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Mol Cell Biol, January 1998, p. 499-511, Vol. 18, No. 1
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
The C-Terminal Domain of B-Myb Acts As a Positive
Regulator of Transcription and Modulates Its Biological
Functions
Il-Hoan
Oh and
E. Premkumar
Reddy*
Fels Institute for Cancer Research and
Molecular Biology, Philadelphia, Pennsylvania 19140
Received 26 August 1997/Returned for modification 2 October
1997/Accepted 21 October 1997
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ABSTRACT |
The myb gene family consists of three members, named
A-, B-, and c-myb. All three members of this family encode
nuclear proteins that bind DNA in a sequence-specific manner and
function as regulators of transcription. In this report, we have
examined the biochemical and biological activities of murine
B-myb and compared these properties with those of murine
c-myb. In transient transactivation assays, murine
B-myb exhibited transactivation potential comparable to that of c-myb. An analysis of deletion mutants of
B-myb and c-myb showed that while the
C-terminal domain of c-Myb acts as a negative regulator of
transcriptional transactivation, the C-terminal domain of B-Myb
functions as a positive enhancer of transactivation. To compare the
biological activities of c-myb and B-myb, the
two genes were overexpressed in 32Dcl3 cells, which are known to
undergo terminal differentiation into granulocytes in the presence of granulocyte colony-stimulating factor (G-CSF). We observed that c-myb blocked the G-CSF-induced terminal differentiation of
32Dcl3 cells, resulting in their continued proliferation in the
presence of G-CSF. In contrast, ectopic overexpression of
B-myb blocked the ability of 32D cells to proliferate in
the presence of G-CSF and accelerated the G-CSF-induced granulocytic
differentiation of these cells. Similar studies with
B-myb-c-myb chimeras showed that only chimeras
that contained the C-terminal domain of B-Myb were able to accelerate
the G-CSF-induced terminal differentiation of 32Dcl3 cells. These
studies show that c-myb and B-myb do not exhibit identical biological activities and that the carboxyl-terminal regulatory domain of B-Myb plays a critical role in its biological function.
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INTRODUCTION |
The myb gene family
currently consists of three members, named A-, B-, and c-myb
(28). All three members of this family encode nuclear
proteins that share extensive sequence homology and bind DNA in a
sequence-specific manner and function as regulators of transcription
(4, 11, 16, 24, 34, 42). The first one-third of each protein
consists of an unusual structure of three tandem 50- to 52-amino-acid
direct repeats which appear to mediate binding of the Myb proteins to
DNA (4, 33, 34, 42). The central portion of the molecule
contains a region which mediates the transactivating function of the
proteins (34, 42). The C-terminal ends of these proteins
contain a third conserved region whose function is at present unclear.
A negative regulatory function has been proposed for this domain
because deletion in this region appears to enhance the transcriptional
transactivation potential of the c-myb gene product
(10, 34, 42).
The sequence-specific DNA binding activity and ability to activate
transcription of reporter genes linked to certain promoter-enhancer sequences suggest that Myb proteins act as nuclear transcription factors (11, 34, 42). Studies with antisense
oligonucleotides demonstrate that expression of the c-myb
gene product is essential for the proliferative potential of several
myeloid and T-cell lines (15). In addition, studies with
hematopoietic and neuronal cell lines suggest that terminal
differentiation of these cells is accompanied by downregulation of
c-myb gene expression (31, 37, 41) and that
constitutive expression of c-myb blocks terminal differentiation of these cells (5, 7, 29, 30, 35, 38).
Elimination of c-myb function in vivo by gene knockout techniques, has indicated that homozygous null c-myb mutant
mice fail to show effective fetal hepatic hematopoiesis, resulting in
their death in utero (25).
While c-myb and A-myb are known to be
transactivators of transcription, there appears to be some controversy
regarding the transactivation function of B-myb. In the
chicken system, Foos et al. (13) have reported that
B-myb lacks transactivation function and indeed functions as
an antagonist to c-myb. However, Mizuguchi et al.
(24), using human B-myb clones, reported the
transcriptional transactivation of reporter genes containing Myb
recognition sequences. Furthermore, deletion of the carboxyl terminus
of B-Myb has been found to downregulate the transactivation potential
of B-myb (26), suggesting that the C-terminal
domains might have distinctive functions in c-myb and
B-myb. However, like c-myb, the expression of
B-myb is cell cycle dependent, and antisense inhibition of either c-myb or B-myb was found to independently
inhibit cell proliferation, suggesting that both c-myb and
B-myb regulate cell growth (1, 14, 15, 20).
In this report, we analyzed transcriptional transactivation properties
of murine B-myb and the contribution of the three functional domains to this biochemical function. In addition, we studied the
effect of ectopic overexpression of c-myb and
B-myb on granulocyte colony-stimulating factor
(G-CSF)-induced granulocytic differentiation of 32Dcl3 cells to
determine if the two genes can exhibit similar biological effects in
this cell system. These studies show that c-myb and
B-myb genes perform distinctive biological functions, and
these distinctions are determined by their C-terminal sequences.
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MATERIALS AND METHODS |
Cell culture.
NIH 3T3 cells were cultured in Dulbecco's
modified Eagle medium (DMEM) supplemented with 10% calf serum and
0.5% penicillin-streptomycin (Gibco). COS cells were cultured in the
same medium, except that it was supplemented with 10% fetal bovine
serum (FBS). WEHI3B cells were cultured in RPMI 1640 with 10% FBS.
32Dcl3 (17, 39) was maintained in Iscove's modified
Dulbecco's medium (IMDM) supplemented with 10% FBS and 10% WEHI 3B
cell-conditioned medium as a source of interleukin 3 (IL-3). HD11 cells
were cultured in Iscove's modified DMEM supplemented with 2% chicken
serum and 8% FBS.
Plasmids.
Construction of the reporter plasmids pMIL-luc and
pTA3-luc has been previously described (11, 27). For
expression of c-myb, B-myb, and
B-myb-c-myb chimeras in COS cells or NIH 3T3 cells, each construct was inserted into the expression vector pRC/CMV
(In-vitrogen), which places the inserts under control of the
cytomegalovirus (CMV) immediate-early promoter. Rous sarcoma virus
(RSV)-
-galactosidase (-Gal) plasmid (Invitrogen), which expresses the lacZ gene, was used as an internal standard to
determine transfection efficiencies.
The inducible vector pMT-neo, which has the human metallothionein
promoter containing metal-responsive elements (19) and which
was modified from parental plasmid, was kindly provided by Dan
Libermann.
Construction of chimeric genes and truncation mutants.
The
C-terminal truncated mutants of c-myb and B-myb
were constructed by PCR utilizing primers tagged with NotI
and XbaI sites, and the PCR product was ligated to pRC/CMV
(Invitrogen). The inserts were completely sequenced to ensure that the
PCRs did not introduce any mutations in the two genes. Chimeric
constructs between B-myb and c-myb were generated
by the gene fusion technique described earlier (12). For
example, chimera CCB, which has a 5' end encoding the DNA binding and
transactivation domains of c-myb, was fused to the 3' end of
B-myb, following the protocol described below, which is
schematically illustrated in Fig. 1.
First, a PCR fragment was generated by using a pair of primers. These
included a forward primer (CDF), 5'-ATA GCGGCCGC ATG GCC
CGG AGA CCC CGA CAC-3', which spans the 5' end of c-myb
c-DNA with a NotI site (underlined), and a reverse primer
(CBNR), 5'-GCG CAC TTC TCC CAG ATC AGC GGG GTA GCT GCA AGT
GTG GTT-3', which has the antisense sequence of c-myb up to
the end of the transactivation domain (amino acid 325) fused to the
antisense sequence of B-myb (underlined), corresponding to
the starting region of the B-myb C terminus which encodes
amino acids 260 to 704. A second PCR was performed to amplify the 3' end of B-myb encoding the amino acid sequence 260 to 704 with overlapping c-myb sequences in its 5' terminus. For
this, the forwarding primer, CBNF (5'-AAC CAC ACT TGC AGC TAC
CCC GCT GAT CTG GGA GAA GTG CGC-3'), which contains the fusion
sequences of c-myb and B-myb coding for amino
acids 317 to 325 (underlined) of c-myb and amino acids 261 to 267 of B-myb, was used along with the reverse primer, BNR
(5'-ATA TCT AGA TCA GGA CAG AAT GAG GGT CCG AGA-3'), which
has an XbaI restriction site (underlined) and the 3'
terminus of the B-myb c-DNA. Both PCR products were
combined, and a third PCR was carried out with primer CDF and primer
BNR in order to fuse the two fragments by virtue of their shared
overlapping regions; this reaction generated a full-length chimeric
gene, CCB, with a 5' NotI site and a 3' XbaI
site. In similar manner, a series of domain swapped chimeric genes
between B-myb and c-myb were generated, and each
construct was subcloned into the pRC/CMV expression vector with the
corresponding NotI/XbaI sites in the vector. All
of the constructs which were generated in this manner were completely
sequenced to ascertain that no mutations were introduced into the
coding sequences during PCR.
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FIG. 1.
Schematic representation of the fusion PCR protocol used
for the generation B-myb-c-myb chimeras.
Construction of chimera CCB is illustrated. Outer primer CDF is derived
from the c-myb coding sequence, while BNR is derived from
the B-myb coding sequence. Primers CBNR and CBNF contain
sequences derived from c-myb and B-myb and
determine the point of fusion between the two genes.
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For the insertion of a hemagglutinin (HA) tag into
myb
coding sequences, the c-
myb cDNA cloned into the pRC/CMV
vector was
digested with
BsmBI (which cuts the cDNA
approximately 500 bp
upstream of the terminator codon) and
XbaI (which is in the polylinker
site of the vector), and
this fragment was replaced by a PCR product
of the corresponding coding
region, into which the sequence 5'-TAC
CCA TAC GAC GTC CCA GAC TAC
GCT-3' encoding the sequence YPYDVPDYA
was inserted immediately
upstream of the terminator codon TGA.
Antisera.
To generate anti-c-Myb antiserum, the 5' end of
the c-myb c-DNA encoding amino acids 1 to 325 was subcloned
into the pDS5-6His vector (Quiaexpress), and the resulting fusion
protein was purified by nickel chelate affinity chromatography
(Quiaexpress). The purified protein was injected into rabbits for the
generation of polyclonal antibodies. To generate B-Myb-specific
antibodies, a region of the B-myb c-DNA which shows minimal
homology to c-myb encoding the amino acid sequence 321 to
446 was subcloned into the pDS5-6His vector. Purified B-Myb fusion
protein was used for injection into rabbits to raise B-Myb-specific
antibodies. To detect HA-tagged proteins, a rabbit polyclonal antibody,
Y11, raised against the HA epitope (purchased from SantaCruz
Biotechnology, Santa Cruz, Calif.) was used.
Transient transfection assays.
For transfection into NIH 3T3
cells, cells were seeded into 100-mm petri dishes at a density of
1.5 × 105 to 2 × 105 cells per
plate. After 18 to 24 h, DNA was transfected by the calcium
phosphate precipitation method (2). In each transfection, 5 µg of reporter and 5 µg of effector plasmids were transfected along
with 1 µg of RSV--Gal DNA as an internal standard. Following incubation for 60 to 70 h, the cells were harvested in 900 µl of
reporter lysis buffer (Promega). Luciferase activity was assayed with a
luciferin substrate (Promega) according to the manufacturer's protocol. Luciferase activities were normalized against
-galactosidase activity to determine relative luciferase activities.
Establishment of stable cell lines expressing transgenes.
Exponentially growing 32Dcl3 cells were electroporated with DNA with a
Gene-Pulser (Bio-Rad) at a pulse of 230 V, 960 µF. The transfected
cells were selected in 500 µg of G418 (Gibco-BRL) per ml for 2 to 3 weeks. To isolate single-cell clones, transfected cells were serially
diluted in 96-well plates in the presence of G418 and selected for
clonal expansion.
Northern blot analysis.
Total RNAs from individual 32Dcl3
cell lines were purified with the Ultra-spec RNA (Biotecx) purification
reagent. To purify RNA from Zn2+-induced cells, the cells
were incubated with 100 µM ZnCl2 for 30 h prior to
RNA isolation. Northern blot analysis was performed as previously
described (2). To detect c-myb transcripts, a 2.3-kb c-DNA fragment that contained the entire coding region was
isolated following digestion with BamHI and
HindIII and was used as a probe. To detect
B-myb-specific transcripts, a 1.72-kb B-myb-specific probe was prepared by digestion with
SalI and XbaI.
Western blot analysis.
To analyze the protein products of
the transfected genes, normalized amounts of protein from each cell
lysate were separated by sodium dodecyl sulfate-polyacrylamide gel
electrophoresis (SDS-PAGE) and the separated proteins were transferred
to a polyvinylidene difluoride membrane (Millipore) in transfer buffer
(10 mM CAPS, 10% methanol [pH 11.0]). The filter was blocked with
5% nonfat milk in TTS solution (0.05% Tween 20, 25 mM Tris-HCl [pH
7.4], 150 mM NaCl) for 4 h, incubated with primary antibody in
the same buffer for 1 h, and washed three times in TTS solution.
The filters were then incubated with horseradish peroxidase-conjugated
anti-rabbit immunoglobulin G (Amersham) and washed in the same manner.
The Amersham ECL detection system was used for visualization as
specified by the manufacturer.
Growth and differentiation assays.
32Dcl3 cells were
maintained in IMDM containing 10% FBS and IL-3. Prior to the induction
of differentiation, the cells were washed twice in IL-3-free medium and
plated at a density of 105 cells per ml in medium
containing 10% FBS and GCSF as described earlier (29, 39).
The viability and proliferation rate of the cell cultures were
monitored at regular intervals. Morphological analysis of G-CSF-treated
cells was performed with an aliquot of cells that were cytospun and
stained with May-Grunwald-Giemsa stain. To determine the proliferation
rate in IL-3, cells were plated at a density of 105 cells
per ml in medium containing IL-3 and 10% FBS, and cell numbers were
determined at daily intervals.
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RESULTS |
Comparison of the transactivation potentials of murine
c-myb and B-myb.
Figure
2A shows a structural comparison between
c-Myb and B-Myb proteins. The two proteins share highest structural
homology in the DNA binding domain (87%), while they are least
homologous (48%) in the transactivation domain. In the C-terminal
regulatory domain, they share 51% sequence identity (21).
As can be expected from the high degree of homology in the DNA binding
domain, it has been shown that both c-Myb and B-Myb bind to the
sequence motif PyAACT/GG (24).
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FIG. 2.
(A) Structural comparison of c-Myb and B-Myb. Schematic
structures of B-Myb and c-Myb proteins are presented. The numbers above
each diagram are the positions of amino acid residues in each
corresponding region. Thick bar, region of homology; percent homology
values to c-Myb in each domain are given. Horizontal arrows, the three
51-to-52-amino-acid repeats that constitute the DNA-binding domain;
DNBD, DNA-binding domain; TA, transactivation domain; NRD, negative
regulatory domain. (B) Schematic representation of reporter and
effector plasmids used in transient transactivation assays. Dotted box,
promoters; arrows in promoters, starting sites of transcription; arrows
in Myb, the three 51-to-52-amino-acid repeats of the DNA-binding
domain; black box, transactivation domain; boxed A, B, and C in
pMIL-luciferase, the three Myb binding sites in the mim-1
promoter; TK, herpes simplex virus thymidine kinase (TK) promoter; CMV,
immediate-early promoter for CMV. (C and D) Transcriptional activation
by B-Myb and c-Myb. Each myb expression plasmid was
transfected into NIH 3T3 cells along with either reporter plasmid
pMIL-luc (C) or pTA3-luc (D) and the RSV--Gal plasmid as described
in Materials and Methods. After 60 to 70 h of transfection, the
cells were harvested and assayed for -Gal activity. The luciferase
activities were normalized to -Gal activities, and the degrees of
activation were obtained by setting the value of empty vector as 1.0. Shown are the means of activation obtained from at least three
independent experiments. Vertical bars, standard deviations of the
values.
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To gain an understanding of the relative transactivation potential of
murine B-
myb and c-
myb, we carried out
transcriptional
transactivation studies. Figure
2B shows the two
reporter plasmids
pMIL-luc and pTA3-luc. The reporter plasmid pMIL was
generated
by cloning the naturally occurring Myb-inducible promoter of
the
mim-1 gene into a luciferase vector (
11,
27).
The reporter
plasmid pTA3-luc contained three copies of Myb binding
sites,
cloned in tandem upstream of a truncated thymidine kinase
promoter
(
27). The expression vectors for c-
myb
and B-
myb were generated
by cloning the two murine cDNAs
into pRC/CMV (Invitrogen), which
places the two genes under the control
of the CMV early promoter.
Following transfection of the reporter and
myb expression plasmids
into a murine cell line, NIH 3T3, we
analyzed the relative transcriptional
transactivation potentials of the
two genes. The results presented
in Fig.
2D show that both c-Myb and
B-Myb transactivated pTA3-luc
reporter approximately 9-fold. Similar
results were obtained with
the pMIL-luc reporter, in which
c-
myb and B-
myb exhibited somewhat
lower but
comparable transactivation potentials of 4.2- and 4.6-fold,
respectively (Fig.
2C). These results demonstrate that murine
B-Myb can
transactivate promoters containing Myb-binding sites
with the same
efficiency as that of c-Myb.
The C terminus of B-Myb is a positive regulatory domain.
Since
deletion of the C-terminal domain of c-Myb results in increased
transactivation potential, we carried out transcriptional transactivation experiments with a mutant of B-myb, from
which the C-terminal sequences were similarly deleted (Fig.
3A). In addition, since the
transactivation domain of B-Myb has been found to lack the acidic amino
acid residues that are considered critical for the transactivation
function of many transcription factors, we examined the transactivation
potential of a mutant form of B-myb, in which the
transactivation domain of the protein had been deleted and the
DNA-binding domain was fused to the C-terminal domain maintaining the
reading frame of the gene (Fig. 3A). The integrity of each construct
was verified by sequence analysis and in vitro translation experiments
to ascertain that different deletion mutants produced translational
products of expected sizes (data not shown). Each expression construct
was then transfected into NIH 3T3 cells along with the pTA3-luc
reporter plasmid, since both c-myb and B-myb
showed higher transactivation levels with this reporter (Fig. 2D). The
results presented in Fig. 3B show that deletion of the 3' end of
c-myb cDNA which encodes the negative regulatory domain
results in a two- to threefold increase in the transactivation
potential of this mutant. On the other hand, deletion of the 3' end of
B-myb, which encodes the corresponding domain, resulted in a
substantial loss of its transcriptional transactivation potential.
Deletion of the transactivation domain of the B-myb gene
resulted in a complete loss of its transactivation potential.
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FIG. 3.
(A) Structures of deleted and truncated mutants of
B-myb. The schematic structures of B-myb mutants
in which the transactivation domain (dl-B-Myb) or the C-terminal domain
(Tr.-BB) have been deleted are presented. Also shown are the structures
of wild-type c-myb and the C-terminus-truncated mutant of
c-myb (Tr.-CC). aa, amino acid. (B) Transcriptional
activation by the wild type and deletion mutants of B-myb.
NIH 3T3 cells were transfected with expression plasmids containing the
deletion mutants of B-myb or c-myb. In each
transfection, 5 µg of effector plasmid and 5 µg of pTA3-luc were
transfected along with 0.5 µg of RSV--Gal DNA. Shown are the mean
values of activation obtained from at least three independent
experiments with standard deviations. Other abbreviations are as
defined in the legend to Fig. 2. (C) Transient expression of effector
molecules. NIH 3T3 cell lysates transfected with expression plasmids
and expressing equal amounts of -Gal activity were subjected to
Western blot analysis and probed with an antibody raised against the HA
epitope. Trunc., truncated.
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To rule out the possibility that the observed increase and decrease of
the transactivation potential of the truncated forms
of
c-
myb and B-
myb are not due to differences in the
expression
levels of effector molecules, we carried out experiments to
determine
the intracellular levels of effector molecules in NIH 3T3
cells
transfected with the effector and reporter DNAs. Since the
antibodies
that are currently available do not recognize C-Myb and
B-Myb
proteins with the same affinity, we constructed c-
myb
and B-
myb expression vectors, which are tagged with the HA
epitope, thus
allowing detection of these proteins with a single
monoclonal
antibody. The transactivation potentials of the various HA
epitope-tagged
molecules were found to be identical to those of their
nontagged
counterparts (data not shown). Analysis of the NIH 3T3 cell
extracts
(normalized to units of
-Gal activity) transiently
transfected
with normal and truncated c- and B-
myb
expression vectors revealed
that the full-length c-Myb protein was
expressed at the highest
levels in these cells, which was approximately
twofold higher
than that seen with the truncated c-Myb. If one were to
normalize
the transactivation activities of the two constructs to the
intracellular
effector protein levels, one could conclude that the
truncated
form of c-Myb exhibits four- to sixfold higher
transactivation
potential than that seen with the full-length
c-
myb expression
vector. This is in agreement with
previously published data (
24,
42). When a similar analysis
was carried out with NIH 3T3 cells
transfected with full-length and
truncated forms of B-Myb, it
was found that the truncated form of B-Myb
was expressed at a
level similar to or slightly higher (1.5- to 2-fold)
than that
of the full-length counterpart. These results allow us to
conclude
that the C-terminal domain of c-Myb acts as a negative
regulator
of its transactivation potential in NIH 3T3 cells, while
under
identical conditions, the C-terminal domain of B-Myb functions
as
a positive enhancer of this transactivation function. This
is in
agreement with the results reported for the human B-
myb gene
(
26).
Construction of chimeric genes between B-myb and
c-myb.
To further demonstrate the distinctive roles played
by the C-terminal domains of c-Myb and B-Myb, we constructed a series of chimeric molecules where the three functional domains of the c-Myb
protein were replaced by the homologous domains of B-Myb. The
structures of these chimeras are shown in Fig.
4A.
Each DNA construct was subcloned into pRC/CMV (Invitrogen), and the
integrity of each construct was verified by sequence analysis and in
vitro transcription-translation assays, which showed that all of the constructs produced translation products of expected sizes (data not
shown). In addition, the constructs were transfected into NIH 3T3 cells
or COS-1 cells, and the cell lysates were examined by Western blot
analysis, which showed that all of the chimeric genes produced proteins
of appropriate sizes and appropriate immune reactivities.
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FIG. 4.
(A) Schematic structures of chimeric genes between
B-myb and c-myb. Schematic structures of
different chimeric constructs between B-myb and
c-myb are presented along with those of wild-type
c-myb and B-myb. Crossed boxes, domains derived
from B-myb (B); blank boxes, domains derived from
c-myb (C). (B) Transactivational activities of
chimeric genes between B-myb and c-myb. NIH
3T3 cells were transfected with 5 µg of each expression plasmid
DNA along with 5 µg of pTA3-luc DNA and 0.5 µg of RSV--Gal
DNA. Activation values were obtained as described above. Shown
are the mean values of activation with standard deviations obtained
from at least three independent experiments. (C) Transient expression
of effector molecules. Cell lysates transfected with expression
plasmids and expressing equal amounts of -Gal activities were
subjected to Western blot analysis and probed with an antibody raised
against the HA epitope. (D) Transactivational activities of chimeric
genes between B-myb and c-myb in HD-11 cells.
HD-11 cells were transfected with 5 µg of each expression plasmid DNA
along with 5 µg of pTA3-luc DNA and 0.5 µg of RSV--Gal DNA.
Activation values were obtained as described above. Shown are the mean
values of activation with standard deviations obtained from at least
three independent experiments. chim, chimera; trunc., truncated.
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Each expression construct was then transfected into NIH 3T3 cells along
with the pTA3-luc reporter plasmid to study their
transactivation
potentials (Fig.
4B). Replacement of the transactivation
domain of
c-Myb with that of B-Myb in chimera CBC resulted in
a reduction of its
transcriptional activity by twofold, an activity
identical to that seen
with the deletion mutant of B-
myb, BB,
which lacks the
C-terminal end. This suggests that the transactivation
domain of B-Myb
loses its ability to transactivate transcription
in the absence of the
C-terminal domain of B-Myb. Replacement
of the C-terminal domain of
B-Myb with that of c-Myb (chimera
BBC) failed to restore the full
transactivation potential of B-Myb,
further indicating that the two
domains do not perform the same
function. These results suggest that
the transactivation and the
C-terminal domains of B-Myb act in concert
in the transcriptional
transactivation of target genes. Replacement of
both the transactivation
domain and the C-terminal domain of B-Myb with
that of c-Myb (chimera
BCC) restored the transactivation potential of
the chimera to
that seen with wild-type c-Myb, suggesting that the
DNA-binding
domains of the two genes are interchangeable.
Interestingly, replacement of the C-terminal negative regulatory domain
of c-Myb with the C-terminal domain of B-Myb, as seen
in chimera CCB,
resulted in a twofold enhancement of the transactivation
potential
compared to that of full-length c-Myb. Similarly, chimera
CBB, which
contains the DNA-binding domain of c-Myb and the transactivation
and
C-terminal domains of B-Myb, showed a transactivation potential
comparable to that of chimera CCB. While the transactivation potentials
of chimeras CCB and CBB are higher than that of wild-type c-Myb,
it
should be noted that there is little or no difference among
the
activities of CCB, CBB, and truncated c-Myb (CC) in this assay.
These
results suggest that the B-Myb carboxyl terminus functions
as a
positive enhancer of transcription in conjunction with its
own
transactivation domain and fails to exhibit a negative regulatory
activity when fused to the DNA-binding and transactivation domains
of
c-Myb. Analysis of the intracellular levels of the effector
molecules
suggests that these chimeric proteins are expressed
at similar levels
in transfected cells (Fig.
4C).
Since the inhibitory activities of the c-Myb C-terminal region vary
considerably among cell lines, we studied the transactivation
potentials of wild-type and various truncated and chimeric forms
of c-
and B-
myb genes in another cell line, HD-11, which is of
hematopoietic origin and which has been used extensively by other
investigators for studies with the c-
myb gene. For this set
of
experiments, we used the reporter plasmid pTA3-luc, since this
construct gives the highest levels of transactivation. Following
transfection of the reporter and
myb expression plasmids
into
HD-11 cells, we analyzed the relative transcriptional
transactivation
potentials of the various constructs, and the results
of this
experiment are presented in Fig.
4D. These results show that
deletion
of the C-terminal domain of c-Myb had little or no effect on
its
transactivation potential. However, deletion of the C-terminal
domain of B-myb resulted in twofold decrease of its transactivation
potential, a result similar to that seen with NIH 3T3 cells. These
results suggest that while the negative regulatory effect of the
C-terminal domain of c-Myb is dependent on the cell type, the
C-terminal domain of B-Myb exhibits its positive influence in
both cell
types. In the HD-11 cell background, chimeras CCB and
CBB exhibited
transactivation potentials 1.5- to 2-fold higher
than that of c-Myb as
well as that of the truncated form of c-Myb
(CC), suggesting a positive
regulatory effect of this domain.
As can be expected, chimeras BBC and
BCC exhibited levels of transactivation
similar to those seen with
B-Myb, again suggesting that the C-terminal
domain of c-Myb does not
exert its negative regulatory effect
in HD-11 cells.
Effect of ectopic overexpression of B-myb and
c-myb on myeloid cell proliferation.
Based on the
observation that both c-myb and B-myb are
expressed during the late G1 phase of the cell cycle and
that antisense oligonucleotides directed against c-myb and
B-myb inhibit cell proliferation, it has been proposed that
these two proteins might have an analogous function in cells in which
the two genes are expressed (1). To determine whether
c-myb and B-myb can function in an analogous
manner, we studied the effect of ectopic overexpression of these two
genes on myeloid cell differentiation. For this we utilized the 32Dcl3
cell line, which is a myeloid precursor cell line derived from normal
mouse bone marrow. This cell line was found to be strictly dependent on
IL-3 for growth and, when cultured in a medium containing GCSF, was
found to undergo terminal differentiation to granulocytes in a period
of 10 to 12 days (17, 29, 32). We had earlier demonstrated
that v-myb and c-myb genes, when ectopically overexpressed in this cell line, blocked its ability to undergo terminal differentiation in the presence of G-CSF and enabled this cell
line to continuously proliferate in G-CSF (29, 30). This
cell line provides a convenient assay system to test whether c-myb and B-myb can exert similar biological
effects in a cell system. For these experiments, the complete coding
regions of both c-myb and B-myb cDNAs were
subcloned into the expression vector containing the human
metallothionein promoter (pMT), the DNAs were electroporated into
32Dcl3 cells and selected in G418, and both mass cultures and single
cell clones were established. Deletion of noncoding sequences from the
c-myb cDNA allowed detection of transgene mRNA as a smaller
transcript. As negative controls, the cells were transfected with an
empty pMT vector that carried the G418 resistance gene. Following the
establishment of permanent cell lines, we examined the effect of
Zn2+ on the expression of the two transgenes.
Figure
5A and B shows the expression of
c-
myb in transfected 32Dcl3 cell lines. 32D cells
transfected with empty vector DNA
(32DpMT neo) showed the presence of a
3.8-kb endogenous c-
myb band in the presence or absence of
Zn
2+. In mass cultures (32DpMT/c-
myb) as well as
single-cell clones
(32DpMT/c13 and -14) that were transfected with
c-
myb expression
vectors, transgene expression was seen as a
2.3-kb transcript
which could be detected at low levels in the absence
of Zn
2+. In the presence of Zn
2+, the levels of
this transcript were elevated by approximately
5- to 10-fold (Fig.
5A).
Interestingly, the endogenous levels
of c-
myb transcripts
were found to be downregulated concomitant
to transgene expression,
suggesting that an autoregulatory mechanism
operates in these cells to
maintain a constant amount of c-
myb (
18). This
does not appear to be due to the addition of Zn
2+, since
such a downregulation was not observed in cells transfected
with empty
vector. When the same cultures were examined for induction
of c-Myb
protein synthesis, we did not observe a significant increase
in the
levels of the Myb protein (Fig.
5B). This appears to be
due to the
downregulation of endogenous c-
myb transcript levels,
which
results in the maintenance of a constant amount of c-Myb
protein. In
order to demonstrate that cells transfected with c-
myb expression vectors do express transgenic c-Myb protein, we compared
the
c-Myb protein levels in cells that were cultured for 12 days
in the
presence of G-CSF. It had been previously shown that in
32Dcl3 cells
grown in the presence of G-CSF, the endogenous levels
of
c-
myb RNA and protein are downregulated and become
undetectable
by the 10th day of G-CSF treatment (
29). Taking
advantage of
this observation, we analyzed the levels of c-Myb protein
in control
and c-
myb expression vector-transfected cells
following their
incubation in G-CSF for 12 days. As shown in Fig.
5B,
c-Myb protein
could be readily detected in control and
vector-transfected cells
prior to their treatment with G-CSF. However,
incubation of the
empty vector-transfected cells in the presence of
G-CSF for 12
days resulted in a complete downregulation of Myb protein
levels,
which became undetectable. In sharp contrast, in the
c-
myb expression
vector-transfected cells, a small amount of
c-Myb protein was
observed in the absence of Zn
2+ and these
levels were markedly increased by Zn
2+ treatment.
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FIG. 5.
Inducible expression of c-myb in 32Dcl3 cell
lines. c-myb c-DNA in pMT-neo vector was transfected into
32Dcl3 cells, and mass cultures (32DpMT/c-myb) as well as
single-cell clones (32DpMT/c13 and -14) were established as described
in Materials and Methods. (A) Northern blot analysis of total RNA
extracted from different cell lines with a full-length c-myb
c-DNA probe. Endogenous (end.) c-myb transcript (upper band)
and c-myb transcript encoded by the transgene (exo; lower
bands) are marked. Ethidium bromide staining of RNA after completion of
RNA transfer onto the nitrocellulose filter is shown in the lower
panel. (B) Expression of c-Myb protein in empty vector-transfected
cells (lanes 1, 2, 5, and 6) and c-myb expression in
vector-transfected cells (lanes 3, 4, 7, and 8). Lanes: 1 and 2, cell
lysates from empty vector-transfected cells grown in the presence of
IL-3; 3 and 4, lysates from cells transfected with
c-myb expression vector grown in the presence of
IL-3; 5 and 6, lysates from cells transfected with empty vector but
grown in the presence of G-CSF for 12 days (note the absence of c-Myb
protein); 7 and 8, lysates from cells transfected with c-myb
expression vector, also grown in the presence of G-CSF for 12 days.
Note the low levels of c-Myb protein in cell lysates in the absence of
Zn2+ (lane 7) and induction of high levels of
transgenic Myb protein in the presence of Zn2+ (lane 8).
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Figure
6A and B shows expression of
transgenic B-
myb RNA and protein in the mass cultures as
well as single-cell clones (pMT/B-10,
-11, and -12) by Northern and
Western blot analyses. 32Dcl3 cells
transfected with empty vector were
found to express little or
no endogenous B-
myb RNA in the
presence or absence of Zn
2+. However, cell lines
transfected with B-
myb expression vectors
showed a high
level of B-
myb RNA expression in the presence or
absence of
Zn
2+. To analyze the expression of the B-
myb
protein in these cells,
we carried out Western blot analyses using a
B-Myb-specific polyclonal
rabbit antiserum. As shown in Fig.
6B, there
was little or no
B-Myb protein expressed in cells transfected with
empty vector
in the presence or absence of Zn
2+. However,
in cells that were transfected with B-
myb expression
vector,
a high level of B-Myb protein could readily be detected
in the absence
or presence of Zn
2+. These results show that the expression
of B-
myb driven by the
metallothionein promoter showed a
significant level of leakiness
such that there was no discernible
difference in the expression
levels between induced and uninduced cells
at both RNA and protein
levels. Despite the apparent lack of inducible
expression, the
absence of B-
myb expression in 32Dcl3 cells
and a high-level expression
of B-
myb in cells transfected
with B-
myb expression vectors allowed
us to study the
effects of ectopic overexpression of B-
myb on
the growth and
differentiation properties of these cells.
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FIG. 6.
Overexpression of B-myb in 32Dcl3 cell lines.
B-myb c-DNA was subcloned into pMT-neo and transfected into
32Dcl3 cells by electroporation. After selection in G418, both mass
cultures (pMT/B-myb) and single-cell lines (pMT/B9, -10, -11, and -12) were established. (A) Northern blot analysis of RNAs
extracted from different cell lines grown in the presence (+Zn) or
absence ( Zn) or Zn2+ was performed with a
B-myb-specific probe as described in Materials and Methods.
A picture of the nitrocellulose filter after ethidium bromide staining
is shown below the Northern blot. (B) Analysis of B-Myb protein in
32Dcl3 cells transfected with B-myb (pMT/B-myb),
c-myb (pMT/c-myb), and empty vector (pMTneo) in the presence
(+Zn) or absence (Zn) of Zn2+ in the medium. Each 32D
cell line overexpressing B- or c-myb expression vector was
lysed, and the cell lysates were subjected to Western blot analysis as
described above. For detection of B-myb-specific
translational product, antibodies specific for B-Myb protein (as
described in Materials and Methods) were used.
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The effects of overexpression of c-
myb and B-
myb
on G-CSF-induced terminal differentiation of 32Dcl3 cells are shown in
Fig.
7 and
8 and Table
1. As shown in Fig.
7A, upon incubation
in
a medium containing G-CSF, 32D cells transfected with the empty
vector underwent several rounds of cell division followed by growth
arrest around day 10 in the absence or presence of Zn
2+. On
the other hand, cells transfected with the c-
myb
expression
vector continued to proliferate without showing any growth
arrest.
In addition, the proliferation rates of these cells were
higher
in Zn
2+-treated cells compared to uninduced cells
(Fig.
7B). These results
suggest that even low-level c-
myb
expression (which is seen in
cells in the absence of Zn
2+)
delays G-CSF-induced growth arrest and that induction of high
levels of
c-Myb expression results in a higher rate of cell proliferation
in the
presence of G-CSF. In contrast, when 32D cells transfected
with
B-
myb expression vector were placed in a medium containing
G-CSF, they underwent growth arrest and failed to proliferate
in the
presence of G-CSF (Fig.
7C). Identical growth profiles
were obtained
with mass cultures as well as all of the single-cell
clones. These
results show that while c-
myb expression results
in
increased proliferation of 32D cells in the presence of G-CSF,
expression of B-
myb results in a block to their ability to
proliferate
in the presence of G-CSF. Interestingly, this
growth-inhibitory
effect of B-
myb was not seen in cells that
were cultured in the
presence of IL-3 (Fig.
7D), suggesting that the
growth-inhibitory
effect of B-
myb is dependent on factors
induced by G-CSF.
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FIG. 7.
Effect of B-myb overexpression on the growth
of 32Dcl3 cells in the presence of G-CSF or IL-3. Cultures of 32Dcl3
cells transfected with empty vector (pMT/neo) (A), c-myb
(pMT/c-myb) (B), or B-myb (pMT/B-myb)
(C) were analyzed for growth in the presence of G-CSF. The cells were
washed twice in IL-3-free medium and plated at a density of
105 per ml in medium containing 10% G-CSF. On each
indicated day, the numbers of viable cells were determined by trypan
blue exclusion. (D) Cell lines described for panels A to C were plated
in IL-3-containing medium at a density of 105 per ml, and
the cell numbers were determined at the indicated time points. Results
are the means ± standard deviations of triplicate determinations
from one representative experiment.
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FIG. 8.
(A) Morphological analysis of 32Dcl3 cells
overexpressing c-myb following incubation in
G-CSF-containing medium. 32D cells overexpressing c-myb were
compared with mock-transfected 32Dcl3 cells for their responses to
G-CSF addition. Aliquots of the cells were cytospun, stained with
May-Grunwald-Giemsa stain, and analyzed for morphological changes
during incubation in the presence (+Z) or absence (Z) of
Zn2+ on day 0 (d0) and day 10 (d10). (B) Morphological
analysis of 32Dcl3 cells overexpressing B-myb following
incubation in G-CSF. 32D cells overexpressing B-myb
(B-myb) were compared with mock-transfected cells (Neo) for
their responses to the addition of G-CSF. Aliquots of cells cultured in
the absence of Zn2+ for 0, 4, and 7 days in the presence of
G-CSF were analyzed by May-Grunwald-Giemsa staining as described in
Materials and Methods.
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Effect of ectopic overexpression of B-myb and
c-myb on myeloid cell differentiation.
To determine
the effects of ectopic overexpression of B-myb on
G-CSF-induced 32D cell differentiation, we carried out a morphological analysis of these cells cultured in the presence of G-CSF, which is
shown in Fig. 8. As was expected, cells transfected with empty vector
underwent terminal differentiation to granulocytes by day 10 of G-CSF
treatment (Fig. 8A), in the presence or absence of Zn2+.
However, 32Dcl3 cells transfected with the c-myb expression vector were slow to undergo terminal differentiation in the absence of
Zn2+, even though they all differentiated into mature
granulocytes following culturing of cells in the presence of G-CSF for
15 days. On the other hand, in the presence of Zn2+, these
cells failed to undergo terminal granulocytic differentiation and were
blocked in the promyelocytic stage and proliferated indefinitely as
promyelocytes (Fig. 8A). These results confirm earlier observations that ectopic overexpression of c-myb in 32Dcl3 cells results
in their continued proliferation in the presence of G-CSF as
promyelocytes (29, 30). In sharp contrast, 32D cells
overexpressing B-myb showed an accelerated pattern of
differentiation, and within 4 days following the addition of G-CSF,
approximately 50% of the cells were found to have differentiated into
metamyelocytes and mature granulocytes (Fig. 8B and Table 1). By day 7, the entire culture consisted of granulocytes and the onset of apoptotic
death could be seen in cells that had differentiated into granulocytes at an earlier time point. These results suggest that ectopic
overexpression of B-myb results in growth arrest of cells in
the presence of G-CSF and an acceleration of the granulocytic
differentiation program in these cells.
Localization of the B-Myb-specific domain which accelerates myeloid
cell differentiation.
To determine the molecular basis for the
observed differences between the biological activities of
c-myb and B-myb, we examined the effects of
ectopic overexpression of various chimeras that contained portions of
c-myb and B-myb on G-CSF-induced 32D cell differentiation. These chimeras were subcloned into the pMT-neo plasmid
vector and stably transfected into 32Dcl3 cell line as previously
described. As can be seen in Fig. 9A, all
three cell lines transfected with the expression vectors expressed the
transgene, which, in all cases is smaller than the endogenous
c-myb transcript. Since the C-terminal domain of B-Myb was
larger than that of c-Myb, chimeras CCB and CBB expressed transcripts
slightly larger than that of chimera CBC. In Western blot analysis, an
antiserum directed against the N terminus of c-Myb was used. All three
chimeric gene products migrated on SDS-polyacrylamide gels with the
expected mobilities and exhibited immune reactivity to the N-terminal
Myb antibody (Fig. 9B). Again, as was described for wild-type
B-myb, the inducible promoter was leaky. With the exception
of chimera CBC, in which slight induction of B-myb RNA and
protein synthesis was observed in the presence of Zn2+, no
significant difference was seen with the other constructs in the levels
of RNA and protein in the presence and absence of Zn2+.
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FIG. 9.
Establishment of 32Dcl3 cell lines overexpressing
chimeric genes between c-myb and B-myb. Each
chimeric gene was subcloned into pMT-neo and transfected into 32Dcl3
cells. Following G418 selection, the established cell lines were
analyzed for expression of each transgene in the presence (+Zn) or
absence (Zn) of Zn2+. (A) Northern blot analysis of total
RNA extracted from each transfectant was performed with labeled c-DNA
of chimera CBC as a probe. The endogenous c-myb (upper
bands) transcript and transcripts from transfected genes (lower bands)
could be distinguished due to differences in the sizes of the
transcripts. The staining of RNA with ethidium bromide after completion
of transfer to nitrocellulose paper is shown below the Northern blot.
(B) Western blot analysis of cell lysates from control and expression
vector-transfected cells was performed with antiserum raised against
the N terminus of c-Myb. Arrows, each gene product of the expected
size. Chim, chimera.
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The cell lines overexpressing these chimeric genes were then examined
for their responses to the addition of G-CSF. The results
of this
experiment are presented in Fig.
10 and
11 and Table
2.
Upon incubation in a medium containing
G-CSF, cells which overexpress
the chimera CBB and CCB exhibited almost
complete growth arrest,
a phenotype which is very similar to that seen
with the overexpression
of wild-type B-
myb. On the other
hand, cells which overexpress
the chimera CBC displayed a slightly
suppressed growth rate compared
to that of the empty vector-transfected
cells (Fig.
10). As shown
in Fig.
11, morphological analysis of these
cells showed that cells
overexpressing the chimera CBB and CCB
terminally differentiated
between days 4 and 6, while cells expressing
chimera CBC followed
the same differentiation course as the empty
vector-transfected
cells, which terminally differentiated at day 12. These results
are also schematically presented in Fig.
12. Addition of Zn
2+ to
these cell cultures did not make a significant difference
in the
observed differentiation rate. Taken together, these results
demonstrate that chimeras CCB and CBB, but not chimera CBC, mimic
B-Myb
in their biological activities. Since all of the chimeras
that contain
the C-terminal domain of B-Myb induce growth arrest
and accelerate the
terminal differentiation of 32Dcl3 cells, we
conclude that the B-Myb
carboxyl-terminal domain which appears
to function as a positive
regulator of transcription confers a
unique set of properties to the
B-Myb protein, which distinguishes
it from that of c-Myb. In addition,
our results suggest that the
observed B-Myb-specific effects are not
due to differential recognition
of target promoters by the
B-
myb gene, because both chimeras CBB
and CCB are expected
to recognize the same sets of target promoters
as c-Myb since they
contain the DNA-binding domain of c-Myb.
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FIG. 10.
The growth of 32Dcl3 cells overexpressing chimeras
between c-myb and B-myb in the presence of G-CSF.
Each 32Dcl3 cell line overexpressing chimeras CBC, CCB, and CBB and
mock-transfected cells were analyzed for their growth in the presence
of G-CSF as described above, except that the cells were plated at a
density of 2 × 105 per ml of G-CSF-containing
medium.
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FIG. 11.
Morphological analysis of 32Dcl3 cells overexpressing
chimeras between c-myb and B-myb following the
addition of G-CSF. 32D cell lines overexpressing each chimeric gene
were analyzed for morphological changes during G-CSF-induced
differentiation in the absence of Zn2+. On days 0, 4, 6, and 12 (d0, d4, d6, and d12, respectively) of G-CSF treatment, aliquots
of the cells were cytospun and stained with May-Grunwald-Giemsa stain
as described above. (A) Morphology of 32D cells overexpressing chimera
CBC and mock-transfected cells following G-CSF-induced differentiation;
(B) analysis of cells overexpressing chimeras CBB and CCB following
incubation in G-CSF-containing medium.
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FIG. 12.
Schematic representation of differentiation profiles of
32D cells overexpressing c-myb, B-myb, and
B-myb-C-myb chimeras (chim). The percentages of
terminally differentiated cells (metamyelocytes plus granulocytes) were
determined on the seventh day of G-CSF-induced differentiation in the
presence (+Zn) or absence (Zn) of Zn2+.
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DISCUSSION |
The myb gene family consists of three members, named
A-, B-, and c-myb, all of which bind DNA in a
sequence-specific manner and function as regulators of transcription.
While A-myb and c-myb have been described as
potent activators of transcription, there appears to be a controversy
regarding the ability of B-myb to transactivate
transcription and its role in mediating cell proliferation and
differentiation. Thus, some of the earlier reports had provided evidence for transcriptional activation of promoters containing Myb-responsive elements by B-myb (24, 26), while
others showed that B-myb is incapable of transactivating
transcription of promoters containing Myb-binding elements (13,
40). It should be noted that these conflicting results were
obtained with B-myb clones derived from different species,
and their transactivation potentials were often tested in cell lines
derived from exogenous species. In addition, different investigators
used widely different reporter plasmids which could have contributed to
these experimental variations. A recent report provides support to the
argument that the transcriptional transactivating activity of the human
B-myb gene is highly dependent on the cell type used
(36). In addition, most of the studies conducted so far were
limited to transcriptional transactivation assays, since a simple
biological assay was not available for myb genes until
recently.
In this communication, we have examined two aspects of B-myb
function. In the first set of experiments, we have studied the comparative abilities of murine c-myb and B-myb
genes to activate transcription of reporter genes that are driven by
promoters containing Myb-binding sites. To avoid problems associated
with species specific variations that may be associated with these
transcription factors, we used murine c-DNA clones to transactivate
transcription in a mouse cell line. Our results show that both
c-myb and B-myb c-DNA clones exhibit comparable
transactivation potentials with two different sets of reporters. Both
proteins exhibit a modular structure, with an N-terminal DNA-binding
domain, a central transactivation domain, and a C-terminal regulatory
domain. It had earlier been shown that the C-terminal domain of
c-myb acts as a negative regulator of transcriptional
transactivation function, since deletion of this region was found to
considerably enhance this activity. Our results presented here show
that unlike the case with c-Myb, deletion of the C-terminal domain of
B-Myb was found to considerably reduce the ability of this protein to
transactivate transcription of target genes, suggesting that this
domain might act as an enhancer of transactivational function of this
protein.
To further delineate the function of the C-terminal regulatory domain
of B-Myb, we constructed several chimeric molecules in which we
systematically replaced the three functional domains of c-Myb with
those of B-Myb. An analysis of the transactivation potentials of these
chimeric molecules suggests that the C-terminal domain of B-Myb
functions as an enhancer of transactivation and that its deletion
results in a substantial decrease of this activity of B-Myb. The
molecular basis for this difference between c-Myb and B-Myb is at
present unclear. It has been recently shown that c-Myb protein contains
a Ser motif at position 528, which is phosphorylated by p42MAPK,
resulting in an inhibition of the transactivation potential of c-Myb
(3). While the Ser moiety is conserved in B-Myb, the A/EVES
motif (9) adjacent to this Ser is not well conserved in
B-myb, and at present it is unclear that this Ser can be phosphorylated
by MAP kinase. Additional mutagenesis studies with the C-terminal
domain of B-Myb, including creation of c-Myb-B-Myb chimeras in which
small regions of the C-terminal domain are interchanged between the two
molecules, might shed additional light on the mechanisms by which the
carboxyl terminus of B-Myb exerts this enhancer effect.
To test whether ectopic overexpression of B-myb and
c-myb can produce similar phenotypic effects in a biological
assay system, we studied the effect of overexpression of these two
genes in 32Dcl3 cells, which provided us with an unexpected insight
into the function of B-myb. As shown previously, ectopic
overexpression of c-myb in these cells resulted in a block
to G-CSF-induced differentiation, resulting in continued proliferation
of cells in G-CSF. In contrast, when the 32D/B-myb cells
were cultured in a medium containing G-CSF, they underwent growth
arrest and completed the differentiation process in 4 to 6 days, which
otherwise takes 10 to 12 days for normal 32Dcl3 cells. Most strikingly,
unlike c-myb, B-myb appears to be incapable of
inducing a block to G-CSF-induced terminal differentiation of 32Dcl3
cells. In addition, while transgenic expression of c-myb
allowed the cells to proliferate indefinitely in G-CSF, transgenic
expression of B-myb inhibited proliferation of cells in
G-CSF. These results provide strong evidence for the argument that
c-myb and B-myb function very differently in a
biological context.
The mechanisms by which B-myb brings about this biological
effect on 32Dcl3 cells could be due to activation of a new set of
genes, which could be dictated by subtle differences that the two
proteins might exhibit with respect to their target sequence binding
(24). A second mechanism could be due to promoter occupancy by B-myb, which blocks the ability of c-myb to
transactivate transcription of proliferation-associated genes. A third
possibility is that the DNA-binding domains of c-Myb and B-Myb have
similar binding specificities but that the two proteins perform
different biological functions due to the unique role played by the
C-terminal domains, which could mediate the assembly of specific
transcriptional complexes. To discern among these possibilities, we
transfected different B-myb-c-myb chimeras into
32Dcl3 cells and examined the abilities of these chimeras to induce
growth arrest and accelerate terminal differentiation of 32Dcl3 cells.
Our results show that only chimeras that contain the C-terminal domain
of B-Myb are capable of bringing about an effect similar to that seen
with B-myb. Substitution of the DNA-binding domain of B-Myb
with that of c-Myb or substitution of the DNA-binding and
transactivation domains of B-Myb with that of c-Myb seemed to produce
no alteration of this biological phenotype produced by
B-myb. It is interesting to note that chimeras CCB and CBB
exhibited the highest levels of transcriptional transactivation in
transient transfection assays and that both contained the DNA-binding domain of c-Myb. These results strongly suggest that the unique biological effects of B-myb are exclusively dictated by its
C-terminal portion of the molecule and not by its DNA-binding or
transactivation domains.
It is now established that c-Myb and B-Myb function effectively in the
presence of appropriate cooperating factors, which interact with the
two proteins and form an enhancer complex (6, 8, 9, 11, 23).
We propose that the nature of transcription factors that interact with
B-Myb or c-Myb is determined by their C-terminal domains, which dictate
the nature of the enhancer complex formed between c-Myb and B-Myb
proteins and other cooperating factors (Fig. 9). In the absence of any
cooperating factors, it is expected that c-Myb assumes an inactive
state via an intramolecular conformation such as the one suggested
recently (9). However, following posttranslational
modifications, which seem to activate the transactivating potentials of
these proteins (3, 22), c-Myb appears to assume a
conformation that allows its interaction with discrete sets of
transcription factors which specify the nature of target genes that are
transactivated by c-Myb. It is possible that the B-Myb protein is not
so very stringently regulated, since it does not seem to exist in an
inactive state under normal conditions. We propose that the C-terminal
domains of the two proteins play an active role in dictating the nature
of factors that interact with each other. It is likely that some of
these factors might be common to both c-Myb and B-Myb, while others might be unique to the individual Myb proteins. This combination of
interacting factors is likely to dictate the nature of target genes
that are transactivated by individual members of the Myb family of
proteins. It is conceivable that the C-terminal domain of c-Myb allows
the interaction of c-Myb with a defined set of nuclear factors that
activate transcription of a group of target genes that promote
proliferation and block terminal differentiation of myeloid precursor
cells. On the other hand, B-Myb might transactivate transcription of a
different set of genes by virtue of its ability to interact with a
distinctive set of nuclear factors, and this transcription complex
transactivates genes that are associated with terminal differentiation
of myeloid cells. This model predicts that c-myb and
B-myb cannot compensate for the biological function of each
other. It is at present unclear whether the C-terminal domains of B-Myb
and c-Myb regulate the nature of the enhancer complex formed by
participating in protein-protein interactions or solely through steric
effect. Studies aimed at the identification of nuclear factors that
interact with B-Myb and c-Myb and identification of the domains of
c-Myb and B-Myb that participate in these interactions are likely to
shed further insight into the mechanism of action of this gene family.
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ACKNOWLEDGMENT |
This work was supported by a grant from NIH (CA 68239).
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FOOTNOTES |
*
Corresponding author. Phone: (215) 707-4307. Fax: (215)
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Mol Cell Biol, January 1998, p. 499-511, Vol. 18, No. 1
0270-7306/98/$04.00+0
Copyright © 1998, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
