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Previous Article | Next Article 
Journal of Virology, April 2001, p. 3089-3094, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3089-3094.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
"Hit-and-Run" Transformation by
Adenovirus Oncogenes
Michael
Nevels,1,2
Birgitt
Täuber,1
Thilo
Spruss,1
Hans
Wolf,1 and
Thomas
Dobner1,*
Institut für Medizinische Mikrobiologie
und Hygiene, Universität Regensburg, D-93053 Regensburg,
Germany,1 and Department of
Molecular Biology, Princeton University, Princeton, New Jersey
08544-10142
Received 20 September 2000/Accepted 11 January 2001
 |
ABSTRACT |
According to classical concepts of viral oncogenesis, the
persistence of virus-specific oncogenes is required to maintain the
transformed cellular phenotype. In contrast, the "hit-and-run" hypothesis claims that viruses can mediate cellular transformation through an initial "hit," while maintenance of the transformed state is compatible with the loss ("run") of viral molecules. It is
well established that the adenovirus E1A and E1B gene products can
cooperatively transform primary human and rodent cells to a tumorigenic
phenotype and that these cells permanently express the viral oncogenes.
Additionally, recent studies have shown that the adenovirus E4 region
encodes two novel oncoproteins, the products of E4orf6 and E4orf3,
which cooperate with the viral E1A proteins to transform primary rat
cells in an E1B-like fashion. Unexpectedly, however, cells transformed
by E1A and either E4orf6 or E4orf3 fail to express the viral E4 gene
products, and only a subset contain E1A proteins. In fact, the majority
of these cells lack E4- and E1A-specific DNA sequences, indicating that
transformation occurred through a hit-and-run mechanism. We provide
evidence that the unusual transforming activities of the adenoviral
oncoproteins may be due to their mutagenic potential. Our results
strongly support the possibility that even tumors that lack any
detectable virus-specific molecules can be of viral origin, which could
have a significant impact on the use of adenoviral vectors for gene therapy.
| |
INTRODUCTION |
The observation that a number of
viral oncogenes are recurrently expressed in virus-transformed cells
and in the corresponding tumors led to the general view that the
persistence of virus-specific genes is required to maintain the
transformed cellular phenotype (21). In contrast to this
conventional concept of viral oncogenesis, the "hit-and-run"
hypothesis, originally proposed by Skinner (31), claims
that viruses can mediate cellular transformation through an initial
"hit," while maintenance of the transformed state is compatible
with the loss ("run") of viral molecules. The hit-and-run concept
raises the intriguing possibility of an etiological role of viral
agents in tumors that lack any viral genes and proteins.
It is well established that cellular transformation by adenovirus type
5 (Ad5) is initiated through expression of the E1A oncogene, which is
sufficient to immortalize cells, although transformation by E1A alone
is inefficient and often incomplete (reviewed in references
6 and 29). The 19- and 55-kDa proteins
expressed from the E1B transcription unit of Ad5 (E1B-19 kDa and E1B-55 kDa) can individually cooperate with Ad5 E1A proteins to increase transformation efficiency and to convert primary human and rodent cells
to a fully transformed tumorigenic phenotype (6, 29). We
and others have recently shown that two early region 4 (E4) gene
products of Ad5, the E4orf6 (E4-34 kDa) and E4orf3 (E4-11 kDa)
proteins, can also cooperate with E1A and E1A plus E1B to substantially
enhance transformation (16, 18-20). Consistent with the
conventional concept of viral oncogenesis, it has been reported that
cells transformed by E1A and E1B continuously express the whole set of
viral oncoproteins (7, 10, 35). However, evidence from
earlier work suggested that the permanent presence and stable
expression of E1 gene products are not absolutely required to maintain
the transformed phenotypes of some cells, implying that hit-and-run
mechanisms may play a role during adenoviral oncogenesis (12,
24). Moreover, Shenk and coworkers recently demonstrated that
adenovirus E1A proteins can cooperate with the major immediate-early
gene products (IE1 and IE2) of human cytomegalovirus (CMV) to mediate
hit-and-run transformation of primary rat cells (28).
To evaluate the role of classical versus hit-and-run mechanisms in
adenoviral oncogenesis, we compared cells transformed by E1A and E1B or
E1A and E4orf6 or E4orf3 for the retention of virus-specific genes and proteins.
| |
MATERIALS AND METHODS |
Plasmids.
All viral proteins examined in this study were
expressed from their respective complementary DNAs under the control of
the CMV immediate-early promoter. The plasmids
pCMV-E4orf3-neo, pCMV-E4orf6-neo, and pCMV-E1B-55
kDa-neo express the Ad5 E4orf3 (E4-11 kDa), E4orf6 (E4-34
kDa), and E1B-55 kDa proteins and were derived from the pcDNA3 vector
(InVitrogen), which contains a neo gene conferring resistance to G418. The construction of pCMV-E4orf3-neo and
pCMV-E4orf6-neo (formerly designated pCMV-E4orf3 and
pCMV-E4orf6, respectively) has been described previously (20,
25). Plasmid pCMV-E1B-55 kDa-neo was generated by
insertion of the E1B-55 kDa coding sequence into the BamHI
and XbaI sites of pcDNA3. Plasmid pCMV-E1A
expresses Ad5 E1A proteins, lacks a neo gene, and has
been described previously (17).
Transformation assays and cell lines.
Primary cells were
obtained from kidneys of 6- to 7-day-old Sprague-Dawley rats as
previously described (18, 20) and grown in Dulbecco's
modified Eagle's medium (DMEM) supplemented with 10% fetal calf serum
(FCS). For focus assays, subconfluent cells on 90-mm-diameter dishes
were transfected by the calcium-phosphate procedure (11)
with 1.5 µg of pCMV-E1A and 1 µg of empty vector-neo (pcDNA3), pCMV-E1B-55 kDa-neo, pCMV-E4orf6-neo,
or pCMV-E4orf3-neo, as described previously
(18). Total DNA was adjusted to 20 µg with empty vector
and salmon sperm carrier DNA (Boehringer Mannheim). Four weeks
after transfection, plates were stained with crystal violet, and dense
foci of morphologically transformed cells were counted. Alternatively,
individual foci or pools of foci were expanded into permanent cell lines.
Immunoprecipitation and immunoblotting.
For analysis of
protein expression by immunoprecipitation and immunoblotting, cells
were lysed in radioimmunoprecipitation assay (RIPA) buffer (50 mM
Tris-HCl [pH 8.0], 150 mM NaCl, 0.1% sodium dodecyl sulfate, 1%
Nonidet P-40, 0.5% sodium deoxycholate, 1 mM phenylmethylsulfonyl
fluoride, 0.3 µM aprotinin, 1 µM leupeptin, 1 µM pepstatin).
Protein concentrations were normalized with the Bio-Rad protein assay,
and equal amounts of total protein were subjected to
immunoprecipitation and/or immunoblotting exactly as described
previously (20). The following primary antibodies were
used in this study: the mouse monoclonal antibodies M73, 2A6, and RSA3
directed against the Ad5 E1A, E1B-55 kDa, and E4orf6 proteins,
respectively (8, 15, 27); and 6A11, a rat monoclonal antibody recognizing the Ad5 E4orf3 protein (20).
PCR.
Total cellular DNA was isolated by using the DNeasy
tissue kit (Qiagen). PCRs were performed with 500 ng of genomic DNA or 50 ng of plasmid template and specific pairs of primer oligonucleotides with the following sequences:
5'-CCGAAGAAATGGCCGCCAGTCTTTTGGACCAGC-3' (330-E1A-fw)
and 5'-GCGTCTCAGGATAGCAGGCGCCATTTTAGGACGG-3' (331-E1A- rev), 5'-GGAGCGAAGAAACCCATCTGAGCGGGGGGTACC-3' (640- E1B55K-fw) and 5'-GCCAAGCACCCCCGGCCACATATTTATCATGC-3' (641-E1B55K-rev), 5'-CACGGATCCATGACTACGTCCGG-3'
(1-E4orf6-fw) and 5'-CGCGAATTCGTCGACGCGCGAATAAACTGCTGC-3'
(48-E4orf6-rev), and 5'-CGCTGCTTGAGGCTGAAGGTGGAGGGCGC-3'
(363-E4orf3-fw) and
5'-CCAAAAGATTATCCAAAACCTCAAAATGAAG-3' (364-E4orf3-rev).
Tumorigenicity testing.
Cells were harvested with a cell
scraper, washed twice with phosphate-buffered saline (PBS), and
resuspended in serum-free DMEM at a concentration of
107 cells per ml. NMRI
(nu/nu) mice were injected subcutaneously with
106 cells, and tumor growth was recorded during a
6-week period as described previously (19).
Mutagenesis assays.
Mutagenesis assays were performed
essentially as described by Shen et al. (28). Chinese
hamster ovary (CHO)-D422 cells (2) were maintained in
purine-free alpha-MEM medium containing 10% FCS. A total of
105 cells were plated on 90-mm-diameter dishes
and transfected 2 days later by the calcium-phosphate precipitation
technique followed by a 10% glycerol shock (11) with the
indicated plasmids and salmon sperm carrier DNA as described above for
the transformation assays. After transfection, cells were incubated in
nonselective growth medium for 4 days to allow the manifestation of
mutations. After that, 105 cells were plated in
medium containing 10% dialyzed FCS and 10 µM 6-thioguanine to select
for hprt mutants. For each culture, 100 cells were also
plated in nonselective medium to determine the plating efficiency.
Drug-resistant colonies were stained 7 to 8 days thereafter with
crystal violet (1% in 25% methanol), and the mutation frequency was
calculated from the number of resistant colonies compared to the
plating efficiency.
| |
RESULTS |
The majority of cell lines transformed by E1A and E4orf6 or E4orf3
fail to express viral proteins and lack viral DNA sequences.
When we cotransfected primary baby rat kidney (BRK) cells with a
plasmid encoding Ad5 E1B-55 kDa in combination with a neomycin resistance gene (pCMV-E1B-55 kDa-neo) and a plasmid
expressing Ad5 E1A (pCMV-E1A lacking a neo gene), we
consistently observed considerable numbers of G418-resistant,
transformed colonies (Fig. 1 and Table
1). Similar results were obtained
following cotransfections with pCMV-E1A and pCMV-E1B-19
kDa-neo (data not shown), indicating the presence of
the E1B-55 kDa or E1B-19 kDa coding sequences in these cells.
Cotransfections with a plasmid expressing the Ad5 E1A and E1B genes
(pAd5XhoI-C) and constructs encoding Ad5 E4orf6 or E4orf3
plus a neo gene (pCMV-E4orf6-neo or
pCMV-E4orf3-neo) gave rise to large numbers of
G418-resistant colonies that could be readily expanded into permanent
cell lines (ABS cells or ABT cells, respectively). All of these cell
lines expressed substantial levels of the respective E1 and E4 proteins
(18-20) (Fig. 2b and c,
ABS1 and ABT29 cells). In contrast, transfections with combinations of
pCMV-E1A and pCMV-E4orf6-neo or pCMV-E4orf3-neo
in the absence of the E1B gene resulted in the formation of stably
transformed colonies that were never (E4orf6) or very rarely (E4orf3)
resistant to G418 (Fig. 1 and Table 1). These experiments suggest that the E4 oncogenes only regularly persist in transformed cells
coexpressing E1B.
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FIG. 1.
Cells transformed by Ad5 E1A and Ad5
E4orf6-neo or E4orf3-neo are G418
sensitive. Shown are representative plates from transfections of
primary rat cells with empty vector-neo or combinations
of pCMV-E1A with empty vector-neo, pCMV-E1B-55
kDa-neo, pCMV-E4orf6-neo, or
pCMV-E4orf3-neo, which contain transformed colonies
obtained in the absence or presence of the selective drug G418.
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TABLE 1.
G418 resistance of transformed foci derived from
transfections of primary rat cells with different combinations of
Ad5 E1- and E4-expressing plasmids
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FIG. 2.
Absence of E1A and E4 proteins and genes in the majority
of cell lines transformed by E1A plus E4orf6 or E4orf3. (a to c)
Analysis of viral oncogene expression in 10 different AB (a), AS (b),
and AT (c) cell lines by immunoblotting with M73 (E1A) or 2A6 (E1B-55
kDa) antibodies or by combined immunoprecipitation and immunoblotting
with RSA3 (E4orf6) or 6A11 (E4orf3) antibodies. (d to f) PCR screening
for the presence of E1A-, E1B-, E4orf6-, or E4orf3-specific DNA in 10 different AB (d), AS (e), and AT (f) cell lines. IgG, immunoglobulin
G.
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To confirm this idea, we derived a further set of cell lines from foci
transformed by E1A/E1B-55 kDa (AB cells), E1A/E4orf6 (AS cells), and
E1A/E4orf3 (AT cells) and subjected them to immunoblot analyses (Fig.
2a to c). As expected, all of the AB cell lines tested contained high
levels of E1A and E1B-55 kDa proteins, while the previously discussed
ABS and ABT cell lines additionally expressed the E4orf6 or E4orf3
proteins, respectively. In contrast, all AS and AT cell lines failed to
express the corresponding E4 proteins at detectable levels. Curiously,
even E1A expression was undetectable in 6 of 10 AS cell lines and 7 of
10 AT cell lines. To test whether the lack of viral protein expression
was due to the absence of these genes, we screened our transformed cell
lines by PCR for the presence of the respective DNA sequences (Fig. 2d
to f). The results from these analyses show that all AS and AT cell
lines failing to express E1A did indeed not contain the corresponding DNA. Likewise, no E4-specific DNA sequences were amplified from most of
these cells, with the exception of two AS cell lines and one AT cell
line. As a positive control, E1A and E1B sequences were PCR amplified
from all AB, ABS, and ABT cell lines examined. These results clearly
demonstrate that the E1A and E4 genes are only regularly retained and
expressed in transformed cells when E1B is coexpressed. In the absence
of E1B, the E1A and E4orf6 or E4orf3 genes can apparently cooperate to
initiate transformation without subsequently being retained in the
resulting cells.
A subset of hit-and-run-transformed cell lines exhibit
tumorigenicity in nude mice.
To check whether our transformed rat
cell lines exhibit a fully transformed phenotype even in the absence of
viral oncogenes, we subcutaneously injected several AS, AT, and AB cell
lines into athymic mice and monitored them for tumor development. The
results summarized in Table 2 show that
one of six AS cell lines (AS5), two of three AT cell lines (AT1 and
AT3), and one of two AB cell lines (AB3) displayed tumorigenicity.
Since AS5 and AT1 cells do not contain any detectable viral genes or
proteins, we conclude that the persistence of Ad5 oncogenes is not
absolutely required for maintaining the fully transformed cellular
phenotype. Rather, the transient presence of the E1A and E4 genes may
have generated an initial hit, resulting in the oncogenic conversion of
the affected primary cells, which has been followed by the loss
("run") of all viral genes after the transformed phenotype has been
established.
Transient expression of E1A with E4orf6 or E4orf3 increases the
mutation frequency at the hprt locus.
Given the
fact that virtually all DNA tumor viruses including adenoviruses induce
chromosomal damage and other mutations in the host cell genome
(14, 23, 37), we next asked whether the oncogenic hit may
be caused by mutations that accumulate during the transient presence of
the viral E1A and E4 genes. To this end, we performed mutagenesis
assays with the hypoxanthine phosphoribosyltransferase (hprt) locus as an indicator gene to monitor the mutation
frequency. We transiently transfected CHO-D422 cells with different
plasmid combinations and maintained them in medium containing the
selective drug 6-thioguanine. This purine analogue is converted to a
toxic nucleotide through a reaction that requires a functional
hprt-encoded enzyme. Thus, medium that contains
6-thioguanine kills normal cells but does not affect the growth of
mutant cell clones harboring inactivating mutations within the
hprt gene. The results from our mutagenesis assays (Fig.
3) indicate that the transient expression of Ad5 E1A can enhance the mutation frequency within the indicator gene
by less than twofold, while transfection of Ad5 E4orf6 or E4orf3 alone
had no mutagenic effect (data not shown). However, the combination of
E1A with either E4orf6 or E4orf3 resulted in a significant increase in
the number of resistant colonies compared to that with E1A alone,
indicating that both E4 genes can act as comutagens in the presence of
E1A. To check for specificity, we also tested two other Ad5 E4 genes
(coding for E4orf4 and E4orf6/7), which do not induce focus formation
in cooperation with E1A (18; unpublished results), for
mutagenic activities in combination with E1A (Fig. 3). As expected,
neither E4orf4 nor E4orf6/7 had any enhancing effect on the mutation
frequency. Rather, a decrease was observed, which may be related to the
ability of both of these E4 proteins to induce apoptosis (13, 30,
34). Similar results were obtained from cotransfections of E1A
with E1B-55 kDa, which did not further increase the mutation frequency
compared to E1A alone.
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FIG. 3.
Transient coexpression of Ad5 E4orf6 or E4orf3 with Ad5
E1A increases the mutation frequency at the hprt locus.
For mutagenesis assays, 105 CHO-D422 cells were transfected
with either empty vector or plasmids encoding the indicated viral
genes. After 4 days, cells were trypsinized and replated at a density
of 105 cells per plate in selective growth medium
containing 6-thioguanine. Drug-resistant colonies from two of these
plates corresponding to a total of 2 × 105 cells
plated in selective medium were counted 7 to 8 days thereafter, and
numbers were corrected for the plating efficiency. The mean and
standard deviation for at least three independent experiments are
presented. After correction for the plating efficiency, the average
number of 6-thioguanine-resistant colonies was 7 per plate for the
vector control. The same results were obtained in two separate
experiments in which we plated a total of 106 cells (10 plates with 105 cells/plate) in selective growth medium
(data not shown).
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| |
DISCUSSION |
The present study confirms previous observations that the
expression of Ad5 E1A with either Ad5 E4orf6 or Ad5 E4orf3 can initiate the stable transformation of primary rat cells (16, 18,
20). Some of these cells are converted to a fully oncogenic
phenotype, as demonstrated by their ability to form tumors in nude
mice. Curiously, none of the cell lines tested contained the E4
proteins, and many failed to express E1A. Strikingly, the majority of
transformed cell lines lacked any detectable viral DNA sequences. These
observations are not compatible with the conventional concepts of
virus-induced oncogenesis, in which the continuous expression of viral
proteins is required to sustain the transformed phenotype. Rather, they fit the hit-and-run model, which claims that viral molecules are necessary for the initiation but not the maintenance of cellular transformation. The fact that the transient expression of E1A with
E4orf6 or E4orf3 proved to be mutagenic suggests that the viral genes
could mediate hit-and-run transformation by inducing oncogenic
mutations in cellular genes. This idea has been suggested in a recent
study by Shen et al. reporting that cells transformed by combinations
of E1A with the HCMV IE1 and IE2 genes only transiently expressed the
HCMV proteins, but accumulated mutations in the cellular p53 gene
(28).
As yet, we can only speculate on the mechanism by which the viral
oncogenes cause mutations. The mutagenic effects are apparently not
based simply on the presence of viral DNAs, since plasmids containing
complementary DNAs of E4orf3 or E4orf6 in an antisense orientation were
not mutagenic (data not shown). More likely, the accumulation of
genetic alterations requires the transient expression of the viral E1A
and E4 genes. The Ad5 E1A protein has been shown previously to be
involved in the generation of chromosomal aberrations (3).
Interestingly, in these experiments, not only was the E1A-dependent
mutagenic effect already apparent within 11 h after infection, but
a contribution of E4 genes has not been ruled out (3).
Very recently, Ad5 E1A has been associated with a specific human
chromosomal translocation, which fuses the EWS and FLI1 genes to create
a chimeric, oncogenic fusion protein (EWS-FLI1) characteristic of Ewing
sarcomas (26). Moreover, recent work demonstrated that Ad5
E4orf6 and Ad5 E4orf3 are physically associated with the catalytic
subunit of the DNA-dependent protein kinase, thereby inhibiting
double-strand-break repair (1, 22). Besides, both E1A and
E4orf6 can individually compromise the function of the tumor suppressor
protein p53 (4, 32), a critical mediator of genome
integrity, while E1A and E4orf3 associate with PML bodies (5), which have been recently implicated in genomic
stability (36). Together, these E1A- and E4-dependent
activities may lead to the accumulation of chromosomal aberrations and
other mutations. However, continuous mutagenesis may be detrimental to
cells, selecting against the permanent presence of the E1A and E4
genes. Conversely, the E1B proteins may favor retention of the E1A and
E4 genes by virtue of their ability to efficiently interfere with
different apoptosis pathways (reviewed in reference 33).
Alternatively, E1B may actively suppress the mutagenic effects of the
E4 proteins. However, this seems unlikely, since coexpression of E1B-55
kDa with E1A and E4orf6 or E4orf3 in CHO cells did not result in lower mutation frequencies than those of E1A and E4orf6 or E4orf3 alone (data
not shown).
Adenovirus infections have never been convincingly linked to human
oncogenesis, because none of the human neoplasms examined consistently
contained adenoviral DNA (6, 29). Our results support the
intriguing possibility that adenovirus infections may contribute to the
development of some human tumors through a mutagenesis-based
hit-and-run mechanism resulting in tumors that do not carry viral genes
and proteins. If true, it would be extremely difficult, if not
impossible, to implicate this widespread pathogen in human oncogenesis.
Finally, our data may also have direct safety implications for the use
of oncolytic adenovirus vectors currently being tested in clinical
trials for human tumor therapy (9), because they contain
the E1A and E4 genes.
| |
ACKNOWLEDGMENTS |
We thank Christian Endter for plasmid pCMV-E1B-55
kDa-neo, Franz Wiesenmeyer and Oskar Baumann for
excellent technical assistance, Rainer Apfel for preparing the
printouts, and Yuqiao Shen for help with the mutagenesis assays.
This work was supported by grants from the Deutsche
Forschungsgemeinschaft and the Fonds der Chemischen Industrie. M.N.
received an Emmy-Noether fellowship awarded by the Deutsche Forschungsgemeinschaft.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institut
für Medizinische Mikrobiologie und Hygiene, Universität
Regensburg, D-93053 Regensburg, Germany. Phone: 49 941 944 6451. Fax:
49 941 944 6402. E-mail:
thomas.dobner{at}klinik.uni-regensburg.de.
| |
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Journal of Virology, April 2001, p. 3089-3094, Vol. 75, No. 7
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.7.3089-3094.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
