![[Feedback]](/icons/banner/feedbackACT.gif)
![[For Subscribers]](/icons/banner/subscriberACT.gif)
![[Archive]](/icons/banner/archiveACT.gif)
![[Search]](/icons/banner/searchACT.gif)
![[Contents]](/icons/banner/tocACT.gif)
Previous Article | Next Article 
Journal of Virology, June 2000, p. 5123-5132, Vol. 74, No. 11
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
Characterization and Construction of Functional cDNA Clones
of Pariacoto Virus, the First Alphanodavirus
Isolated outside Australasia
Karyn N.
Johnson,1
Jean-Louis
Zeddam,2 and
L. Andrew
Ball1,*
Department of Microbiology, University of
Alabama at Birmingham, Birmingham, Alabama
35294,1 and IRD c/o International
Potato Center, Lima 12, Peru2
Received 18 January 2000/Accepted 10 March 2000
 |
ABSTRACT |
Pariacoto virus (PaV) was recently isolated in Peru from the
Southern armyworm (Spodoptera eridania). PaV particles are
isometric, nonenveloped, and about 30 nm in diameter. The virus has a
bipartite RNA genome and a single major capsid protein with a molecular mass of 39.0 kDa, features that support its classification as a
Nodavirus. As such, PaV is the first
Alphanodavirus to have been isolated from outside
Australasia. Here we report that PaV replicates in wax moth larvae and
that PaV genomic RNAs replicate when transfected into cultured baby
hamster kidney cells. The complete nucleotide sequences of both
segments of the bipartite RNA genome were determined. The larger genome
segment, RNA1, is 3,011 nucleotides long and contains a
973-amino-acid open reading frame (ORF) encoding protein A, the
viral contribution to the RNA replicase. During replication, a
414-nucleotide long subgenomic RNA (RNA3) is synthesized which is
coterminal with the 3' end of RNA1. RNA3 contains a small ORF which
could encode a protein of 90 amino acids similar to the B2 protein of
other alphanodaviruses. RNA2 contains 1,311 nucleotides and encodes the
401 amino acids of the capsid protein precursor 
. The amino acid
sequences of the PaV capsid protein and the replicase subunit share 41 and 26% identity with homologous proteins of Flock house
virus, the best characterized of the alphanodaviruses. These and
other sequence comparisons indicate that PaV is evolutionarily the most
distant of the alphanodaviruses described to date, consistent with its novel geographic origin. Although the PaV capsid precursor is cleaved
into the two mature capsid proteins 
and 
, the amino acid
sequence at the cleavage site, which is Asn/Ala in all other alphanodaviruses, is Asn/Ser in PaV. To facilitate the investigation of
PaV replication in cultured cells, we constructed plasmids that
transcribed full-length PaV RNAs with authentic 5' and 3' termini.
Transcription of these plasmids in cells recreated the replication of
PaV RNA1 and RNA2, synthesis of subgenomic RNA3, and
translation of viral proteins A and .
| |
INTRODUCTION |
Nodaviruses are a family of
small (30 nm in diameter), nonenveloped, spherical viruses with
T=3 icosahedral symmetry (33). These viruses have a
bipartite genome of messenger-sense RNAs which are capped but not
polyadenylated (11, 13, 21, 28). The family
Nodaviridae contains two genera: the alphanodaviruses, which
primarily infect insects, and the betanodaviruses, which infect
fish (45).
The best studied of the alphanodaviruses are Flock house
virus (FHV), Black beetle virus (BBV), Nodamura
virus (NoV), and Boolarra virus (BoV) (for a review,
see reference 6). These four viruses were isolated
from insects of the orders Coleoptera, Diptera, and Lepidoptera, but they all replicate
well in larvae of the greater wax moth (Galleria
mellonella), and all but NoV infect Drosophila
melanogaster cells in culture. Furthermore, productive infections
of some alphanodaviruses result from introducing viral RNA into
plant (43), yeast (39), or mammalian
(2, 5) cells.
The larger genomic segment, RNA1, contains about 3 kb and
encodes protein A, the viral contribution to the RNA-dependent RNA polymerase (RdRp). During RNA replication, a subgenomic
RNA3 is synthesized which is coterminal with RNA1 and encodes one or
two small proteins (B1 and B2) with unknown functions. The smaller genomic segment, RNA2, contains about 1.4 kb and encodes the
capsid protein precursor . A single capsid is assembled from 180 copies of protein which coencapsidate RNA1 and RNA2 (23, 30,
44). Following assembly, the capsid protein precursor of
alphanodaviruses is autocatalytically cleaved near its C terminus to
form the two mature capsid proteins and , with approximate sizes
of 40 and 4 kDa, respectively (20). The cleavage site,
Asn/Ala, is conserved among all the alphanodaviruses that have been
examined, as is an aspartate residue near the N terminus which
catalyzes the cleavage (28, 47).
RNA2 sequences are available for four of the alphanodaviruses (NoV,
BBV, FHV, and BoV) (11, 12) and for two of the
betanodaviruses (Striped jack nervous necrosis virus and
Dicenthrarchus labrax encephalitis virus) (15,
37), and partial RNA2 sequences from several other
betanodaviruses have also been published (36, 37). Although
the betanodaviruses have capsid proteins and virions of sizes similar
to those of the alphanodaviruses, their amino acid sequences share less
than 11% similarity (37). Furthermore, it has been
suggested that the nodaviruses of fish have a capsid protein processing
pathway different from that of their insect counterparts
(15).
The nucleotide sequences of RNA1 are available for only two
alphanodaviruses, BBV (13) and FHV (R. Dasgupta, GenBank
accession no. X77156), and the RNA1 sequence of the betanodavirus
Striped jack nervous necrosis virus was recently published
(34). The BBV and FHV nucleotide sequences are 99%
identical. The encoded amino acid sequences include a GDD box and other
characteristic RdRp motifs in protein A, but they provide little
insight into other conserved regions of the protein because they were
so nearly identical. Protein A sequences from more divergent
alphanodaviruses would allow further definition of important structural
and functional domains.
The infectious cycle of FHV has been reconstructed from cDNA clones.
FHV RNA1 transcripts made in vitro replicate autonomously when
transfected into D. melanogaster cells, and they also
support the replication of RNA2 transcripts and the production of
infectious virus (14). In an alternative approach, cDNA
copies of the FHV RNAs were transcribed in cultured baby hamster kidney
(BHK-21) cells from specialized transcription plasmids that directed
the synthesis of RNAs with authentic termini, which were found to be
necessary for efficient RNA replication (2). This approach allowed more thorough investigation of the events involved in FHV
replication (4, 7, 8, 26). The simplicity and robustness of
the nodavirus replication cycle and the ability to manipulate it using
DNA-based technology affords many advantages for the examination of RNA
replication, virus structure, and virion assembly.
Pariacoto virus (PaV) was recently isolated from larvae of the southern
armyworm Spodoptera eridania (46) which were
found to be infected when collected from sweet potato plants near
Pariacoto, Ancash province, Peru. In addition to its natural host, PaV
multiplies in larvae of S. ochrea but not those of S. frugiperda (46); however, its ability to replicate in
cell culture or in common laboratory-reared insects has not been
tested. PaV particles are isometric, nonenveloped, and about 30 nm in
diameter. The virus has a bipartite RNA genome and a single major
capsid protein with an apparent molecular mass of 40.5 kDa, features
that support its classification as a nodavirus (46). As
such, PaV would be the first alphanodavirus isolated from outside Australasia.
In the work reported here, we characterized PaV at the molecular level
and confirmed that PaV is a new and distinct member of the
Alphanodavirus genus of the family Nodaviridae.
We constructed transcription plasmids that contained full-length cDNA
copies of each of the PaV genomic segments and used them to
reconstruct viral RNA replication and protein synthesis in transfected
BHK-21 cells. The sequence of these cDNA clones showed that PaV is the most distantly related of the characterized alphanodaviruses in both
its capsid protein and its replicase protein. This work provides information and reagents to investigate the biology of PaV as well as
potential applications of the nodaviruses.
| |
MATERIALS AND METHODS |
Virus.
The PaV isolate used in this study for inoculation of
G. mellonella was an aliquot of sucrose gradient-purified
virus from S. eridania larvae collected in the field in 1996 (46). All virus used for the experiments described below had
been passaged only once or twice in G. mellonella larvae.
Use of the vaccinia virus recombinant expressing T7 RNA polymerase
(vTF7-3) (18) for the reconstruction of nodavirus RNA
replication in vertebrate cells has been described previously
(2).
Cells.
Baby hamster kidney (BHK-21) cells were grown at
37°C as monolayer cultures in Dulbecco's modified Eagle's medium
(DMEM) containing 5% newborn calf serum and 5% fetal calf serum in an
atmosphere containing 5% CO2. Drosophila line 2 (DL2) cells (41) were propagated as monolayer cultures at
28°C in Schneider's medium (Gibco/BRL) supplemented with 10% fetal
calf serum.
Propagation of PaV in wax moth larvae.
Larvae of the greater
wax moth (G. mellonella; Carolina Biologicals) were reared
at 31°C on artificial medium containing 46% (wt/vol) baby rice
cereal, 4% (wt/vol) dried yeast, 20% (wt/vol) honey, 20% (wt/vol)
glycerol, 9.8% (wt/vol) water, and 0.2% (wt/vol) methyl-p-hydrobenzoate. PaV was injected into the hemocoel
of late-instar larvae; after incubation at 31°C for 8 days, larvae were collected and stored at 
20°C.
PaV purification.
PaV was purified by homogenizing frozen
infected larvae in 0.05 M sodium phosphate (pH 7.2) containing 0.1%
2-mercaptoethanol (PB). The homogenate was clarified by centrifugation
(9,000 × g, 15 min, 4°C), and virus was pelleted
through a 30% sucrose cushion in PB (100,000 × g,
4 h, 4°C). The virus pellet was resuspended in PB and layered
onto gradients of 15 to 45% sucrose in PB; following centrifugation
(100,000 × g, 3 h, 10°C), the opalescent band
of virus particles was harvested, diluted with PB, and pelleted
(100,000 × g, 3 h, 4°C). Virus was resuspended
in PB and stored at 80°C. Virus concentration was calculated using
an extinction coefficient at a wavelength of 260 nm of 4.15/mg
(32) and particle mass of 8 × 106 g/mol
(24). Approximately 20 µg of virus was recovered per larva.
Infection and transfection of cells in culture.
For all
infections and transfections, BHK-21 and DL2 cells were plated in
35-mm-diameter wells of six-well tissue culture plates and grown
overnight to reach 80 to 100% confluence (corresponding to
approximately 106 or 107 cells per well,
respectively). For transfection of cells with virion RNA, cells were
washed once with phosphate-buffered saline containing magnesium
chloride and calcium chloride (PBSM). The cells were then overlaid with
1 ml of serum-free medium containing virion RNA (0.2 to 1 µg) and
Lipofectamine (20 µg; BHK-21 cells) or Lipofectin (10 µg; DL2
cells) as instructed by the manufacturer (Gibco/BRL). Transfected cells
were incubated at 28°C for 5 h before the medium was replaced
with medium containing serum. Incubation of transfected cells was
continued at 28°C for the times specified for the individual experiments.
For plasmid transfections, BHK-21 cells were washed twice with PBSM and
infected with vTF7-3 at a multiplicity of infection (MOI) of 10 PFU/cell. vTF7-3 expresses T7 RNA polymerase which is necessary for
primary RNA transcription from cDNA plasmids. The virus was allowed to
adsorb for 60 min at room temperature before removal of the inoculum.
Cells were washed twice with PBSM and then transfected with 2.5 µg of
each plasmid, combined with 10 µg of Lipofectamine in serum-free
DMEM. After incubation for 5 h at 28°C, the transfection medium
was removed and replaced with DMEM containing serum. Incubation of
transfected cells was continued at 28°C for the times specified for
the individual experiments.
RNA labeling, extraction, and analysis.
The products of RNA
replication were labeled by metabolic incorporation of
[3H]uridine in the presence of actinomycin D as described
previously (2). RNA was extracted, either from cells or from
virion particles, by the acid phenol guanidinium thiocyanate method
(10) as described previously (27).
cDNA synthesis, cloning, and sequence determination.
RNA
extracted from purified PaV virions was used as the template for cDNA
synthesis, using Superscript II reverse transcriptase (RT) at 42°C
under reaction conditions recommended by the supplier (Gibco/BRL). To
generate the initial cDNA clones, first-strand cDNA synthesis was
primed with random hexamer oligonucleotides and second-strand synthesis
was performed with RNase H and Escherichia coli DNA
polymerase I (Gibco/BRL). Blunt-ended cDNAs were cloned, and their
sequences were determined. Subsequent clones were constructed by RT-PCR
primed with specific oligonucleotides designed according to the
sequences of the initial clones. To obtain clones that included the 5'
ends of each of the viral genomic RNAs, rapid amplification of
cDNA ends (RACE) (17) was performed using the 5' RACE system
with PaV-specific oligonucleotides under conditions recommended by the
supplier (Gibco/BRL). The 5' termini of PaV RNAs were also mapped by
primer extension as previously described (7), using
oligonucleotides that annealed to nucleotides (nt) 76 to 98 of RNA1, 98 to 119 of RNA2, or 95 to 115 of RNA3.
Clones were sequenced as double-stranded DNA by the dideoxy-chain
termination method (40) using both vector-specific and PaV-specific oligonucleotide primers. Sequencing reactions were performed using dye terminators and analyzed on an automated sequencer. Overlapping cDNA clones that corresponded to the entire length of both
RNA1 and RNA2 were sequenced completely in both directions.
Plasmid construction and analysis of full-length clones.
Full-length cDNA copies of genomic RNA segments 1 and 2 were
synthesized by RT-PCR using oligonucleotides specific for the 5' and 3'
termini of each RNA. These PCR products were ligated into transcription
plasmids between a T7 promoter and cDNA sequences that encode the
hepatitis delta virus (HDV) antigenomic ribozyme followed by a
T7 terminator. The 5' and 3' nucleotides of the PaV cDNAs were
positioned precisely at the sites of transcriptional initiation and
ribozyme-mediated cleavage, respectively, in order to achieve
transcription of RNAs which, following autocatalytic cleavage by the
HDV ribozyme, had no additional nucleotides at either terminus. To
construct a convenient version of the transcription vector which
provided cohesive ends for the insertion of the cDNAs, Pfu
DNA polymerase was used to amplify transcription vector (2,0) (38) as a template using primers VBbsI-T7
(5'-ATCGAATTCGAAGACATTATAGTGAGTCGTCGTATTATTTCGC-3') and VBbsI-Rz
(5'-ATCCTCGAGGAAGACCCGGGTCGGCATGGCATC-3'). The nucleotides in bold type anneal to the last 26 nt of the T7 promoter and first 16 nt of the HDV ribozyme sequence, respectively. In
each case, these are preceded by an italicized sequence that corresponds to the recognition site for the remote cutting restriction enzyme BbsI, which cleaves double-stranded DNA to leave a
4-nt cohesive end (underlined). The primers also contained cleavage sites for either EcoRI or XhoI and half of an
EcoRV site. Following circularization of the PCR product by
blunt-end self-ligation and transformation into E. coli
DH5, plasmid TVT7R(0,0) (Fig. 1) was
isolated. It was sequenced from the T7 promoter to the T7 terminator to
confirm the insertion of the new sequences. Digestion of this plasmid
with BbsI left cohesive termini that corresponded to the
last 4 nt of the T7 promoter and the first 4 nt of the HDV ribozyme.
View larger version (22K):
[in this window]
[in a new window]
|
FIG. 1.
Schematic representation of the transcription plasmid
TVT7R(0,0). (A) DNA sequence of the region encompassing the T7 promoter
(underlined), transcription start site, and site of RNA cleavage (both
indicated with arrowheads). The BbsI recognition sequences
are shown in italics, and the nucleotides that remain following
excision of the short stuffer fragment by BbsI digestion are
shown in bold. Positions of the HDV antigenomic ribozyme (Rz)
and T7 terminator sequences are shown. (B) Positioning of PaV cDNAs in
the transcription plasmid.
|
|
First-strand cDNA copies of RNA1 and RNA2 were synthesized at 50°C
using Superscript II RT (Gibco/BRL), PaV virion RNA as the template,
and oligonucleotide primers that annealed to the 3' ends of the RNAs:
RNA1
(5'-GCTCTAGACGTCTCTACCCGGCCGTGCGTTGGGATTTAC-3') and RNA2
(5'-GC TCTAGACGTCTCTACCCGGCCATGGTTGTTTCTTTTATG-3'). These oligonucleotides
were complementary to 3'-end sequences of the PaV RNA1 and RNA2 (shown
in bold) and included recognition sequences for the remote cutting
restriction enzyme BsmBI (italicized, with the cohesive end
nucleotides underlined) and XbaI to facilitate cloning. The
single-stranded cDNAs were used as templates for PCR using the above
oligonucleotides and the following second primers: RNA1
(5'-GGGGTACCCGTCTCATATAATGTTGTAGTACGAAAGTACC-3') and RNA2
(5'-GGGGTACCCGTCTCATATAATGTACAGGTATAACATCAAAGATG-3'). These sequences corresponded to the 5' ends of RNA1 and RNA2
(shown in bold) next to the recognition sequences for BsmBI
(italicized, with the cohesive end nucleotides underlined) and
KpnI to facilitate cloning. PCR fragments that corresponded
to full-length cDNAs of each RNA were gel purified, digested with
BsmBI, and ligated into TVT7R vector that had been digested
with BbsI. This strategy created the desired
promoter-cDNA-ribozyme junction sequences shown in Fig. 1.
Sequence analysis.
Nucleotide sequences were assembled and
analyzed using the University of Wisconsin Genetics Computer Group
(GCG) programs (16). Other sequences were retrieved from the
nonredundant nucleotide database of GCG and analyzed using BLAST
(1). Amino acid sequences were aligned using PILEUP.
SDS-PAGE.
Proteins were labeled with
[35S]methionine-cysteine, and cytoplasmic extracts were
harvested as described previously (2). Sodium dodecyl
sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) was performed by
standard techniques (31).
MALDI-TOF (matrix-assisted laser desorption
ionization-time-of-flight) mass spectrometry.
Samples were
analyzed in the positive mode on a Voyager Elite mass spectrometer with
delayed extraction technology (PerSeptive Biosystems, Framingham,
Mass.). The acceleration voltage was set at 20 kV, and 10 to 50 laser
shots were summed. Sinapinic acid (D13,460-0; Aldrich) dissolved in
acetonitrile-0.1% trifluoroacetic acid (1:1) was used as the matrix.
Virus samples (0.8 to 7.0 µg/µl) were diluted 1:10 with matrix, and
1 µl was pipetted onto a smooth plate.
Nucleotide sequence accession numbers.
The nucleotide
sequences of PaV RNA1 and RNA2 were submitted to the GenBank database
and assigned accession no. AF171942 and AF171943, respectively.
| |
RESULTS |
Replication of PaV in insects and in tissue culture cells.
PaV
was initially purified from larvae of S. eridania (southern
armyworm) collected near Pariacoto, Ancash province, Peru (46). To characterize the virus further, it was necessary to find a convenient system for the growth of PaV in the laboratory. Many
of the alphanodaviruses grow well in larvae of G. mellonella (6), and so we tested the ability of PaV to infect these
larvae. Following injection of virus into the hemocoel, the larvae
became inactive, flaccid, and stunted in growth compared to
uninoculated control insects, and some mortality was observed.
Virus was purified from groups of PaV-infected larvae, and the RNA and
protein contents of the purified virus were analyzed. The virion RNAs
were resolved by electrophoresis under denaturing conditions on an
agarose gel alongside molecular size standards (0.24- to 9.5-kb RNA
marker; Gibco/BRL) and visualized by staining with ethidium bromide
(Fig. 2A). Two RNAs with estimated sizes of 3 and 1.4 kb were observed and designated RNA1 and RNA2,
respectively, by analogy with other nodaviruses. PaV virions were
analyzed by SDS-PAGE, and one major and one minor protein band, with
estimated sizes of 39 and 42 kDa, respectively, were detected by
Coomassie blue staining (data not shown). These results are similar to
those observed previously for PaV purified from S. eridania by Zeddam et al. (46); however, in that
publication the RNA markers were erroneously labeled in the figure
(J. L. Zeddam, personal communication).
View larger version (73K):
[in this window]
[in a new window]
|
FIG. 2.
PaV RNAs and replication in BHK-21 cells. (A) RNAs
extracted from purified PaV and FHV virions were resolved by
electrophoresis in a 1% agarose-formaldehyde gel along with RNA
markers (Gibco/BRL) and visualized by ethidium bromide staining. Sizes
of the RNA markers are indicated on the left. (B) BHK-21 cells were
transfected with 1 µg of PaV virion RNA or with 0.5 µg of FHV
virion RNA and incubated at 28°C. After 22 h of incubation,
actinomycin D was added at 5 µg/ml; 30 min later, replicating RNAs
were metabolically labeled by incorporation of
[3H]uridine for a period of 2 h before total
cellular RNA was harvested. RNAs were resolved by electrophoresis on a
1% agarose-formaldehyde gel and visualized by fluorography. (C) The
PaV lane of the autoradiogram in panel B was overexposed so that PaV
RNA3 could be visualized. PaV RNA1, RNA2, and RNA3 are identified on
the right, as are two additional minor RNAs, bands a and b.
|
|
We used PaV grown in G. mellanella larvae to attempt
infection of insect cell lines from D. melanogaster (lines
DL1 and DL2) and from S. frugiperda (Sf9 cells). In no case
were viral RNAs metabolically labeled with [3H]uridine
24 h postinfection, even at MOIs of up to 104
particles per cell (data not shown). Furthermore, no RNA replication was detected following transfection of DL2 or Sf9 cells either with
purified PaV virions (22) or with naked PaV RNA using four different lipid carriers: Cellfectin, Lipofectin, Lipofectamine, and
DMRIE-C (Gibco/BRL) (data not shown). However, when four mammalian cell
lines (BHK-21, Vero, BSC40, and HEp-2) were transfected with PaV RNAs
using the same four lipid reagents, some replication of the viral RNAs
was detected. The most abundant signal was seen in BHK-21 cells
transfected with RNA using Lipofectamine. A very low level of PaV RNA
replication was observed in Vero, BSC40, and HEp-2 cells (data not shown).
BHK-21 cells were transfected with PaV virion RNA1 and -2 and labeled
24 h posttransfection by metabolic incorporation of [3H]uridine in the presence of actinomycin D. Two major
and three minor RNA species were labeled under these conditions (Fig.
2B and C); the two major species comigrated with virion RNAs and ran
slightly faster than RNA1 and -2 of FHV when analyzed on 1% agarose-formaldehyde gels (Fig. 2B). The smallest labeled RNA species
(Fig. 2C) resembled the subgenomic RNA3 of FHV and was not
detected in virions. It was therefore a good candidate for a
subgenomic PaV RNA and was designated RNA3 accordingly. Two additional minor RNA species were visualized on longer exposures of the
RNAs labeled in transfected cells (bands a and b in Fig. 2C). These
RNAs have the mobilities expected for dimers of RNA1 (band a) and RNA2
(band b), and similar species have been observed during replication of
FHV and NoV RNAs (2, 3). Despite the ability of PaV RNA to
replicate in BHK-21 cells, no RNA replication was observed when BHK-21
cells were exposed to intact virus, even at MOIs of up to 7,000 virions
per cell. In contrast to results previously reported for virions of FHV
and NoV (22), no RNA replication was detected in BHK-21
cells transfected with intact PaV virions. Nevertheless, transfection
of PaV RNAs into BHK-21 cells provided a system in which to examine RNA
replication and a convenient source of replication intermediates.
Sequence determination of PaV RNAs and their termini.
The
sequences of the two genomic RNAs were originally reconstructed
from two families of overlapping cDNA clones. Initial sequence
information was obtained from randomly primed cDNA clones, and gaps in
the sequence were filled from clones generated by RT-PCR using
PaV-specific primers. About 95% of the PaV genomic sequences
were determined in this way, but it seemed unlikely that any of the
clones contained the complete 5' or 3' termini of the genomic RNAs.
The 5' termini of the two genomic RNAs were determined by
examining clones generated by 5' RACE. Virion RNA was used as the template for 5' RACE using oligonucleotide primers specific for either
RNA1 or RNA2. For each RNA, a single major PCR product was synthesized;
these amplification products were cloned into plasmid vectors, and the
sequences of four clones from each RNA were determined (Fig.
3). The sequences of all four RNA1 5'
RACE clones began with GnAUGUU. Three of the
RNA2 5' RACE clones began with the sequence
GnAUGUA, and the fourth began with the sequence
GnUGAUGUA. 5' RACE, which involves adding a
poly(C) tail to the product of first-strand cDNA synthesis, allows
recovery of the exact 5' end of an RNA molecule, but the method can
leave some ambiguity at the junction between the 5'-terminal nucleotide
of the RNA and the first residue of the homopolymeric tail. Therefore,
the products of primer extension of PaV-specific oligonucleotides on
virion RNAs were analyzed to map their 5' termini (Fig.
4). For each RNA, we identified two
primer extension products which differed in size by one nucleotide, the
larger bands being more intense than the smaller. The primer
extension products were sized by comparison with ladders generated
using the same primer to sequence the corresponding 5' RACE
cDNA clone. For RNA1, the smaller band corresponded to an RNA terminus
initiating 5'-AUGUU...-3'; for RNA2, the smaller band corresponded
to the terminal sequence 5'-AUGUA...-3'. Assuming that PaV RNAs are
capped, like those of other nodaviruses (11, 13, 28), the
larger, more intense primer extension products most likely correspond
to the capped versions of these sequences. The 5' terminus of
subgenomic RNA3 was also determined by primer extension
(Fig. 4). Again, we detected two primer extension products differing in
size by one nucleotide which indicated that the terminus of RNA3 lies at nt 2598 of RNA1 and begins with the capped sequence
5'-GUGUU...-3'.
View larger version (31K):
[in this window]
[in a new window]
|
FIG. 3.
Sequences of the 5' and 3' termini of PaV RNA1 and RNA2.
The consensus sequences of the termini of PaV RNA1 and RNA2 were
compiled using three independent methods, and the sequences generated
by each method are shown. The homodimer junction sequences have been
separated into their corresponding 5' and 3' termini for clarity of
presentation. In each case, the number of clones (x) having
the particular sequence out of the total number of clones examined
(y) is expressed as x/y in the far right column.
The consensus terminal sequences derived from the tabulated data are
shown in bold for each RNA. The termini of the primer extension
products corresponded to the nucleotides indicated by the arrowheads.
We attribute the larger products to extension on capped RNAs.
|
|
View larger version (36K):
[in this window]
[in a new window]
|
FIG. 4.
Analysis of the 5' termini of genomic RNA1 and
RNA2 and subgenomic RNA3 by primer extension. (A and B)
RNAs extracted from PaV virions were used as templates for extension of
primers designed to anneal to nt 76 to 98 of RNA1 (A, lane P) and 98 to
119 of RNA2 (B, lane P). Dideoxynucleotide sequencing ladders of
plasmids containing 5' RACE products of RNA1 and RNA2 were generated
using the same two primers and are shown for reference. (C) BHK-21
cells were transfected with 1 µg of PaV virion RNA (lane P) or mock
transfected (lane M) and incubated at 28°C. After 24 h of
incubation, total cellular RNA was harvested and used as a template for
extension of a primer designed to anneal to nt 2692 to 2712 of RNA1. A
dideoxynucleotide sequencing ladder generated using the same primer and
plasmid pPaV1(0,0) is shown for reference. For simplicity, in all
panels the individual lanes of the sequencing ladders are labeled with
the complement of the terminating dideoxynucleotide.
|
|
As with other nodaviruses (11, 13, 21, 28), attempts to
polyadenylate PaV genomic RNAs in vitro were unsuccessful (C. Albarino and L. A. Ball, unpublished data), and so the sequences of the 3' ends of the virion RNAs were inferred from the 5'-terminal sequences of the respective negative-strand RNAs. Oligonucleotides complementary to the negative strand of either RNA1 or RNA2 were used
to prime cDNA synthesis for 5' RACE. In the case of RNA1, the
oligonucleotide used for first-strand cDNA synthesis was designed so
that it annealed outside the region encoding RNA3. In both cases, the
template was total RNA extracted from BHK-21 cells 24 h after
transfection with PaV virion RNAs. The sequences of four
negative-strand RNA1 5' RACE clones were examined, and the results are
expressed in terms of the sequence of the 3' end of the positive
strand (Fig. 3). Three of the cDNA clones yielded the positive-strand
RNA1 terminal sequence as
5'-...CACGGCn-3', and the fourth
yielded 5'...CACGGCACn-3'. The
three 5' RACE clones from negative-strand RNA2 that were examined all
gave the positive-strand RNA2 terminal sequence as
5'-...CAUGGCn-3' (Fig. 3).
Because the junctions between the templated cDNAs and the nontemplated
poly(C) tails were indeterminate in these clones, we next examined the
putative RNA dimers seen during PaV RNA replication (Fig. 2). In
previous work with FHV and NoV, we detected homodimers of RNA1 and -2 during RNA replication and found that at least some of these molecules
contained head-to-tail junctions that comprised perfectly juxtaposed
termini (references 2 and 3; L. A. Ball, unpublished data). Using as template total cellular RNA
extracted from BHK-21 cells that had been transfected 24 h earlier
with PaV virion RNA, we primed cDNA synthesis with specific negative-sense oligonucleotides that annealed toward the 5' terminus of
the positive strand of PaV RNA1 or RNA2. The resulting first-strand cDNAs were then used as templates for PCR with positive-sense primers
designed to amplify a DNA fragment that spanned the junction between the two adjacent RNA copies. We observed PCR products of the
expected size to have been templated by positive-sense RNA1
dimers and by both positive- and negative-sense RNA2 dimers (data not shown).
The junction PCR fragments were cloned, and the terminal RNA sequences
derived from 12 clones of RNA1 are shown in Fig. 3. For clarity of
presentation, we have separated the sequence of the dimer at the
inferred junction and portrayed its 5' and 3' components as the termini
of monomeric positive-strand RNA1. In 11 of the 12 clones, the
sequences flanking the inferred 3'-5' junction were identical to those
previously found for the 3'- and 5'-terminal regions of RNA1.
Similarly, the junction sequences of seven RNA2 dimer clones confirmed
the terminal sequences determined for RNA2 (Fig. 3). The one discrepant
RNA1 clone contained a single substituted residue (C to G) at the
junction. Of the 18 junction clones (11 for RNA1 and 7 for RNA2) that
confirmed the 5' RACE results, the junction sequences were divided
equally into two classes that differed by one nucleotide. One class
predicted that the 3' end of each RNA terminated with a single C
residue (i.e., 5'-...GGC-3'), whereas the other class predicted two
C residues at the termini (i.e., 5'-...GGCC-3'). Both junction
sequences were consistent with the results of 5' RACE from
negative-strand RNA1 and RNA2 (i.e.,
5'-...GGCn-3'). For construction of
full-length cDNAs, the 3'-terminal sequence 5'-...GGCC-3' was used
for both RNAs.
Construction and functionality of full-length cDNA clones.
Full-length cDNAs were synthesized using primers that annealed to the
termini of PaV RNA1 and -2 and ligated into the transcription vector
TVT7R(0,0) as described in Materials and Methods. In each case,
plasmids were constructed so that RNA transcripts made by T7 RNA
polymerase would, when cleaved by the HDV ribozyme, have termini that
corresponded to those determined for the PaV genomic RNAs. The
resulting plasmids were named pPaV1(0,0) and pPaV2(0,0) for RNA1 and
RNA2 cDNAs, respectively, the numbers in parentheses reflecting the
absence of terminal extensions on the DNA-templated, ribozyme-cleaved transcripts.
To test whether the full-length cDNA clones were functional, plasmids
pPaV1(0,0) and pPaV2(0,0) were transfected into BHK-21 cells that were
infected with the vaccinia virus recombinant vTF7-3, and 22 h
later the products of RNA replication were labeled by metabolic
incorporation of [3H]uridine for 4 h in the
presence of actinomycin D. Total cellular RNA was extracted, resolved
by electrophoresis on an agarose-formaldehyde gel, and visualized by
fluorography (Fig. 5A). In cells
transfected with pPaV1(0,0) alone (Fig. 5A, lane 1), RNAs corresponding
in size to authentic PaV RNA1 and -3 (Fig. 5A, lane 3) were labeled, indicating that pPaV1(0,0) encoded active PaV RNA replicase which catalyzed autonomous RNA1 replication and RNA3 synthesis. Cells cotransfected with pPaV1(0,0) and pPaV2(0,0) supported replication of
both RNA1 and RNA2, indicating that pPaV2(0,0) encoded a replicable copy of RNA2 (Fig. 5A, lane 2). As expected, no replication of RNA2 was
observed when cells were transfected with pPaV2(0,0) alone (data not
shown). As observed with other nodaviruses, the presence of replicating
RNA2 down-regulated the synthesis of RNA3 (6).
View larger version (66K):
[in this window]
[in a new window]
|
FIG. 5.
Replication of RNAs and synthesis of viral proteins in
cells transfected with PaV cDNA clones. (A) BHK-21 cells were infected
with vTF7-3 at an MOI of 10 PFU/cell. One hour postinfection, the cells
were transfected with 5 µg of pPaV1(0,0) (lane 1), 2.5 µg each
of pPaV1(0,0) and pPaV2(0,0) (lane 2) or 1 µg of PaV virion RNA
(lane 3) and incubated at 28°C. After 22 h of incubation,
actinomycin D was added at 5 µg/ml; 30 min later, replicating RNAs
were metabolically labeled by incorporation of
[3H]uridine (20 µCi/ml) for 4 h before total
cellular RNA was harvested. RNAs were resolved by electrophoresis on a
1% agarose-formaldehyde gel and visualized by fluorography. PaV RNA1,
RNA2, and RNA3 are identified on the left. (B) BHK-21 cells were
infected with vTF7-3 at an MOI of 10 PFU/cell. One hour postinfection,
the cells were transfected with water (lane 1), 1 µg of PaV virion
RNA (lane 2), or 2.5 µg each of pPaV1(0,0) and pPaV2(0,0) (lane
3) and incubated at 28°C. After 44 h of incubation, actinomycin
D was added at 5 µg/ml and incubation continued. Following a 0.5-h
preincubation in methionine-cysteine-free medium, 48 h
posttransfection proteins were labeled with
[35S]methionine-cysteine for a period of 2 h.
Cytoplasmic extracts were harvested and resolved by SDS-PAGE on a
12.5% gel, and the labeled proteins were visualized by
autoradiography. PaV proteins A and are identified on the right.
|
|
To determine whether the RNA2 encoded by pPaV2(0,0) could direct the
synthesis of PaV capsid protein, BHK-21 cells infected with vTF7-3 were
cotransfected with pPaV1(0,0) and pPaV2(0,0). Forty-eight hours later,
proteins were labeled with [35S]methionine-cysteine,
cytoplasmic extracts were resolved by SDS-PAGE, and the labeled
proteins were visualized by autoradiography (Fig. 5B). Proteins of the
sizes expected for both protein A and were labeled in cells
transfected with virion RNA (Fig. 5B, lane 2), and the band
corresponding to protein was also observed in extracts of cells
transfected with pPaV1(0,0) and pPaV2(0,0) (Fig. 5B, lane 3). These
results established that plasmids pPaV1(0,0) and pPaV2(0,0) were
functional and could be used to reconstruct PaV RNA replication in
BHK-21 cells.
Sequences of functional cDNA clones.
As described above, these
plasmids successfully initiated PaV RNA replication in transfected
cells; therefore, both strands of both viral cDNAs were fully sequenced
to establish definitive, functional, nucleotide sequences of the two
viral genome segments. Every nucleotide was sequenced at least four
times from at least two independent cDNA clones, one of which was
either pPaV1(0,0) or pPaV2(0,0). The sequence of pPaV2(0,0) was
identical to that compiled from the overlapping cDNA clones, whereas
the sequence of pPaV1(0,0) differed from the preliminary sequence
by one nucleotide: position 1724 was T in pPaV1(0,0) and C in the
preliminary sequence. The pPaV1(0,0) sequence encodes Phe at
position 568 in protein A rather than Leu, and since this protein was
found to be functional, this was the sequence submitted to GenBank and
used here for further analysis.
Analysis of PaV genomic sequences.
The organization of
the PaV genome revealed by these sequences resembles that of other
alphanodaviruses (Fig. 6). The larger genome segment RNA1 is 3,011 nt in length and encodes two overlapping open reading frames (ORFs) flanked by 5' and 3' untranslated regions of
22 and 69 nt, respectively. The larger ORF starts at the first AUG
codon of RNA1 (nt 23 to 25) and terminates at nt 2941. A smaller ORF is
found in the 3' region of the RNA and extends from nt 2622 to 2891. The
larger ORF encodes a 973-amino-acid protein with a calculated size of
108 kDa which contains a GDD sequence and other motifs characteristic
of viral RdRps (29). The deduced translation of this ORF
also shares 26% sequence identity with protein A of FHV. The smaller
ORF encodes a 90-amino-acid protein with a calculated size of 10.3 kDa.
This small protein shares 26% sequence identity with FHV B2 and is
encoded in an analogous position in the PaV genome, within the sequence
of subgenomic RNA3. By analogy with the other
alphanodaviruses, the two proteins encoded by PaV RNA1 have been
designated proteins A and B2. The RNA1 sequences of FHV and BBV also
encode a second small ORF on RNA3 that directs the synthesis of a
protein called B1 which corresponds to the C-terminal region of protein
A (13). A similar ORF was identified in PaV RNA3, but in
contrast to FHV and BBV, its AUG lies downstream of that for the B2
ORF, 60 nt from the 5' end of the RNA3. The smaller genomic RNA
segment, RNA2, contains 1,311 nt and encodes a single large ORF that
encompasses nt 23 to 1225, flanked by 5' and 3' untranslated regions of
22 and 86 nt, respectively. Comparisons with other alphanodaviruses
indicate that the RNA2 ORF encodes protein , the precursor to the
viral capsid proteins; it contains 401 amino acids and has a calculated
size of 43.3 kDa.
View larger version (11K):
[in this window]
[in a new window]
|
FIG. 6.
Schematic representation of the arrangement of the ORFs
encoded by the PaV genomic RNA1 and RNA2. The horizontal lines
represent the RNAs, with vertical lines above and below the RNA
indicating positions of methionine codons and termination codons,
respectively. For each RNA, the three frames on the
positive-sense RNA are shown. The 5' end of the
subgenomic RNA3 is indicated by the dotted vertical line.
Bold arrows indicate the four major ORFs which are predicted to
encode protein A (RdRp catalytic subunit), protein B1, protein B2, and
capsid precursor protein (1 to 4, respectively). The scale
indicates length of RNAs in nucleotides.
|
|
Comparison of PaV proteins with those of other viruses.
The
amino acid sequence of PaV protein A contains the core motifs defined
for RdRps including the characteristic GDD box. PaV protein A is 25 amino acids shorter than the homologous FHV protein, with which it
shares 26% amino acid identity (35% similarity). Pairwise alignment
of the PaV and FHV B2 proteins show that they also share 26% sequence
identity. Further analysis of the sequences of RNA1, protein A, and
protein B2 will be reported elsewhere.
The amino acid sequence of the PaV capsid protein was
compared with the other available alphanodavirus sequences
those of NoV (AF174534), FHV (X15959), BBV (X00956), and BoV (X15960) (references 11 and 12; K. L. Johnson and L. A. Ball, unpublished data)in a pairwise
manner using the program GAP (16). This analysis showed that
PaV is the most distantly related of the alphanodaviruses and shares
the following levels of protein sequence identity with the other
viruses in this genus: BBV, 40%; FHV, 41%; NoV, 39%; and BoV, 38%.
These protein sequences were aligned with that of PaV (Fig.
7) by using the program PILEUP. We
included in the analysis the capsid protein sequences of two betanodaviruses (Dicentrarchus labrax encephalitis
virus [U39876] and Striped jack nervous necrosis
virus [D30814] [15, 37]), but they shared less
than 20% identical amino acids with each of the alphanodaviruses and
are not shown in Fig. 7. The data in Fig.
8 summarize the extent of relatedness of
the proteins of all the alphanodaviruses and show that PaV is the
most distant.
View larger version (127K):
[in this window]
[in a new window]
|
FIG. 7.
Alignment of amino acid sequences of capsid protein
precursors from all available alphanodaviruses, generated using the
GCG program PILEUP. The number of amino acids from the N terminus of
protein is shown at the left. Amino acids that are conserved in
three or more of the viruses are shaded. The site of cleavage of the
capsid protein precursor into the two mature capsid proteins and is indicated with an arrow below the alignment. The conserved
catalytic Asp residue (75 for FHV) is indicated with an asterisk. Above
the alignment, the secondary structural elements as determined from the
crystal structure of BBV and labeled according to Johnson and Reddy
(25) are indicated as follows: arrows, regions of sheet;
solid lines, regions of helix; dotted lines; other regions of
peptide that are visible in the BBV crystal structure.
|
|
View larger version (14K):
[in this window]
[in a new window]
|
FIG. 8.
Genotypic relationships among the capsid protein
precursors of five alphanodaviruses. (A) Phenogram produced based on
the distance matrix generated from the alignment shown in Fig. 7; (B)
percent amino acid identity among protein of the five viruses.
|
|
The amount of conservation varies along the length of the alignment of
the capsid protein sequences, and much but not all of this variation
correlates with the placement of the region of the polypeptide chain
within the capsid structure. The positions of the secondary structural
elements identified from the well-defined BBV crystal structure
(23-25, 28) are shown in Fig. 7. The 50 N-terminal residues
show only a low level of conservation in aligned residues. However, all
five sequences contain a very high percentage of basic residues (28%
for PaV); since much of this region of the protein lies within the
interior of the capsid, it has previously been suggested that these
residues interact with the phosphate backbone of the encapsidated RNA
(28). The next 40 residues (56 to 90 for BBV) are highly
conserved among the viruses and are located on the interior of the
capsid shell. Several regions which are found toward the outside of the
capsid are less well conserved, including the regions encompassing the
antiparallel sheets C'/C" and E'/E", and also a loop region from
residues 247 to 292 (BBV).
Another interesting feature of the capsid protein alignment involves
the site at which the capsid protein precursor is cleaved during
virion maturation to form the two mature capsid proteins, and (20) (Fig. 7). The cleavage site Asn/Ala, which is conserved in all other alphanodaviruses, aligns unambiguously to an Asn-Ser dipeptide (residues 361 and 362) in PaV. In fact, the dipeptide Asn-Ala
does not occur anywhere in the PaV capsid protein, which suggests that
if the PaV protein is cleaved, cleavage must occur at a novel sequence.
Asp 68 of PaV aligns in a region of high sequence conservation with
Asp 75 of FHV (Fig. 7), which catalyzes the autoproteolytic
cleavage reaction in FHV virions (47).
Detection of protein .
Candidates for both capsid precursor
and the mature protein were resolved by SDS-PAGE analysis of
PaV virion proteins (data not shown), and conservation of the catalytic
Asp residue suggested that PaV protein may be cleaved into the
mature capsid proteins and . However, PaV protein was not
detected in purified virions on SDS-polyacrylamide gels even under
conditions of gel analysis where the proteins of FHV and NoV could
be readily visualized (data not shown).
We therefore sought an alternative method to investigate the existence
of protein in PaV virions. Since the protein in FHV virions can
be detected using mass spectrometry (9), we applied
MALDI-TOF mass spectrometry to intact sucrose gradient-purified PaV
virions to see if we could detect protein . The spectrum of PaV in
Fig. 9 shows a clear peak of
Mr 4,246. The 40-amino-acid peptide which would
be liberated following cleavage of protein between Asn 361 and Ser
362 has a calculated Mr of 4,244. Similar analyses of purified FHV and NoV showed peptides with
Mrs of 4,397 for FHV (calculated, 4,396) and
4,587 for NoV (calculated, 4,584) (Fig. 9), confirming the reliability
of this method for the analysis of nodavirus peptides in general.
These results showed not only that PaV protein was cleaved, but
that it was cleaved between Asn 361 and Ser 362, a novel cleavage site
sequence for nodavirus capsid maturation.
View larger version (18K):
[in this window]
[in a new window]
|
FIG. 9.
MALDI-TOF spectrum of protein . Whole virus particles
were analyzed by MALDI-TOF mass spectrometry. The part of the spectrum
which contains protein is shown for three nodaviruses: PaV, FHV,
and NoV. In each case, the molecular mass of the peak is
indicated.
|
|
| |
DISCUSSION |
The results presented above confirmed the placement of PaV in the
Alphanodavirus genus of the Nodaviridae family
and revealed several interesting features of the viral genome.
Comparison of the capsid protein sequence with those of other
nodaviruses indicated that PaV is the most distantly related member of
the Alphanodavirus genus, which contains the nodaviruses of
insects. This is consistent with PaV being the first alphanodavirus to
be isolated outside the Australasian region. The sequence divergence
extends even as far as the cleavage site of the capsid protein
precursor, which is Asn/Ala for all other alphanodaviruses but Asn/Ser
for PaV. Cleavage at this site was confirmed using mass spectrometry,
which proved to be an easy and reliable method for detecting the small protein from intact nodavirus particles. Despite the novel cleavage sequence, the catalytic Asp residue was conserved at position 68 of PaV
protein , suggesting that the cleavage mechanism may also be
conserved (47). Analysis of the crystal structure of PaV
capsids will provide further insight into this issue.
Full-length cDNA clones of both genomic segments were
constructed and used to recreate PaV RNA replication in BHK-21 cells. For this purpose, we developed the new generic T7 transcription plasmid
TVT7R(0,0), which readily accommodated cDNAs such that the
corresponding T7 transcripts contained no terminal extensions (Fig. 1).
This was advantageous because extraneous terminal nucleotides interfere
with the replication of other nodaviral RNAs (3, 4, 7).
Transcription of the full-length PaV clones in BHK-21 cells led to the
replication of RNA1 and RNA2, synthesis of the subgenomic
RNA3, and translation of proteins A and (Fig. 5). As with other
nodaviruses (4, 19), RNA1 encodes protein A, the likely
catalytic subunit of the viral RdRp. PaV RNA1 transcribed from the cDNA
clone replicated autonomously and supported the replication of RNA2
transcripts in trans (Fig. 5), establishing that both cDNA
clones were functional for RNA replication. A detailed comparative
analysis of the sequences and structures of RNA1 and protein A from six
nodavirus species will be presented elsewhere (Johnson et al.,
unpublished data).
Although RNA-dependent replication of PaV RNAs was observed following
transfection of BHK-21 cells with clones of RNA1 and RNA2, the level of
replication was significantly lower than that observed with FHV cDNA
clones. It remains to be determined whether this is because BHK-21
cells provide a suboptimal environment or whether vaccinia virus
coinfection interferes with PaV RNA replication. Another possibility is
that the second C residue at the 3' termini of the synthetic
transcripts may interfere with optimal RNA replication. We are
currently screening several cell lines in an attempt to identify one
which is susceptible to infection with PaV and able to support more
robust RNA replication.
Since the 3' ends of nodavirus RNAs are not polyadenylated (35,
42) or reactive with poly(A) polymerase or RNA ligase (11,
13, 21, 28), determination of their extreme 3'-terminal sequences
is not straightforward. However, previous work in this laboratory has
shown that head-to-tail homodimers of RNA1 and -2 accumulate to low
levels during replication of FHV and NoV RNAs in cell culture (2,
8), and these molecules provide an accessible source of
information about the sequences at both termini of the monomeric RNAs.
Since PaV also produced homodimers of both RNAs during replication, we
determined the sequences across the head-to-tail junctions and combined
the results with those generated by 5' RACE on strands of both
polarities. This approach yielded unambiguous sequences for the termini
of each RNA molecule and suggested that the replicating RNA population
might show microheterogeneity in having one or two 3'-terminal C
residues. The origin of this microheterogeneity is unclear at present,
as is the function of the RNA dimers themselves, but their presence
during replication of three diverse alphanodaviruses suggests that
dimeric RNAs may be a general feature of nodaviral RNA replication.
We have described the molecular characterization of PaV, the first
Alphanodavirus to be isolated from outside Australasia. In
accordance with its geographic origin, PaV's genome sequence reveals
it to be the most distantly related of the known alphanodaviruses; as
such, it has several features worthy of further investigation. The
functional cDNA clones of the two viral genomic segments have served both to confirm the sequences of functional PaV RNAs and to
provide us with an experimental system that will be the basis of future
research on the biology of this novel nodavirus.
| |
ACKNOWLEDGMENTS |
We thank Cesar Albarino for testing whether PaV virion RNAs
could be polyadenylated, Sean Whelan for advice on the strategy for constructing vector TVT7R(0,0), UAB Microbiology
Department core DNA sequencing facility, and Lori Coward for conducting
the MALDI-TOF analyses.
The mass spectrometer was purchased with funds from an NIH Shared
Instrumentation Grant (S10 RR11329) and from a Howard Hughes Medical
Institute infrastructure support grant to UAB. Its operation was
supported in part by an NCI Core Research Support Grant to the
Comprehensive Cancer Center (P30 CA13148-27). This work was supported
by NIH grant AI18270.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Microbiology, University of Alabama at Birmingham, BBRB 373/17, 845 19th St. South, Birmingham, AL 35294-2170. Phone: (205) 934-0864. Fax: (205) 934-1636. E-mail: AndyB{at}uab.edu.
| |
REFERENCES |
| 1.
|
Altschul, S. F.,
W. Gish,
W. Miller,
E. W. Myers, and D. J. Lipman.
1990.
Basic local alignment search tool.
J. Mol. Biol.
215:403-410[CrossRef][Medline].
|
| 2.
|
Ball, L. A.
1992.
Cellular expression of a functional nodavirus RNA replicon from vaccinia virus vectors.
J. Virol.
66:2335-2345[Abstract/Free Full Text].
|
| 3.
|
Ball, L. A.
1994.
Replication of the genomic RNA of a positive-strand RNA animal virus from negative-sense transcripts.
Proc. Natl. Acad. Sci. USA
91:12443-12447[Abstract/Free Full Text].
|
| 4.
|
Ball, L. A.
1995.
Requirements for the self-directed replication of flock house virus RNA 1.
J. Virol.
69:720-727[Abstract].
|
| 5.
|
Ball, L. A.,
J. M. Amann, and B. K. Garrett.
1992.
Replication of nodamura virus after transfection of viral RNA into mammalian cells in culture.
J. Virol.
66:2326-2334[Abstract/Free Full Text].
|
| 6.
|
Ball, L. A., and K. L. Johnson.
1998.
Nodaviruses of insects, p. 225-267.
In
L. K. Miller, and L. A. Ball (ed.), The insect viruses. Plenum Publishing Corporation, New York, N.Y.
|
| 7.
|
Ball, L. A., and Y. Li.
1993.
cis-acting requirements for the replication of flock house virus RNA2.
J. Virol.
67:3544-3551[Abstract/Free Full Text].
|
| 8.
|
Ball, L. A.,
B. Wohlrab, and Y. Li.
1994.
Nodavirus RNA replication: mechanism and harnessing to vaccinia virus recombinants.
Arch. Virol. Suppl.
9:407-416[Medline].
|
| 9.
|
Bothner, B.,
X. F. Dong,
L. Bibbs,
J. E. Johnson, and G. Siuzdak.
1998.
Evidence of viral capsid dynamics using limited proteolysis and mass spectrometry.
J. Biol. Chem.
273:673-676[Abstract/Free Full Text].
|
| 10.
|
Chomczynski, P., and N. Sacchi.
1987.
Single-step method of RNA isolation by acid guanidinium thiocyanate-phenol-chloroform extraction.
Anal. Biochem.
162:156-159[Medline].
|
| 11.
|
Dasgupta, R.,
A. Ghosh,
B. Dasmahapatra,
L. A. Guarino, and P. Kaesberg.
1984.
Primary and secondary structure of black beetle virus RNA2, the genomic messenger for BBV coat protein precursor.
Nucleic Acids Res.
12:7215-7223[Abstract/Free Full Text].
|
| 12.
|
Dasgupta, R., and J.-Y. Sgro.
1989.
Nucleotide sequences of three nodavirus RNA's: the messengers for their coat protein precursors.
Nucleic Acids Res.
17:7525-7526[Free Full Text].
|
| 13.
|
Dasmahapatra, B.,
R. Dasgupta,
A. Ghosh, and P. Kaesberg.
1985.
Structure of the black beetle virus genome and its functional implications.
J. Mol. Biol.
182:183-189[CrossRef][Medline].
|
| 14.
|
Dasmahapatra, B.,
R. Dasgupta,
K. Saunders,
B. Selling,
T. Gallagher, and P. Kaesberg.
1986.
Infectious RNA derived from transcription from cloned cDNA copies of the genomic RNA of an insect virus.
Proc. Natl. Acad. Sci. USA
83:63-66[Abstract/Free Full Text].
|
| 15.
|
Delsert, C.,
N. Morin, and M. Comps.
1997.
Fish nodavirus lytic cycle and semipermissive expression in mammalian and fish cell cultures.
J. Virol.
71:5673-5677[Abstract].
|
| 16.
|
Devereux, J.,
P. Haeberli, and O. Smithies.
1984.
A comprehensive set of sequence analysis programs for the VAX.
Nucleic Acids Res.
12:387-395.
|
| 17.
|
Frohman, M. A.
1990.
RACE: rapid amplification of cDNA ends, p. 28-38.
In
M. A. Innis, D. H. Gelfand, J. J. Sninsky, and T. J. White (ed.), PCR protocols: a guide to methods and applications. Academic Press, San Diego, Calif.
|
| 18.
|
Fuerst, T. R.,
E. G. Niles,
F. W. Studier, and B. Moss.
1986.
Eukaryotic transient-expression system based on recombinant vaccinia virus that synthesizes bacteriophage T7 RNA polymerase.
Proc. Natl. Acad. Sci. USA
83:8122-8126[Abstract/Free Full Text].
|
| 19.
|
Gallagher, T. M.,
P. D. Friesen, and R. R. Rueckert.
1983.
Autonomous replication and expression of RNA1 from black beetle virus.
J. Virol.
46:481-489[Abstract/Free Full Text].
|
| 20.
|
Gallagher, T. M., and R. R. Rueckert.
1988.
Assembly-dependent maturation cleavage in provirions of a small icosahedral insect ribovirus.
J. Virol.
62:3399-3406[Abstract/Free Full Text].
|
| 21.
|
Guarino, L. A.,
A. Ghosh,
B. Dasmahapatra,
R. Dasgupta, and P. Kaesberg.
1984.
Sequence of the black beetle virus subgenomic RNA and its location in the viral genome.
Virology
139:199-203[CrossRef][Medline].
|
| 22.
|
Hiscox, J. A., and L. A. Ball.
1997.
Cotranslational disassembly of flock house virus in a cell-free system.
J. Virol.
71:7974-7977[Abstract].
|
| 23.
|
Hosur, M. V.,
T. Schmidt,
R. C. Tucker,
J. E. Johnson,
T. M. Gallagher,
B. H. Selling, and R. R. Rueckert.
1987.
Structure of an insect virus at 3.0 angstrom resolution.
Protein Struct. Funct. Genet.
2:167-176.
|
| 24.
|
Hosur, M. V.,
T. Schmidt,
R. C. Tucker,
J. E. Johnson,
B. H. Selling, and R. R. Rueckert.
1984.
Black beetle virus-crystallization and particle symmetry.
Virology
133:119-127[CrossRef].
|
| 25.
|
Johnson, J. E., and V. Reddy.
1998.
Structural studies of nodaviruses and tetraviruses, p. 171-223.
In
L. K. Miller, and L. A. Ball (ed.), The insect viruses. Plenum Publishing Corporation, New York, N.Y.
|
| 26.
|
Johnson, K. L., and L. A. Ball.
1997.
Replication of flock house virus RNAs from primary transcripts made in cells by RNA polymerase II.
J. Virol.
71:3323-3327[Abstract].
|
| 27.
|
Johnson, K. N., and P. D. Christian.
1996.
A molecular taxonomy for cricket paralysis virus including two new isolates from Australian populations of Drosophila (Diptera: Drosophilidae).
Arch. Virol.
141:1509-1522[CrossRef][Medline].
|
| 28.
|
Kaesberg, P.,
R. Dasgupta,
J.-Y. Sgro,
J.-P. Wery,
B. H. Selling,
M. V. Hosur, and J. E. Johnson.
1990.
Structural homology among four nodaviruses as deduced by sequencing and X-ray crystallography.
J. Mol. Biol.
214:423-435[CrossRef][Medline].
|
| 29.
|
Koonin, E. V., and V. V. Dolja.
1993.
Evolution and taxonomy of positive-strand RNA viruses: implications of comparative analysis of amino acid sequences.
Crit. Rev. Biochem. Mol. Biol.
28:375-430[Medline].
|
| 30.
|
Krishna, N. K., and A. Schneemann.
1999.
Formation of an RNA heterodimer upon heating of nodavirus particles.
J. Virol.
73:1699-1703[Abstract/Free Full Text].
|
| 31.
|
Laemmli, U. K.
1970.
Cleavage of structural proteins during the assembly of the head of bacteriophage T4.
Nature
227:680-685[CrossRef][Medline].
|
| 32.
|
Longworth, J. F., and G. P. Carey.
1976.
A small RNA virus with a divided genome from Heteronychus arator (F.) [Coleoptera: Scarabaeidae].
J. Gen. Virol.
33:31-40[Abstract/Free Full Text].
|
| 33.
|
Murphy, F. A.,
C. M. Fauquet,
D. H. L. Bishop,
S. A. Ghabrial,
A. W. Jarvis,
G. P. Martelli,
M. A. Mayo, and M. D. Summers (ed.).
1995.
Virus taxonomy: sixth report of the International Committee on Taxonomy of Viruses.
Springer-Verlag, New York, N.Y.
|
| 34.
|
Nagai, T., and T. Nishizawa.
1999.
Sequence of the non-structural protein gene encoded by RNA 1 of striped jack nervous necrosis virus.
J. Gen. Virol.
80:3019-3022[Abstract/Free Full Text].
|
| 35.
|
Newman, J. F. E., and F. Brown.
1976.
Absence of poly(A) from the infective RNA of Nodamura virus.
J. Gen. Virol.
30:137-140[Abstract/Free Full Text].
|
| 36.
|
Nishizawa, T.,
M. Furuhashi,
T. Nagai,
T. Nakai, and K. Muroga.
1997.
Genomic classification of fish nodaviruses by molecular phylogenetic analysis of the coat protein gene.
Appl. Environ. Microbiol.
63:1633-1636[Abstract].
|
| 37.
|
Nishizawa, T.,
K.-i. Mori,
M. Furuhashi,
T. Nakai,
I. Furusawa, and K. Muroga.
1995.
Comparison of the coat protein genes of five fish nodaviruses, the causative agents of viral nervous necrosis in marine fish.
J. Gen. Virol.
76:1563-1569[Abstract/Free Full Text].
|
| 38.
|
Pattnaik, A. K.,
L. A. Ball,
A. W. LeGrone, and G. W. Wertz.
1992.
Infectious defective interfering particles of VSV from transcripts of a cDNA clone.
Cell
69:1011-1020[CrossRef][Medline].
|
| 39.
|
Price, B. D.,
R. R. Rueckert, and P. Ahlquist.
1996.
Complete replication of an animal virus and maintenance of expression vectors derived from it in Saccharomyces cerevisiae.
Proc. Natl. Acad. Sci. USA
93:9465-9470[Abstract/Free Full Text].
|
| 40.
|
Sanger, F.,
S. Nicklen, and A. R. Coulson.
1977.
DNA sequencing with chain-terminating inhibitors.
Proc. Natl. Acad. Sci. USA
74:5463-5467[Abstract/Free Full Text].
|
| 41.
|
Schneider, I.
1972.
Cell lines derived from late embryonic stages of Drosophila melanogaster.
J. Embryol. Exp. Morphol.
27:353-365[Medline].
|
| 42.
|
Scotti, P. D.,
S. Dearing, and D. W. Mossop.
1983.
Flock house virus: a nodavirus isolated from Costelytra zealandica (White) (Coleoptera: Scarabaeidae).
Arch. Virol.
75:181-189[CrossRef][Medline].
|
| 43.
|
Selling, B. H.,
R. F. Allison, and P. Kaesberg.
1990.
Genomic RNA of an insect virus directs synthesis of infectious virions in plants.
Proc. Natl. Acad. Sci. USA
87:434-438[Abstract/Free Full Text].
|
| 44.
|
Selling, B. H., and R. R. Rueckert.
1984.
Plaque assay for black beetle virus.
J. Virol.
51:251-253[Abstract/Free Full Text].
|
| 45.
|
Van Regenmortel, M. H. V.,
C. M. Fauquet,
D. H. L. Bishop,
E. B. Carstens,
M. K. Estes,
S. M. Lemon,
D. J. McGeoch,
J. Maniloff,
M. A. Mayo,
C. R. Pringle, and R. B. Wickner (ed.).
2000.
Virus taxonomy, classification and nomenclature of viruses, 7th ed.
Academic Press, San Diego, Calif.
|
| 46.
|
Zeddam, J. L.,
J. L. Rodriguez,
M. Ravallec, and A. Lagnaoui.
1999.
A noda-like virus isolated from the sweetpotato pest Spodoptera eridania (Cramer) (Lep.; Noctuidae).
J. Invert. Pathol.
74:267-274[CrossRef][Medline].
|
| 47.
|
Zlotnick, A.,
V. S. Reddy,
R. Dasgupta,
A. Schneemann,
W. J. Ray, Jr.,
R. R. Rueckert, and J. E. Johnson.
1994.
Capsid assembly in a family of animal viruses primes an autoproteolytic maturation that depends on a single aspartic acid residue.
J. Biol. Chem.
269:13680-13684[Abstract/Free Full Text].
|
Journal of Virology, June 2000, p. 5123-5132, Vol. 74, No. 11
0022-538X/00/$04.00+0
Copyright © 2000, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Hedges, L. M., Johnson, K. N.
(2008). Induction of host defence responses by Drosophila C virus. J. Gen. Virol.
89: 1497-1501
[Abstract]
[Full Text]
-
Shi, X., Kohl, A., Li, P., Elliott, R. M.
(2007). Role of the Cytoplasmic Tail Domains of Bunyamwera Orthobunyavirus Glycoproteins Gn and Gc in Virus Assembly and Morphogenesis. J. Virol.
81: 10151-10160
[Abstract]
[Full Text]
-
Fenner, B. J., Thiagarajan, R., Chua, H. K., Kwang, J.
(2006). Betanodavirus B2 Is an RNA Interference Antagonist That Facilitates Intracellular Viral RNA Accumulation. J. Virol.
80: 85-94
[Abstract]
[Full Text]
-
Iwamoto, T., Mise, K., Takeda, A., Okinaka, Y., Mori, K.-I., Arimoto, M., Okuno, T., Nakai, T.
(2005). Characterization of Striped jack nervous necrosis virus subgenomic RNA3 and biological activities of its encoded protein B2. J. Gen. Virol.
86: 2807-2816
[Abstract]
[Full Text]
-
Johnson, K. N., Tang, L., Johnson, J. E., Ball, L. A.
(2004). Heterologous RNA Encapsidated in Pariacoto Virus-Like Particles Forms a Dodecahedral Cage Similar to Genomic RNA in Wild-Type Virions. J. Virol.
78: 11371-11378
[Abstract]
[Full Text]
-
Johnson, K. N., Ball, L. A.
(2003). Virions of Pariacoto virus contain a minor protein translated from the second AUG codon of the capsid protein open reading frame. J. Gen. Virol.
84: 2847-2852
[Abstract]
[Full Text]
-
Krondiris, J. V., Sideris, D. C.
(2002). Intramolecular disulfide bonding is essential for betanodavirus coat protein conformation. J. Gen. Virol.
83: 22
Top
Abstract
Introduction
