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Molecular and Cellular Biology, May 2000, p. 3417-3424, Vol. 20, No. 10
0270-7306/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
E2F4 and E2F1 Have Similar Proliferative Properties
but Different Apoptotic and Oncogenic Properties In Vivo
Dawei
Wang,
Jamie L.
Russell, and
David G.
Johnson*
Department of Carcinogenesis, Science
Park-Research Division, University of Texas M. D. Anderson
Cancer Center, Smithville, Texas 78957
Received 26 October 1999/Returned for modification 1 December
1999/Accepted 21 February 2000
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ABSTRACT |
Loss of retinoblastoma (Rb) tumor suppressor function, as occurs in
many cancers, leads to uncontrolled proliferation, an increased
propensity to undergo apoptosis, and tumorigenesis. Rb negatively
regulates multiple E2F transcription factors, but the role of the
different E2F family members in manifesting the cellular response to Rb
inactivation is unclear. To study the effect of deregulated E2F4
activity on cell growth control and tumorigenesis, transgenic mouse
lines expressing the E2F4 gene under the control of a keratin 5 (K5)
promoter were developed, and their phenotypes were compared to those of
previously generated K5 E2F1 transgenic mice. In contrast to what has
been observed in vitro, ectopically expressed E2F4 was found to
localize to the nucleus and induce proliferation to an extent similar
to that induced by E2F1 in transgenic tissue. Unlike E2F1, E2F4 does
not induce apoptosis, and this correlates with the differential
abilities of these two E2F species to stimulate
p19ARF expression in vivo. To examine the role
of E2F4 in tumor development, the mouse skin two-stage carcinogenesis
model was utilized. Unlike E2F1 transgenic mice, E2F4 transgenic mice
developed skin tumors with a decreased latency and increased incidence
compared to those characteristics in wild-type controls. These findings
demonstrate that while the effects of E2F1 and E2F4 on cell
proliferation in vivo are similar, their apoptotic and
oncogenic properties are quite different.
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INTRODUCTION |
The E2F family consists of six
distinct genes, E2F1 through E2F6, that encode structurally related
proteins (for a review, see references 6 and
18). The DNA-binding domain located in the amino
terminus represents the area of greatest homology between the six E2F
species (28). Adjacent to the DNA-binding domain of each E2F
is a domain involved in dimerization with the more distantly related
DP1 and DP2 proteins. Each E2F species can heterodimerize with either
DP1 or DP2 to generate a functional E2F factor capable of binding
classical E2F sites (TTTSSSCGC [S is C or G]) with high affinity.
With the exception of E2F6, the carboxy terminus of each E2F protein
contains the defined transcriptional activation domain. Embedded within
the transactivation domain is a region of homology involved in binding
to proteins of the retinoblastoma (Rb) tumor suppressor family (Rb,
p107, and p130). Binding of Rb and related proteins to E2F factors
inhibits their ability to activate transcription and, in some cases,
converts E2F factors from activators to repressors of transcription
(10, 29, 35). E2F6 lacks transcriptional activation and
Rb-binding domains and is believed to function as an inhibitor of
E2F-dependent transcription independently of Rb family proteins
(16, 32).
Several findings suggest that E2F4 may play an important and perhaps
unique role in regulating E2F-dependent transcription and cell growth.
E2F4 is the most abundant E2F species, making up the majority of the
total E2F in most cells (9, 15). Unlike the other E2F genes,
E2F4 is constitutively expressed throughout the cell cycle and is
expressed even in quiescent cells (2, 7). Another difference
between E2F4 and the other E2F proteins is that E2F4 complexes with all
three members of the Rb family in a cell cycle-regulated manner
(9, 15). E2F1, E2F2, and E2F3 associate exclusively with Rb,
while E2F5 associates exclusively with p130. Furthermore, E2F4 appears
to be regulated at the level of subcellular localization and lacks the
nuclear localization signal that is present in E2Fs 1, 2, and 3 (12, 14, 17, 33). E2F4 also lacks the cyclin A-binding
domain found in E2Fs 1, 2, and 3 and so is resistant to negative
regulation by cyclin A-associated kinases (5). Finally, E2F4
contains a unique serine repeat domain not found in the other E2F
family members. Although the function of this serine domain is unknown,
it has been shown to be a target for mutation in replication
error-positive colorectal cancers (8).
A number of studies have also demonstrated that the biological activity
of E2F4 differs from those of the other E2F species. E2F4 is a less
potent activator of transcription than E2F1 but a more potent activator
than E2F5 (13, 22). This difference in transactivation
potential appears to be related to both the relative strengths of the
transcriptional activation domains in these E2F proteins and the
presence of a nuclear localization signal found in E2F1 but not in E2F4
or E2F5. In addition, overexpression of E2F4 activates only a subset of
the target genes that are activated by other E2F family members
(3). Overexpression of E2F4 induces serum-starved rat embryo
fibroblasts to enter S phase but not as efficiently as can E2Fs 1, 2, and 3 (3, 13). E2F5 is unable to induce S phase under these
conditions, consistent with its weaker ability to activate
E2F-dependent transcription. Unlike E2F1, E2F4 does not induce
apoptosis when it is overexpressed in serum-starved rat embryo
cells (3). Adding a nuclear localization signal to E2F4
enhances its ability to induce S phase (17). The ability of
nuclear E2F4 to induce apoptosis has not been examined.
Deregulation of E2F-dependent transcription through impairment of Rb
function occurs in most human cancers. This deregulation can occur
through mutation of the RB1 gene, overexpression of cyclin
D1, or inactivation of the p16INK4a cyclin-dependent kinase
inhibitor (30). The end result of each of these events is
the release of E2F factors from Rb control and the activation of
E2F-dependent transcription. These processes in turn lead to
uncontrolled cell proliferation and an increased propensity to undergo
apoptosis. Since E2Fs 1, 2, 3, and 4 all associate with Rb,
each would be expected to be deregulated in cancer cells that lack
functional Rb. How the different E2F family members contribute to the
loss of cell growth control and tumorigenesis as a result of Rb
inactivation is unclear.
As a model to study the role of E2F in cell growth control and cancer
in vivo, we previously developed transgenic mouse lines in which
expression of the E2F1 gene was targeted to stratified epithelial
tissue by a keratin 5 (K5) promoter (19). Deregulated expression of E2F1 results in hyperplasia, hyperproliferation, and
p53-dependent apoptosis in the epidermis of K5 E2F1 transgenic mice (19, 20). Moreover, K5 E2F1 transgenic mice are
predisposed to developing tumors in several epithelial tissues
expressing the transgene, including the skin and odontogenic epithelium
(21). In addition, the K5 E2F1 transgene can cooperate with
either a v-Ha-ras transgene to induce benign skin papillomas
or p53 deficiency to induce spontaneous skin carcinomas (19,
20). In sharp contrast to these oncogenic effects of E2F1,
overexpression of E2F1 can suppress tumor development under some
experimental conditions. K5 E2F1 transgenic mice were found to be
resistant to tumor development in a two-stage chemical carcinogenesis
model (21). Experiments demonstrate that tumor suppression
by E2F1 occurs at the promotion stage and may involve the induction of
apoptosis. Thus, E2F1 has both oncogenic and tumor-suppressive
properties when it is expressed in a deregulated manner.
In this study, the phenotype of transgenic mice expressing E2F4 under
the control of the same K5 promoter is examined. We find that several
properties ascribed to E2F4 from in vitro studies differ when they are
examined in this in vivo model. We also find that E2F4 and E2F1 are
similar in their abilities to induce proliferation but differ in their
abilities to induce apoptosis. The difference in
apoptosis-promoting activity correlates with differential
abilities to activate the expression of the
p19ARF gene. Finally, E2F4 is found to have an
oncogenic potential different from that of E2F1.
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MATERIALS AND METHODS |
Transgenic mice.
The K5 E2F4 transgene was made by cloning
the full-length human E2F4 cDNA (2) into a plasmid
containing the bovine K5 promoter (26), the rabbit
-globin intron 2, and the simian virus 40 polyadenylation signal
(19). Founder transgenic mice were made by microinjecting
the purified transgene into the pronuclei of zygotes and then by
implanting the zygotes into pseudopregnant female mice. Lines were
established and maintained by backcrossing the founders to the SENCAR
outbreed strain (for the 4.3 line) or the SENCAR inbred strain SSIN
(for the 4.0 line). K5 E2F1 transgenic mice have previously been
described (19) and were in the SSIN background.
Northern and Western blot analyses.
Northern blot analysis
was performed using RNA isolated from primary keratinocytes. The method
for isolating primary keratinocytes from newborn pups has been
described (19). Total RNA was isolated with Tri-reagent
(Molecular Research Center, Inc.) by the manufacturer's protocol. The
full-length human E2F4 cDNA was labeled and used as probe under
high-stringency conditions. Murine cDNA probes were obtained from Tim
Kowalik (p19ARF) and Julie DeLoia (cyclin E).
For E2F4 Western blot analysis, whole-cell protein extract was made
from primary keratinocytes as described previously (19). Antibody specific for E2F4 (C-20; catalog number sc-1082) was purchased
from Santa Cruz Biotechnology, Inc.
Immunohistochemistry.
Frozen tissue sections were fixed in
acetone for 5 min, air dried, and placed in methanol containing 0.3%
H2O2 for 20 min. Tissue sections were then
rinsed with phosphate-buffered saline (PBS) three times for 5 min each
before addition of primary E2F4 antiserum (catalog number sc-866, 1:100
dilution; Santa Cruz Biotechnology, Inc.). Sections were incubated for
30 min, rinsed with PBS, and then incubated with biotinylated
anti-rabbit immunoglobulin G (Vector) for 30 min. Slides were rinsed
with PBS and developed with a streptavidin-horseradish peroxidase
conjugate (Vectastain kit; Vector) and a diaminobenzidine substrate.
Tissue sections were rinsed again with H2O and
counterstained before being mounted.
EMSA.
E2F electrophoretic mobility shift assays (EMSA) used
extract from primary keratinocytes as previously described
(20). A fragment derived from the adenovirus E2 gene
containing two E2F sites was used as a probe. Antisera used in
supershift studies were purchased from Santa Cruz Biotechnology (E2F4,
catalog number sc-1082; p107, catalog number sc-250; p130, catalog
number sc-317) and Oncogene Research Products (Rb, AB-2).
BrdU incorporation and TUNEL assays.
Mice were injected with
bromodeoxyuridine (BrdU), and skin samples were immunostained using
antibody specific for BrdU (Becton Dickinson) as previously described
(19). For determining percent incorporation, interfollicular
basal keratinocytes were examined and the numbers of unstained and
stained cells were determined. Terminal
deoxynucleotidyltransferase-mediated dUTP-biotin nick end labeling
(TUNEL) assays were performed using formalin-fixed, paraffin-embedded skin sections and an ApopTag in situ
apoptosis detection kit (Oncor). TUNEL-positive epidermal
keratinocytes were visualized by peroxidase-diaminobenzidine staining,
and the average number of positive cells per 10 mm of linear skin was determined.
Mouse skin two-stage carcinogenesis assay.
Tumors were
initiated by topical application of 10 nmol of DMBA
(9,10-dimethyl-1,2-benzathracene) in 200 µl of acetone to previously
shaved dorsal skin. Tumors were promoted twice weekly by topical
application of 1.0 µg of
12-O-tetradecanoylphorbol-13-acetate (TPA) in 200 µl of
acetone beginning 2 weeks after initiation. Mice were scored for
papillomas weekly. For short-term TPA treatments, the shaved dorsal
skin of mice was treated with 2.0 µg of TPA twice weekly for 2 weeks.
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RESULTS |
Expression and localization of E2F4 in K5 E2F4 transgenic
mice.
The K5 E2F4 transgene was generated by subcloning the human
E2F4 cDNA into a vector containing the bovine K5 promoter, the rabbit
-globin intron 2, and the simian virus 40 polyadenylation signal
(Fig. 1A). The bovine K5 promoter
fragment has been shown to direct expression to the basal cell layer of
the epidermis, the hair follicles, and other stratified squamous
epithelia in transgenic mice (26). Four founders containing
the K5 E2F4 transgene were originally identified by PCR analysis of
genomic DNA. One of the founders did not pass the transgene, while mice
from another line did not express the transgene in skin keratinocytes.
Transgenic mouse lines that overexpressed E2F4 in the epidermis and in
primary keratinocytes were established from the two remaining
founders. By Northern blot analysis, line 4.0 and line 4.3 expressed the human E2F4 transgene to similar extents in transgenic
keratinocytes (Fig. 1B). Under the high-stringency conditions used for
this Northern blot analysis, endogenous murine E2F4 was not detected. Western blot analysis using antiserum that recognizes both mouse and
human E2F4 confirmed that transgene overexpression resulted in a five-
to sevenfold increase in E2F4 protein levels in each line (Fig. 1C).
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FIG. 1.
Generation of K5 E2F4 transgenic lines. (A) Schematic
representation of the K5 E2F4 transgene. Primary keratinocytes were
isolated and cultured from the epidermis of newborn nontransgenic
(wild-type) and K5 E2F4 transgenic mice (lines 4.0 and 4.3). (B) Total
RNA (20 µg per lane) from primary keratinocytes was subjected to
Northern blot analysis using the human E2F4 cDNA as a probe. (C)
Whole-cell protein lysate (20 µg per lane) from primary-keratinocyte
cultures was subjected to Western blot analysis using polyclonal
antiserum specific for E2F4.
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Overexpression of E2F4 in transgenic tissues could also be detected by
immunohistochemistry. Previous experiments have demonstrated
that E2F4
lacks a nuclear localization signal and that when it
is overexpressed
in immortalized fibroblasts or human cancer cell
lines, it is localized
primarily to the cytoplasm (
12,
14,
17,
33). In contrast to
these findings, immunostaining revealed
that the overexpressed E2F4
protein localized to the nuclei of
transgenic keratinocytes in the
basal cell layer of the epidermis
and in the hair follicles (Fig.
2). Our immunohistochemistry assay
did
not detect endogenous E2F4 in nontransgenic tissues.
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FIG. 2.
Ectopically expressed E2F4 localizes to the nucleus in
transgenic tissue. Tail sections were taken from nontransgenic (A) or
K5 E2F4 line 4.0 (B) mice and immunohistochemically stained with
antiserum specific for E2F4. BL, basal layer; HF, hair follicle. (C)
Higher magnification of K5 E2F4 line 4.0 tissue demonstrating the
nuclear localization of E2F4.
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To examine the resultant change in E2F DNA-binding activity associated
with expression of the E2F4 transgene, whole-cell extract
was prepared
from primary keratinocytes isolated from newborn
transgenic mice.
Extracts from each of the transgenic lines and
from nontransgenic mice
were used in an E2F EMSA. In wild-type
keratinocytes, two prominent E2F
complexes were observed (Fig.
3A). One of
these bands corresponded to a complex containing E2F4,
as was evidenced
by a supershift with E2F4 antiserum. The faster-migrating
complex
likely contained one or more of the other E2F family members
since it
also was specifically competed by excess unlabeled oligonucleotide
containing a wild-type E2F site but not a mutated E2F site. Neither
complex appeared to contain an Rb family member, as was evidenced
by a
lack of supershift with antibody specific for Rb, p107, or
p130 (Fig.
3B). Minor complexes above the two more-prominent complexes
were
supershifted by the p107 and p130 antisera. In keratinocytes
from K5
E2F4 line 4.0 or 4.3, the intensity of the E2F4 DNA-binding
complex was
modestly increased between 1.8- and 1.6-fold as measured
by
densitometry. These findings are consistent with previous findings
from
K5 E2F1 transgenic mice demonstrating that expression of
the E2F1
transgene results in a relatively small increase in E2F
DNA-binding
activity (
20).
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FIG. 3.
E2F DNA-binding activity from K5 E2F4 transgenic
keratinocytes. (A) An E2F EMSA was performed using whole-cell extracts
(10 µg) from primary keratinocytes isolated from nontransgenic (lanes
1 and 2), line 4.0 (lanes 3 and 4), or line 4.3 mice (lanes 5 and 6).
Antiserum specific for E2F4 was added (lanes 2, 4, and 6) to identify
complexes containing E2F4. (B) An E2F EMSA was performed using
whole-cell extract (10 µg) from primary keratinocytes isolated from
line 4.0 mice. Excess double-stranded oligonucleotide (20 ng)
containing either wild-type (wt) E2F sites (lane 1) or mutated (mut)
E2F sites (lane 2) was added to the binding reaction mixtures to
distinguish specific E2F complexes. Antisera specific for E2F4 (lane
3), Rb (lane 4), p107 (lane 5), and p130 (lane 6) were added to
identify proteins in specific complexes.
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Growth-regulatory activities of E2F4 in transgenic epidermis.
To examine the effect of deregulated E2F4 expression on cell growth
control in vivo, skin samples from adult K5 E2F4 transgenic mice were
analyzed. Epidermis from both K5 E2F4 transgenic lines was found to be
hyperplastic (Fig. 4 and
5A). The thickness of the epidermis of
nontransgenic sibling controls averaged 13 µm, while the average
thickness of the epidermis from line 4.0 and 4.3 mice was approximately
30 µm. K5 E2F4 epidermis was more hyperplastic than epidermis from
either K5 E2F1 transgenic mouse line. The proliferation index of
interfollicular basal keratinocytes was determined for transgenic mice
and nontransgenic siblings by measuring BrdU incorporation. Two to
three percent of basal keratinocytes were in S phase in wild-type mice,
while this is increased to 9.0 and 9.4 percent in line 4.0 and 4.3 transgenic mice, respectively (Fig. 5B). These levels of epidermal
hyperproliferation in K5 E2F4 mice were between those found in the two
K5 E2F1 transgenic lines.
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FIG. 4.
Histological appearance of K5 E2F4 transgenic skin.
Photomicrographs of skin samples from a nontransgenic mouse (A) and K5
E2F4 transgenic line 4.0 (B) and line 4.3 (C) mice stained with
hematoxylin and eosin.
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FIG. 5.
Hyperplasia, proliferation, and apoptosis in K5
E2F1 and K5 E2F4 transgenic epidermis. (A) Epidermal thickness was
measured from skin samples taken from nontransgenic (wild-type [wt]),
K5 E2F4 line 4.0 (4.0), K5 E2F4 line 4.3 (4.3), K5 E2F1 line 1.1 (1.1),
and K5 E2F1 line 1.0 (1.0) mice. Samples were taken from five different
mice in each group, and 100 measurements were taken for each sample to
calculate the average thickness. (B) The percentage of interfollicular
basal keratinocytes in S phase was calculated for the same mice as
those used to obtain the results in panel A by measuring BrdU
incorporation. Mice were injected with BrdU 30 min prior to sacrifice,
and antibody specific for BrdU was used to immunostain skin samples.
Five hundred cells were counted per sample, and the average percentages
of positive cells from five mice in each group are presented. (C) The
TUNEL assay was used to examine apoptosis in skin sections from
the same mice. At least 40 measurements were taken from each sample
(five mice per group) to calculate the average number of TUNEL-positive
epidermal cells per 10 mm of linear skin.
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The effect of transgene expression on apoptosis in the
epidermis was also measured by performing the TUNEL assay on skin
sections.
K5 E2F4 transgenic mice were found to have only a slight
increase
in the number of apoptotic cells over background
levels (Fig.
5C). As shown previously (
20), K5 E2F1
transgenic mice had a
three- to fourfold increase in the number of
TUNEL-positive cells
in the epidermis compared to the number for
nontransgenic mice
(Fig.
5C). Thus, the K5 E2F4 transgene induces
proliferation,
but not apoptosis, as efficiently as the K5 E2F1
transgene. The
increased survival of cells in K5 E2F4 epidermis may
explain why
the level of hyperplasia, as measured by epidermal
thickness,
is greater in K5 E2F4 mice than in K5 E2F1
mice.
Expression of p19ARF and cyclin E in K5 E2F1 and K5
E2F4 primary keratinocytes.
It has been suggested that the ability
of E2F1 to induce apoptosis is related to its ability to
transcriptionally activate the p19ARF tumor
suppressor gene (1, 31). The p19ARF protein is
encoded at the INK4a locus in an overlapping, alternative reading frame
from the cyclin-dependent kinase inhibitor p16INK4a
(24). The p19ARF protein activates the p53 tumor
suppressor by inhibiting the activity of mdm2 (23, 34, 37).
The p19ARF gene promoter contains a consensus
E2F DNA-binding site and is transcriptionally activated by
overexpression of E2F1 (1, 3). To determine if differential
regulation of p19ARF contributes to the differential
abilities of E2F1 and E2F4 to induce apoptosis in the skin of
transgenic mice, Northern blot analysis was performed on RNAs isolated
from primary keratinocytes derived from K5 E2F1, K5 E2F4, and
nontransgenic mice. In nontransgenic and K5 E2F4 transgenic
keratinocytes, p19ARF expression was virtually
undetectable (Fig. 6). In contrast, p19ARF expression was significantly induced in
keratinocytes from K5 E2F1 transgenic mice. Expression of another E2F
target, cyclin E, was also found to be upregulated in keratinocytes
from K5 E2F1 transgenic mice but not from K5 E2F4 transgenic mice (Fig.
6). After normalization with 7S RNA expression, the level of cyclin E
expression in K5 E2F1 keratinocytes was found to be twice the level
found in nontransgenic keratinocytes while a slight decrease in cyclin
E expression was observed in K5 E2F4 keratinocytes.
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FIG. 6.
Induction of p19ARF and cyclin E expression
in K5 E2F1 but not K5 E2F4 keratinocytes. Total RNA (20 µg per lane)
was isolated from primary keratinocytes derived from nontransgenic
(wild-type [wt]), K5 E2F4 line 4.0 (4.0), K5 E2F4 line 4.3 (4.3), and
K5 E2F1 line 1.0 (1.0) transgenic mice. Northern blot analysis was
performed on the same filter using probes for murine
p19ARF, cyclin E, and 7S.
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Analysis of E2F4 in multistage carcinogenesis.
Previously we
found that the expression of several E2F family members, including
E2F4, is increased during premalignant progression in the mouse skin
model of multistage carcinogenesis (27). This model has been
extensively used to study the molecular events that occur during the
multistep process of cancer development. In one of the most common
protocols, initiation of carcinogenesis is carried out by a single
application of DMBA, which induces an activating mutation at codon 61 of the c-Ha-ras gene (25). Initiated cells are
expanded during the promotion stage by repetitive treatments with TPA,
which results in the outgrowth of exophytic papillomas. A subset of
these benign papillomas can progress to malignant skin carcinomas.
To examine the role of increased E2F4 activity in tumor development, K5
E2F4 transgenic mice were used in the mouse skin model
of multistage
carcinogenesis. First, K5 E2F4 transgenic mice and
nontransgenic
sibling controls were treated with TPA twice weekly
for 2 weeks to
examine their responses to TPA. K5 E2F4 transgenic
mice responded to
TPA treatment in a manner similar to that of
nontransgenic control mice
(Fig.
7). Compared to results with
acetone vehicle-treated controls, TPA treatment increased epidermal
thickness 1.6-fold in nontransgenic mice and 2.0-fold in K5 E2F4
transgenic mice. TPA treatment induced proliferation in the epidermis
as measured by BrdU incorporation 3.2-fold in nontransgenic mice
and
3.4-fold in K5 E2F4 transgenic mice. The hyperplastic and
hyperproliferative responses to TPA observed in K5 E2F4 transgenic
mice
were similar to what was seen in K5 E2F1 transgenic mice
(
19).
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FIG. 7.
Response of K5 E2F4 transgenic mice to TPA. K5 E2F4 line
4.3 transgenic mice (E2F4.3) and nontransgenic siblings (wild type)
were treated with 2 µg of TPA or acetone vehicle control (ACE) twice
weekly for 2 weeks. Mice were sacrificed 24 h following the last
TPA treatment and 30 min following BrdU injection. (A) The average
percentage of basal keratinocytes in S phase was determined for
anti-BrdU immunostained skin sections from three mice in each group.
(B) The average epidermal thickness was determined from hematoxylin-
and eosin-stained skin sections from three mice in each group.
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K5 E2F4 transgenic mice and nontransgenic siblings were also used in
DMBA-TPA two-stage carcinogenesis experiments. Tumor
development was
initiated in 6- to 8-week-old transgenic and wild-type
sibling mice by
topical application of DMBA. Two weeks following
initiation, tumors
were promoted twice weekly with TPA for a total
of 20 weeks. K5 E2F4
transgenic mice from both lines developed
tumors sooner after the
beginning of promotion and in greater
numbers than did control mice
(Fig.
8A). Both lines of K5 E2F4
transgenic mice had approximately three times as many tumors as
their
nontransgenic control siblings. This is in sharp contrast
to the lack
of tumor development observed in K5 E2F1 transgenic
mice following the
DMBA-TPA two-stage protocol (
21). The size
of each tumor was
measured in nontransgenic and K5 E2F4 transgenic
mice at 18 weeks of
promotion. At this time, tumor size was relatively
stable, with only a
few tumors enlarging or regressing. The average
size of the tumors from
K5 E2F4 transgenic mice was four times
greater than that from
nontransgenic mice (Fig.
8B).
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FIG. 8.
Enhanced tumor development in K5 E2F4 transgenic mice
following two-stage carcinogenesis. (A) Carcinogenesis was initiated in
mice from both K5 E2F4 transgenic lines (E2F4.0+ and E2F4.3+) and
nontransgenic siblings (E2F4.0 and E2F4.3) by topical application
of 10 nmol of DMBA to shaved dorsal skin. Two weeks following
initiation, tumors were promoted by twice weekly applications of TPA (1 µg) to dorsal skin for 20 weeks. The average numbers of palpable
tumors per mouse at each week are presented. The number of mice in each
group was five for line 4.0+, 8 for line 4.0, six for line 4.3+, and
three for line 4.3. (B) The size of each tumor in the study was
calculated at 18 weeks of promotion by multiplying tumor length by
tumor width. The average sizes of tumors from nontransgenic (39 tumors
total), line 4.0 (61 tumors total), and line 4.3 (89 tumors total) mice
are presented.
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DISCUSSION |
To directly examine the effect of E2F4 upregulation on cell growth
control and tumorigenesis, we generated transgenic mouse lines
expressing E2F4 under the control of a K5 promoter. K5 E2F4 transgenic
mice are the first animal model for studying the in vivo properties of
this E2F family member. A caveat of this study is that E2F4 is
overexpressed, and so it may not accurately reflect the normal role of
E2F4. It can be argued, however, that overexpression of E2F4 in some
ways mimics the activation of E2F4 that occurs when Rb function is
lost. Loss of Rb function results in deregulated proliferation,
increased apoptosis, and tumorigenesis. The downstream factors
regulated by Rb that are responsible for this phenotype are not
entirely clear, although E2F family members (E2F1 to -4) may play an
important role. The data presented here suggest that E2F4 contributes
to the hyperproliferative and tumorigenic effects of Rb inactivation
but not to the apoptotic effects.
In transgenic tissue, exogenous E2F4 protein is detected in the
nucleus. This is in contrast to results of previous in vitro studies
that found that overexpressed E2F4 was localized primarily to the
cytoplasm because it lacks a nuclear localization signal (12, 14,
17, 33). In immortalized cultured fibroblasts, the subcellular
localization of endogenous E2F4 is regulated in response to the growth
state of the cell. In quiescence, endogenous E2F4, in association with
Rb family members, is found to be predominately nuclear. When these
cultured cells are cycling, however, the majority of E2F4, both in the
free form and complexed with p107, is in the cytoplasm. In K5 E2F4
transgenic mice, exogenous E2F4 is localized to the nuclei of
keratinocytes in the basal layer of the epidermis and the outer root
sheath of hair follicles despite the fact that the majority of these
cells are cycling (4). In vitro, coexpression of a DP2
splice variant that contains a nuclear localization signal was found to
promote nuclear localization of overexpressed E2F4 through
heterodimerization (12, 14, 33). Coexpression of p107 or
p130 may also promote nuclear localization of E2F4 (12, 14).
According to EMSA and supershift experiments using extract from E2F4
transgenic keratinocytes, the majority of E2F4 DNA-binding activity
does not appear to be in complex with p107 or p130 and is found in
association with DP1, not DP2 (data not shown). Thus, the factor(s)
that promotes E2F4 nuclear localization in K5 E2F4 transgenic tissue is unclear.
Previous in vitro studies also demonstrated that E2F4 is a weaker
inducer of proliferation than E2F1. When transiently overexpressed in
serum-starved rat fibroblast cells, E2F4 either was unable to induce
S-phase entry (13) or was less than half as effective as
E2F1 at inducing S phase (3). In the K5 transgenic mouse model, overexpression of E2F4 induces proliferation, as was indicated by an increase in BrdU-incorporating cells in the basal layer of the
epidermis. The levels of hyperproliferation observed in the epidermis
of both K5 E2F4 transgenic lines are between those found in the
epidermis of the two K5 E2F1 transgenic lines. The increases in E2F
DNA-binding activity as a result of transgene expression are also
similar between K5 E2F4 and K5 E2F1 transgenic mice (20).
This finding suggests that E2F4 is as effective at inducing
proliferation as E2F1 in this model system. The apparent discrepancy
between the in vitro and in vivo data regarding E2F4's ability to
induce proliferation may be related to the difference in the
subcellular localizations of E2F4 in the two systems. When a nuclear
localization signal is fused to E2F4, it can induce S-phase entry as
efficiently as E2F1 in vitro (13). Since E2F4 is
localized to the nuclei of transgenic cells through another mechanism,
it may not need a nuclear localization signal to efficiently induce proliferation.
In contrast to the comparable abilities of E2F4 and E2F1 to induce
proliferation, E2F4 is less efficient than E2F1 at inducing apoptosis when it is overexpressed in the epidermis of
transgenic mice. In vitro studies have also found that E2F4 lacks
E2F1's potent apoptosis-promoting activity (3). The
finding that K5 E2F4 transgenic epidermis has only a minor increase in
TUNEL-positive cells over background levels is consistent with the
gross phenotype of K5 E2F4 transgenic mice. K5 E2F1 transgenic mice
have alopecia due to aberrant, p53-dependent apoptosis in the
hair follicles (20). In contrast, K5 E2F4 transgenic mice
have a normal hair coat. The increased survival of K5 E2F4 transgenic
keratinocytes compared to that of K5 E2F1 transgenic keratinocytes may
explain why the skin of K5 E2F4 mice is more hyperplastic than the skin of K5 E2F1 mice as measured by epidermal thickness.
The abilities of E2F1 and E2F4 to induce apoptosis correlates
with their differential abilities to stimulate expression from the
p19ARF gene. The p19ARF protein
interacts with mdm2 and sequesters it in the nucleolus (34,
37). This prevents the negative feedback of mdm2 on p53 and
results in the accumulation of active p53 in the nucleoplasm. The
p19ARF gene promoter contains a consensus
E2F-binding site (1), but this site appears to respond
specifically to E2F1 and not to E2F4. While
p19ARF expression was significantly induced in
primary keratinocytes from K5 E2F1 transgenic mice,
p19ARF expression was virtually undetectable in
K5 E2F4 and nontransgenic keratinocytes. The same differential
expression patterns for p19ARF were observed
when Northern blot analysis was performed on RNAs isolated directly
from the epidermis of transgenic and nontransgenic mice (data not
shown). The idea that p19ARF induction
participates in E2F1-mediated apoptosis in our transgenic model
is supported by the finding that apoptosis in K5 E2F1 epidermis is largely p53 dependent (20). In a p53 null background,
apoptosis in K5 E2F1 transgenic mice is reduced to near
background levels.
Expression of the cyclin E gene was also found to be upregulated only
in primary keratinocytes from K5 E2F1 transgenic mice and not from K5
E2F4 transgenic mice. This finding is in contrast to a previous report
suggesting that E2F4 could stimulate cyclin E expression to a similar
extent as E2F1 in immortalized rat fibroblast cells infected with
recombinant adenoviruses (3). We have also found that cdk2
gene expression is upregulated only in E2F1 transgenic cells and not in
E2F4 transgenic cells (data not shown). Despite the lack of cyclin E or
cdk2 upregulation, K5 E2F4 transgenic epidermis is as
hyperproliferative as K5 E2F1 transgenic epidermis. At present, it is
unclear which E2F target genes, if any, are upregulated by E2F4 to
mediate hyperproliferation in K5 E2F4 transgenic mice.
E2F1 and E2F4 have both been shown to behave as oncogenes in cell
culture-based transformation assays (2, 7, 11, 36). However,
a direct comparison between the oncogenic capacities of E2F1 and E2F4
has not been performed. In the K5 transgenic model, E2F4 does not
appear to be as oncogenic as E2F1. We have yet to observe spontaneous
tumors in K5 E2F4 transgenic mice. The K5 E2F4 transgene also does not
appear to cooperate with p53 deficiency to induce skin carcinomas, as
does the K5 E2F1 transgene (D. Wang and D. G. Johnson, unpublished
data). An oncogenic activity for E2F4 can be revealed when K5 E2F4
mice are used in the two-stage mouse skin carcinogenesis model. K5 E2F4
transgenic mice develop tumors sooner and in greater numbers following
DMBA-TPA treatment than nontransgenic mice. Tumors from K5 E2F4
mice are also larger than those from nontransgenic mice.
These results are in sharp contrast to the resistance to
two-stage carcinogenesis observed for K5 E2F1 transgenic mice
(21). This difference in responses to chemical
carcinogenesis may be related to the differential abilities of E2F1 and
E2F4 to stimulate genes such as p19ARF and
induce apoptosis. These findings demonstrate that E2F4 has an
oncogenic activity but suggest that it, unlike E2F1, lacks a
tumor-suppressive activity.
| |
ACKNOWLEDGMENTS |
We are very grateful to Claudio Conti, Robin Schneider-Broussard,
and Aijin Wang for advice and assistance during this work. We thank
Shawnda Sanders and Michelle Gardiner for preparation of the
manuscript, Dale Weiss and coworkers for animal care, Judy Ing and
Chris Yone for artwork, and Jennifer Smith and Jennifer Philhower for
expert technical assistance.
This work was supported by grants from the National Institutes of
Health (GM56144 to D.G.J., CA 79648 to D.G.J., NIEHS Center grant
ES007784, and CA16672).
| |
FOOTNOTES |
*
Corresponding author. Mailing address: U.T.
M. D. Anderson Cancer Center, Department of Carcinogenesis,
Science Park Research Division, P.O. Box 389, Smithville, TX 78957. Phone: (512) 237-9511. Fax: (512) 237-9566. E-mail:
djohnson{at}sprd1.mdacc.tmc.edu.
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Molecular and Cellular Biology, May 2000, p. 3417-3424, Vol. 20, No. 10
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Abstract
Introduction
