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Previous Article | Next Article 
Journal of Virology, March 2001, p. 2174-2184, Vol. 75, No. 5
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.5.2174-2184.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Type B Leukemogenic Virus Has a T-Cell-Specific
Enhancer That Binds AML-1
Jennifer A.
Mertz,1
Farah
Mustafa,1
Shari
Meyers,2 and
Jaquelin
P.
Dudley1,*
Section of Molecular Genetics and
Microbiology and Institute for Cellular and Molecular Biology, The
University of Texas at Austin, Austin, Texas
78712,1 and Department of Biochemistry
and Molecular Biology, Feist-Weiller Cancer Center, Louisiana State
University Medical Center, Shreveport, Louisiana
711302
Received 10 October 2000/Accepted 6 December 2000
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ABSTRACT |
Type B leukemogenic virus (TBLV) induces rapidly appearing T-cell
tumors in mice. TBLV is highly related to mouse mammary tumor virus
(MMTV) except that TBLV long terminal repeats (LTRs) have a deletion of
negative regulatory elements and a triplication of sequences flanking
the deletion. To determine if the LTR triplication represents a viral
enhancer element, we inserted the triplication upstream and downstream
in either orientation relative to the thymidine kinase promoter linked
to the luciferase gene. These experiments showed that upregulation of
reporter gene activity by the TBLV triplication was relatively
orientation independent, consistent with the activity of eukaryotic
enhancer elements. TBLV enhancer activity was observed in T-cell lines
but not in fibroblasts, B cells, or mammary cells, suggesting that
enhancer function is cell type dependent. To analyze the transcription factor binding sites that are important for TBLV enhancer function, we
prepared substitution mutations in a reconstituted C3H MMTV LTR that
recapitulates the deletion observed in the TBLV LTR. Transient
transfections showed that a single mutation (556M) decreased TBLV
enhancer activity at least 20-fold in two different T-cell lines. This
mutation greatly diminished AML-1 (recently renamed RUNX1) binding in
gel shift assays with a mutant oligonucleotide, whereas AML-1 binding
to a wild-type TBLV oligomer was specific, as judged by competition and
supershift experiments. The 556 mutation also reduced TBLV enhancer
binding of two other protein complexes, called NF-A and NF-B, that did
not appear to be related to c-Myb or Ets. AML-1
overexpression in a mammary cell line enhanced expression from the TBLV
LTR approximately 30-fold. These data suggest that binding of AML-1 to
the TBLV enhancer, likely in combination with other factors, is
necessary for optimal enhancer function.
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INTRODUCTION |
Mouse mammary tumor virus (MMTV)
causes mammary carcinomas and, at lower frequency, T-cell lymphomas in
mice (2, 18, 46). At least one strain of MMTV, type B
leukemogenic virus (TBLV), causes exclusively T-cell tumors with a
short latency (2 to 3 months) (14). TBLV is virtually
identical to MMTV strains that cause mammary tumors, except in the
region of the long terminal repeats (LTRs) (4). The TBLV
LTRs have a 443-bp deletion that is accompanied by triplication of the
62-bp sequences flanking the deletion (4). We and others
have shown that this deletion eliminates several negative regulatory
elements (NREs) that bind the homeoproteins, special AT-rich binding
protein 1 (SATB1) and CCAAT displacement protein, and suppress MMTV
expression in lymphoid cells (9, 24, 35). Mutation of the
promoter-proximal SATB1 binding site in the MMTV LTR elevates
expression in lymphoid tissues of transgenic mice (35).
Acquired MMTV proviruses in T-cell lymphomas invariably delete this
SATB1 binding site in the LTR (4, 24, 32, 35, 45), leading
to elevated transcription of the viral genome and integration near
proto-oncogenes, e.g., c-myc (55). Moreover,
Yanagawa et al. showed that substitution of the LTRs of a mammotropic
MMTV provirus with truncated LTRs lacking the NREs resulted in a
provirus that caused exclusively T-cell tumors (66). These
results indicated that loss of the NREs is critical for MMTV-induced
T-cell lymphomas.
Multimerization of sequences flanking the NRE deletion also is common
in MMTV strains that cause T-cell tumors (4, 32, 45).
Paquette et al. have shown that the TBLV LTR (containing both an NRE
deletion and a triplication) was sufficient to direct c-myc
or CD4 expression primarily to the thymic tissues of transgenic mice;
the TBLV LTR-c-myc transgenic mice developed exclusively CD4+ CD8+ T-cell tumors (54),
whereas TBLV induces both CD4+ CD8+ and
CD4
CD8 lymphomas in mice (42,
48). Multimers of LTR elements have been proposed to function as
T-cell-specific enhancers based on transfection experiments in cell
culture (61, 67). In support of this hypothesis, results
from Yanagawa et al. indicated that multimerized regions flanking the
NRE deletion accelerated lymphomagenesis compared to MMTV strains that
had simple LTR deletions (66). Analysis of other
leukemogenic murine retroviruses also reveals the presence of repeated
regions within the LTRs that are important for viral disease
specificity (10, 15, 25, 33, 56). For example, replacement
of the enhancer repeats in the LTRs of a thymotropic Moloney murine
leukemia virus (MuLV) with the enhancer of an erythroleukemia-inducing
MuLV is sufficient to switch viral disease specificity (11, 20,
26). Mutagenesis experiments have shown that several
transcription factor binding sites within the MuLV enhancers are
crucial for the ability of these viruses to induce T-cell lymphomas,
including those for AML-1 (47) (also known as RUNX1
[36, 38], polyomavirus enhancer binding protein 2 [1], SL3 enhancer factor 1 [62], and core
binding factor [39, 60]), c-Myb (51), and
Ets-1 (34, 37, 51, 69).
To determine the role of the TBLV LTR in viral transcriptional
specificity in T cells, we inserted the TBLV LTR enhancer region upstream of the C3H MMTV promoter in a luciferase reporter vector. The
repeated region elevated MMTV promoter activity at least 100-fold in
transient transfection assays of T-cell lines. The increased activity
was detectable when the repeats were upstream or downstream of a herpes
simplex virus (HSV) thymidine kinase (TK) promoter in either
orientation, typical of eukaryotic enhancer elements, yet the enhancer
activity appeared to be cell type specific. Mutagenesis experiments
indicated that a region spanning the +556 site in the TBLV LTR was
crucial for enhancer activity in T cells. Gel shift experiments
indicated that the transcription factor AML-1, and two unknown
complexes, bound to this critical region. AML-1 overexpression elevated
TBLV LTR reporter gene expression approximately 30-fold in non-T cells.
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MATERIALS AND METHODS |
Construction of plasmids.
Plasmid pC3H-LUC previously
described as pLC-LUC (9), has been modified by the
destruction of the SstI site in the polylinker; this
construct contains the MMTV C3H LTR upstream of the firefly luciferase
gene. Plasmid pTBLV-LUC was engineered by replacement of the ~760-bp
ClaI-to-SstI fragment of the C3H MMTV LTR in
pC3H-LUC with the ~440-bp ClaI-to-SstI fragment
of the TBLV LTR; this region of the TBLV LTR includes the triplicated
enhancer sequence as well as the 443-bp deletion of the NREs
(4) (Fig. 1). The pC3H
NRE-LUC vector was created by
digestion of pC3H-LUC with AflII, filling the ends,
digestion with StuI, and religation. The vector
pC3H3RNRE-LUC was made by substitution of a ~240-bp
StuI-to-SstI fragment from the TBLV LTR
(generated by PCR using a 5' primer with a Stul site) for
the ~531-bp StuI-to-SstI fragment of the C3H
MMTV LTR. Plasmid pC3H3R-LUC was engineered by insertion of the
StuI-to-SstI fragment of pC3H3RNRE-LUC into
the StuI site of the pC3H-LUC vector.
The pd6 parental vector for substitution mutations was prepared using a
recombinant PCR strategy (23). Using pLC-LUC as a
template, two separate PCRs were performed, one using LTR 329+ (5'
CCG CAT CGA TTT TGT CCT TCA 3') and LTR 523
(5' CGT TTT
AGG CCT TTG AGG TTG AGC GTC TCT TTC T 3') and the
other using LTR 1024+ (5' CCT CAA AGG CCT AAA ACG AGG
ATG TGA GAC AAG T 3') and LTR1068- (5' CTC AGA GCT CAG ATC
AGA ACC TTT GAT 3'). (The added StuI site is shown in
bold.) The products were purified by polyacrylamide gel
electrophoresis, and equimolar amounts of the two PCRs were combined.
Using LTR 329+ and LTR 1068, the final product was amplified,
resulting in the deletion of the LTR sequence from positions 523 to
1024 and the creation of a StuI site. Plasmid pC3H-LUC was
partially digested with ClaI and completely digested with
SstI, and the ClaI-to-SstI fragment
from the C3H LTR was removed by gel purification using Prep-A-Gene matrix (Bio-Rad, Hercules, Calif.). The TBLV PCR product also was
digested with ClaI and SstI and ligated into the
digested vector to generate pd6. This clone was verified by sequencing. The wild-type 62-bp enhancer element was cloned into the vector pGEM-TEasy (Promega, Madison, Wis.), and the resulting plasmid (pGEM-62) was used to generate single copies of the substitution mutants by a modification of the QuikChange site-directed mutagenesis method described by Stratagene (La Jolla, Calif.). Briefly, the plasmid
vector was mixed with complementary primers containing 6- to 8-bp
mutations (including a BglII site) in the enhancer element;
each mutation was flanked by 16 to 22 bp of the pGEM-62 sequence. After
PCR using PfuTurbo (Stratagene), a mutant enhancer plasmid with
staggered nicks was generated and the reaction was digested with
DpnI, thus cleaving the methylated parental wild-type DNA.
The undigested mutant plasmids then were recovered by transformation of
Escherichia coli DH5
and screened for the presence of an
appropriate BglII site. The mutations (shown in Fig. 4A)
were verified by sequencing and then amplified by PCR using primers
that had been treated with T4 polynucleotide kinase. The PCR products
then were concatemerized, and the triplicated product was purified and
cloned into the pd6 vector that had been linearized with
StuI. Clones containing the triplication in the correct
orientation were verified by sequencing.
Plasmid pRL-TK (Promega) contains the HSV TK promoter upstream of the
sea pansy (Renilla reniformis) luciferase gene. After digestion with either BamHI, BglII, or
HindIII to linearize the plasmid, blunt ends were
generated by treatment of the linear vectors with Klenow enzyme (New
England Biolabs, Beverly, Mass.), and 5' phosphates were removed using
calf intestinal phosphatase (Roche Molecular Biochemicals, Mannheim,
Germany). The triplicated enhancer region of the TBLV LTR was amplified
by PCR using a positive-strand primer (5' AAT AGA AAG AGA CTC TCA
ACC TC 3'), a negative-strand primer (5' AAC CAC TTG TCT CAC
ATC CTC G 3'), and pTBLV-LUC as the template. The primers were
treated with T4 polynucleotide kinase prior to ligation with the
vector. Individual clones were verified by sequencing.
Cell culture and preparation of cell extracts for gel shift
assays.
The culture of Jurkat human T cells has been described
elsewhere (35). The RL1 (42), LBB.11
(49), and A20 (29) cell lines were maintained
in RPMI medium (GIBCO BRL, Gaithersburg, Md.) supplemented with 7.5%
fetal bovine serum (FBS); Summit Biotechnology, Fort Collins, Colo.),
gentamicin sulfate (50 µg/ml), streptomycin (50 µg/ml), penicillin
(100 U/ml), and 5 × 105 M 2-mercaptoethanol.
Culture of NMuMG (53) and HC11 (5) mouse
mammary cells has been described elsewhere (70).
Whole-cell extracts were prepared by washing the cells with
Tris-buffered saline (10 mM Tris-HCl [pH 7.4], 150 mM NaCl) prior to
sonication on ice in microextraction buffer (20 mM HEPES [pH 7.4],
450 mM NaCl, 0.2 mM EDTA, 0.5 mM dithiothreitol, 25% glycerol)
supplemented with 1.25 mM phenylmethylsulfonyl fluoride (Sigma, St.
Louis, Mo.) and 0.2 mM pepstatin A (Sigma). After sonication, the
lysates were clarified by centrifugation at 13,000 × g
at 4°C, and protein concentrations were determined as previously
described (70). Alternatively, whole-cell extracts were
prepared by washing cells with Tris-buffered saline prior to disruption
with glass beads (Sigma).
Transfections.
DNA samples for transfection were prepared as
described by Bramblett et al. (9). Jurkat T cells were
transfected using SuperFect transfection reagent (Qiagen, Inc.,
Valencia, Calif.) as specified by the manufacturer. Cells (2.5 × 106) were plated in six-well plates in a volume of 2.5 ml
of complete medium on the day of transfection. In some cases, cells
were cultured in 7.5% charcoal-stripped FBS to remove endogenous
steroid hormones. Samples included 2 µg of pC3H-LUC or one of the
substitution mutants and 0.25 µg of pRL-TK. DNA was mixed with 75 µl of RPMI medium with no additives. Superfect (10 µl) was mixed
with the DNA and incubated for 10 min at room temperature. The solution
then was added dropwise to the cells and mixed thoroughly. XC cells
were passaged to achieve 90% confluence on the following day. The
wild-type or substitution mutant plasmids (5 µg) and pRL-TK (0.5 µg) were transfected using DMRIE-C transfection reagent (GIBCO BRL)
according to instructions from the manufacturer. RL1 cells were
passaged to achieve 80 to 90% confluence on the following day. The
wild-type or mutant plasmids (30 µg) and pRL-TK (5 µg) were
transfected using a BTX (San Diego, Calif.) electroporator at 140 V and
1,900 µF in a 0.2-cm cuvette. Cells were electroporated at a
concentration of 107/200 µl in RPMI medium containing
10% FBS. HC11 cells were passaged to achieve 90% confluence on the
following day. Plasmids containing firefly luciferase (30 µg) and
pRL-TK (2 µg) were transfected using a BTX electroporator at 165 V
and 1,700 µF in a 0.2-cm cuvette. Electroporations were performed at
a concentration of 107 cells/200 µl in RPMI medium
containing 10% FBS. The LBB.11 cells were electroporated by the method
of Knutson and Yee (30). Cells were seeded at 6 × 105 cells/ml the day prior to transfection, and 2 × 107 cells were electroporated with a test plasmid (30 µg)
and a control reporter plasmid (5 µg) in 550 µl of complete medium
in a 1-cm cuvette at 2,000 V and 100 µF (electroporator; University
of Wisconsin Medical Electronics Laboratory). All cells (except for
LBB.11) were incubated for 48 h at 37°C prior to preparation of
extracts for reporter gene assays. LBB.11 cells were harvested at
24 h.
Reporter gene assays.
Assays were performed using the
Dual-Luciferase reporter assay system (Promega) that independently
measures Renilla and firefly luciferase activities. Briefly,
cells were rinsed once with phosphate-buffered saline and subsequently
disrupted using passive lysis buffer (Promega) and two to three
freeze-thaw cycles. The lysates then were clarified by centrifugation
at 13,000 × g for 5 min at 4°C. Luciferase activity was determined according to the manufacturer's instructions using a
Turner TD-20e luminometer (Turner Designs, Inc., Sunnyvale, Calif.)
after assays for protein concentration. Samples were normalized for DNA
uptake using luciferase values obtained from the cotransfected pRL-TK
or firefly luciferase vectors.
EMSAs.
Probes for electrophoretic mobility shift assays
(EMSAs) were prepared by annealing the appropriate oligonucleotides and
end labeling with Sequenase version 2.0 (Amersham Pharmacia Biotech, Piscataway, N. J.) as described previously (35). DNA
binding reactions (10 to 20 µl) were performed on ice in a buffer
containing 20 mM HEPES (pH 7.9), 1 mM MgCl2, 0.1 mM EGTA,
0.4 mM dithiothreitol, 200 mM KCl, 12 µg of salmon sperm DNA/ml, and
4 µg of poly(dl-dC) (Amersham Pharmacia). Reactions were analyzed
using 4% nondenaturing polyacrylamide gels and TBE running buffer
(22.3 mM Tris base, 22.3 mM boric acid, 0.5 mM EDTA) prior to
autoradiography of the dried gel. Supershift experiments were performed
with rabbit antiserum against the AML-1 peptide
Arg-lle-Pro-Val-Asp-Ala-Ser-Thr-Ser-Arg-Arg-Phe-Thr-Pro-Pro-Ser as
described previously (41). To verify the specificity of
supershift experiments, the peptide (4 µg) was preincubated with
antibody before addition to EMSAs.
| |
RESULTS |
Unique cis-acting elements in the TBLV LTR confer
T-cell-specific transcriptional activity.
Previous experiments
using TBLV LTR reporter genes in transgenic mice suggested that TBLV
has a unique transcriptional control region that is preferentially
active in CD4+ CD8+ T cells (54).
Examination of the TBLV LTR sequence shows that there is a deletion of
443 bp of the U3 region and triplication of 62 bp flanking the deletion
relative to the MMTV LTR (Fig. 1)
(4). We have previously reported the presence of several NREs within the MMTV LTR that inhibit transcription in lymphoid tissues
(9, 24). Therefore, the contributions of the NRE and the
triplication to TBLV-mediated transcription were determined. We
compared the transcriptional activity of the wild-type C3H MMTV LTR
with that of an LTR containing an NRE deletion between the
StuI and AflII sites (pC3HNRE-LUC), an LTR
with an insertion of the triplicated region from TBLV into the
StuI site (pC3H3R-LUC), or a C3H LTR containing either a
substitution of the TBLV LTR region between the ClaI and
SstI sites (pTBLV-LUC) or StuI and SstI (pC3H3RNRE-LUC) (Fig.
2A). Transient transfections of these constructs into Jurkat T cells showed that elimination of the NREs
between the C3H MMTV StuI and AflII sites
(pC3HNRE-LUC) elevated reporter gene expression threefold compared
to pC3H-LUC (Fig. 2B). Inclusion of the TBLV triplication in the
NRE-minus LTR (either pTBLV-LUC or pC3H3RNRE-LUC) increased
expression ca. 700- to 800-fold over that observed with pC3H-LUC,
whereas the triplication alone (pC3H3R-LUC) elevated expression
ca. 250-fold above the activity of the C3H MMTV LTR. These assays
revealed that the combined effects of the deletion and triplication
were sufficient to account for the differences in the transcriptional activities of the MMTV and TBLV LTRs in Jurkat cells.
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FIG. 1.
Structures of MMTV and TBLV LTRs. The U5, R, and U3
regions are shown. The start of transcription (+1) occurs at the U3/R
junction. Horizontally striped regions indicate positions of the NREs
in the MMTV LTR; black and diagonally hatched elements within the U3
region indicate sequences flanking the NREs in the MMTV LTR that are
present in three copies in the TBLV LTR. The triplicated element is
shown as the T-cell enhancer in the TBLV LTR.
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FIG. 2.
cis-acting elements in the TBLV LTR lead to
high transcriptional activity in T cells. (A) Reporter gene constructs
used in transient transfection assays. The positions of relevant
restriction enzyme sites within the U3 region that were used for
cloning are shown. The construct pTBLV-LUC was prepared by substituting
the ClaI-to-SstI fragment of TBLV for the
ClaI-to-SstI fragment of pC3H-LUC. The construct
pC3H3RNRE-LUC was made by substitution of a
StuI-to-SstI fragment from the TBLV LTR for the
StuI-to-SstI fragment of pC3H-LUC. (B) Activities
of reporter gene constructs in Jurkat cells. Luciferase (LUC) activity
is given in light units/100 µg of protein normalized for DNA uptake
as measured by cotransfection with the pRL-TK reporter plasmid.
Luciferase activity is reported relative to that of pC3H-LUC, assigned
a value of 1; standard deviations from the means of triplicate assays
are shown. (C) Activities of reporter gene constructs in RL1 cells.
Luciferase activity is reported relative to pC3HNRE-LUC (assigned a
value of 1) since pC3H-LUC was not detected in these assays.
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Transient transfections with MMTV and TBLV LTR constructs also were
performed in RL1 T cells and other cell types. Results for RL1 cells
(CD4+ CD8+) were similar to those for Jurkat
cells except that we could not detect the basal activity of the MMTV
promoter in RL1 cells (probably due to lower transfection efficiencies)
(Fig. 2C). In contrast to results obtained with T-cell lines, there was
little difference in the transcriptional activity of the C3H MMTV LTR relative to the TBLV LTR in HC11 mouse mammary cells, XC rat
fibroblasts, or LBB.11 mouse B cells (Table
1). Together, these experiments showed
that loss of the NREs and acquisition of the triplicated region allowed
higher transcriptional activity of the MMTV LTR in T cells but not
other cell types, including B cells.
Enhancer properties and cell-type specificity of the TBLV
triplication.
Because the TBLV triplication is reminiscent of
other retroviral enhancer regions that have been shown to be important
for viral disease specificity (10, 16, 33, 56), we
amplified the entire triplicated region (three copies of the 62-bp
sequence) using PCR and inserted the triplication in both orientations
at three positions upstream and downstream of the HSV TK promoter in
the pRL-TK reporter gene plasmid (Fig.
3A). The resulting constructs then were
used in transient transfections of Jurkat T cells. Insertions of the
TBLV LTR triplication upstream or downstream showed 9- to 89-fold
elevation of luciferase expression from the TK promoter, and expression
was relatively orientation independent (Fig. 3B). The highest level of
expression was observed when the triplication was downstream of the
reporter gene in the sense orientation. These results were consistent
with the ability of the TBLV LTR triplication to act as a
transcriptional enhancer (7, 31).
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FIG. 3.
Transcriptional enhancement by the TBLV
triplication is relatively independent of distance and orientation from
the HSV TK promoter. (A) Structures of plasmids containing the TBLV
triplication in the pRL-TK vector. The transcriptional orientations of
the Renilla luciferase (R-LUC) and ampicillin resistance
(Ampr) genes are shown by arrows above the plasmid
construct. The TBLV triplication was inserted in three positions within
the TK promoter-luciferase vector at the BglII,
HindIII, and BamHI sites. The forward (F) and
reverse (R) orientations of the triplication inserts are shown by
arrows below the plasmid construct. (B) Transient transfections in
Jurkat human T cells. (C) Transient transfections in RL1 mouse T cells.
(D) Transient transfections in rat XC fibroblasts. Standard deviations
from the means of triplicate assays are shown. Luciferase activity is
reported as described in the legend to Fig. 2 except that values are
relative to that for the pRL-TK plasmid without the TBLV enhancer
(assigned a value of 1). DNA uptake was normalized using pTBLV-LUC.
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To determine if the LTR enhancer activity was cell type dependent, we
used the pRL-TK plasmids containing the TBLV triplication for transient
transfections in a second T-cell line, RL1. Such experiments showed
orientation-independent enhancement of TK promoter activity (Fig. 3C).
We also used the same constructs to perform transient transfection
assays in XC rat fibroblast cells (Fig. 3D). In these experiments, the
TBLV triplication did not enhance transcription from the TK promoter;
instead, the presence of the triplication inhibited (up to fivefold)
transcriptional activity of the promoter. Similar results were obtained
with HC11 mammary cells (data not shown). Together with previous
results, these experiments suggest that the TBLV enhancer is active
only in specific cell types, particularly T cells.
Activity of TBLV enhancer mutations.
To determine the specific
sequences required for T-cell enhancer activity, we prepared a reporter
gene construct that replicated the TBLV LTR changes in the context of
the C3H MMTV LTR. A 62-bp enhancer monomer from the TBLV LTR was
synthesized, triplicated, and inserted into the StuI site of
a C3H MMTV LTR that had been modified by deletion of the 443-bp
sequence that includes the NRE and replacement with a StuI
restriction site (pTBLV-WT-LUC) (Fig.
4A). Transient transfections comparing
the transcriptional activities of pTBLV-WT-LUC and pTBLV-LUC (Fig. 2)
revealed no significant differences (data not shown). Subsequently, 6- to 8-bp substitution mutations containing a BglII site were
introduced across the length of the enhancer monomer, triplicated, and
inserted into the StuI site as indicated for pTBLV-WT-LUC
(Fig. 4A).
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FIG. 4.
Characterization of substitution mutants in the TBLV LTR
enhancer. (A) Diagram of the TBLV LTR and positions of enhancer
substitution mutations. The reporter gene plasmid used as the backbone
for preparation of the substitution mutations (pd6) was prepared as
described in Materials and Methods. After the NREs were removed and
replaced with a StuI site, triplicated regions containing
the wild-type (WT) or mutant (M) sequences were inserted. (B) Reporter
gene activity of mutant enhancers in transient assays in Jurkat or RL1
T cells. Means of triplicate assays with standard deviations are shown.
Luciferase activity was determined as described in the legend to Fig. 2
except that values are relative to that of the pTBLV-WT-LUC vector
(assigned a value of 100).
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Transient transfection experiments were performed in two different
T-cell lines (Jurkat and RL1) to compare the reporter gene activity of
the wild-type construct to that of the mutants. In Jurkat cells, the
540, 564, and 572 mutations affected transcriptional activity less than
twofold, whereas the mutations at positions 548, 578, and 594 suppressed enhancer activity approximately two- to three-fold (Fig.
4B). On the other hand, mutations at positions 556 and 586 affected
reporter gene expression 20-fold or more. Interestingly, results from
the CD4+ Jurkat line were not identical to those from RL1
cells (CD4+ CD8+). In RL1 cells, mutations at
positions 540, 572, and 578 had wild-type activity, the 564, 586, and
594 mutations had less than a 2-fold effect on promoter function, and
mutation at position 548 gave a 10- to 20-fold loss of reporter gene
activity assayed in this cell type (Fig. 4B). Neither the 548 or 556 mutations compromised LTR reporter gene activity in HC11 mammary cells
(data not shown), suggesting that the effect of these mutations is cell type specific. Since the mutation at 556 decreased reporter gene activity at least 20-fold in both CD4+ and CD4+
CD8+ T cells, these results suggested that the 556 mutation
compromised one or more transcription factor binding sites that are
critical for the T-cell enhancer activity of the TBLV LTR.
AML-1 binding to a crucial region of the TBLV enhancer.
To
further characterize the nature of the sequences at position 556, we
used the TRANSFAC software program (64) to identify a
putative AML-1 site spanning this mutation. This LTR sequence closely
matched a consensus AML-1 site (39) as well as a
high-affinity AML-1 site in the MuLV LTR described by Thornell et al.
(63) (Fig. 5A). To determine
if this TBLV region contains an AML-1 binding site, we synthesized a
26-bp oligonucleotide based on the wild-type TBLV LTR (556WT) sequence.
The oligonucleotide was end labeled and used in a gel shift assay with
whole-cell extracts from Jurkat T cells (Fig. 5B, lanes 1 to 6). As a
control, we also used a labeled oligonucleotide containing a known
AML-1 binding site (lanes 7 to 12) (6). Results of this
experiment showed that the TBLV LTR probe bound at least two complexes
with mobilities similar to those obtained with the AML-1 probe (compare
lanes 2 and 8). Only the slower-migrating complex was specific, as
judged by its ability to be competed with homologous oligomer; this
complex contained AML-1 since it was supershifted with antibody
specific for AML-1 (lane 4; supershifted band comigrates with NF-A)
(41). This supershift was abolished by addition to the
reaction of the peptide used to generate the antibody (lane 5). At
least two other complexes that were not observed with the AML-1 probe
(named NF-A and NF-B) also appeared to be specific, as judged by
competition with homologous oligomer (lane 6).
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FIG. 5.
AML-1 binding to the TBLV LTR enhancer region. (A)
Comparison of the AML-1 consensus sequence to that from TBLV, MuLVs,
and the T-cell receptor alpha chain (TCR). The AML-1 high-affinity
site was selected as described previously (63). Sites
shown are as reported by Lewis et al. (34). (B) Supershift
experiments show AML-specific binding to the TBLV enhancer monomer
element. The TBLV enhancer probe (556WT) was used for EMSA with
whole-cell Jurkat extracts in lanes 1 to 6, whereas a known AML-1
binding site probe was used in lanes 7 to 12. Sequences of probes are
shown in Fig. 6A. The NF-A complex (indicated by an arrow) and the
AML-1 supershifted complex (indicated by an asterisk) migrate similarly
on the gel. The AML-1 antibody (Ab) specificity has been demonstrated
(44). Normal rabbit immunoglobulin G (IgG) was used as a
negative control in lanes 3 and 9.
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|
Transient transfection experiments in RL1 T cells showed that two
adjacent mutations starting at positions 548 and 556 resulted in
dramatic reductions in TBLV enhancer activity (Fig. 4B). Comparisons of
the mutations to the consensus sequence indicated that the AML-1
binding site spanned these mutations. However, the effect of the 548 mutation was more dramatic in RL1 cells than in Jurkat T cells. To
determine if the effect of both mutations in T cells was due to a
decrease in AML-1 binding to the TBLV enhancer, we performed gel shift
assays with Jurkat cell extracts to measure competition of various
oligomers for AML-1 binding to the 556WT oligomer from the TBLV
enhancer (Fig. 6A). Oligomers containing a known AML-1 binding site (Fig. 6B, lanes 3 and 4) or the TBLV LTR
oligomers 548WT and 556WT (lanes 5, 6, 9, and 10) competed for AML-1
binding. The 548M oligomer also showed competition, suggesting that
this mutation did not significantly affect AML-1 binding. As expected
from previous results, the AML-1-specific oligonucleotide did not
compete for binding of NF-A and -B (lanes 3 and 4, see arrows). The
NF-A complex was competed with the 548WT and 556WT oligomers but showed
poor competition with the 556M oligomer, whereas the 548M sequence did
not compete for this complex. These results suggested that the NF-A
binding site spans the 548 and 556 mutations. The NF-B complex was
competed with 548WT, 556WT, and 548M sequences, but competition with
the 556M oligomer was minimal (lanes 11 and 12). These assays suggested
that the 556 mutation, but not the 548 mutation, affected binding of
both AML-1 and NF-B binding. Together, these experiments suggest that
there are at least three complexes (NF-A, AML-1, and NF-B) that bind to
the TBLV LTR in close proximity (within 16 bp) to control enhancer activity. None of these complexes was competed by oligonucleotides containing consensus binding sites for Myb, Ets-1, or Ets family members (data not shown).
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FIG. 6.
Cell-type specificity of factor binding to TBLV LTR
probes. (A) Nucleotide sequences of probes and competitors used for gel
shift assays. Dashes indicate sequence identities with the 548WT and
556WT probes; the AML-1 binding site is overlined. (B) Binding
specificity of NF-A, AML-1, and NF-B complexes. The 556WT probe was
labeled and used for EMSA with whole-cell Jurkat extracts in the
presence of 20- to 100-fold molar excesses of the unlabeled competitor
oligonucleotides. The positions of specific complexes are shown with
arrows. Lane 1 had no added cell extract. (C) Cell type specificity of
factor binding to the 556WT probe. Different amounts of
whole-cell extracts from HC11 mammary cells (lanes 2 and 3), Jurkat T
cells (lanes 4 and 5), NMuMG mammary cells (lanes 6 and 7), RL1 T cells
(lanes 8 and 9), and LBB.11 B cells (lanes 10 and 11) were incubated
with the TBLV enhancer probe. Lanes 10 and 11 were derived from a gel
different from that shown for lanes 1 to 9. Lane 1 shows a reaction
with no added cell extract. The positions of NF-A, AML-1, and NF-B
complexes are shown with arrows on the left. Gel shifts using A20
B-cell extract were similar to those shown for LBB.11 (data not shown).
(D) HC11 cells contain a small amount of AML-1. HC11 extract (5 µg)
was incubated with the 556WT probe in the absence of added antibody
(Ab; lane 1) or in the presence of rabbit immunoglobulin G (IgG; lane
2) or antibody specific for AML-1B (lane 3). Note that a complex that
migrates slightly slower than AML-1 (larger amounts are seen in lanes 2 and 3 [asterisk in panel C]) is not AML-1, as judged by its failure
to supershift with specific antisera. The small amount of AML-1 in HC11
cells is more apparent after the supershift.
|
|
The cell-type-specific distribution of these complexes also was
determined using gel shift assays with the 556WT probe. As anticipated
from previously published data (40, 47, 57), AML-1
complexes were abundant as measured using cellular extracts from Jurkat
and RL1 cells (Fig. 6C, lanes 4, 5, 8, and 9). Small amounts of AML-1
also were detectable in mammary cell extracts, but a more abundant
complex migrated slightly slower than those determined to contain AML-1
by supershift experiments (Fig. 6C, lanes 2 and 3) (Fig. 6D). LBB.11
B-cell extracts had no detectable AML-1 activity by gel shift assays or
by Western blotting (data not shown). The NF-B complexes were
particularly abundant in HC11 extracts but were easily detected in
extracts from the NMuMG mouse mammary cell line, the Jurkat and RL1
T-cell lines, and the LBB.11 B-cell line. Complexes of NF-A were
detected using Jurkat and RL1 cell extracts and B-cell extracts but
were undetectable or in low amounts in mammary cell extracts.
Effect of the 586 mutation in Jurkat CD4+ cells.
Transient transfection experiments showed that the 586 mutation
dramatically reduced TBLV enhancer activity in Jurkat but not RL1 cells
(Fig. 4B). Analysis of transcription factor binding sites in this
region revealed the presence of a glucocorticoid receptor (GR) site. To
determine if the 586 mutation eliminated the GR site, we performed
transient transfection assays in XC rat cells in the presence or
absence of dexamethasone (Fig. 7A). As
expected, the wild-type C3H MMTV LTR showed a strong (over 60-fold)
induction in the presence of glucocorticoids, as did the reconstructed
TBLV-WT-LUC plasmid, confirming that the TBLV enhancer has a functional
GR binding site. However, the 586 mutation, but not the 556 mutation,
eliminated the glucocorticoid-induced stimulation of reporter gene
expression.
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FIG. 7.
The GR binding site mutation in the TBLV enhancer
abolishes hormone-dependent transcriptional activation but not T-cell
enhancer activity. (A) Activity of the GR binding site mutant 586M in
transient transfections of XC rat cells. Hormones were added as
indicated 24 h after transfection using the DMRIE-C method as
specified by the manufacturer. After an additional 24 h in the
presence or absence of 106 M dexamethasone, cell extracts
were prepared for reporter gene assays. (B) Activity of the GR binding
site mutant in transient transfection assays of Jurkat T cells grown in
the absence of exogenous steroid hormones. Luciferase (LUC) activity
was determined as described in the legend to Fig. 2 except that values
are relative to that for pC3H-LUC in the absence of dexamethasone
(assigned a value of 1). Means of triplicate assays with standard
deviations are shown.
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|
GR requires the presence of hormone to allow
functional receptor to translocate into the nucleus and allow DNA
binding (27). Jurkat cells appear to have low levels of
functional GR, as measured by low-level enhancement of MMTV LTR
reporter gene expression in the presence of hormones compared to that
without added hormone (data not shown). To determine if the 586 mutation affects TBLV enhancer activity in the absence of steroid
hormones, we used media supplemented with hormone-depleted serum to
perform transient transfection assays in Jurkat cells grown without
exogenous glucocorticoids (Fig. 7B). The TBLV enhancer-containing
plasmid had approximately 500-fold greater expression than the C3H MMTV
LTR, and this activity was greatly diminished by the 556 and 586 mutations. A similar result was obtained when the experiment was
repeated with stripped serum and phenol red-free media (data not
shown). Thus, the absence of glucocorticoid hormones did not affect
TBLV transcriptional activity in Jurkat cells, suggesting that binding
of GR is not critical for enhancer function.
AML-1 overexpression in non-T cells.
Transient
transfection experiments identified a critical region of the TBLV
enhancer for optimal transcriptional activity in both Jurkat and RL1
cells (Fig. 4); this region was shown to bind AML-1, a transcription
factor that also binds the MuLV enhancers (69). Because
the TBLV and MMTV LTRs have equivalent transcription levels in
non-T-cell lines, we tested whether overexpression of the
transcriptionally active splice variant of AML-1
(AML-1B) (43) would enhance reporter gene
activity from the TBLV LTR. Plasmid pTBLV-LUC was transfected into HC11
mammary cells in the presence of increasing amounts of an
AML-1B expression vector (43) (Fig.
8A). Cotransfection with the
AML-1B expression plasmid gave approximately 30-fold
enhancement of reporter gene activity relative to transfections
containing a control plasmid lacking AML-1B. Activity of the
TBLV LTR was dependent on the amount of AML-1B expression
vector; doubling of the AML-1B vector amount resulted in
twice as much reporter gene expression. This effect was specific for
AML-1B since cotransfection of an AML-3
expression construct did not increase transcriptional activity from the
TBLV LTR (data not shown). Overexpression of AML-1B failed
to elevate expression of a TBLV LTR reporter construct that contained
the 556 mutation (Fig. 8B).
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FIG. 8.
Overexpression of AML-1B in transient
transfection assays using HC11 cells. Luciferase (LUC) activity was
determined as described in the legend to Fig. 2 except that values are
relative to that for pTBLV-WT-LUC (A) or pTBLV-556M-LUC (B) without
AML-B cotransfection (assigned a value of 1). Means of
triplicate transfections with standard deviations are shown. The
AML-1B vector contains the transcriptionally active splice
variant of AML-1 with two additional exons, 7B and 8 (43). The amount of AML-1B expression vector
used is indicated. All transfections contained 22.5 µg of total
DNA.
|
|
| |
DISCUSSION |
Identification of a T-cell-specific enhancer in the TBLV LTR.
TBLV causes exclusively T-cell lymphomas in mice (2, 3).
The major differences between TBLV and closely related MMTV strains
that cause mammary carcinomas are a deletion of negative elements
within the LTR and triplication of unique sequences flanking the
deletion (4). In this study, we have shown that the TBLV LTR triplication constitutes a cell-type-specific enhancer element. In
support of this idea, the LTR triplication increased MMTV promoter activity approximately 250-fold in transient reporter gene assays in
Jurkat T cells (Fig. 2B). In addition, the triplication elevated reporter gene expression from the heterologous TK promoter 10- to
140-fold in T cells when inserted upstream or downstream in either
orientation (Fig. 3B and C). Such properties are consistent with the
action of transcriptional enhancer elements (7, 8, 31).
Unlike some enhancers, however, the TBLV triplication enhances expression specifically in T cells (Fig. 2 and 3 and Table 1). Even a
closely related lymphoid lineage, B cells, did not support TBLV
enhancer function. Previous experiments by Paquette et al. (54) that use the TBLV LTR to drive CD4 or
c-myc expression also are consistent with the
T-cell-specific enhancer activity of the TBLV triplication. However,
the latter experiments did not distinguish the transcriptional activity
of the triplication from the effects of NRE deletion.
Recently members of our group reported that TBLV, similar to other
retroviruses that induce leukemias, frequently integrates near the
c-myc oncogene (55). In two of the tumors, the
TBLV provirus inserted downstream up to 3 kb from the c-myc
third exon in the same transcriptional orientation. Both tumors showed
elevated levels of c-myc RNA compared to that obtained from
normal murine thymus or thymomas lacking TBLV integrations. Since there
was no alteration in the size of the c-myc RNA observed in
TBLV-induced tumors, these results favor the idea that the TBLV LTR,
like the MMTV LTR, activates oncogene expression primarily through
enhancer, rather than promoter, insertion (12, 28, 52,
55). Preliminary experiments in which the TBLV LTR has been
inserted upstream or downstream of a c-myc expression vector
confirm that the LTR has enhancer activity in transient transfections
of T cells (D. Broussard et al., unpublished data). Thus, it appears
that TBLV enhancer elements can elevate transcription from MMTV, TK,
and c-myc promoters.
AML-1 binding to a critical region of the TBLV enhancer.
To
determine the sequences necessary for TBLV enhancer function, we
engineered substitution mutations into a single copy of the 62-bp
element that then were triplicated and inserted into a C3H MMTV LTR
lacking the NREs. The activities of these mutant LTRs upstream of a
luciferase reporter gene were measured in transient transfection assays
in two different T-cell lines (Fig. 4B). A single substitution mutant
(556M) showed dramatic loss of enhancer function in both cell lines,
and this mutation overlapped a putative AML-1 binding site
(GTGCGGTTC) (compare to consensus in Fig. 5A). Several
pieces of evidence confirm that AML-1 (recently renamed RUNX1
[36, 38]) binding contributes to TBLV enhancer function. (i) Gel shift experiments showed that AML-1 DNA binding activity was
detectable in whole-cell extracts from Jurkat cells using a wild-type
probe that overlapped the 556 mutation within the TBLV LTR. This
complex had a molecular mass similar to that detected with a known
AML-1 binding site probe. (ii) The DNA binding activity for the TBLV
LTR was confirmed to be AML-1, as judged by supershift experiments with
specific antibody; the supershifted complex was not obtained with
antibody against AML-2 or AML-3 (data not shown). (iii) The AML-1
supershift was greatly reduced by the addition of an excess of the
AML-1 peptide used to produce the antibody. (iv) Overexpression of
AML-1B, but not AML-3 (also known as
Runx2 [17]), in mammary cells was sufficient
to elevate TBLV LTR activity 30-fold compared to cells without
AML-1B overexpression (Fig. 8 and data not shown).
Therefore, enhancer mutations, gel shift experiments, and
overexpression assays indicated that AML-1 DNA binding activity
contributes to the cell-type-specific activity of the TBLV enhancer.
MMTV strains that induce leukemias (other than TBLV) also have been
described (18, 32, 45, 67). Invariably these strains have
an LTR deletion spanning the NREs, and in some cases, the sequences
flanking the deletion are duplicated. The duplication encompasses
sequences in the LTRs of several mammotropic MMTV proviruses (RGTGGT)
that match five of six bases within a consensus AML-1 binding
site (YGYGGT) (4, 32, 45, 67). Lee et al. showed
that the altered LTR from the DBA/2 ML T-cell tumor was more
transcriptionally active in NIH 3T3 cells than mammotropic MMTV LTRs
(32), whereas another altered LTR from the DL-8 tumor showed enhanced activity in mammary cells compared to LTRs derived from
mammotropic MMTVs (67). However, we observed TBLV enhancer activity only in T-cell lines. Similarly, Yanagawa et al.
(67) and Theunissen et al. (61) showed that
altered MMTV enhancer elements from DBA/2 or GR-derived leukemias could
stimulate transcription in T cells above that observed with mammotropic
LTRs. As pointed out by Yanagawa et al. (67), the region
of the LTR containing an AML-1 binding site contributes greatly to
T-cell enhancer function. Thus, AML-1 DNA binding activity may be
important for T-cell-specific enhancer activities of many leukemogenic
MMTV strains.
Mechanism of retroviral enhancers active in T cells.
AML-1
binding activity is crucial for the activity of the MuLV family of
enhancers, including those from the gibbon ape and feline leukemia
viruses (69). Many experiments have shown MuLV LTRs carry
viral determinants of leukemogenicity (10, 15, 25, 33, 56)
in tandem repeats of 50- to 100-bp segments of the U3 region
(21). Exchange of Friend and Moloney MuLV LTR repeat
regions also switched the type of leukemia induced (11, 20,
26). Within the enhancer repeat region of MuLVs that cause T-cell tumors are binding sites for AML-1. Some MuLVs that induce rapidly appearing T-cell leukemias (e.g., SL3-3) have two binding sites
for AML-1 (called cores I and II) in the 72-bp repeat element (68, 69), and therefore four AML-1 binding sites in the
enhancer, whereas other MuLVs, such as Moloney, have a single AML-1
binding site in each repeat element (51). Core I of SL3
appears to have the strongest affinity for binding to AML-1
(68), and mutations within this binding site reduce
leukemogenicity in mice and transcriptional activity in T-cell lines
(34, 37, 68, 69). An MuLV strain (SAA) that has a 1-bp
mutation in core I of each enhancer repeat (TGTGGTCAA) is
weakly leukemogenic compared to SL3-3 (containing TGTGGTTAA),
and most SAA-induced lymphomas had reversions or second-site suppressor mutations within the enhancer (37).
Interestingly, there is a general correlation between increased
affinity of AML-1 for the core I enhancer and both transcriptional
activity in T cells and leukemogenicity. However, this correlation can
be subtle. For example, the AML-1 DNA-binding (Runt) domain has an
apparent Kd of 3.5 × 1011
for core I of the weakly leukemogenic Akv virus and an apparent Kd of 2.4 × 1011 for the
highly leukemogenic SL3-3 core (34). This observation suggests that binding of factors in addition to AML-1 is important for
MuLV leukemogenicity.
A number of other transcription factor complexes have been reported to
bind to the MuLV enhancer repeats, including Ets-1, Myb, GR, NF1, and
basic helix-loop-helix (HLH) proteins (13, 21, 50, 58). In
the Moloney MuLV enhancer, the AML-1 binding site is flanked by Ets-1
binding sites (also called LVb and LVc) (58, 59). Intact
binding sites for both Ets-1 and AML-1 are required for constitutive
activity of the MuLV and T-cell receptor 
-chain enhancers in T-cells
(59). Recent evidence suggests that interactions between
Ets-1 and AML-1 stimulate binding to DNA (65) and that the
interaction counteracts autoinhibitory sequences in both proteins
(19, 22). The Myb-binding site (like core II) is present
only in the SL3 and Gross passage A virus (51). Mutations
of the Myb site in the SL3-3 LTR had greater effects on enhancer
activity in T cells than did mutations of the Ets site; however, other
MuLVs (e.g., Moloney) that lack Myb sites also have high
transcriptional activity in T cells (51). Interestingly,
like the MuLV enhancers, we found a consensus GR binding site in the
TBLV 62-bp repeat, and this site could stimulate transcription in XC
fibroblasts in the presence of glucocorticoids (Fig. 7A). Our
experiments also showed that the GR site was most important for
function of the enhancer in Jurkat CD4+ T cells, and not in
CD4+ CD8+ cells, one of the major cell targets
for TBLV-induced leukemias (42, 48). Moreover, experiments
using hormone-stripped serum suggested that the factor in Jurkat cells
that binds to the GR element of the TBLV enhancer is not GR (Fig. 7B)
and may be related to the basic HLH protein SEF2 or ALF1 described for
the MuLV enhancers (51). Nevertheless, these data indicate
that AML-1 binding in conjunction with several other proteins may
provide potent transcriptional enhancement in T cells.
The region spanning the 548 and 556 mutations is crucial for the
function of the TBLV LTR enhancer in T cells. The AML-1 binding site in
the TBLV LTR overlapped with both the 548 and 556 mutations, yet only
the 556 mutation abolished AML-1 binding activity for the viral
enhancer (Fig. 6B). The 556 mutation probably eliminates AML-1 binding
because it alters a G residue that universally appears in PCR-based
selections for the AML-1-binding site (41). Mutation of
the 556 region also affected binding of the NF-A and NF-B complexes to
the TBLV enhancer. Because the failure of both NF-A and NF-B to bind
the TBLV triplication is correlated with diminished enhancer activity
in CD4+ CD8+ T cells, a target for TBLV-induced
disease, our results suggest that these factors may be necessary for
optimal function of the TBLV enhancer. The identities of NF-A and -B
are unclear since a transcription factor consensus site spanning the
LTR sequence affected by 548 and 556 mutations (other than AML-1) was
not detected by our software analysis. In addition, oligonucleotides
with consensus sites for either Myb or Ets family members did not
compete for NF-A, AML-1, or NF-B binding (data not shown), suggesting
that the TBLV enhancer is unique compared to those described for the MuLVs. A sequence (CAGGTG) related to an E-box (CACGTG)
overlaps with the 5' end of the AML-1 binding site in the TBLV
enhancer. Since NF-A binding is affected by the 548 mutation and
appears to be present in T-cell and B-cell lines, but is absent or low in mammary cells, it is possible that NF-A is a lymphoid-specific E-box
binding protein. These experiments are consistent with experiments of
Zaiman et al. (69), suggesting that AML-1 requires
assistance from other transcription factors for MuLV enhancer function.
The role of NF-A, NF-B, or other factors in TBLV transcription will await their identification. However, the evidence that AML-1
overexpression in HC11 causes a 30-fold elevation of transcription from
the TBLV LTR strongly suggests that AML-1 binding contributes to the
activity of the novel TBLV enhancer.
| |
ACKNOWLEDGMENTS |
We thank Susan Ross and members of the Dudley lab for helpful
discussions and comments on the manuscript.
This work was supported by grants R01 CA34780 and P01 CA77760 from the
National Institutes of Health. F.M. is a recipient of an NRSA award
from the National Institutes of Health.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Section of
Molecular Genetics and Microbiology, The University of Texas at Austin, 100 W. 24th St., ESB 226, Austin, TX 78705. Phone: (512) 471-8415. Fax:
(512) 471-7088. E-mail: jdudley{at}uts.cc.utexas.edu.
| |
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Abstract
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