
with 10% fetal calf serum were infected for 2 days for the preparation
of secreted IL-6. One-liter stocks of IL-6 were prepared by Cell
Trends, Inc. (Middletown, Md.) and used at a concentration of 1:500
after testing for the ability to induce differentiation.
De novo protein synthesis was inhibited by cultivating the cells in the
presence of cycloheximide (Sigma) at a concentration of 10 µg/ml for
3 to 6 h. Under these experimental conditions, 35S
incorporation was found to be reduced to more than 90% in treated cell samples.
De novo transcription was blocked by cultivating the cells in the
presence of actinomycin D (Sigma) at a concentration of 10 µg/ml for
3 to 6 h.
Plasmids and construction of retroviral vectors.
The vector
pLMybERSN was constructed by cloning the c-Myb-ER (MybER) gene of
pJ4
4R/MER as SacI/ClaI fragment into the
HpaI site of LXSN (43). pJ44R/MER encodes a
C-terminally deleted c-Myb (amino acids 1 to 489) fused to the mutant
mouse ER and was constructed by cloning a
SalI/SacI c-myb fragment from plasmid pJ4R into SalI/BamHI-digested pJ4MER. MybEnER
(a fusion protein consisting of the Myb DNA binding region, the
Drosophila Engrailed [En] transrepressor, and a modified
ER hormone binding domain) and EnER (36) were cut out of
pJ4/Myb/En/ER or pJ4En/ER as BamHI/ClaI fragments
that were inserted into the HpaI site of pLXSN to create pLMybEnERSN or pLEnERSN, respectively. pMTCB6+MybEn and pMTCB6+c-Myb were cloned as a BamHI fragment from the MEnT (1)
expression vector pUHIT/MEnT or the c-Myb expression vector pLFLmybSN
(42) by insertion into the BamHI site of pMTCB6+
(9, 11). MycER (34) expressing pBabe Puro MycER
was transfected directly.
Preparation of RNA and Northern blot analysis.
Total RNA was
prepared using a RNAeasy Mini kit (Qiagen). Five-microgram samples of
RNA were electrophoresed in a Tris-acetate-EDTA buffer on a 1.0%
agarose gel containing 20 mM guanidine thiocyanate as described in
reference 20. After blotting to a nylon membrane, the RNA was cross-linked to the membrane by using a Stratalinker 1800 (Stratagene). Probes used for hybridization were labeled using a
random priming kit (GIBCO-BRL). The following DNA fragments were used
as probes: EnER, BamHI/ClaI fragment
(36); MybER, SacI/ClaI fragment;
MybEn, BamHI fragment (1); c-myc,
1.4-kb SstI/HindIII fragment (63);
MycER, 2.2-kb EcoRI fragment; c-myb, 2.0-kb
NcoI fragment (4); rat GAPDH cDNA
(18); 
-actin cDNA (25);
cdc2 cDNA (66); ornithine decarboxylase gene
(ODC), 0.7-kb PstI fragment (14);
v-kit, 0.7-kb SacI/SalI fragment (5); cyclinD1 cDNA (41).
Analysis of apoptosis.
Early-stage apoptosis was detected
using the TACS annexin V apoptosis detection kit (Trevigen, Inc.)
according to the manufacturer's instructions. For detection of
late-stage apoptosis, DNA was analyzed for fragmentation as described
recently (8). Briefly, 2 × 106 cells were
lysed in a buffer containing 0.5% sodium dodecyl sulfate (SDS), 0.1 M
NaCl, 1 mM EDTA, and 50 mM Tris-HCl (pH 8.0) and incubated for 4 h
at 50°C in the presence of proteinase K (0.1 mg/ml; GIBCO-BRL). The
samples were then extracted with chloroform-isoamyl alcohol,
precipitated with ethanol, dissolved in 10 mM Tris-1 mM EDTA (pH 7.4),
and treated with RNase A for 1 h at 37°C. Five micrograms of DNA
was electrophoresed on a 2% agarose gel containing 1 mg of ethidium
bromide per ml and visualized by UV fluorescence.
Cell cycle analysis.
Cells were prepared for cell cycle
analysis as described in reference 50. Cells were
harvested and fixed in 70% ethanol for a minimum of 18 h. For
cell cycle analysis, the cells were collected by centrifugation and
stained in a solution of phosphate-buffered saline (PBS), propidium
iodide (50 µg/ml), RNase A (100 U/ml), and glucose (1 g/liter) and
measured in a FACScan apparatus (Becton Dickinson). The data were
analyzed for cell cycle distribution using the ModfitLT V2.0 program.
Western blot analysis.
Cells were lysed in 10 mM Tris (pH
7.4)-0.15 M NaCl-1% NP-40, 1% sodium deoxycholate-0.1% SDS with
10 mM iodoacetamide, 1 mM phenylmethylsulfonyl fluoride and Complete
protease inhibitor cocktail as instructed by the manufacturer
(Boehringer Mannheim). Samples of 100 µg of protein were separated by
SDS-polyacrylamide gel electrophoresis using 8% gels and a
discontinuous Tricine buffer system (57). Western blot
analysis was carried out by standard procedures. Briefly, proteins were
electrophoretically transferred to nitrocellulose membranes, then
blocked for 2 to 24 h in PBS with 10% nonfat dry milk, and washed
twice in PBS with 0.5% Tween 20 for 5 to 10 min. Incubation with a
monoclonal antibody to c-Myc (N-262; Santa Cruz Biotechnology) or c-Myb
(a kind gift from Eric Westin and Tim Bender) was carried out at room
temperature in PBS with 5% dry milk. Protein was detected using an ECL
kit (Amersham Life Sciences Inc.).
| |
RESULTS |
A conditionally active Myb reverses IL-6-induced growth arrest in
M1 cells and directly activates c-myc.
M1 cells cultivated
in the presence of IL-6 undergo terminal differentiation to a mature
macrophage phenotype over the course of 3 to 4 days. This effect is
accompanied by growth arrest 2 to 3 days after treatment and by cell
death through apoptosis 5 to 7 days poststimulation (6, 58).
c-myb RNA is reduced to nondetectable levels in the
differentiating cells by as early as 3 h after stimulation with
IL-6, while c-myc RNA, after a transient increase for 3 h, gradually decreases until it is no longer detectable at around
24 h (6, 58). To determine if c-Myb can positively regulate c-myc, we investigated whether a conditionally
active c-Myb could induce proliferation and reactivate c-myc
expression in M1 cells. For this study, we used a conditionally active
MybER fusion protein (see Materials and Methods) (Fig.
1A). It has been demonstrated that in the
absence of hormone stimulation, constitutively expressed chimeric
proteins such as this one are inactive but can change to an active
conformation upon binding of the estrogen analog 4-OHT to the ER part
of the protein (10, 35, 51). A plasmid containing MybER was
transfected into M1 cells. Western blot analysis of M1 cells stably
transfected with MybER (M1/MybER cells) confirmed expression of the
chimeric MybER protein (Fig. 1B).
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FIG. 1.
Effects of MybER on cell growth in IL-6-treated M1
myeloblastic cells. (A) Structure of the retroviral vector LXSN with
sequences encoding MybER inserted downstream of the virus long terminal
repeat (LTR). SV, simian virus 40 promoter; neo, neomycin resistance
gene; TA, transactivation domain; LZ, leucine zipper; aa, amino acids.
(B) Western blot analysis showing expression of MybER. The protein was
detected using a monoclonal c-Myb antibody. (C) Growth curve of
M1/MybER cells cultivated in the presence of IL-6 for 3 days prior to
treatment with 4-OHT; control cultures were incubated with IL-6 alone
or 4-OHT alone. Shown is the mean of three independent results with a
standard deviation smaller than 15%.
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The effect of MybER protein on cell growth was examined first. As shown
in Fig. 1C, M1/MybER cells that had been cultivated in the presence of
IL-6 for 3 days and had undergone growth arrest were able to
proliferate again following stimulation with 4-OHT (Fig. 1C). In fact,
the doubling time for this IL-6 and 4-OHT-treated cell population (30 h) was almost identical to that of the control cells grown only in the
presence of 4-OHT (29 h). Therefore, the chimeric MybER protein was
shown to have a dramatic influence on M1 cell growth.
Northern blot analysis of c-myc expression showed that in
M1/MybER cells incubated with IL-6 alone, c-myc was down
regulated 24 h following treatment with the cytokine. M1/MybER
cells with the inactive fusion protein showed, therefore, a response to
treatment with IL-6 comparable to that reported for M1 wild-type cells
by Bies et al. (6) and Selvakumaran et al. (58).
In sharp contrast was the continued expression of c-myc in
the same cells 24 h following treatment with IL-6 in the presence
of 4-OHT (Fig. 2A and B). Significantly,
c-myc expression, in addition to being maintained at high
levels when 4-OHT was added at the same time as IL-6, could be restored
when 4-OHT was added to cells that had been differentiating in the
presence of IL-6 for up to 3 days, the longest period tested (Fig. 2B).
4-OHT itself had no effect on c-myc expression as shown in
Fig. 2C. To determine if the effect of the modified c-Myb was direct or
indirect, we treated the cells with cycloheximide to inhibit protein
synthesis. As shown for parental M1 cells, cycloheximide itself had no
effect on c-myc mRNA levels during the incubation period
used for these experiments (Fig. 2C). Since c-myc expression
was restored in M1/MybER cells in the presence of cycloheximide, as
demonstrated in Fig. 2C, we conclude that MybER directly up regulates
c-myc in these myeloid cells and is likely responsible for
reversing growth arrest. Furthermore, we have evidence that the effect
of c-Myb on c-myc expression is through regulation at the
transcriptional level, because c-myc expression could not be
restored in cultures that were treated with an inhibitor of
transcription, actinomycin D (Fig. 2D).
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FIG. 2.
Northern blot analysis showing regulation of
c-myc by c-Myb in M1/MybER cells differentiating in the
presence of IL-6. (A) Down regulation of c-myc RNA in M1
cells stimulated with IL-6. Total RNA was separated on a agarose gel,
blotted on nitrocellulose, and hybridized with a c-myc
probe. The same blot was rehybridized with a probe for GAPDH
to control for sample loading. (B) Analyses of IL-6-stimulated cells
showing continued expression of c-myc or reactivation of
c-myc due to activation of MybER by 4-OHT. Cells were
cultivated in the presence of IL-6. 4-OHT was added at either 0 or
72 h following IL-6 treatment, as shown on the left, and RNA was
analyzed for c-myc expression at 0, 3, 12, 24, and 48 h
after activation of MybER. (C) Reactivation of c-myc
expression in IL-6-treated M1/MybER cells in the presence or absence of
the protein synthesis inhibitor cycloheximide. As a control, parental
M1 cells were tested for effects of 4-OHT or cycloheximide on
c-myc RNA expression. Cells were incubated with IL-6 for
72 h prior to addition of 4-OHT and/or cycloheximide. RNA was
analyzed for c-myc expression at 0, 3, and 6 h after
treatment with 4-OHT and/or cycloheximide. (D) Reactivation of
c-myc expression in IL-6-treated M1/MybER cells is blocked
in the presence of the transcription inhibitor actinomycin D. Cells
were incubated with IL-6 for 72 h prior to addition of 4-OHT and
actinomycin D. RNA was analyzed for c-myc expression at 0, 3, and 6 h after treatment with 4-OHT and actinomycin D.
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To rule out the possibility that the ER part of the MybER fusion
protein is responsible for the observed effect on c-myc
expression, we switched to a conditionally active system that allows us
to express the full-length, native c-Myb protein. For this purpose, we
cloned full-length c-myb under control of the
metallothionein (MT) promoter (MTCB6+c-Myb) and transfected the plasmid
into M1 cells. Northern blot analysis of the resulting single-cell
clones showed expression of c-myb following stimulation of
the MT promoter with ZnCl2. An example is shown in Fig.
3A. Cultivation of these cells in the
presence of IL-6 and ZnCl2 resulted in inhibition of the
down regulation of c-myc expression. This is in contrast to
the observed down regulation in control cells, expressing the empty
MTCB6+ vector (Fig. 3B). Furthermore, c-myc expression could be restored by c-Myb in cells that were already differentiating in the
presence of IL-6 for 24 h prior to activation of the MT promoter
with ZnCl2 (Fig. 3B). The up regulation was not as dramatic or as long lasting as that observed for MybER and may be explained by
the fact that the overall activation of the MT promoter was significantly lower and started dropping a few hours following stimulation with ZnCl2 (Fig. 3A). Use of both conditionally
active systems led us to the same result, that activation of c-Myb in M1 cells during differentiation can not only inhibit the IL-6-induced down regulation of c-myc but reinduce its expression as
well.
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FIG. 3.
Conditional expression of c-Myb using the MT promoter
also results in up regulation of c-myc RNA in M1/MTCB6+c-Myb
cells differentiating in the presence of IL-6. (A) M1/MTCB6+c-Myb cells
were first incubated with IL-6 for 72 h to down regulate
endogenous c-Myb and then treated with ZnCl2. Total RNA was
examined for c-Myb expression at the indicated time points by Northern
blot analysis using c-Myb as a probe. Depicted here is the result for
the single-cell clone used in the following experiments. (B) Analyses
of IL-6-stimulated cells showing continued expression of
c-myc or reactivation of c-myc due to activation
of exogenous c-Myb in M1/MTCB6+c-Myb cells. c-myc is down
regulated in M1/MTCB6+ control cultures. Cells were cultivated in the
presence of IL-6. ZnCl2 was added at either 0 or 24 h
following IL-6 treatment, as shown on the left, and RNA was analyzed
for c-myc expression at 0, 3, 12, 24, and 48 h or at 0, 3, 7, 14, and 24 h after activation of c-Myb.
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Dominant negative Myb influences growth of an MML cell line with
c-Myb activated by insertional mutagenesis.
A goal of our study
was to determine if the regulation of c-myc by c-Myb in M1
cells also functions in leukemias in which c-Myb is proposed to be the
direct cause for the development of the disease. For this purpose, we
studied both c-Myb's functional roles and its regulatory properties in
the leukemic cell line RI-4-11 (45). This cell line is one
of many leukemias derived in vivo by inoculation of a murine retrovirus
in pristane-treated mice. It, like others derived in this model system
(61, 72), has undergone insertional mutagenesis of the
c-myb locus and demonstrates constitutive expression of
c-Myb. In these cells, unlike in M1 cells, c-myb cannot
easily be down regulated by treatment with differentiation inducers
such as IL-6. Therefore, to determine whether constitutive expression
of c-myb may contribute to the continuous growth behavior
through regulation of c-myc, we took a different approach by
inhibiting Myb's function using a dominant negative Myb (MybEnER)
(Fig. 4A) (36). RI-4-11 and M1
cells were infected with a retrovirus expressing either MybEnER or EnER as a control. To obtain cells expressing the dominant negative protein
at high levels, infected RI-4-11 and M1 cells were selected in G418,
cloned, and analyzed for MybEnER or EnER expression by Northern blot
analysis. Figure 4B shows examples of the clones chosen for the studies
presented here. Protein levels, determined by Western blot analysis,
correlated with the detected RNA levels (data not shown).
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FIG. 4.
Analysis of M1 or RI-4-11 cells with blocked Myb
function due to expression of a dominant negative Myb (MybEnER). (A)
Structure of the fusion genes MybEnER and the control EnER, inserted
downstream of the virus long terminal repeat in LXSN (Fig. 1A). aa,
amino acids. (B) Total RNA from individual cell clones of transfected
M1 or RI-4-11 cells were analyzed for MybEnER or EnER expression. A
EnER probe was used for hybridization. (C) Effect of the dominant
negative Myb on the number of viable cells. Viable counts were
determined using trypan blue dye exclusion in clonal populations of
M1/MybEnER cells, RI-4-11/MybEnER cells, or their respective controls
expressing EnER, following activation of the fusion protein. Data shown
are calculated as the mean of three independent experiments with a
standard deviation smaller than 15% and plotted as ratio of the number
of viable cells in the stimulated population versus the number of cells
in the unstimulated population and expressed as percentage.
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RI-4-11/MybEnER and M1/MybEnER cells were first characterized for
changes in the ability to proliferate after stimulation with 4-OHT.
Activation of the dominant negative Myb caused a substantial decrease
in the number of viable cells. There was a slight inhibitory effect on
all cells due to 4-OHT alone; however, the inhibitory effect of MybEnER
on proliferation in the tumor cell line RI-4-11 was 5- to 10-fold
stronger than that observed in EnER cultures (Fig. 4C). A less dramatic
but still reproducible effect was observed in M1 cells, where
proliferation was two- to threefold less in MybEnER-expressing clones
than in the EnER-expressing clone.
To determine if apoptosis was responsible for the cell death observed,
clonal cell populations were examined by the annexin V assay.
Stimulation with 4-OHT led to increases in the number of apoptotic
cells (Fig. 5A).
In RI-4-11 cells with activated MybEnER, the first evidence that the cells were undergoing apoptosis was found at 24 h poststimulation, while in M1 cells apoptosis became evident at 36 to 48 h postinduction. The maximum increases in apoptotic cells were 8.2-fold in RI-4-11 cells and 5.4-fold in M1
cells compared to nonstimulated cells. Consistent with these results,
we detected a strong increase in DNA fragmentation after stimulation of
the MybEnER clones with 4-OHT (Fig. 5B). Because the antiapoptotic
gene bcl-2 has been demonstrated to be a target of c-Myb in
some cell systems, we examined its expression by Northern blot analysis
in hormone-stimulated cells expressing MybEnER. Although we were unable
to show large changes in bcl-2 expression after 4-OHT
treatment in the dominant negative system, activation of MybER in
M1/MybER cells caused a clear up regulation of bcl-2 expression several hours following stimulation, suggesting that c-Myb
is also able to influence the antiapoptotic pathway in this cellular
system (data not shown).
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FIG. 5.
Activation of MybEnER in clonal populations of M1 and
RI-4-11 cells leads to apoptosis and cell cycle arrest. (A) Increase in
apoptotic cells as determined by the TACS annexin V apoptosis assay.
The y axis depicts the fold increase in the amount of
apoptotic cells, and the x axis depicts the hours after
stimulation with 4-OHT. Data shown are the mean of three independent
results with a standard deviation smaller than 15%. (B) A DNA
fragmentation assay used to detect late-stage programmed cell death.
DNA laddering is prominent in MybEnER clones following activation of
the fusion protein. (C) Flow microfluorometric analysis of the cell
cycle distribution in RI-4-11/MybEnER or RI-4-11/EnER cells stimulated
with 4-OHT for 24 h. Cell cycle distribution was examined using a
Becton Dickinson FACScan and analyzed with the ModFitLT V2.0 program.
The proportions of cells in G0-G1,
G2-M, and S are shown in boxes in each graph as percentages
of the total population.
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Although it could be demonstrated, as described above, that apoptosis
accounts, at least in part, for reduced cell growth in MybEnER cells,
we wanted to determine if alterations in the cell cycle could also be
responsible for this effect. MybEnER cells treated with 4-OHT for
24 h, a period corresponding to one doubling time, were shown to
have an increase in the proportion of cells remaining in G1
compared to unstimulated cells (Fig. 5C). Cell cycle arrest was
observed in both RI-4-11 (clone 16 [cl16] and cl38) and M1 (cl9 and
cl16) cells, with increases in the G1 populations of 1.4-, 1.3-, 1.3-, and 1.6-fold, respectively, compared with the negative
control EnER. We concluded that the reduced cell numbers in MybEnER
cells, stimulated with the synthetic steroid, was due to G1
arrest as well as increased apoptosis. We also concluded that
deregulated c-Myb is responsible for the uncontrolled growth of the
leukemia cells.
Use of a dominant negative Myb to substantiate the regulatory
connection between c-myc and c-Myb in an MML induced by
disregulated c-myb.
As shown in Fig. 2, in partially
differentiated and growth-arrested M1 cells, induction of active MybER
led to a reactivation of c-myc expression. We wanted to
determine if c-myc is also responsible for Myb-dependent
proliferation in the RI-4-11 leukemia cell line with constitutively
activated c-myb. Following stimulation with 4-OHT,
RI-4-11/MybEnER and M1/MybEnER cells were examined for c-myc
expression by Northern blot analysis. c-myc was down
regulated in RI-4-11 cell clones expressing the dominant negative Myb,
3 to 7 h after stimulation with the synthetic steroid (Fig.
6A). Similar results were obtained for M1
cells (Fig. 7A). In contrast, no change
in c-myc RNA levels in individual clones expressing EnER was
observed. Western blot analysis using a monoclonal c-Myc antibody
confirmed the down regulation at the protein level (Fig. 6B and 7B).
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FIG. 6.
Down regulation of c-myc in RI-4-11/MybEnER
cells stimulated with 4-OHT. (A) Clonal populations of RI-4-11 cells
expressing MybEnER or EnER were treated with 4-OHT and analyzed at the
indicated times poststimulation for expression of c-myc RNA
by Northern blot analysis. -actin was used to probe the
same blots as a control for loading. (B) c-Myc protein expression was
determined by Western blot analysis in RI-4-11/MybEnER or EnER cells at
0 and 24 h following stimulation with 4-OHT.
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FIG. 7.
Down regulation of c-myc in M1/MybEnER cells
stimulated with 4-OHT. (A) Clonal populations of M1 cells expressing
MybEnER or EnER were treated with 4-OHT and analyzed at the indicated
times poststimulation for expression of c-myc RNA by
Northern blot analysis. -actin was used to probe the same
blots as a control for loading. (B) c-Myc protein expression was
determined by Western blot analysis in M1/MybEnER or EnER cells at 0 and 24 h following stimulation with 4-OHT.
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To rule out the possibility that the ER part of the dominant negative
protein was responsible for the observed effects, we placed the MybEn
part of the fusion gene under the control of the inducible MT promoter
in the pMTCB6+. In M1 cells stably transfected with MTC6+MybEn, MybEn
could be detected within 14 h when stimulated with 50 µM
ZnCl2 (Fig. 8A). Consistent
with our previous results, c-myc expression was found to be
significantly down regulated by MybEn, while there was no change in
c-myc mRNA levels in cells transfected with the empty
plasmid pMT-CB6+ (Fig. 8B). The reduction in c-myc first
became visible after 7 h after stimulation with ZnCl2
in M1/MybEn cells. Interestingly, this is 4 h later than the
response observed with the fusion protein MybEnER and can be explained
by the fact that expression of MybEn must be induced at the RNA level,
while MybEnER is constitutively expressed. Therefore, we concluded that
in both inducible systems, Myb controls expression of c-myc
in leukemic cells.
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FIG. 8.
Conditional expression of dominant negative Myb in M1
cells using the MT promoter also results in down regulation of
c-myc RNA. (A) M1/MTC6+MybEn cells were treated with
ZnCl2 and analyzed for MybEn RNA expression at the
indicated times. Induction of MybEn RNA expression was examined by
Northern blot analysis using MybEn as a probe. (B) c-myc
expression was examined in the same cells by Northern blot analysis at
the indicated times after addition of ZnCl2. Cells
transfected with the empty pMTC6+ vector were used as a control.
GAPDH was used as a probe to control for loading.
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|
We noticed that the effect on c-myc was transient in both
conditional systems used to activate the dominant negative Myb. Analysis of the MybEnER protein itself revealed no differences in the
levels of expression during the stimulation period (data not shown). In
addition, restimulation of M1/MybEnER cells 48 h after the first
induction had no influence on prolonging the inhibitory effect of the
dominant negative protein. Since this observation cannot be explained
by inactivation of the drug or a feedback mechanism affecting the
receptor level, we suggest that the effect is due to a negative
selection process against cells in which c-myc and other
genes are down regulated. As activation of the dominant negative Myb
leads to cell cycle arrest and apoptosis around 24 h following
induction, RNA isolated at later time points comes from an increasing
percentage of cells that are not affected by the treatment.
Expression of other putative c-Myb target genes in M1/MybEnER
cells.
In addition to c-myc, several putative target
genes of c-Myb have been described which may be involved in c-Myb's
function in regulating proliferation, such as cdc2,
c-kit, and c-myb itself (48, 71). By
examining the endogenous expression of c-myb in activated
M1/MybEnER cells by Northern blot analysis, we determined that
c-myb was down regulated 3 to 7 h after stimulation
with 4-OHT, in a pattern analogous to what we had observed for
c-myc (Fig. 9A). This result
indicated that the mouse c-Myb protein is able to influence its own
expression in myeloid cells. This observation was not completely
unexpected, as it has been shown before that the human c-Myb protein is
able to autoregulate its own promoter in T cells and fibroblasts
(24, 49).
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FIG. 9.
Expression of putative c-Myb target genes in M1/MybEnER
cells treated with 4-OHT. (A) MybEnER cl38 cells were treated with
4-OHT; at the indicated times, expression of endogenous
c-myb RNA was examined by Northern blot analysis.
GAPDH was used as a probe to control for loading. (B) RNA
analysis was carried out as for panel A, using probes for
cdc2, cyclinD1, and ODC.
-actin was used to probe the same blots as a control for
loading.
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|
Ku et al. demonstrated that c-Myb is able to transactivate the human
cdc2 promoter and suggested that c-Myb may regulate cell cycle progression by activating expression of the cdc2 gene
(31). We detected no changes in cdc2 expression
after stimulating M1/MybEnER cl38 cells with 4-OHT for 96 h (Fig.
9B). A connection between c-Myb and CDC2, therefore, could not be
confirmed in mouse myeloid cells using the dominant negative Myb.
Another regulator of the cell cycle, c-Kit, a tyrosine kinase receptor
that plays an important role in hematopoietic cell growth, has recently
been suggested to be regulated by c-Myb and to be important for
proliferation of very early myeloid cells derived from fetal liver
(27, 54). However, we were unable to study the potential
effects of c-Myb on c-kit in the system used here, because
expression of this gene could not be detected in M1 or RI-4-11 cells
(data not shown). The stem cell factor is normally expressed only in
very early progenitor cells.
Interestingly, we found an inhibitory effect on cyclinD1
expression after stimulation of the dominant negative Myb protein in
M1/MybEnER cl38 cells (Fig. 9B). Cyclin D1 is known to be an important
factor for cell cycle progression by driving cells from the quiescent
G0 phase to G1 phase, and it was shown to be
regulated by c-Myc (26). As expected, the effects on
cyclinD1 occurred later than those on c-myc. To
further evaluate downstream effects of deregulated c-myc
expression due to activation of MybEnER, we examined the influence of
the dominant negative protein on another target gene of c-Myc,
ODC. ODC is involved in polyamine biosynthesis and has been
shown to be required for entry and progression through the cell cycle
(23, 26). In M1/MybEnER cl38 cells, stimulation with 4-OHT
caused a reduction of ODC several hours later than the down
regulation of c-myc with a time course similar to that seen
for cyclinD1 (Fig. 9B). This experiment demonstrated that
the blocking of c-Myb function not only influences expression of direct
target genes like c-myc but also has an effect on genes further down in this regulatory pathway of proliferation.
A conditionally active Myc reverses IL-6-induced growth arrest in
M1 cells comparably to MybER.
Next we wanted to determine whether
c-Myb might control proliferation in myeloid cells solely through
c-myc. In the first experiment, we attempted to reverse the
growth arrest, induced in cells with the dominant negative Myb, by
constitutive over expression of c-myc. However, treatment of
the double transfectants with tamoxifen led to a dramatic increase in
the number of apoptotic cells and was responsible for inconsistent cell
cycle results. Induction of apoptosis in these cells was probably due
to an acquired increased sensitivity to drugs, since this has been
reported recently for cells which overexpress c-myc
(47). Because of this, we went back to the M1
differentiation model to establish a role for c-Myc as the major
transducer of Myb's proliferation signal. In this model, we compared
the effects of MycER with those of MybER on cell cycle distribution. M1
cells transfected with a MycER fusion gene were checked for expression
by Northern blot analysis (Fig. 10;
Table 1). Significantly, activation of
MycER in cells that were cultivated with IL-6 for 3 days, and therefore growth arrested and nearly terminally differentiated, reversed growth
arrest to almost the same degree as activation of MybER (Table 1)
(40.6% to 70.5% reversal, versus 70.6% to 107.0%). Although we
cannot rule out the possibility that an additional c-Myb target gene(s)
may be involved in proliferation in myeloid cells, this experiment
demonstrates that c-myc plays a very dominant role in this
process.
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FIG. 10.
Northern blot analysis showing expression of MycER in
transfected M1 cells. Total RNA from M1 cells transfected with the
c-myc expression vector pBabe Puro MycER was monitored for
MycER expression, using MycER as the probe.
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| |
DISCUSSION |
The data presented here show for the first time that the
expression of endogenous chromosomal c-myc, a gene well
known to be involved in cell growth, can be directly regulated by
c-Myb. By demonstrating that inhibition of c-Myb simultaneously leads to growth arrest and down regulation of c-myc, we are able
to suggest a mechanism by which the proto-oncogene c-Myb exerts its oncogenic activity. Additionally, this study provides an explanation for the leukemogenic phenotype observed in an MML-derived cell lines
where c-myb has been activated by retroviral insertional mutagenesis.
Evidence for the regulation of c-myc by c-Myb came from four
conditional expression systems. Two of these systems exploited the M1
cell differentiation model, in which IL-6 treatment causes growth
arrest and down regulation of both c-myb and
c-myc. In this model, it was possible by using MybER to
restore both growth and c-myc expression even after the
cells were nearly terminally differentiated. To eliminate potential
regulatory effects of the ER portion of the fusion protein, the coding
sequences for full-length c-Myb were placed under control of the MT
promoter. With this construct, it was possible not only to confirm
Myb's ability to inhibit the down regulation of c-myc
during differentiation but also to confirm its ability to reinduce
expression of c-myc in cells that were already
differentiating. Two additional systems utilizing conditional
expression of dominant negative Myb proteins were initiated to study
the function of c-Myb in the leukemia cell line RI-4-11, in which
c-myb cannot be easily down regulated by cytokines. When
activated in RI-4-11 cells, the dominant negative Myb led to apoptosis
and cell cycle arrest, effects which are likely to be caused, at least
in part, by the observed major reduction in the level of c-Myc.
Expression of downstream targets of c-Myc were also affected by MybEnER
subsequent to its effect on c-myc. While expression of
c-myc was down regulated 3 to 7 h following activation
of the dominant negative protein, expression of two proposed c-Myc
target genes, cyclinD1 and ODC (26, 56,
67), was reduced several (7 to 14) hours later. Repression of
indirect target genes demonstrates how Myb transduces proliferation
signals down a pathway to other important regulators of the cell cycle.
c-Myb's ability to regulate the expression of c-myc may be
tissue specific, because studies in lymphoid and erythroid cells, using
conditionally active Myb or a conditionally active dominant negative
Myb, did not support this connection. For example, in a murine
erythroleukemia cell line, a conditionally active MybER blocked
differentiation but had no effect on proliferation or c-myc
expression (35). Similarly, dominant negative Myb caused apoptosis in T cells, but this effect was not accompanied by growth arrest or deregulation of c-myc (65). The fact
that regulation of the resident c-myc by c-Myb was observed
in myeloid cells and not lymphoid or erythroid cells is consistent with
reporter gene experiments which showed that transactivation of the
c-myc promoter by c-Myb is significantly higher in myeloid
cells than in all other cell types examined (13).
The c-myc promoter has been shown to have binding sites for
many transcription factors, in addition to those for c-Myb, and it is
presumed that the transactivation of this promoter by c-Myb would
require additional transcription factors as well as cofactors. Known
cofactors that bind to the DNA binding and transactivation domains of
c-Myb are p100 and p300/CBP, respectively (48). Presumably, additional known factors, as well as perhaps unknown factors, could be
involved in the activation of c-myc. As c-Myb was able to
induce c-myc in nearly terminally differentiated cells
during IL-6-induced differentiation, it must be assumed that if such transcription factors or coactivators are necessary, they have remained
at sufficiently high levels during the differentiation process.
Recently, it was reported that in fetal liver-derived,
c-Myb-transformed primitive myeloid cells, c-Myb was able to regulate proliferation by activating c-kit but had no effect on
c-myc (27). We were not able to detect expression
of the stem cell factor gene c-kit in M1 or RI-4-11 cells.
However, both cell lines seem to be more differentiated than those used
in the study mentioned above (27) and would not be expected
to express c-kit any longer. It is not inconceivable that
during the in vivo development of leukemias such as RI-4-11,
c-kit may be an additional important target for c-Myb in
establishing myeloid tumors. This would fit with the proposed notion
that preleukemic myeloid cells, initiated by provirus integration in
the c-myb locus, are early progenitors that later
differentiate into mature cells in which c-kit is ultimately no longer expressed (46). Alternatively, it is possible that target cells transformed by infection of fetal liver cells in vitro are
even more primitive than those transformed in adult mice in the MML
model, which gives rise to leukemias such as RI-4-11 (45).
c-kit, as a target gene of c-Myb, would in this case not be
important for the development of MML.
Although the function of c-Myc is not yet clear, it is generally
accepted that it acts as a ubiquitous regulator of proliferation in
cycling cells and normally is not detected in growth-arrested cells.
There is a rapid increase in c-Myc levels shortly after cells enter the
cell cycle which remain high as long as the cells are proliferating
(26, 67). Consistent with this observation, c-Myc has been
shown to be important for most cells to proceed from the G1
to the S phase of the cell cycle and also functions in G2
(59). Homozygous deletion of c-myc in a
fibroblast cell line has been shown to increase the cell cycle length
around threefold (40). Here, we attempted to answer the
question of whether c-myc might be the sole target of Myb
responsible for proliferation by determining if MycER could effectively
reverse IL-6-induced cell cycle arrest. We found that the percentage of
cells moving back into the cell cycle, after activation of MycER, was
almost as high as after activation of MybER. That MycER was not quite as effective as MybER could be due to the fact that the human c-Myc
domain expressed in the fusion gene may not be as effective in
promoting growth as the authentic murine c-Myc. It is also possible
that when c-Myc is expressed as a fusion protein, dimerization with its
partner Max and/or DNA binding may occur with lower affinity than with
the native protein. An additional consideration is that activation of
MybER results in the up regulation of bcl-2, inhibiting the
induction of apoptosis in these cultures, while the overexpression of
MycER can induce apoptosis, which may impair cell proliferation. Therefore, we conclude that c-myc may be the only gene
transducing Myb-dependent proliferation; however, because of the
quantitatively greater effects of MybER than of MycER, we cannot rule
out the possibility that Myb promotes cell growth through regulation of another gene(s) as well.
As demonstrated here, activation of the dominant negative Myb has an
influence on the expression of endogenous c-myb in myeloid progenitor cells, suggesting that an autoregulatory mechanism that
involves the mouse c-myb promoter is functioning in these cells. It has been previously reported for the human c-myb
promoter that binding of c-Myb to its binding sites in the 5' flanking region of the c-myb gene leads to a positive autoregulation
in fibroblasts. Negative regulation was detected in T cells, while the
Myb binding sites seemed to have no function in a myeloid cell line
(24, 49). Because of the general repressive nature of
MybEnER, due to the fact that it contains the Drosophila En transrepressor, it is not yet clear if the authentic c-Myb protein has
a positive or negative effect on regulation of endogenous c-myb expression. However, comparison of endogenous
c-myb mRNA expression in M1/MybER cells with that in
parental M1 cells suggests a positive feedback loop, which would
contribute to Myb's oncogenic potential (data not shown).
In conclusion, the results presented here indicate that c-Myb's role
in leukemias in which c-Myb is activated by insertional mutagenesis is
to maintain continued expression of c-myc, which is
usually down regulated during myeloid differentiation. c-Myb would
therefore influence the proliferation state of these cells by carrying
out this function. Although the prevention of growth arrest is
important to leukemogenesis, it is not necessarily the only function
contributing to the transformed state. Previous data and our data
presented here suggest that c-Myb's role in preventing apoptosis
through the up regulation of Bcl-2 may also contribute to the
neoplastic state. Autoregulation of the c-Myb promoter may contribute
to this state as well. The exact role of c-Myb in regulating
bcl-2, c-myb, and other genes which are potentially involved in the development of myeloid leukemias will require further investigation.
| |
ACKNOWLEDGMENTS |
We thank Jacques Van Snick for providing baculovirus expressing
IL-6 and Stuart Rudikoff and Emily Shacter for assistance in preparing
IL-6 stocks used in this study. We are grateful to Sandra Ruscetti, Dan
Liebermann, and Konrad Huppi for kindly providing probes for
v-kit, cdc2, ODC, and
-actin and to Alan Friedman for sending the MT promoter
plasmid pMT-C6+ as well as to Eric Westin and Tim Bender for the
monoclonal c-Myb antibody. We also thank Doug Lowy for critical reading
of the manuscript.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Laboratory of
Cellular Oncology, National Cancer Institute, Bldg. 37, Rm. 2D11, 37 Convent Dr. MSC 4255, Bethesda, MD 20892-4255. Phone: (301) 496-6763. Fax: (301) 594-3996. E-mail: lwolff{at}helix.nih.gov.
Present address: Institute of Molecular Biology, Slovak Academy of
Sciences, Bratislava, Slovakia.
| |
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Top
Abstract
Introduction
