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Journal of Virology, November 1999, p. 9247-9255, Vol. 73, No. 11
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
trans-Complementation Analysis of the
Flavivirus Kunjin ns5 Gene Reveals an Essential Role for Translation of
Its N-Terminal Half in RNA Replication
Alexander A.
Khromykh,*
Petra L.
Sedlak, and
Edwin G.
Westaway
Sir Albert Sakzewski Virus Research Centre,
Royal Children's Hospital, Brisbane, Queensland 4029, Australia
Received 30 April 1999/Accepted 30 June 1999
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ABSTRACT |
Recently we described rescue of defective Kunjin virus (KUN) RNAs
with small deletions in the methyltransferase and RNA polymerase motifs
of the ns5 gene, using BHK cells stably expressing KUN replicon RNA
(repBHK cells) as helper (A. A. Khromykh et al., J. Virol.
72:7270-7279, 1998). We have now extended our previous observations
and report successful trans-complementation of defective KUN RNAs with most of the ns5 gene deleted or substituted with a
heterologous (dengue virus) ns5 sequence. Replication of full-length KUN RNAs with 3'-terminal deletions of 136 (5%), 933 (34%), and 1526 (56%) nucleotides in the ns5 gene was complemented efficiently in
transfected repBHK cells. RNA with a larger deletion of 2,042 nucleotides (75%) was complemented less efficiently, and RNA with an
even larger deletion of 2,279 nucleotides (84%) was not complemented at all. Chimeric KUN genomic RNA containing 87% of the KUN ns5 gene
replaced by the corresponding sequence of the dengue virus type 2 ns5
gene was unable to replicate in normal BHK cells but was complemented
in repBHK cells. These results demonstrate for the first time
complementation of flavivirus RNAs with large deletions (as much as
75%) in the RNA polymerase gene and establish that translation of most
of the N-terminal half of NS5 is essential for complementation in
trans. A model of formation of the flavivirus replication
complex implicating a possible role in RNA replication of conserved
coding sequences in the N-terminal half of NS5 is proposed based on the
complementation and earlier results with KUN and on reported data with
other flaviviruses.
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INTRODUCTION |
Kunjin virus (KUN) is an Australian
member of the Flavivirus genus within the family
Flaviviridae and is closely related to other members of the
Japanese encephalitis virus subgroup (23). The KUN genome
consists of single-stranded RNA of positive polarity comprising 11,022 nucleotides (13) with one long open reading frame coding for
3,433 amino acids in three structural proteins (C, prM, and E) and
seven nonstructural (NS) proteins (NS1 to NS5) for which the boundaries
of all flavivirus genes were first defined (6). KUN has long
been a very useful model for studying the events of flavivirus
replication and in particular the composition and functions of the RNA
replication complex (RC). Earlier we proposed a model for flavivirus
RNA replication demonstrating the role of double-stranded RNA (dsRNA)
as the template for RNA synthesis late in infection (4). Our
later studies on partial purification of the RC (5),
coprecipitations of NS proteins and dsRNA in a radioimmunoprecipitation
reaction, and colocalizations of NS proteins and dsRNA defined by
electron microscopy using immunogold labelling of cryosections
(22, 31, 32) demonstrated involvement of nearly all of the
NS proteins in the flavivirus RC. Of particular interest is the role in
RNA replication of NS5 protein due to the presence in its sequence of
several domains associated with conserved RNA-dependent RNA polymerase
(RdRp) motifs (16, 27) and the demonstrated activity for
dengue virus type 1 (DEN1) NS5 protein of nonspecific copying of RNA in
an in vitro RdRp assay (30). There are currently eight
identified conserved RdRp motifs (16, 26, 27) which in the
KUN ns5 gene are situated in the 3'-terminal half extending
approximately from nucleotides 1370 to 2214 (Fig.
1) (6). These motifs are thought to be involved in substrate binding, RNA binding, catalytic activity, and formation of the proper secondary structure of RdRps (16, 26). The N-terminal half of the flavivirus NS5 protein contains two conserved domains characteristic for methyltransferases (MT motif [Fig. 1]) (17).
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FIG. 1.
KUN ns5 deletion mutants. (A) Fragments of pBS-based
intermediate plasmids representing ns5 and 3'UTR regions. ns5His3'
represents part of the pBSns5His3'UTR sequence that codes for KUN NS5
comprising 905 amino acids (large box), an additional six histidines
and BamHI site (filled box), followed by the complete KUN
3'UTR sequence (thick line), which was used in the construction of
deletion mutants as described in Materials and Methods. Open boxes
within the ns5 gene represent regions containing MT motifs
(17) and RdRp motifs (16). Striped boxes show
three amino acid sequences, a, b, and c, strongly conserved among
flaviviruses (6). AgeI, EcoRV (E), Bsu36I (Bs), NruI (N),
AatII (A), SmaI (S), BamHI (B), and XhoI denote recognition sites for
corresponding restrictases, respectively, with the numbers indicating
their nucleotide positions starting in the KUN RNA sequence commencing
from the first nucleotide of the ns5 gene. A four-nucleotide insertion
at the AgeI site (ns5Age* construct; see Materials and Methods)
produced a frameshift in the subsequent coding sequence. (B) In vitro
translation products of RNAs prepared from the pBS-based intermediate
plasmids shown in panel A, performed as described in Materials and
Methods. Arrowheads show positions of the corresponding deleted NS5
proteins. The expected number of amino acids in wild-type (wt) NS5 is
905 and in the deleted proteins, including the number of additional
amino acids derived from the vector during construction (indicated in
parentheses), are as follows: ns5dSB, 867 (5); ns5dAB, 600 (5); ns5dNB,
407 (9); ns5dBsB, 236 (9); and ns5dEB, 156 (9). Numbers on the left
show positions of proteins from low-range prestained protein molecular
weight standards (Bio-Rad).
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One way of identifying the role of a particular motif in the functional
activity of a viral protein is to delete it and examine the effect of
the deletion on normal function of the protein as well as to examine
whether this defective function can be complemented by addition of the
native undeleted protein. The development of the stable KUN full-length
infectious cDNA clone (13) and of a functional cDNA clone
for production of subgenomic KUN replicon RNA with deleted structural
genes (14) allows us to study the effects of introduced
deletions and mutations in NS proteins on their functions in RNA
replication as well as to devise a system for
trans-complementation of these defective proteins. Thus
we showed that deletion of the active site GDD in one of the RdRp motifs and the S-adenosylmethionine-binding site in one
of the MT motifs of KUN ns5 gene in the full-length RNA (FLdGDD
and FLdSAM constructs, respectively) resulted in a total loss of
the replication ability of these RNAs (15), hence
demonstrating an essential role of these motifs in the NS5 protein for
RNA replication. We were also able to complement replication of these
defective full-length RNAs by providing functional NS5 protein in
trans from the KUN replicon RNA persistently replicating in
repBHK cells (15). repBHK cells were prepared by antibiotic
G418 selection of BHK cells transfected with KUN replicon RNA
C20DXrepNeo deleted of most of the KUN structural region and containing
an insertion of encephalomyocarditis virus internal ribosomal entry
site-neomycin resistance gene (Neo) cassette in the KUN 3' untranslated
region (3'UTR) (15). In this paper, we show that deletions
of the carboxy-terminal coding region comprising up to 56% of NS5
(including the entire RdRp region) can be efficiently complemented in
trans by NS5 expressed in repBHK cells. In contrast, coding
deletions extending toward the amino-terminal half of NS5 were
complemented either much less efficiently or not at all. These results
as well as our failure to complement a frameshift mutation at the
beginning of NS5 allowed us to postulate a role for the translated
N-terminal part of NS5 protein as a cis-acting element for
RNA replication and to propose a model for formation of the flavivirus RC.
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MATERIALS AND METHODS |
Cells.
BHK-21 cells were maintained in the Dulbecco's
modification of minimal essential medium (DMEM) supplemented with 10%
fetal bovine serum (FBS). repBHK cells containing stably replicating KUN replicon RNA (15) were maintained in DMEM-10% FBS
supplemented with 1 mg of G418 (Geneticin; Gibco BRL) per ml.
Construction of plasmids.
C-terminal deletions in the ns5
gene were prepared initially using plasmid pBSns5His3'UTR (ns5His3'
[Fig. 1A]) (12) by digestion first with BamHI
and then with SmaI, AatII, NruI,
Bsu36I, or EcoRV, then blunt ending
and religating the resulting purified vectors to obtain
intermediate plasmid pBSns5dSB3'UTR, pBSns5dAB3'UTR, pBSns5dNB3'UTR, pBSns5dBsB3'UTR, or pBSns5dEB3'UTR, respectively. Full-length KUN plasmids ns5dSB, ns5dAB, ns5dNB, ns5dBsB, and ns5dEB
were then obtained by transferring the AgeI-XhoI
fragments containing deleted ns5 sequences followed by the KUN 3'UTR
sequence from the corresponding intermediate pBS plasmids (see above)
into the KUN full-length FLSDX vector (15) digested with
AgeI and XhoI (Fig. 1A). The ns5Age* (frameshift)
construct (Fig. 1A) was prepared by digesting FLSDX plasmid
(15) with AgeI restrictase, filling in with
Klenow DNA polymerase, and religating the resulting vector. These
manipulations introduced a four-nucleotide insertion at the former
AgeI site (AgeI* in Fig. 1A), leading to a frameshift in the
subsequent coding sequence (grey box in ns5Age* construct in Fig. 1A)
and introduction of an artificial translation termination codon 39 codons downstream of the mutated AgeI site (Fig. 1A, Stop).
Plasmid DENns5 containing an in-frame replacement of most of the KUN
ns5 gene by the corresponding region of the DEN ns5 gene
was
constructed by preparing an
AgeI-
XmaI PCR
fragment amplified
from the DEN2 cDNA clone pMK8.5 (
10)
(kindly provided by R.
Padmanabhan, University of Kansas Medical
Center), using primers
DENns5F
(5'-CAC
ACCgGtAGGGAAAGTA-3') and DENns5R
(5'-GGTGG
CCCgGgTTGTTAG-3')
with incorporated
AgeI and
XmaI sites (underlined nucleotides;
Fig.
2A) and high-fidelity
Pfu DNA
polymerase. Lowercase nucleotides
in the primer sequences denote the
mutated nucleotides in the
DEN2 sequence that were incorporated to
create restriction sites.
This fragment was cloned into the KUN
full-length FLSDX clone
digested with
AgeI and
XmaI (Fig.
2A). To confirm an open reading
frame of the
chimeric ns5 gene by in vitro translation, the
AgeI-
XhoI
fragment from the DENns5 clone (Fig.
2A) was transferred into
plasmid pBSNS5wt (
15) digested with
AgeI and
XhoI to obtain
plasmid pBSDENns5.
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FIG. 2.
Complementation of chimeric KUN-DEN2 RNA. (A) Fragments
from the chimeric full-length cDNA constructs KUNns5-3' and DENns5,
representing the ns5 and 3'UTR regions. Hatched boxes and thick lines
represent KUN ns5 and KUN 3'UTR sequences, respectively, as in Fig. 1A
except that the additional sequence coding for six histidine residues
and BamHI site was not present in these constructs. The open
box represents the DEN ns5 sequence PCR amplified from the DEN2 cDNA
clone pMK8.5 (10). Age, Xma, and Xho denote positions of
recognition sites for AgeI, XmaI, and
XhoI restrictases in the KUN cDNA (13) used in
construction of chimeric clone as described in Materials and Methods.
Numbers in bold indicate positions of KUN nucleotides, and underlined
numbers mark the positions of DEN2 nucleotides, both commencing from
the first nucleotide of the corresponding ns5 gene. (B) In vitro
translations of chimeric RNAs transcribed from an intermediate plasmid
DNA, pBSNS5wt (KUNns5 lane) or pBSDENns5 (DENns5 lane), performed as
described in Materials and Methods. The position of a 107-kDa protein
from prestained low-range molecular weight standards (Bio-Rad) is shown
on the left. (C) IF analysis with KUN anti-E antibodies of
DENns5-transfected repBHK cells at day 1 (1d panel) and day 3 (3d
panel) after transfection and of DENns5-transfected BHK cells at day 5 after transfection (BHK 5d panel). (D) Northern blot analysis of total
RNA isolated from repBHK cells and from normal BHK cells at 1 day and 3 days after transfection with DENns5 RNA. An arrowhead indicates the
position of RNA of about 11 kb, determined as described for Fig. 3B.
The control lane contains ~5 ng of in vitro-transcribed full-length
KUN RNA.
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RNA transcription and transfection.
All full-length RNA
transcripts were prepared with SP6 RNA polymerase from
XhoI-linearized plasmid DNAs and electroporated into BHK-21
or repBHK cells as described previously (14, 15).
In vitro translation.
All intermediate pBS-based plasmid
DNAs with deleted and substituted ns5 mutants were linearized with
XhoI (Fig. 1A and 2A), and corresponding RNAs were
transcribed in a standard in vitro transcription reaction with T7 RNA
polymerase (Promega). Approximately 1 µg of purified RNA was used in
10-µl in vitro translation reactions with rabbit reticulocyte lysate
(Promega) essentially as described by the manufacturer. Aliquots of 2 µl of the radioactive translation reaction mixture were subjected to
electrophoresis in a sodium dodecyl sulfate (SDS)-10% polyacrylamide
gel, and labelled proteins were detected by exposure of the dried gel
to an X-ray film.
Immunofluorescence and Northern blot analyses.
Detection of
replication of complemented KUN full-length RNA in transfected cells
was performed by indirect immunofluorescence (IF) analysis of
acetone-fixed cells with KUN anti-E antibodies and by Northern blot
hybridization of total cell RNA with a 32P-labelled
AatII-ClaI cDNA fragment representing 568 nucleotides of the KUN virus prM-E region (KUN nucleotides 522 to 1089 [6, 13]) as described previously (15).
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RESULTS |
Complementation of defective KUN RNAs with large deletions in the
ns5 gene.
Encouraged by our recent success in the
trans-complementation of defective KUN RNAs with a small
deletion in either the RNA polymerase or the MT motifs of the ns5 gene
(15), we decided to define the maximum extent of the
deletion in the ns5 gene which can be complemented in trans.
To rescue replication of deleted RNAs, we used BHK cells persistently
expressing KUN replicon RNA (repBHK cells [15]). Use
of repBHK cells as a helper for complementation of full-length KUN RNAs
with introduced deletions allows quick evaluation of the replication of
complemented RNAs by IF analysis with KUN anti-E antibodies, which was
shown to correlate well with the accumulation of complemented RNA
detected by Northern blot analysis (15).
The NS5 mutants containing progressive 3'-terminal deletions were
initially prepared in intermediate pBS-based plasmids (Materials
and
Methods; Fig.
1A). In vitro translation of these pBS-based
plasmids
produced NS5 protein products of expected sizes (Fig.
1B), thus
demonstrating correct translation of the deleted RNAs.
We then used
these intermediate plasmids to prepare full-length
KUN cDNA plasmids
with corresponding deletions in the ns5 gene
(Materials and Methods;
Fig.
1A). The RNA transcripts prepared
from these NS5-deleted
full-length cDNA plasmids were electroporated
into repBHK cells for
complementation. IF analysis showed that
100% of repBHK cells were
anti-E positive by 2 days after electroporation
of ns5dSB, ns5dAB, and
ns5dNB RNAs, thus demonstrating efficient
complementation of these RNAs
(Fig.
3A). Noticeably, the largest
efficiently complemented deletion was 1,526 nucleotides (ns5dNB),
which
represents more than half of the ns5 gene including all
the RNA
polymerase motifs (Fig.
1A) (
16). Further deletion of
516 nucleotides (ns5dBsB [Fig.
1A]) produced significantly less
complementation of the corresponding deleted RNA in repBHK cells,
with
only a few single anti-E-positive cells by day 2 after electroporation,
shown in the ns5dBsB (2d) panel in Fig.
3A. However, foci of
anti-E-positive
cells were observed at day 4 after electroporation, as
shown in
the ns5dBsB (4d) panel in Fig.
3A, indicating a slow spread of
the complemented virus in repBHK cells. No anti-E-positive cells
were
detected even at 5 to 7 days after transfection of any of
these deleted
RNAs into normal BHK cells (data not shown). Further
deletion of
another 237 nucleotides (ns5dEB in Fig.
1A) resulted
in complete
inability of the ns5dEB RNA to be complemented in
repBHK cells, as
judged by the absence of anti-E-positive cells
at day 4, as shown in
the ns5dEB (4d) panel in Fig.
3A, and at
day 6 (results not shown)
after electroporation.
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FIG. 3.
Complementation of KUN RNAs with large deletions in the
ns5 gene. (A) IF analysis with KUN anti-E antibodies of repBHK cells
transfected with deleted RNAs as shown. (B) Northern blot analysis with
a radioactive prM-E cDNA probe of the total RNA isolated from repBHK
cells transfected with deleted RNAs. Designations for RNAs used for
transfections and the time in days after transfections when the
analyses were performed are as indicated. The arrow in panel B
indicates the position in the gel of RNA of about 11 kb, determined
relative to migration in the same gel of an ethidium bromide-stained 1 Kb Plus DNA Ladder (GibcoBRL). The control lane in panel B contains
~5 ng of in vitro-transcribed full-length KUN RNA.
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We next confirmed the IF results on complementation of defective RNAs
by Northern blot analysis of the parallel samples of
total cell RNA by
using a radioactive cDNA probe representing
part of the KUN prM-E
region which is absent in the KUN replicon
RNA (Fig.
3B). Appropriate
differences in size of complemented
RNAs were observed in the blots, as
expected from the differences
in size of the corresponding deletions
(Fig.
3B, lanes 1 to 4
and 7 to 10). These results demonstrated that
replication of defective
KUN RNAs with lethal C-terminal coding
deletions in the KUN ns5
gene ranging from as few as 137 nucleotides up
to as many as ~2,070
nucleotides, representing more than two-thirds
of the gene, could
be complemented in
trans by the
functional ns5 gene expressed
from the KUN replicon RNA. The results
also showed that the KUN
ns5 sequence between nucleotides 442 and 679 (present in ns5dBsB
but not in ns5dEB) is absolutely essential for
maintaining the
ability of the corresponding RNA to be complemented in
trans and
thus probably represents part of a
cis-acting element. In a separate
experiment, we could not
complement KUN full-length RNA ns5Age*
with a frameshift mutation at
the
AgeI site (construct shown in
Fig.
1A) (results not
shown), demonstrating that translation of
the amino acid sequence of
the first 679 nucleotides of ns5 gene
rather than the RNA sequence per
se in this region is required
for
trans-complementation to
occur.
Complementation of KUN RNA containing the chimeric DEN2-KUN ns5
gene.
Having established an essential role for translation of the
N-terminal half of the KUN ns5 gene in complementation, we then investigated the stringency of these amino acid sequence requirements by substituting in the KUN sequence a heterologous ns5 sequence from a
distantly related flavivirus. For this purpose, we prepared a
full-length KUN cDNA construct containing a chimeric DEN2-KUN ns5 gene.
The sequence from AgeI to XmaI sites representing
approximately 87% of the KUN ns5 gene (including the essential region
for complementation in the N-terminal half shown above) was replaced by
the corresponding sequence of the DEN2 ns5 gene that has about 29%
difference in amino acid sequence (Fig. 2A) (2, 6).
Retention of the open reading frame in the chimeric ns5 gene was
confirmed by in vitro translation of the RNA transcribed from the
corresponding pBSDENns5 plasmid (Fig. 2B). We then addressed the
question of whether this chimeric RNA can replicate in transfected
cells by itself and, if it cannot, whether the function of this
chimeric NS5 protein can be complemented in trans by the
functional KUN replication complex. No replication was detected even by
5 days after transfection of DENns5 RNA into normal BHK cells (Fig. 2D,
lanes 4 and 5), suggesting that chimeric DEN-KUN NS5 protein could not
amplify KUN RNA. However, replication of DENns5 RNA was complemented in transfected repBHK cells, as judged by IF and Northern blot analyses (Fig. 2C and D). The noticeable increase in the amount of
anti-E-positive cells (Fig. 2C) and in the amount of accumulated RNA
(Fig. 2D) from day 1 to day 3 after transfection indicates spread of
complemented virus. These results demonstrate that a chimeric NS5
protein comprising most of the DEN2 NS5 could not recognize the KUN RNA
molecule for amplification, but this chimeric RNA molecule with an
authentic KUN 3'UTR was apparently recognized and amplified by the
functional KUN RC present in repBHK cells. Therefore, we concluded that
the RNA polymerase function of chimeric DEN-KUN NS5 protein was
efficiently complemented by the native KUN NS5 protein produced as a
part of functional KUN RC in repBHK cells.
Characterization of secreted complemented viruses.
The
presence of deleted or substituted RNAs in the recovered defective
viruses was confirmed by RT-PCR analysis of RNA isolated from the
secreted defective virus particles immunoprecipitated with anti-E
antibodies (Fig. 4). The primers used for
reverse transcription (RT)-PCR analysis were designed so that they
could amplify packaged defective full-length RNA but not packaged
helper replicon RNA (Fig. 4A). To ensure that RT-PCR amplification
occurred only from RNA purified from recovered complemented virus
particles, culture fluids (CFs) from transfected repBHK cells were
exhaustively treated with RNase A and DNase before and during the
precipitation with anti-E antibodies (see the legend to Fig. 4). The
gel migrations of the RT-PCR-amplified fragments correlated well with
the predicted sizes, which were 2,797 nucleotides for purified
full-length KUN virion RNA, 2,661 nucleotides for ns5dSB virus RNA,
1,864 nucleotides for ns5dAB virus RNA, 1,271 nucleotides for ns5dNB
virus RNA, 759 nucleotides for ns5dBSB virus RNA (Fig. 4A and B), and
2,353 nucleotides for DENns5 virus RNA (Fig. 2A and 4C). Although a fragment of the correct size was detected in the RT-PCR product from
RNA purified from 6-day CF of ns5dBsB virus (Fig. 5B), no RT-PCR
product was detected in the RNA sample isolated from 4-day CF of
ns5dBsB virus or in a control reaction with RNA isolated from 4-day CF
collected from BHK cells transfected with FLdGDD RNA (results not
shown). The latter represents full-length KUN RNA with a coding
deletion of the RNA polymerase motif GDD described previously
(15). These negative RT-PCR results confirmed the very
inefficient complementation of nd5dBsB RNA and the slow
secretion of complemented virus observed in transfection experiments
(Fig. 3), as well as demonstrating the specificity of the RT-PCRs.
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FIG. 4.
Characterization of secreted complemented viruses by
RT-PCR analysis. (A) Schematic representation of the KUN full-length
and replicon genomes in the ns5-3'UTR sequence. The numbers represent
nucleotide positions in the KUN RNA sequence in the ns5-3'UTR sequence
including an additional nine nucleotides incorporated in primer a
described below. These numbers were used to calculate the size of
RT-PCR fragments shown above the lines. Bs, N, A, and S show positions
of the restriction sites used for generation of the deletions as in
Fig. 1A, with addition of nine nucleotides present in primer a. Primers
used in RT-PCRs, indicated by a and b, were as follows: (a)
5'-ggtcatatgGGTGGGGCAAAAGGA-3' (nucleotides in capital
letters correspond to nucleotides 1 to 15 of the KUN ns5 gene
[6]; nucleotides in lowercase show an additional nine
nucleotides, not present in the KUN sequence), and (b)
5'-CACACTAAACACTATTATAAAGCTAAA-3' (minus sense,
complementary to nucleotides 2771 to 2797 of the KUN ns5-3'UTR
sequence, which contains an additional nine nucleotides derived from
the 5' end of primer a). Note that primer b cannot bind to the 3'UTR
sequence in the replicon RNA due to a deletion introduced during its
construction (see Materials and Methods and reference
14). (B) RT-PCR analysis of recovered defective
viral RNAs. Aliquots of 630 µl of 1-ml CFs collected at day 3 (DENns5), day 4 (ns5dSB, ns5dAB, and ns5dNB), and day 6 (ns5dBsB) after
transfection of repBHK cells with corresponding defective RNAs were
treated by addition of 50 µg of RNase A (Sigma) per ml and 5 U of RQ
DNase (Promega) per ml for 30 min at 37°C to ensure the absence of
any possible DNA and RNA contaminations from transfected in vitro
transcription mixtures. CFs still containing RNase A and DNase were
then incubated overnight at 4°C with 70 µl of anti-E monoclonal
antibodies followed by a further 2-h incubation with 100 µl of a 10%
slurry of protein A-Sepharose beads (Pharmacia). The precipitates on
the washed beads were treated with proteinase K in the presence of
0.5% SDS, followed by phenol-chloroform extraction and ethanol
precipitation of the RNA. Precipitated RNA was dissolved in 6 µl of
diethyl pyrocarbonate-treated H2O, and 1 µl of this RNA
was used in a 10-µl RT-PCR performed with the SuperScript One-Step
RT-PCR system (GibcoBRL) essentially as described by the manufacturer
and with primers a and b, defined above. In panel C, primers for
amplifying DENns5 virus RNA by RT-PCR were DENns5F and DENns5R (see
Materials and Methods). KUN lanes shown as wt in panels B and C
represent RT-PCRs with ~10 ng of KUN virion RNA purified as described
previously (13). M lanes in panels A and B show the 1 Kb
Plus DNA Ladder (GibcoBRL).
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We then investigated replication of the recovered defective viruses in
infected repBHK and normal BHK cells by dual-label
(fluorescein
isothiocyanate [FITC] and Texas red [TR]) IF analysis.
Infection of
repBHK cells with 1/10 dilution of ns5dSB or ns5dNB
or 1/100 dilution
of ns5dAB defective viruses secreted in the
4-day CF resulted in
detection of 100% cells positive in IF analysis
with anti-E antibodies
by 2 days after infection (repBHK panels
in Fig.
5A), indicating transmission and
efficient replication
of the complemented defective viruses in repBHK
cells. Infection
of repBHK cells with 1/10 dilution of DENns5 virus
(3-day CF)
produced ~60 to 70% anti-E-positive cells by 2 days after
infection
(Fig.
5B), also showing efficient replication of DENns5
virus.
As expected from inefficient complementation of ns5dBsB RNA
(Fig.
3), infection of repBHK cells with undiluted ns5BsB virus (4-day
CF) resulted in detection of only a few anti-E-positive cells
at
day 2 after infection (Fig.
5B), and a slight increase in number
of
positive cells was observed at day 5 after infection (results
not
shown). To compare relative efficiencies of complementation,
we
titrated repBHK CFs harvested at 4 days after transfection
of ns5dSB,
ns5dAB, ns5dNB, and DENns5 RNAs by infection of repBHK
cells.
Infectious titers were calculated by counting foci of anti-E
IF-positive cells at 2 days after the infection. The number of
IF foci
decreased linearly with the dilutions of CFs, and the
titers were
~3 × 10
5 to 5 × 10
5 infectious
units (IU) per ml for ns5dSB, ns5dNB, and DENns5 viruses
and ~5 × 10
6 IU per ml for ns5dAB virus. These results with
secreted viruses
correlated well with our observations that ns5dAB RNA
was complemented
more efficiently in transfected repBHK cells in the
same experiment
than were ns5dSB and ns5dNB RNAs (compare, for example,
lane 3
with lanes 2 and 4 in Fig.
3B). The titers of 4-day and 6-day
CFs of ns5dBSB virus were ~10
2 and ~5 × 10
2 IU per ml, respectively, thus confirming the very low
efficiency
of ns5dBsB RNA complementation observed in transfection
experiments
(see above).
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FIG. 5.
Characterization of the recovered viruses by IF
analysis. (A) IF analysis of repBHK and BHK cells which were infected
with diluted or undiluted CFs (as indicated) collected at 4 days after
transfection of ns5dSB, ns5dAB, and ns5dNB RNAs. repBHK panels show IF
analysis at day 2 after infection of repBHK cells using anti-E
antibodies (anti-E panels). Pairs of joined BHK panels representing the
same selected field were dual labelled with anti-E (anti-E,FITC panels)
and anti-NS3 antibodies (anti-NS3,TR panels). White arrows indicate
selected cells positive in IF with both anti-E and anti-NS3 antibodies.
(B) IF analysis using anti-E antibodies of repBHK and BHK cells
infected with CFs containing complemented ns5dBsB and DENns5 viruses.
Designations are as in panel A. FITC-conjugated secondary antibodies
were used in all experiments with repBHK and BHK cells for IF detection
of E protein, and TR-conjugated secondary antibodies were used for IF
detection of NS3 protein in experiments with dual labelling in BHK
cells.
|
|
We showed previously in complementation experiments with FLdGDD and
FLdSAM RNAs performed with repBHK cells (
15) that infection
of normal BHK cells with recovered defective complemented viruses
may
lead to detection of rare anti-E-positive cells due to simultaneous
coinfection of these cells with two types of particles, one containing
packaged replicon RNA from repBHK cells (replicon RNA particles)
and
the other containing packaged complemented defective full-length
RNA
(defective RNA particles). This coinfection event occurred
rarely and
these two types of particles could be distinguished
by dual IF analysis
using anti-NS3 antibodies (able to detect
replication of both replicon
RNA and deleted full-length RNA)
and anti-E antibodies (able to detect
replication of only deleted
full-length RNA). The results of such dual
IF analyses performed
at 2 days after infection of normal BHK cells
with undiluted CFs
containing ns5dSB, ns5dAB, and ns5dNB complemented
viruses showed
that while a significant number of these normal BHK
cells were
anti-NS3 positive (BHK, anti-NS3 panels in Fig.
5A), only
very
few of these anti-NS3 positive cells were also positive in IF
with
anti-E antibodies (BHK, anti-E panels in Fig.
5A), as shown
previously
for complemented FLdGDD and FLdSAM viruses (
15).
No
anti-E-positive cells were detected after infection of BHK
cells with
undiluted CF containing complemented DENns5 virus (Fig.
5B).
Interestingly, longer incubation of normal BHK cells infected
with
ns5dSB, ns5dAB, and ns5dNB viruses resulted in detection
of a small
number of slowly spreading anti-E-positive foci by
day 5 after
infection (results not shown) which may have arisen
either from the
spread of secreted complemented virus in the neighboring
cells infected
with replicon RNA particles or from self-replicating
recombinant virus.
Further passaging of the CFs collected from
these infected BHK cells
with spreading anti-E-positive foci on
fresh BHK or repBHK cells did
not produce anti-E-positive BHK
cells, but the majority of repBHK cells
were anti-E positive (results
not shown), indicating the presence of
only defective virus particles
in the repBHK-complemented virus
material passaged once on BHK
cells. These passaging results for
BHK-infected CFs as well as
results for initial infections of repBHK
and BHK cells with recovered
complemented viruses (Fig.
5) and results
of RT-PCR analysis of
secreted complemented viral particles (Fig.
4)
clearly demonstrate
that the majority of secreted complemented virus
particles recovered
in repBHK transfection experiments contained
defective full-length
KUN RNAs able to replicate in repBHK cells but
deficient in the
ability to independently replicate in normal BHK
cells. Thus,
possible recombinant self-replicating viruses were either
absent
or present in negligible or undetectable
amounts.
| |
DISCUSSION |
We constructed several KUN mutants whose genomes contained large
deletions, a frameshift mutation, and a heterologous (DEN) substitution
retaining only 13% of the KUN NS5 coding region, all in the RNA
polymerase gene ns5. None of the mutant RNAs was able to replicate
independently in transfected BHK cells, thus demonstrating an essential
role of the deleted or substituted amino acid sequences in the NS5
protein for RNA replication. We then used repBHK cells stably
expressing KUN replicon RNA as a helper to trans-complement
replication of these mutant RNAs. The RNAs containing deletions
representing the C-terminal half of NS5 were complemented efficiently
in repBHK cells, while RNAs with deletions extending into the
N-terminal half of NS5 were complemented either much less efficiently
or not at all (Table 1). This is the
first report on successful trans-complementation of large
deletions (as much as 75%) in the flavivirus RNA polymerase gene. In
other experiments, RNA with a frameshift mutation at codon 71 in the
KUN ns5 gene (ns5Age* [Fig. 1A]) was not complemented (see Results).
Interestingly, KUN RNA with a 3'-terminal deletion of 509 codons
including the entire NS5 RdRp region was still complemented efficiently
(ns5dNB [Table 1]). Thus, our results clearly demonstrate that
despite the absence of translation in cis of all of the
amino acid sequence representing the enzymatically functional region of
the RdRp gene, the polymerase functions can be complemented by another
(native) RdRp supplied in trans.
Comparative amino acid analysis of the N-terminal half of the
flavivirus NS5 protein revealed the presence of three highly conserved
regions comprising 11, 21, and 23 amino acids situated within the first
365 amino acids of NS5 (motifs a, b, and c, respectively, in Fig. 6;
references 2 and 6). The presence
of one of these conserved regions (c) was previously noted by Coia et
al. (6), but as yet no functions have been assigned to any
of these three homology motifs. The striking difference between the
efficient complementation of ns5dNB RNA (retaining all three motifs)
and the very inefficient complementation of ns5dBsB RNA (retaining only
the first two motifs, a and b) (Table 1) suggests an important role of
at least motif c in retaining the ability of deleted RNA to be
efficiently complemented in trans. Removal of all three conserved regions resulted in total loss of the ability of ns5dEB RNA
to be complemented (Table 1). Interestingly, defective chimeric RNA in
which 87% of the KUN ns5 gene (including the N-terminal coding region
for motifs a, b, and c) was replaced by a corresponding DEN2 ns5
sequence was efficiently complemented in repBHK cells (Results and Fig.
2). Notably, all these three motifs are highly conserved in both KUN
and DEN2 NS5 proteins (Fig. 6), while the remainder of the replaced amino acid sequence differed by approximately 29% (see Results). Importantly, this chimeric RNA was not able to
establish self-replication in normal BHK cells, which demonstrates that
chimeric NS5 protein could not form a functional RC with KUN RNA. The
lack of complementation of RNA with a frameshift mutation at codon 71 (ns5Age* results; see above) and the successful complementation of RNAs
with the deleted and substituted NS5 mutants clearly demonstrate that
only when the N-terminal half of the ns5 gene (encoding conserved
motifs a, b, and c) was translated in cis could the RNA be
recognized and amplified efficiently by a functional RC.
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|
FIG. 6.
Conserved motifs in the N-terminal half of the
flavivirus ns5 gene. a, b, and c represent alignment of NS5 amino acid
sequences (KUN NS5 amino acids 141 to 151, 203 to 223, and 343 to 365, respectively, as indicated) conserved with trivial variations only for
all flaviviruses (2, 6).
|
|
Although NS5 of DEN1 was shown to copy RNA in an in vitro reaction,
there was no specificity in regard to template RNA (30). Our
analyses of the native KUN RC late in infection both in vivo and in
vitro have shown that it has a consensus composition of NS1, NS3, NS5,
NS2A, and NS4A. This was established by cryoimmunoelectron microscopy
of infected cells showing colocalizations with the putative dsRNA
template (22, 31, 32), by purification of the native RdRp
after detergent treatment of the semipurified active membrane fraction
(5), and/or by radioimmunoprecipitation of detergent-treated
cytoplasmic extracts with antibodies to dsRNA (32). We also
showed in binding assays that NS2A and NS4A bind to the same
constellation of proteins as above, that NS4A binds very strongly to
itself, and that NS2A binds to KUN 3'UTR (22) as does NS5
(12). Others have shown that flavivirus NS5 and NS3 in
Japanese encephalitis virus-infected cell lysates can be cross-linked
by UV irradiation specifically to the putative stem-loop within the RNA
positive-strand 3'UTR (3) or be coprecipitated in
DEN2-infected cells by antibodies to DEN2 NS3 or NS5 and also to bind
to each other in vitro (11). DEN2 NS3 was recently shown to
have intrinsic RNA helicase activity as well as the RNA-stimulated nucleoside triphosphatase activity (18) reported for several other flaviviruses (for references, see reference
18), implying strong affinity of this protein for
RNA. Significantly, substitutions of homologous sequences of West Nile
virus RNA in the bottom half of the DEN2 3' stem-loop were lethal
(36).
Like flavivirus RNAs, picornavirus RNA is translated from one long open
reading frame with the gene order of structural genes followed by
NS genes, and after the genomic RNA is copied by the viral replicase
into an RNA minus strand, a double-stranded template is formed
for initiation of synthesis of progeny RNA in association with
membranes (35). Some comparisons with replication of
the well-studied poliovirus therefore have some relevance. For
example, Novak and Kirkegaard (24) reported successful
complementation by helper replicon RNA of poliovirus full-length RNA
with a frameshift mutation at the beginning of the 3Dpol
RNA polymerase gene (codon 28), thus eliminating translation of
virtually all of the 3Dpol. Similarly, deletion of the
entire KUN NS5 RdRp region was also efficiently complemented in
trans (ns5dNB [Table 1]). Interestingly, the N-terminal
region of one of the poliovirus 3Dpol subunits was proposed
to be involved in interaction with the C-terminal region of another
3Dpol subunit during oligomerization (8), and
the N-terminal region (amino acids 40 to 140) of brome mosaic virus
RdRp (2a protein) was shown to interact with the helicase-like domain
of 1a protein (9, 25). However, there are no reports of
specific interactions of the N-terminal region of flavivirus NS5.
In view of the considerations above and assuming that the compositions
of the RC are similar early and late in infection, it is tempting to
speculate that the N-terminal region of the flavivirus NS5 protein
interacts via conserved motifs (a, b, and c) with NS3 and possibly
other NS proteins such as NS2A during translation to initiate formation
of the RC, most likely on the 3'UTR of genomic RNA (Fig.
7). We propose that the RNA template with
the partially formed RC is then transported to an anchor region on
virus-induced membranes to complete the RC where initiation of
synthesis of RNA negative strand can then occur (Fig. 7). The mode of
transport and anchoring of the RC to membranes is speculative. Possible
roles for NS2A arising from our KUN data include targeting the viral
RNA and RC to cytoplasmic membranes, and we suggested that NS4A may
play a targeting or membrane-anchoring role within the RC (22, 31,
32). NS1 dimerizes after synthesis becoming membrane bound, with
increased hydrophobicity (34). Proposals for the role of NS1
include interaction with the RC by directing it to membranes (20,
32) or a role prior to or at initial RNA negative-strand
synthesis involving assembly of the components of the RC directly via
protein-protein interactions or via the relationship between NS1 and
cellular membranes (19). The relationship of NS4A to NS1
shown in the model (Fig. 7B) is supported by a recent report from
Lindenbach and Rice (20) showing genetic interaction between
these products as a determinant of replicase function. Once formed, the
RC appears to be stable because it remains active for several hours
after complete inhibition of all protein synthesis by cycloheximide
treatment (33). Hence, the RC requires no supplementation by
recently translated NS proteins or by polyprotein precursors which are
cleaved rapidly during KUN virus RNA translation in cells synchronized
in translation (29).
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|
FIG. 7.
Proposed model for formation of the flavivirus RC and
initiation of RNA negative-strand [( ) strand] synthesis. (A) NS3 is
assumed to bind to NS5 (3, 11) at one or more of the
conserved regions a, b, and c (each indicated by a thickened line
within the bracket) in the N-terminal region (Fig. 6), possibly
associated also with NS2A. ER, endoplasmic reticulum. (B) On completion
of translation, the complex attaches to the 3'UTR via binding of NS2A
(21) probably at the 3'-terminal stem-loop at which the NS3
and NS5 components also bind (3, 7). The location of the
complex shown on the 3' stem-loop is arbitrary. The complex attached to
the RNA positive strand [(+) strand] is transported (indicated by a
thick arrow) to the membrane site of replication by affinity of the
hydrophobic regions of NS2A interacting with those of NS4A (shown as
dimers), which in turn is bound by hydrophilic extensions in the lumen
between transmembrane domains (6) to dimeric NS1 in the
lumen (20). (C) The RC is now complete and may undergo a
rearrangement as the RdRp domains of NS5 bind to the template plus
strand, allowing copying to proceed. The RC is represented as an
extended circle on the 3'UTR, and a short dashed arrow indicates the
direction of synthesis (5' to 3') of the initiating RNA negative
strand. The association with membranes and the consensus composition of
the RC (NS1, NS3, NS5, NS2A, and NS4A) are described in the text. A
role for NS1 in synthesis of the RNA negative strand early in infection
has been proposed by Lindenbach and Rice (19, 20) based on
complementation experiments with mutated yellow fever virus RNA.
|
|
According to the proposed model (Fig. 7), deletions in the C-terminal
half of the NS5 protein (as in ns5dSB, ns5dAB, and ns5dNB) should still
allow interaction of other NS proteins with motifs a, b, and c in the
N-terminal half of NS5 and thus eventual formation of a defective RC,
probably consisting of a number of NS proteins (presumably NS3 and
NS2A) bound to truncated NS5 protein and to the terminal region of the
3'UTR of genomic RNA (see the legend to Fig. 7). In complementation
experiments, this defective RC would still be able to transport the
defective RNA (possibly directed by NS2A) to the site of helper
(replicon) RNA synthesis anchored on membranes in repBHK cells, thus
allowing initiation of synthesis of a deleted RNA negative strand by
exchanging the helper RC or its components with the defective RC.
Translation of RNA with deletion of c, one of the proposed
protein-binding motifs, as in ns5dBsB may result in the loss of binding
of truncated NS5 to one or more NS proteins, leading to formation of an
unstable or incomplete defective RC, unable to efficiently exchange
components with helper RC. Finally, loss of all proposed
protein-protein binding motifs as in ns5dEB and ns5Age* would not allow
any interaction between truncated NS5 and other NS proteins and thus
would result in an inability to form any defective RC capable of
transporting RNA to the location of the required helper RC. This model
is speculative at present but is based on our results obtained in
complementation experiments with KUN NS5-deleted RNAs and on the
extensive results summarized above describing the composition of the
KUN RC, as well as on the results of binding studies and cited data of
other groups. Further detailed experiments on protein-protein and
RNA-protein binding with deleted NS5 proteins as well as with other NS
proteins are required to determine whether this model accurately
represents the events in flavivirus RNA replication. There is a need to
explore also the role in replication of cellular proteins such as
EF-1
shown to bind to the 3'-terminal stem-loop of several
flaviviruses by Blackwell and Brinton (1), who suggested
that EF-1 may be involved in targeting flavivirus RNA to
intracellular membranes or in assembly of the viral RC. The proposed
model is the first attempt to provide a comprehensive interpretation of
a wide range of reported observations possibly relevant to the
formation of the flavivirus RC for initiation of RNA negative-strand
synthesis and should facilitate further studies on unraveling the
events of flavivirus replication.
| |
ACKNOWLEDGMENTS |
We are grateful to R. Padmanabhan for supplying plasmid pMK8.5
with DEN2 cDNA and R. Hall for supplying KUN anti-E monoclonal antibodies.
This work was supported by grant N981442 from the National Health and
Medical Research Council of Australia.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Royal
Children's Hospital, Herston Rd., Brisbane, Queensland 4029, Australia. Phone: (617) 3253-1568. Fax: (617) 3253-1401. E-mail:
a.khromykh{at}mailbox.uq.edu.au.
Publication no. 93 from the Sir Albert Sakzewski Virus Research Centre.
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0022-538X/99/$04.00+0
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Abstract
Introduction
