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Journal of Virology, September 2001, p. 8516-8523, Vol. 75, No. 18
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.18.8516-8523.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
Effect of Alpha Interferon on the Hepatitis C
Virus Replicon
Ju-Tao
Guo,1
Vadim V.
Bichko,2 and
Christoph
Seeger1,*
Institute for Cancer Research, Fox Chase
Cancer Center, Philadelphia, Pennsylvania
19111,1 and Anadys Pharmaceuticals, San Diego,
California 921212
Received 13 March 2001/Accepted 12 June 2001
 |
ABSTRACT |
Chronic hepatitis C virus (HCV) infections can be cured only in a
fraction of patients treated with alpha interferon (IFN-
) and
ribavirin combination therapy. The mechanism of the IFN- response
against HCV is not understood, but evidence for a role for viral
nonstructural protein 5A (NS5A) in IFN resistance has been provided. To
elucidate the mechanism by which NS5A and possibly other viral proteins
inhibit the cellular antiviral program, we have constructed a
subgenomic replicon from a known infectious HCV clone and demonstrated
that it has an approximately 1,000-fold-higher transduction efficiency
than previously used subgenomes. We found that IFN- reduced
replication of HCV subgenomic replicons approximately 10-fold. The
estimated half-life of viral RNA in the presence of the cytokine was
about 12 h. HCV replication was sensitive to IFN- independently
of whether the replicon expressed an NS5A protein associated with
sensitivity or resistance to the cytokine. Furthermore, our results
indicated that HCV replicons can persist in Huh7 cells in the presence
of high concentrations of IFN-. Finally, under our conditions,
selection for IFN--resistant variants did not occur.
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INTRODUCTION |
Hepatitis C virus (HCV) causes
persistent infection in approximately 80% of infected adults and
variable and severe liver disease in an estimated 70% of those who
cannot clear the virus (1). HCV is an enveloped,
positive-stranded RNA virus encoding a polyprotein that is
proteolytically processed into 10 polypeptides. Four of them are
enzymes: cysteine and serine proteases, an ATP-dependent helicase, and
an RNA-directed RNA polymerase (17). While these enzymes
are used as potential targets for virus-specific antiviral therapies,
their genes exhibit high variability among the different HCV
genotypes, and, most likely, drug-resistant variants will evolve during
antiviral therapy. Currently available combination therapy with alpha
interferon (IFN-) and ribavirin is effective in less than 50% of
treated patients. Although the mechanism controlling the IFN response
in patients is likely to be complex, there is evidence that
nonstructural (NS) protein 5A (NS5A) evolves to confer resistance
against IFN- during antiviral therapy (5, 6). This
resistance is believed to be a consequence of a specific interaction
between NS5A and protein kinase R (PKR), an important mediator of the
antiviral program induced by IFN-.
Unfortunately, efforts to investigate the molecular mechanisms
responsible for IFN resistance were hampered by the lack of tissue
culture systems permissive for the replication and production of
infectious HCV from available cDNA clones. Recently, Lohmann and
colleagues (13) reported that a subgenomic replicon
containing a neomycin phosphotransferase gene (neoR)
in lieu of the viral structural genes replicated in Huh7 cells (see
Fig. 1A). However, from the low frequency with which Huh7 cells
supported replication, it is possible that the selected isolate is
defective and requires genetic changes for efficient genome synthesis.
This possibility has now been confirmed in this and other reports
demonstrating that a selection for replicons occurs in transfected
cells with mutations at different positions in the NS region (3,
12, 13). Furthermore, investigations about the role of NS5A or
other viral proteins in IFN resistance depend on the possibility of testing HCV isolates obtained from IFN responders as well as from nonresponders.
As shown in this report, we constructed a subgenomic replicon composed
of sequences derived from an infectious HCV clone that exhibits a
transduction efficiency approximately 3 orders of magnitude higher than
those for initially described isolates (14). Furthermore, we investigated the response of HCV replicons to the antiviral program
induced by IFN- in Huh7 cells and asked whether IFN can cure cells
from infection and whether IFN-sensitive variants can be selected in
tissue culture cells. We found that HCV replication is sensitive to
IFN- independently of whether the replicon is derived from a
(putatively) IFN-sensitive or -resistant cDNA clone and observed that
even long-term treatment of cell cultures with the cytokine cannot
clear the virus from the cells and does not seem to yield IFN-resistant variants.
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MATERIALS AND METHODS |
Cell culture.
Huh7 cells were grown in Dulbecco's modified
Eagle's medium (DMEM) (Gibco-BRL) supplemented with 10% fetal bovine
serum, L-glutamine, nonessential amino acids, penicillin,
and streptomycin.
Construction of recombinant plasmids.
HCV genotype 1b
replicon I377/NS3-3' (GenBank accession no.
AJ242652) was assembled and cloned from chemically synthesized DNA
oligomers (3). HCV1bneo was engineered by replacing a
BsrGI-ScaI fragment in
I377/NS3-3' with a
BsrGI-XbaI fragment from plasmid HCV-N
(2). BM4-5 was constructed by replacing an
EcoRI (position 5083)-XhoI (position 5570)
fragment of I377/NS3-3' with the corresponding fragment, which was cloned by reverse transcriptase PCR (RT-PCR) with RNA isolated from cell line FCA4. BMB2-2 and BM22-2 were made by
replacing an SspI (position 4045)-EcoRI (position
5083) fragment in I377/NS3-3' with the
corresponding fragment, which was cloned by RT-PCR with RNA isolated
from cell lines FCC2 and FCA22, respectively. Plasmid 1bneo/delS was
derived from HCV1bneo by deletion of nucleotides 6955 to 6957 (HCV-N;
accession no. AF139594) using oligomer-directed site-specific
mutagenesis. I377/NS3-3'X was constructed by
filling in the XhoI site in
I377/NS3-3' (position 5570) with Klenow DNA
polymerase. The nucleotide sequences of the substituted fragments were
determined with an ABI sequencer.
In vitro transcription and purification of RNA.
Plasmids
were linearized with ScaI (I377/NS3-3'
and its derivatives), XbaI (HCV1bneo), or MluI
(D2Rneo) and transcribed in vitro with the MEGAscript kit (Ambion,
Austin, Tex.) in accordance with the manufacturer's protocol. For a
20-µl reaction mixture, transcription was stopped by the addition of
4 U of DNase I and the mixture was incubated for 45 min at 37°C. RNA
was extracted with 1 ml of TRIzol reagent (Gibco-BRL) and precipitated
with 500 µl of isopropanol. RNA pellets were washed once with 75%
ethanol and dissolved in RNase-free water. To remove the residual
amount of template DNA, RNA preparations were extracted once with acid phenol, precipitated with ethanol, and resuspended in RNase-free water
(9).
RNA transfection.
Subconfluent Huh7 cells were trypsinized
and washed once with complete DMEM and once with serum-free DMEM-F12
medium. Cell pellets were resuspended in serum-free DMEM-F12 medium at
a density of 107 cells/ml. To 200 µl of the
cell suspensions in an electroporation cuvette (0.2-cm gap; BTX, San
Diego, Calif.) 1 to 10 µg of in vitro-transcribed RNA was added. The
cells were immediately electroporated with an ECM 630 apparatus (BTX)
set to 200 V and 1,000 µF. After electroporation the cell suspension
was kept for 5 min at room temperature and then diluted into DMEM
supplemented with 10% fetal bovine serum and nonessential amino acids
and seeded into a 10-cm-diameter petri dish. After 24 h,
G418 was added to obtain a final concentration of 1 mg/ml, and medium
was changed every other day. G418-resistant colonies became visible
after 2 to 3 weeks.
Northern blot hybridization.
Total cellular RNA was
extracted with TRIzol reagent (Gibco-BRL). Five to 10 µg of total RNA
was electrophoresed through a 1.0% agarose gel containing 2.2 M
formaldehyde and transferred to a nylon membrane and immobilized by UV
cross-linking (Stratagene). Hybridization was carried out with
[32P]UTP-labeled in vitro-transcribed RNA in a
solution containing 50% deionized formamide, 5× SSC (750 mM sodium
chloride, 750 mM sodium citrate), Denhardt's solution, 0.02 M
sodium phosphate (pH 6.8), 0.2% sodium dodecyl sulfate (SDS), 100 µg
of sheared denatured salmon sperm DNA/ml, and 100 µg of yeast RNA/ml
for 16 h at 58°C. The membranes were washed once in 2×
SSC-0.1% SDS for 30 min at room temperature and twice in 0.1×
SSC-0.1% SDS for 30 min at 68°C. Membranes were exposed to X-ray
film or to a phosphorimaging screen for quantitative analyses with the
Fuji BAS 1000 system.
RT-PCR and DNA sequencing.
HCV replicons were isolated and
cloned from established cell lines by PCR amplification of three
fragments spanning the entire NS region including sequences from
position 1387 to 7794. DNA synthesis was carried out with SuperScript
II RT provided in a cDNA synthesis kit (Gibco-BRL). The DNA oligomers
used as primers for the RT reactions mapped to positions 3876 to 3857, 5640 to 5618, and 7794 to 7760, respectively. The reaction mixtures
were incubated for 1 h at 45°C. PCR was performed with an
Advantage PCR kit (Clontech, Palo Alto, Calif.). One microliter of the
cDNA reaction mixture was used for PCR with primers spanning positions 1387 to 3876, 3400 to 5610, and 5538 to 7794. The PCR products were
purified by agarose gel electrophoresis and ligated with pGEMT Easy
(Promega, Madison, Wis.). Three to six clones of each fragment were
sequenced with an ABI automatic DNA sequencer, and a consensus sequence
was established with the help of a sequence assembly program (Genetics
Computer Group, Madison, Wis.).
In vitro translation
In vitro translation
reactions were carried out with micrococcal-nuclease-treated rabbit
reticulocyte lysates (Promega) in the presence of
[35S]methionine in accordance with the manufacturer's
protocol. Translation products were electrophoresed through SDS-10%
polyacrylamide gels. The gel was fixed with 30% methanol and
10% glacial acetic acid, treated with NAMP100 Amplify solution
(Amersham), dried, and exposed to X-ray film.
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RESULTS |
Adaptive mutations in cell lines expressing HCV subgenomes.
To
conduct our studies, we used a chemically synthesized replica of the
subgenome, I377/NS3-3', described by Lohmann
et al. (13) (Fig. 1A). This
clone expresses an NS5A protein that is associated with an
IFN--resistant phenotype (3). Electroporation of Huh7
cells in the presence of RNA transcribed from linearized I377/NS3-3' plasmids resulted in the selection of
G418-resistant colonies essentially as reported previously
(13). From four independent experiments we estimated that
approximately 1 to 5 out of 106 cells transfected
with 10 µg of RNA survived the selection process. We expanded 20 clones into cell lines for the analysis of viral RNA. All 20 cell lines
contained subgenomic viral RNA of positive as well as negative polarity
(results not shown). RNA expression levels ranged from approximately
200 to 2,000 copies of plus strand RNA per cell, depending on the cell
line examined (Fig. 1C, lanes 1 to 3). Moreover, we found that the
accumulation of viral RNA was strongly influenced by cell density and,
by inference, by the cell cycle. The levels of viral RNA in
subconfluent cells were approximately 10-fold higher than those in
confluent cells (results not shown).
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FIG. 1.
Replication of subgenomic replicons in Huh7 cells. (A)
Physical map of subgenomic HCV replicons. Top, physical map of HCV with
the processed polypeptides and the flanking untranslated regions.
Black, gray, and white circles, cleavage sites for the host signalase,
the NS2/3 protease, and the NS3 protease on the polyprotein,
respectively. Bottom, structure of subgenomic replicon
I377/NS3-3' as described by Lohmann et al.
(13). Black rectangle, 12 amino acids derived from the HCV
core protein. Restriction site BsrG1, used for the
construction of HCV1bneo, is indicated. (B) Replication of adapted
mutants. Huh7 cells were electroporated with the indicated amounts of
in vitro-transcribed RNA. The mutations present in subgenomic RNAs
BM4-5, BMB22-2, and BMB2-2 are listed in Table 1. G418-resistant
colonies were stained with crystal violet 16 days after
electroporation. (C) Northern blot analysis of total RNA extracted from
cell lines FCA4, FCC2, and FCA22 and from pooled G418-resistant cells
transfected with the indicated RNAs. Total RNA (5 µg) obtained from
each plate was loaded onto an agarose-formaldehyde gel. In
vitro-transcribed subgenomic RNA served as a control (C) for the
hybridization reaction. Genomic HCV RNA (vRNA) was detected with a
riboprobe spanning the neor gene.
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In agreement with previous reports (
3,
12), we identified
consensus mutations in cDNAs obtained from replicons present
in the
four cell lines examined (Table
1). Two
cell lines, FCA22
and FCC2, contained an identical mutation changing
lysine 821
in NS4B to threonine. Line FCA4 contained only one consensus
mutation,
a deletion of serine 1176 in NS5A, and FCA1 contained several
consensus mutations in NS3 as well as in NS5A. To examine whether
the
consensus mutations conferred an adapted phenotype, we constructed
variants BM4-5, BMB22-2, and BMB2-2, carrying the consensus mutations
observed in cell lines FCA4, FCA22, and FCC2, respectively (Table
1).
Transfection of Huh7 cells with these mutants resulted in
the
appearance of many colonies, ranging from approximately 250
(BMB22-2) to 3,500 (BM4-5) colonies per µg of RNA (Fig.
1B, Table
2). This represented an increase of the
transduction efficiency
of 3 to 4 orders of magnitude compared to that
for the parent
I
377/NS3-3' construct (Table
2).
Viral RNA levels in pools of
cells transfected with the adapted mutants
were similar to those
in the parental cell lines, indicating that the
nature of the
mutations could influence the level of viral replication.
Replication of a subgenomic replicon derived from an infectious HCV
clone.
This study and previous ones relied on an HCV clone that
has not yet been tested for infectivity in a chimpanzee. Hence, it is
possible that the low transduction efficiency observed with I377/NS3-3' is due to a defect in the NS
protein-coding region that must be corrected to achieve
efficient RNA replication in Huh7 cells. In addition, it is not known
whether HCV clones encoding NS5A associated with an IFN--sensitive
phenotype can replicate in Huh7 cells. Therefore, we designed two
additional constructs using known infectious HCV clones representing
HCV subtypes 1a and 1b (HCV1a and -1b). In the HCV1a-based replicon,
the 5' and 3' untranslated regions as well as the entire NS
protein-coding region were derived from infectious HCV clone H77
(10). In the HCV1b-based replicon, HCV1bneo, the entire NS
protein-coding region of I377/NS3-3', beginning
at a BsrG1 restriction site located 225 nucleotides
downstream from the 5' end of the NS3 coding sequence, was
replaced with the corresponding region of infectious clone HCV-N (Fig.
1A) (2). Due to the design of the construct, the NS3
protein encoded by HCV1bneo differed from NS3 of HCV-N at two amino
acids (amino acid [aa] 27, Arg in place of Lys; aa 73, Thr in place
of Ala).
While transfection of Huh7 cells with HCV1a-based replicon D2Rneo did
not yield any G418-resistant colonies, transfection
with HCV1bneo
resulted in the selection of approximately 350 colonies
per µg of RNA
(Fig.
2A; Table
2). Hence the
transduction efficiency
observed with HCV1bneo was similar to those of
adapted variants
BMB22-2 and BMB2-2 described above and about 700- to
3,500-fold
higher than that observed with RNA derived from
I
377/NS3-3'. An
analysis of HCV1bneo RNA present
in G418-resistant cells derived
from a pool of an estimated 2,000 colonies revealed about 200
copies of RNA per cell, similar to the
levels observed in pools
from cells transfected with BMB22-2 and BMB2-2
(Fig.
2B). Similar
results were obtained with subgenomic replicon
HCVNneo, where
the entire NS protein-coding region was derived from
HCV-N (results
not shown).
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FIG. 2.
Replication of a subgenomic replicon derived from an
infectious HCV1b clone. (A) Huh7 cells were electroporated with RNA
from HCV1bneo, and colonies were stained 16 days after the
transfection. (B) Northern blot analysis of total RNA isolated from
pooled cells transfected with the indicated RNAs. Genomic HCV RNA
(vRNA) was detected as described for Fig. 1. (C) In vitro translation
of viral RNA transcribed from plasmids I377/NS3-3',
HCV1bneo, HCVNneo, D2Rneo, and D2Ineo (lanes 1 to 5) . Luciferase was translated from pLuc as a positive control (lane 6). The
positions of HCV NS3 and the neomycin phosphotransferase (neo) are
indicated.
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These results showed that a subgenomic replicon based on an infectious
HCV1b clone can efficiently establish stable replicons
in transfected
Huh7 cells. On the other hand the results indicated
that an
HCV1a-derived clone was defective in this system. In an
attempt to
explain this difference between the two subtypes, we
performed in vitro
translation reactions with RNA derived from
I
377/NS3-3', HCV1bneo, HCVNneo, and D2Rneo.
Unexpectedly, we noticed
a significant difference between the
translation efficiencies
of the NS polypeptides of the two subtypes
(Fig.
2C). With the
HCV1b-based constructs, translation levels
of the NS proteins
were similar to those of the neomycin gene, whereas
with D2Rneo
translation of the viral proteins was significantly
reduced. Thus,
our results suggested that sequences in the NS region
may somehow
influence the activity of the encephalomyocarditis virus
(EMCV)
internal ribosome entry site (IRES). In apparent
agreement with
such a possibility, a secondary-structure analysis of
sequences
spanning the IRES sequence and the first 200 nucleotides of
NS3
revealed that the HCV1a clone could potentially form a stem-loop
structure with the EMCV IRES (results not shown). Indeed, substitution
of the first 227 nucleotides of the NS region in D2Rneo with the
corresponding fragment of HCV1b rescued the translation of the
NS
proteins (Fig.
2C, lane 5). However recombinant subgenomic
replicon
D2Ineo did not yield colonies after transfection of Huh7
cells,
suggesting that either some other features of the HCV1a
isolate
interfered with the establishment of stable replicons
or the chimeric
NS3 protein was not supporting replication in
transfected Huh7
cells.
To determine whether adaptive mutations identified with
I
377/NS3-3'-based replicons could increase the
replication levels
of HCV-N-based subgenomes, we introduced the
adaptive mutation
of replicon BM4-5, leading to the deletion of serine
1176 in NS5A,
into HCV1bneo. In vitro-transcribed RNA from the
resulting replicon,
1bneo/delS, was transfected along with RNA from
HCV1bneo, I
377/NS3-3',
and BM4-5 into Huh7 cells.
RNA transcribed from I
377/NS3-3'X,
carrying a
frameshift mutation in the NS5A coding sequence, served
as a negative
control. To determine the effect of the mutation
in 1bneo/delS on viral
replication, we determined the levels of
viral RNA 24, 48, and 72 h after transfection (Fig.
3A). This
transient assay is based on the previously published observation
that
adapted replicons can amplify plus strand RNA more efficiently
after
transfection than the wild type (
3,
11). While the
BM4-5
replicon exhibited only moderately enhanced RNA levels compared
with
the wild-type levels, 1bneo/delS showed a much more dramatic
increase
compared with HCV1bneo (Fig.
3). Hence, these results
indicated that
adaptation of HCV-N-based replicons can occur in
a fashion similar to
that observed with I
377/NS3-3'.
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FIG. 3.
Transient replication of adapted mutants in Huh7 cells.
(A) Viral plus strand RNA (vRNA) present in cells transfected with
I377/NS3-3'X (lanes 1 to 3), I377/NS3-3' (lanes
4 to 6), BM4-5 (lanes 7 to 9), HCV1bneo (lanes 10 to 12), and
1bneo/delS (lanes 13 to 15). RNA was extracted from transfected Huh7
cells 24 (lanes 1, 4, 7, 10, and 13), 48 (lanes 2, 5, 8, 11, and 14),
and 72 h (lanes 3, 6, 9, 12, and 15) after the transfection. rRNA
(28S) served as a control for the amount of RNA loaded per lane. (B)
Levels of plus strand RNA in cells transfected with the indicated
subgenomes 24, 48, and 72 h after the transfection as determined
with a phosphorimager. PSL, arbitrary unit.
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IFN response in Huh7 cells.
A major question in HCV biology is
whether IFN--based antiviral therapy leads to the selection of
IFN--resistant viral mutants. To address this question, we
investigated whether the replication of HCV subgenomes is affected by
IFN-. Initial experiments with cell line FCA1 revealed that IFN-
reduced the levels of HCV RNA in Huh7 cells in a dose-dependent manner
(Fig. 4). Inhibition was observed with
IFN- doses as low as 1 IU/ml, and 10- to 20-fold inhibition was
obtained with 25 IU/ml. Of particular interest was the question of
whether NS5A had any influence on the IFN response, as has been
suggested previously. Because the
I377/NS3-3'-based replicon encodes an NS5A
protein that is expected to confer IFN resistance, in contrast to the
HCV-N-based genomes, we directly compared pools of cells transfected
with each replicon for their sensitivities to the antiviral action of
the cytokine. Our results showed that both replicons responded in an
equal fashion to IFN-, suggesting that under our selected conditions
IFN sensitivity is not influenced by variations in NS5A.
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FIG. 4.
Antiviral activity of IFN-. (A) Viral RNA (vRNA)
levels present in cells treated with 0, 1, 3, 10, 30, and 100 IU of
IFN-/ml (lanes 1 to 6) for 72 h were determined by
Northern blot analysis with a plus strand-specific RNA probe. rRNA (28S
and 18S) served as a control for the amount of RNA loaded per lane.
Examined were cell line FCA1 and G418-resistant pooled cells
transfected with BM4-5 and HCV1bneo, respectively. (B) Signal
intensities were measured with a phosphorimager and blotted as
percentages of the values obtained with untreated cells (A, lane 1).
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Cells supporting HCV replication are thought to harbor plus strand RNA
base paired with minus strand RNA in replication complexes
as well as
excess plus strand RNA derived from the RNA amplification
reaction. To
examine whether IFN-
treatment affected only free
plus strand RNA or
replication complexes or both, we measured
the levels of plus and minus
strand RNA in cells treated with
100 IU of IFN-
/ml. Our results
showed that both RNA strands were
reduced with a half-life of about
12 h (Fig.
5). However, the
decline
of minus strand RNA appeared to be delayed by approximately
12 h,
which could reflect differences in the mechanism of RNA
degradation
between free and complexed RNA.
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FIG. 5.
Time course of the IFN- response. (A) FCA1 cells were
incubated with 100 IU of IFN-/ml (lanes 7 to 11) or without IFN-
(lanes 1 to 6) for 12, 24, 36, 48, and 72 h (lanes 2 to 5 and 7 to
11, respectively). Plus and minus strand RNA was analyzed by Northern
blotting with strand-specific RNA probes. (B and C) Levels of plus and
minus strand RNA as determined with a phosphorimager. PSL, arbitrary
unit; diamonds, IFN--treated cells; squares, untreated cells.
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To examine whether IFN-
treatment permitted the selection of
IFN-resistant mutants, we maintained cell line FCA1 for over
100 days
in the presence of G418 and increasing concentrations
of IFN-
to a
final concentration of 1,000 IU/ml (Fig.
6). Although
we noticed that these
conditions reduced the growth rate of the
cells, we did not observe
massive cell death, which occurs during
the selection of G418-resistant
colonies with subgenomic replicons.
Consistent with this observation,
viral RNA continued to replicate
in IFN-
-treated cultures, albeit at
approximately 10-fold-reduced
levels compared to those for untreated
cells (results not shown).
We examined whether IFN-
-resistant
replicons were present in
the FCA1 cells after treatment with
increasing doses of the cytokine
up to 1,000 IU/ml for 4 months. These
cells were incubated for
6 days without the cytokine followed by an
incubation with 1 to
100 IU of IFN-
/ml for 72 h before viral
RNA levels were determined.
The results showed that IFN-
-treated
cells (FCA1/IFN) increased
their viral RNA levels to 20% of the RNA
level present in the
parental FCA1 cell line when IFN-
was removed
from the culture
medium. Furthermore, the FCA1/IFN cells exhibited a
slightly attenuated
dose-response pattern compared with FCA cells (Fig.
6). Whether
this difference reflects changes in the response of the
cells
to IFN-
or alterations in the virus is not yet known. Based on
the observation that the two cell lines did not differ in terms
of the
maximal reduction of viral replication (100 IU/ml), we
favor the former
over the latter possibility.
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FIG. 6.
Long-term treatment of FCA1 cells with IFN-. (A) FCA1
cells were incubated for the indicated number of days (d) with
increasing doses of IFN- in the presence of G418 (1 mg/ml). The
cells were passaged (p) at a ratio of 1:6 during the incubation with 10 to 30 IU of IFN/ml and at a ratio of 1:10 with 100 and 1,000 IU of
IFN/ml at the indicated (asterisks) time points. (B) Control FCA cells
(FCA1; lanes 1 to 6) and IFN-treated cells (FCA1/IFN; lanes 7 to 12)
were incubated for 6 days without IFN and G418 and then with 0, 1, 3, 10, 30, or 100 IU of IFN-/ml for 72 h (lanes 1 to 6 and 7 to
12, respectively). Viral RNA (vRNA) levels were determined by
Northern blot analysis with a plus strand-specific probe. (C) Levels of
viral RNA determined with a phosphorimager in FCA1 (squares) and
FCA1/IFN (diamonds) cells treated with the indicated amounts of
IFN-. PSL, arbitrary unit.
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DISCUSSION |
In this report we demonstrated that a subgenomic replicon
based on an infectious HCV1b isolate can replicate in tissue culture cells with an approximately 1,000-fold-higher colony formation efficiency than the previously reported
I377/NS3-3' replicon (Table 2) (3,
14). In agreement with others, we found that the I377/NS3-3' replicon undergoes adaptation as a
consequence of replication in Huh7 cells (3, 12).
Moreover, the transfer of adapted mutations can also enhance the RNA
replication of related replicons, as shown with the 1bneo/delS replicon
(Fig. 3). Whether adaptive mutations occur in cells transfected with
wild-type HCV-N-based replicons has not yet been determined. However
the results obtained with 1bneo/delS provide support for this
possibility. It is worthy of note that serine residue 1176, which is
deleted in the products of replicons BM4-5 and 1bneo/delS, maps
to one of three proposed hyperphosphorylation sites in NS5A and
coincides with residues associated with other adaptive mutations
that were described previously (3, 11, 20). Nevertheless,
our observations have opened the possibility of analyzing HCV isolates
from different patient sera for their biological properties in
transfected cells. For example, clones from patients taken before and
after therapy with IFN and ribavirin can now be isolated and tested for
their biological behavior including drug resistance in tissue culture
cells. Although the correlation between the expression of the NS
proteins from subgenomic RNA templates in vitro and viral replication
in cells is incomplete, it could be used as one predictor for the
ability of a particular construct to replicate in Huh7 cells (Fig. 2C). However, our results showed that other unknown conditions have to be
met for the establishment of additional HCV replicons in transfected
tissue culture cells.
Our observation that the highest levels of HCV replication occurred in
growing, subconfluent cells is consistent with a report by Pietschmann
et al. (16) but is in direct contradiction with similar
studies performed previously with hepatitis B virus (HBV) (19a). With HBV the accumulation of viral DNA
occurs primarily in confluent or resting cells, which reflects the
natural situation, where the majority of hepatocytes in the liver are
in G0. Although our observation could reflect a
property specific for subgenomic replicons and not for complete HCV
genomes, it suggests that dividing hepatocytes might produce a higher
level of virus than resting cells in an infected liver.
Furthermore, it predicts that virus production increases as a
consequence of liver disease characterized by the death and
regeneration of hepatocytes. Finally, the observation that
replication appears to be dependent on the cell cycle or cell
density or both points to the presence of host factors that could play
a major role in HCV replication. Evidence for the role of such factors
comes from studies indicating that IRES-mediated translation is
activated during the G2/M phase of the cell
cycle, during which cap-dependent translation is suppressed (8,
18).
Antiviral therapy with IFN- and ribavirin is ineffective in about
50% of treated patients (1, 4, 15). Thus, a major question concerns the mechanism responsible for the failure of IFN-
to inhibit viral replication in a large fraction of HCV patients. Our
results showed that subgenomic replicons based on the
I377/NS3-3' construct are sensitive to the
antiviral program induced by IFN- in Huh7 cells (Fig. 4 to 6). IFN
reduced genomic (plus strand) RNA levels with a half-life of
approximately 12 h. Interestingly, inhibition of minus strands was
delayed by about 12 h, which could suggest that replication
complexes are more resistant to degradation by the cellular antiviral
response than free plus strand RNA. Hence, a major unresolved question
concerns the mechanism responsible for the antiviral activity of
IFN-.
Recently PKR has been invoked as an important IFN-induced pathway in
the HCV system because it can bind to NS5A proteins derived from some
IFN-resistant HCV isolates (3, 5, 6). Our results showed
that I377/NS3-3 and HCV-N-based replicon HCV1bneo
behaved almost identically in terms of their response to the cytokine (Fig. 4). These observations are surprising considering that
I377/NS3-3, in contrast to HCV1bneo, encodes a
form of NS5A believed to confer IFN- resistance but are consistent
with results reported previously by Blight et al. and Enomoto et al.
(3, 5, 6). It should be noted that the mutations in NS5A
identified in cell lines FCA1 and FCA4 (Table 1) are outside of the IFN
sensitivity-determining region of NS5A (3, 4). Thus, under
physiological conditions NS5A might be either sequestered in
replication complexes or expressed at lower levels and, either way,
does not seem to act as an inhibitor of PKR (7).
Alternatively, it is possible that PKR is not activated in the Huh7
culture system. However, it is known that the IFN response is
multifactorial, and perhaps as a consequence there is, so far, no known
virus that has adopted an IFN-resistant phenotype. Our results
obtained from the long-term incubation of FCA1 cells with IFN- did
not reveal any evidence for a selection of such variants (Fig. 6). The
most likely explanation lies in the mechanism by which the IFN response
is regulated through the activation of inhibitors of IFN signal
transduction pathways (19). Our observation that
IFN-treated cells were able to maintain low levels of subgenomic
replicons is in good agreement with models predicting the long-term
suppression of the IFN response after a relatively short activation
period. Nevertheless, our observations should not be interpreted to
mean that IFN--resistant HCV variants cannot be identified in Huh7
cells. For example, their isolation might depend on alternative
selection strategies, i.e., the incubation of cell lines such as FCA1
with very high initial doses of IFN-.
| |
ACKNOWLEDGMENTS |
We thank Devron R. Averett, Kerry Campbell, Rene Daniel,
and Bill Mason for helpful comments on the manuscript and acknowledge services provided by the FCCC nucleotide sequencing facility. We are
especially grateful to Charlie Rice for the communication of
unpublished results about adapted variants. We thank Stan Lemon and
Charlie Rice for providing HCV clones HCV-N and
I377/NS3-3'.
This work was supported by grants from the National Institutes of
Health and by an appropriation from the Commonwealth of Pennsylvania.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Institute for
Cancer Research, Fox Chase Cancer Center, 7701 Burholme Ave.,
Philadelphia, PA 19111. Phone: (215) 718-4312. Fax: (215) 728-4329. E-mail: c_seeger{at}fccc.edu.
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Journal of Virology, September 2001, p. 8516-8523, Vol. 75, No. 18
0022-538X/01/$04.00+0 DOI: 10.1128/JVI.75.18.8516-8523.2001
Copyright © 2001, American Society for Microbiology. All rights reserved.
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Abstract
Introduction
