Previous Article | Next Article 
Journal of Virology, January 1999, p. 270-280, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
Porcine Reproductive and Respiratory Syndrome Virus Comparison:
Divergent Evolution on Two Continents
Chris J.
Nelsen,
Michael P.
Murtaugh, and
Kay S.
Faaberg*
Department of Veterinary PathoBiology,
University of Minnesota, St. Paul, Minnesota 55108
Received 13 July 1998/Accepted 16 September 1998
 |
ABSTRACT |
Porcine reproductive and respiratory syndrome virus (PRRSV)
is a recently described arterivirus responsible for disease
in swine worldwide. Comparative sequence analysis of 3'-terminal structural genes of the single-stranded RNA viral genome revealed the presence of two genotypic classes of PRRSV, represented by the
prototype North American and European strains, VR-2332 and Lelystad
virus (LV), respectively. To better understand the evolution and
pathogenicity of PRRSV, we obtained the 12,066-base 5'-terminal nucleotide sequence of VR-2332, encoding the viral replication activities, and compared it to those of LV and other arteriviruses. VR-2332 and LV differ markedly in the 5' leader and sections of the
open reading frame (ORF) 1a region. The ORF 1b sequence was nearly
colinear but varied in similarity of proteins encoded in identified
regions. Furthermore, molecular and biochemical analysis of
subgenomic mRNA (sgmRNA) processing revealed extensive variation in the
number of sgmRNAs which may be generated during infection and in the
lengths of noncoding sequence between leader-body junctions and the
translation-initiating codon AUG. In addition, VR-2332 and LV select
different leader-body junction sites from a pool of similar candidate
sites to produce sgmRNA 7, encoding the viral nucleocapsid protein. The presence of substantial variations across the
entire genome and in sgmRNA processing indicates that PRRSV has evolved
independently on separate continents. The near-simultaneous global
emergence of a new swine disease caused by divergently evolved viruses
suggests that changes in swine husbandry and management may have
contributed to the emergence of PRRS.
| |
INTRODUCTION |
Porcine reproductive and
respiratory syndrome virus (PRRSV) is a small, enveloped positive
single-stranded RNA virus that causes reproductive failure in breeding
swine and respiratory problems in young pigs. The syndrome was first
recognized as a "mystery swine disease" in the United States in
1987 (27), but in the time since the virus was identified in
Europe (Lelystad virus [LV] [67]) and in the
United States (VR-2332 [4, 10]), PRRSV has become a
significant pathogen of swine herds worldwide, with new disease
phenotypes continuing to emerge (49).
PRRSV is a member of the family Arteriviridae in the order
Nidovirales (7). The arterivirus family consists
of PRRSV, lactate dehydrogenase-elevating virus (LDV), equine
arteritis virus (EAV), and simian hemorrhagic fever virus (SHFV)
(46). The 5'-capped (51) and 3'-polyadenylated
(5, 50, 61) RNA is polycistronic, containing (5'
to 3') two large replicase open reading frames (ORFs), 1a and 1b, and
several smaller ORFs (11, 28, 42, 55). In the infected
cell, arteriviruses produce a nested set of six to eight major
coterminal subgenomic mRNAs (sgmRNAs) each thought to
express only the relative 5'-terminal ORF. These sgmRNAs have a
leader sequence derived from the 5' end of the genome that is joined at
specific leader-body junction sites located downstream by an
unclear discontinuous transcription mechanism (29). The sgmRNAs of PRRSV encode four glycoproteins (GP2 to 5, encoded by sgmRNAs 2 to 5), an unglycosylated membrane protein (M,
encoded by sgmRNA 6), and a nucleocapsid protein (N, encoded by
sgmRNA 7) (3, 32, 33, 38, 41, 43). The European
prototype strain of PRRSV, LV, contains all six of these proteins in
the virion (35, 36, 65), but only the proteins encoded by
ORFs 5 to 7 have conclusively been demonstrated to be in the virion of
North American isolates (3, 43, 45).
Nucleotide and amino acid sequence comparisons of the 3'-terminal ORFs
2 to 7 have shown that there are significant differences between
PRRSV strains native to Europe and those found in North America
(26, 42). Therefore, although these two PRRSV strains cause
similar diseases (4, 67), they are genotypically different in the genes encoding structural proteins. In order to fully
investigate the genomic properties of these two divergent groups of
PRRSV strains, we completed the sequencing of the 5' 12,066 nucleotides of North American prototype VR-2332 that contain ORF1 and compared the
generated nucleotide and predicted amino acid sequences to those of the
European PRRSV prototype strain LV (15,111 bases [38,
39]), LDV strain P (LDVP) (14,104 bases
[44]), and EAV strain Bucyrus (12,719 bases
[63]).
The genotypic comparison between strains VR-2332 and LV revealed that
ORF 1a of VR-2332 is vastly different from that of LV in both length
and sequence, while ORF 1b is relatively conserved between the two
strains of PRRSV. The 5' leader sequence of VR-2332 was 31 bases
shorter than that of LV and differed considerably in nucleotide
sequence. Regional amino acid sequence comparisons also revealed that
although the recognized functional domains of the ORF 1a proteins were
present in both strains, the proteins were not well conserved between
these domains. In order to investigate biochemical differences caused
by the total genome variation, we determined the use of subgenomic
leader-body junction sites for VR-2332 mRNAs and found that VR-2332 can
utilize various sites, all of which are different from those used by LV
(37). In particular, examination of the display of
sgmRNA 7 transcripts revealed that three potential leader-body
junction sites are present at the same relative sites on the genomes of
North American VR-2332 and European LV strains, yet the junction site
utilized to form sgmRNA 7 was peculiar to each isolate. Therefore,
these two strains, which cause comparable diseases in the same host,
differ greatly in both genotype and selection of a subgenomic
transcript leader-body junction site. The results, combined with those
of earlier studies (26, 42), suggest that these two PRRSV
strains underwent divergent evolution on two continents from a distant
common ancestor.
| |
MATERIALS AND METHODS |
Virus and cells.
The fourth cell culture passage of the
VR-2332 isolate of PRRSV was obtained from the American Type Culture
Collection and was passaged twice before the isolate was used to
generate nearly full-length VR-2332 mRNA 7 cDNA. The LV isolate was
provided by Boehringer Ingelheim Animal Health, St. Joseph, Mo. David
Benfield (South Dakota State University, Brookings) provided
plaque-purified VR-2332. All PRRSV samples were propagated in simian
MA-104 cells in Dulbecco modified Eagle medium supplemented with 10%
fetal calf serum at 37°C (10). Porcine alveolar
macrophages were prepared as described previously (2). PRRSV
isolates were grown in macrophages in standard RPMI 1640 medium
supplemented with 2% swine serum.
Viral cDNA identification, RNA isolation, RT-PCR, and
cloning.
The construction and screening of a VR-2332-infected cell
library was described previously (42). A 270-bp fragment,
generated by restriction endonuclease digestion of a plasmid containing cDNA of bases 20 to 222 of the LV strain of PRRSV and a flanking vector
sequence, was radiolabeled with [32P]dCTP (3,000 Ci/mmol;
Amersham, Arlington Heights, Ill.) by random oligonucleotide-primed
synthesis (17) and used as a probe for the detection of
similar sequences in VR-2332. VR-2332 library clones 412 and 658 were
identified in this manner.
Viral genomic RNA was isolated from infected MA-104 cell medium. The
medium was collected 4 days postinfection (p.i.), and cellular debris
was removed by centrifugation for 20 min in a JA-14 rotor (Beckman
Instruments, Inc., Fullerton, Calif.) at 8,000 rpm at 4°C. The virus
was pelleted from the supernatant, and the RNA was purified from this
pellet essentially as described previously (9). Viral RNA
was denatured by treatment with 10 mM methylmercuric hydroxide, primed
with VR-2332-specific primers, and reverse transcribed with SUPERSCRIPT
II RNase H
reverse transcriptase (RT) (Life Technologies,
Inc.). PCRs were completed with VR-2332, LV, LDVP primers, or
degenerate primers designed from regions of high homology between LV
and LDVP sequences (Table 1). PCR
amplification was completed with the Long PCR kit (Boehringer Mannheim
Corporation) with an optimization of annealing temperature for
individual primer pairs and an elongation time for predicted product
size. PCR products were purified with a Microcon 100 kit (Amicon).
To obtain leader-body junction sites, total RNA from infected-cell
lysates was isolated by acid guanidine phenol extraction
or by the
RNeasy kit (Qiagen, Santa Clarita, Calif.) on day 3
(MA-104) or day
2 p.i. (alveolar macrophages). Reverse transcription
was performed
with random hexamers and Moloney murine leukemia
virus RT (Perkin-Elmer
Cetus, Norwalk, Conn.). For the first round
of PCRs, a leader sequence
forward primer (658P1/, 5'-CAGGAGCTGTGACCATTGGC)
was
synthesized based on the sequence of clones 658 and 412 and
was used
with reverse primers specific to each of the ORFs (712P5,
5'-CGGCTTCAATGGCGGCTAG [ORF 2]; 712P2,
5'-GGCGCACATGAGTTGATG [ORF
3]; P42,
5'-GCAATCGCGAGCAACAGCC [ORF 4]; 05P1,
5'-GGTTGCCACGGAACCATC
[ORF 5]; 06P1,
5'-GCGGCACTTTCAACGTGG [ORF 6]; and P72,
5'-CGCCCTAATTGAATAGGTGAC
[ORF 7]). First-round PCR products
were diluted 200-fold and used
in nested PCRs with, as the leader
sequence forward primer, 658P2
(5'-GCTGCACAGAAACACCCTTC) and
reverse primers specific to the
internal sequence of each ORF PCR
product generated (712P6, 5'-GGCCTCATAAGATCTTCTG
[ORF2]; 712P3,
5'-CTAGCTCGTCATGATCGTC [ORF3]; 416P1,
5'-CATGTTGGACGTAGCTGG
[ORF4]; O5P2,
5'-GAAGCAAGTCAACGCAGCC [ORF5]; 06P2,
5'-GGTGAAAGCACAATTCAGG
[ORF6]; and P73,
5'-CTTTCCCGGTCCCTTGCC [ORF7]). Alternatively,
nested PCRs
were completed with 658P1/ as the forward primer and
a primer developed
for 3' rapid amplification of cDNA ends (Qt,
5'-CCA GTGAGCAGAGTGACGAGGACTCGAGCTCAAGCTTTTTTTTTTTTTTT TT)
in
the first round, and in the second round, 658P2 and another
primer
developed for 3' rapid amplification of cDNA ends (Qo,
5'-CCAGTGAGCAGAGTGACG)
were used (
19). PCR was
performed for a total of 30 cycles.
These nucleic acids were denatured
for 1 min at 93°C, annealed
at 55 to 63°C for 30 s to 1 min,
and extended at 72°C for 1 min.
The amplified fragments were then
polished at 72°C for 10 min.
Fragments corresponding to the
approximate predicted size were
gel purified with GeneClean II (Bio
101, Vista, Calif.) or a Qiaquick
gel extraction kit
(Qiagen).
Purified fragments were ligated into the pGEM-T vector (Promega,
Madison, Wis.) and transformed into competent DH5
cells.
For each
leader-body junction, at least two clones from independent
PCRs were
sequenced with the exception of mRNA 7, for which a
total of 10 clones
were analyzed (
16).
Primer extension.
RNA was obtained from total RNA from
infected MA-104 cells on day 3 p.i. with Trizol reagent (Gibco
BRL). Primer extension analysis to determine the length of the 5'
leader was completed as described previously but with modifications
(60). Briefly, 1 µg of infected-cell total RNA was
denatured in the presence of 10 mM methylmercuric hydroxide for 5 min
and hybridized for 16 h at 30°C to the leader sequence reverse
complement primer /658P4 (Table 1), which was isotopically 5'-end
labeled with [
-32P]ATP (Amersham Life Science) and T4
polynucleotide kinase (Promega Corporation). The labeled primer was
extended with Superscript II RNase H RT (Gibco BRL). The
fragment was sized with a sequencing reaction on clone 712 (42), with a 19-mer primer, P71/
(5'-GCTGTTAAACAGGGAGTGG), by electrophoresis through a 7 M
urea-polyacrylamide gel (9%).
Northern blotting.
One microgram of total RNA was denatured
with glyoxyl, electrophoresed through a 2% agarose gel (6),
transferred to nylon membranes (MagnaGraph; MSI, Westboro, Mass.), and
cross-linked to the membrane by UV light. Membranes were hybridized to
radiolabeled oligomers in QuikHyb (Stratagene, La Jolla, Calif.) at
68°C for 16 h, washed three times in 6× SSC (1× SSC is 0.15 M
sodium chloride plus 0.015 M sodium citrate [pH 7.0])-0.5% sodium
dodecyl sulfate at 72°C, and exposed to autoradiography film (NEN
Life Science Products, Boston, Mass.) or a phosphorimaging screen
(Molecular Dynamics, Inc., Sunnyvale, Calif.). The reverse complement
oligomer sequences were derived from defined nucleotide regions of
potential sgmRNA 7 species (ORF7-VR, 5'-CCTTCTTTCTCTTCTGCTGCTTGCCGTTGTTATTTGGC AT,
melting temperature (Tm) = 79.5°C; ORF7-LV,
5'-TACTTTTCTTTTTCTTCTGGCTCTGGTTTTTACCGGCCAT, Tm = 76.4°C; ORF7-JS
1,5'-ACGCCGGACGACAAATGCGTGGTTAAAGGGGTGGAGAGAC, Tm = 85.4°C; ORF7-JS 2, 5'-TTATTTGGCATATTTGACAAGGTTTACGGGGTGGAGAGAC, Tm = 76.7°C; and ORF7-JS 3, 5'-GACAAGGTTTACCACTCCCTGTTTAACGGGGTGGAGAGAC, Tm = 78.9°C). The oligomers were 3'-end
radiolabeled with [-32P]dATP (Amersham Life Science)
and terminal deoxynucleotide transferase (Promega Corporation).
Sequence analysis.
Automated sequencing reactions were
completed with a Taq DyeDeoxy terminator cycle sequencing
kit (Applied Biosystems) and a PE 2400 Thermocycler (Perkin-Elmer) at
the University of Minnesota Advanced Genetic Analysis Center. Analysis
of the newly generated VR-2332 sequence and comparison to the sequences
of other arteriviruses were completed with computer software included
in the LASERGENE package (DNASTAR Inc., Madison, Wis.), Wisconsin
package version 9.1 (Genetics Computer Group [GCG], Madison, Wis.),
and EUGENE (Molecular Biology Information Resource, Baylor
College of Medicine, Houston, Tex.). Sequences used for sequence
analysis (and their GenBank accession numbers) include VR-2332 leader
sequence (AF030244), ORF 2 to the 3' end (PRU00153), LV (M96262), LDVP
(PRU15146), and EAV (X53459).
Nucleotide sequence accession number.
The complete genomic
sequence for strain VR-2332 detailed in this report has been deposited
as GenBank accession no. PRU87392.
| |
RESULTS |
Determination of the 5'-end sequence of VR-2332 viral RNA.
Library clones 412 and 658 included putative 5' leader
sequences of 162 and 170 bases, respectively, based on sequence
comparison to other arteriviruses. These separate clones exhibited
complete nucleotide identity for all 162 5' leader nucleotides of clone 412. Eight additional nucleotides were present at the 5' end of clone 658. To establish the sequence as the VR-2332 5' leader sequence,
a SmaI restriction endonuclease digestion of clone 412 was
used to probe, at high stringency, a Northern blot of total RNA from
MA-104 cells infected with PRRSV. Hybridization of the radiolabeled
probe to discrete bands of RNA derived from VR-2332-infected cells but
not to RNA derived from LV-infected cells was observed. A primer
synthesized by using the additional eight nucleotides present in the
170-base (clone 658) sequence has identified the VR-2332 leader
sequence joined to downstream ORF 1 nucleotides (d5800 clones;
Fig. 2A) with no alterations in the leader sequence presented below.
In order to locate the exact 5' end of strain VR-2332, primer extension
reaction products were analyzed. The strong stop for
VR-2332 primer
extension comigrated with a thymidine residue at
nucleotide 2965 in
clone 712 (98 bases from the start of P71),
corresponding to a primer
extension product of 98 nucleotides
(Fig.
1A). Because the primer extension
reaction was completed
with a primer annealing to bases 78 to 59 of the
leader sequence
of ORF 7 clone 658, the 20-base difference represents
an uncloned
genomic sequence. Therefore, the 5' end of the leader
sequence
of PRRSV VR-2332 is 190 bases in length (170 plus 20 nucleotides).
The 20 5'-terminal nucleotides have not yet been
identified.
View larger version (31K):
[in this window]
[in a new window]
|
FIG. 1.
(A) Primer extension analysis of strain VR-2332. RNA
from VR-2332-infected MA-104 cells was hybridized to
-32P-radiolabeled VR-2332 leader reverse primer /658P4
and reverse transcribed. The primer extension products were
electrophoresed alongside the known sequencing products obtained from
clone 712 and forward primer P71/. The primer extension product
migrated with the thymidine residue located at nucleotide 2965 of clone
712, resulting in an extension product of 98 nucleotides. (B)
Comparison of PRRSV leader sequences. VR-2332 leader (190 bases in
length) and LV leader (221 bases in length) sequences exhibit 61.0%
identity as analyzed by the GCG GAP program, with a gap weight of 5 and
a length weight of 5 (lines between the sequences indicate identity).
The leader-body junction sequence utilized for transcription of each
mRNA is boxed.
|
|
Comparison of VR-2332 with other arterivirus leader
sequences.
The VR-2332 leader sequence is intermediate in
length among the leader sequences of LDVP (156 bases
[8]), LDVC (161 bases [20]), SHFV
(208 bases [68]), EAV (211 bases [12,
63]), and LV (221 bases [38, 39]). The
190-base leader sequence was aligned with the 221-base leader sequence
of LV (Fig. 1B). The two PRRSV isolates exhibited an overall moderate
sequence identity of 61.0% for the known leader sequences when aligned with the GAP program in GCG. The leader sequences of two isolates of
LDV exhibited similar sequence identities to VR-2332 (62.5% for LDVP
and 62.3% for LDVC) when they were compared by using the same
parameters. The only region of distinct similarity was in the
approximately 40-base region at the 3' end of the leader sequences, which exhibited 90.4% identity. The hexanucleotide UUAACC (Fig. 1B) was shown to be completely conserved between the two
strains and defines the leader-body junction sequence for strain
VR-2332 (see below).
Determination of the genomic sequence for ORF 1 of strain
VR-2332.
The genomic sequence for VR-2332 ORF 1 was
generated from RT-PCR products covering the region at least
three times, as schematically outlined in Fig.
2A, by using the primers listed in Table
1. The sequence of clone 712 (ORFs 2 to 7) was reported previously (42). Using LV-specific primers, we obtained RT-PCR cDNA
clones LAF1, LAF1s, LAF2-3'40-60, 21, 3'-ORF1b, and 3'42-60. LV-LDVP primers produced clones 8242 and 8342 by similar RT-PCR methods. The
remaining clones were generated by RT-PCR with VR-2332-specific primers disclosed through sequence analysis of the previously mentioned
clones. All clones were sequenced and aligned into 12,066 contiguous
bases.
View larger version (24K):
[in this window]
[in a new window]
|
FIG. 2.
(A) Schematic of the 15,409-base viral genome of VR-2332
(open boxes) with sequenced cDNA clones (shaded boxes). (B) Sequence of
the VR-2332 region between ORF 1a and 1b and its resulting predicted
RNA pseudoknot tertiary structure involved in ribosome frameshifting,
as modeled on the predicted pseudoknot of LV (1, 38). The
proposed heptanucleotide slippery sequence (boxed), UAG stop codon of
ORF 1a (bold), and differences between VR-2332 and LV (italics) are
indicated.
|
|
When the newly generated sequence was combined with the sequence of
clone 712, the complete VR-2332 viral genome consisted
of 15,409 bases
with a polyadenylated tract at the 3' end (Fig.
2A). The genome of LV
is 15,098 nucleotides in length (
39),
and thus, the VR-2332
genome is 311 nucleotides longer than the
genome of the European strain
LV. The predicted lengths (and calculated
molecular masses) of the
products of strain VR-2332 ORF 1a and
1b are 2,502 amino acids (272.1 kDa) and 1,457 amino acids (161.0
kDa), respectively, while strain LV
possesses ORF 1 proteins of
2,396 amino acids (260.1 kDa) and 1,458 amino acids (161.3 kDa),
respectively (Fig.
3A).
View larger version (18K):
[in this window]
[in a new window]
View larger version (68K):
[in this window]
[in a new window]
View larger version (27K):
[in this window]
[in a new window]
View larger version (55K):
[in this window]
[in a new window]
View larger version (58K):
[in this window]
[in a new window]
View larger version (25K):
[in this window]
[in a new window]
|
FIG. 3.
(A) Schematic of amino acid comparisons of VR-2332
(upper bars) and LV (lower bars) by domain, showing regions of
similarity and dissimilarity (GCG GAP program alignments; see text).
(B) ORF 1a alignment of the following: (1) arteriviral PCP and -
domains and their respective catalytic residues ( or ) (with
blosum62.cmp and pam250.cmp, a gap weight of 12, and a gap length
weight of 4); (2) an unusual arteriviral cysteine protease domain with
putative catalytic residues ( ) (with blosum62.cmp, a gap weight of
5, and a gap length weight of 5); and (3) the poliovirus 3C-like
protease (PV1) domain with catalytic H and D and C/S residues (*)
(with blosum62.cmp, a gap weight of 1, and a gap length weight of 2).
(C) ORF 1b with MHV-A59 ORF 1b residues used to align the following:
(1) a putative polymerase region with amino acids conserved among
positive strand RNA viruses (48) shown (*) (with
blosum62.cmp, a gap weight of 5, and a gap length weight of 5); (2) a
domain with conserved cysteine and histidine residues () (with
blosum62.cmp, a gap weight of 6, and a gap length weight of 2); (3)
helicase domains showing conserved amino acids () in Sindbis
virus-like RNA plant virus group A2 (22) (with blosum62.cmp,
a gap weight of 2, and a length weight of 2); and (4) a coronaviruslike
domain (with blosum62.cmp, a gap weight of 5, and a gap length weight
of 5). In all panels, amino acids conserved in aligned sequences are
shown in boldface, those conserved among arteriviruses are shown in
uppercase (except for the PCP and - -alignment which shows
conservation between VR-2332, LV, and LDVP in uppercase), and similar
amino acids between the two PRRSV strains are boxed.
|
|
Genetic comparison of PRRSV VR-2332 ORF 1 sequence to those
of other arteriviruses.
Needleman-Wunsch pairwise
comparisons between VR-2332 ORF 1 and other arterivirus ORF 1 nucleotide and protein sequences showed that ORF 1b is relatively more
conserved than ORF 1a among arteriviruses (Table
2). The low degree of nucleotide and
protein similarity to the European prototype strain of PRRSV, LV,
obtained for both ORF 1a and 1b was particularly striking and was not
expected for two viruses causing the same disease phenotype in the same
host.
The ORF 1 sequence of VR-2332 contained a predicted pseudoknot sequence
at the end of ORF 1a (Fig.
2B), very similar to the
pseudoknot sequence
of strain LV (
1,
38), so that the 1,457
additional amino
acids of ORF 1b were predicted to be translated
through ribosomal
frameshifting (Fig.
3A) (
12). Regions corresponding
to seven
protein domains have been identified in ORF 1 of all
members of the
order
Nidovirales (
12,
13,
56-58). These protein
domains were identified for strain VR-2332 by genetic comparison
and
were aligned with and compared to PRRSV LV (Fig.
3A) and other
viruses
(Fig.
3B and
C).
The VR-2332 ORF 1a sequence, like that of LV, contained two papainlike
cysteine protease (PCP) motifs (PCP
was 78.0% similar
[amino acids
74 to 146] and PCP
was 62.5% similar [amino acids
268 to 339]),
an unusual cysteine protease with a putative CG
catalytic site (63.9%
similar [amino acids 435 to 506]), and a
poliovirus 3C-like serine
protease motif (68.6% similar [amino
acids 1840 to 1946]) that were
moderately conserved between the
strains (Fig.
3A). All four predicted
proteases and their cleavage
sites have yet to be defined. However,
both PCP sites are functional
in LV (
13), and the relative
conservation of these two motifs
suggests that both sites are likely to
be functional in VR-2332.
All serine protease sites predicted for LV
(
62) were shown to
be conserved in the ORF 1b sequence of
VR-2332. A region of little
protein similarity (39.3%), VR-2332
amino acids 507 to 1236 and
LV amino acids 498 to 1119 (optimal
similarity score obtained
with the GCG GAP program, a blosum62.cmp
scoring matrix, a gap
weight of 2, and a gap length weight of 4), in
the ORF 1a product
resided between the third cysteine protease domain
and the serine
protease domain and accounted for the majority of the
extra 106
amino acids in strain VR-2332 (Fig.
3A and data not shown).
An
exhaustive search of many databases revealed no other predicted
protein motifs present in the ORF 1 product of strain VR-2332.
ORF 1b was more conserved than ORF 1a. ORF 1b of VR-2332 was highly
similar to that of LV, in that it coded for polymerase
(86.9% similar
[amino acids 367 to 511]) and nidovirus-unique
coronaviruslike
(89.7% similar [amino acids 1209 to 1305]) domains.
In addition,
nucleoside triphosphate/helicase (77.2% similar [amino
acids 787 to
1010]) and cysteine- and histidine-rich (76.6% similar,
probably
metal binding [amino acids 647 to 693]) domains that
were less
similar to LV were also identified. A region of 151
amino acids at the
C terminus of the ORF 1b product exhibited
only 49.0% similarity
between the two PRRSV strains (Fig.
3A).
Comparison of putative functional domains of VR-2332 ORF
1 to other viruses.
As shown in Fig. 3B, panel 1, VR-2332
ORF 1a PCP motifs were aligned with those of LV, LDVP, and EAV
(13, 57, 58, 66). PCP is well conserved between both
strains of PRRSV and LDVP. However, the putative catalytic residues of
PCP, when aligned, suggest that there is considerable
divergence between the viruses, including those between VR-2332 and LV,
as the lengths of regions between conserved residues are quite
variable. The poliovirus 3C-like serine protease motif also contains
different lengths of nonconserved amino acids between conserved
residues (Fig. 3B, panel 3).
In other ORF 1 functional domains, strains VR-2332 and LV are clearly
more related to each other than to other arteriviruses,
although there
are many short amino acid stretches which also
have identity to LDVP
(Fig.
3). EAV possesses little homology
to other arteriviruses
(
59).
VR-2332 leader-body junction sequences.
Previous results
suggested that each sgmRNA leader-body junction included one
specific junction site on the PRRSV genome (34, 37,
52). However, sequence analysis of the 3' end of VR-2332 identified 15 potential leader-body junction sequences which could theoretically be used for transcription of the six sgmRNAs 2 to 7 (consensus sequence with one mismatch, see below).
Therefore, leader-body junction sequence analysis
was completed by RT-PCR for each ORF-specific sgmRNA
transcript. The leader-body junction consensus sequence for VR-2332 was
determined to be UUAACC, similar to all arterivirus consensus
sequences described to date (8, 14, 15, 21, 34, 37,
52), with nucleotide differences among the sgmRNAs noted for
the first five bases of this sequence ([U/A][U/C/A/G][A/C][A/G][C/U]C) (Table
3).
View this table:
[in this window]
[in a new window]
|
TABLE 3.
Comparison of the numbers of nucleotides between the
leader-body junction site and the initiating AUG for sgmRNAs of
VR-2332 (North American) and LV (European [37]) PRRSV
|
|
The length of untranslated sequence between the leader-body junction
sequence and the starting AUG for each ORF is shown in
Table
3. For
mRNAs 2, 3, and 6 only one junction site was identified.
However, for
mRNAs 4 and 7, two genomic sites were identified
and designated 4.1 and
4.2 and 7.1 and 7.2, respectively, designations
similar to the
nomenclature of additional EAV mRNA 3 species (
14).
Another
mRNA (5-1 [
7]) utilized a site downstream of the
starting
AUG for ORF 5, and it appears to encode a truncated protein
utilizing
the second ORF 5 methionine (amino acid 132; data not shown).
The length of untranslated sequence preceding ORFs 3 and 4.1 for
VR-2332 agrees with that of another North American isolate (ISU79
[
34,
40]). However, mRNA 3-1, detected in
ISU79-infected cells,
was not detected in our analysis of
VR-2332-infected cells. This
could be due to the genomic sequence
variation at this leader-body
junction site (ISU79 has UUGACC
and VR-2332 has UUGACU) or to
the different cell lines used for
sgmRNA junction site analysis.
The lengths of sequences
preceding mRNAs 5, 6, and 7.1 agree with
those of a Japanese isolate
(EDRD-1 [
52]), which was shown to
be more related to
North American isolates than to LV (
38) (Table
3).
Thus, with limited RT-PCR and sequence analysis, we have
obtained
evidence that the leader-body junction sites utilized
by strain VR-2332
for mRNAs 4 and 7 seem to be more heterogeneous
than previously
reported. Because the initial RNA was isolated
from swine alveolar
macrophages, this finding suggests that more
than one leader-body
junction site may be utilized in vivo to
produce at least some
sgmRNAs.
When the untranslated sequence lengths between the leader and initiator
AUG for the mRNAs of North American and Japanese isolates
were compared
to those of LV, significant differences were readily
apparent (Table
3). Also, with the exception of mRNA 7 (see below),
the alignment of
nucleotide sequences from VR-2332 and LV ORFs
2 to 7 revealed that the
junction site motifs used were poorly
conserved between strains
(data not shown). Strain-specific selection
of leader-body
junction sites and their placement in ORFs 2 to
7 delineate a clear
biochemical difference between VR-2332 and
LV.
sgmRNA 7 junction site utilization in virally infected
cells.
sgmRNA 7.1 and 7.2 (coding for the nucleocapsid [N]
protein) (Table 3) were further investigated in order to confirm
the difference in leader-body junction site utilization between
North American and European strains and to assess the relative
abundance of the two VR-2332-specific mRNA 7 species. VR-2332 and LV
contain three potential leader-body junction motifs at the same
relative positions (Fig. 4). However,
Northern analysis of total RNA from VR-2332 and LV-infected MA-104
cells revealed two isoforms for VR-2332 and one for LV. When a Northern
blot was analyzed with a VR-2332 ORF 7 sequence probe, one mRNA 7 was a
highly abundant, slower-migrating band (presumably VR-2332 mRNA 7.1;
see below) and the other was a less abundant, faster-migrating band
(presumably VR-2332 mRNA 7.2) (Fig. 5A,
lane 1). Both cloned (Fig. 5A, lane 1) and uncloned (data not shown)
VR-2332 preparations exhibited similar profiles for mRNA 7. When the blot was reprobed for LV ORF 7 sequence, only one
mobility species was discerned, which migrated with VR-2332 mRNA 7.2 (Fig. 5A, lane 2). Evidence of an LV mRNA 7 equivalent to VR-2332
mRNA 7.1 was not observed in the Northern analysis and has not
been described previously (37).
View larger version (28K):
[in this window]
[in a new window]
|
FIG. 4.
Predicted junction site motifs (bold and underlined) in
VR-2332 and LV ORF 7. VR-2332 mRNA 7.1 utilizes the first junction site
motif (JS 1) and mRNA 7.2 utilizes the third junction site motif (JS
2). LV uses the third junction site motif exclusively (37)
(JS). A potential junction site motif at nucleotide 14577 (VR-2332)
appears not to be used (Fig. 5). The beginning ORF 7 nucleotide and
predicted protein sequences are shown in bold type (with the GAP
program [fastadna.cmp], a gap weight of 16, and a length weight of
4).
|
|
View larger version (41K):
[in this window]
[in a new window]
|
FIG. 5.
(A) Northern blot analysis of PRRSV mRNA 7. Total RNA
from cells infected with VR-2332 (lane 1) or LV (lane 2) were
electrophoresed through an agarose gel and blotted onto a nylon
membrane. The membrane was probed sequentially with a VR-2332 ORF 7 oligomer (lane 1) and then an oligomer to LV ORF 7 (lane 2). No
nonspecific hybridization was detected in several analyses. (B)
Northern blot analysis of total RNA from VR-2332-infected MA-104
(CL2621) cells and alveolar macrophages (AM) shows that junction site 1 is used to transcribe the majority of mRNA 7 (7.1) and that junction
site 2 is used to transcribe a minority of mRNA 7 (7.2). Mock-,
VR-2332-, and LV-infected-cell total RNA populations were
electrophoresed through a 2% agarose gel and transferred to membranes.
The membranes were probed with reverse complement oligomers to VR-2332
ORF 7 (a), VR-2332 ORF 7 junction site 1 (b), VR-2332 ORF 7 junction
site 2 (c), and LV ORF 7 (d). An RNA ladder (Gibco BRL) was used to
assess sgmRNA size.
|
|
We assessed whether all three junction sites were utilized during
VR-2332 infection of simian MA-104 cells and of freshly
isolated porcine alveolar macrophages, the natural host cell of
the
virus. Identification of mRNA 7.1 and 7.2 in infected alveolar
macrophages would suggest that the two species of mRNA 7 are
biologically
relevant. Northern blots of total RNA from both
types of infected
cells were probed with radiolabeled VR-2332 or
LV ORF 7 oligomers.
VR-2332 expresses both mRNA 7.1 and 7.2 in
both populations of
cells (Fig.
5B, panel a). In addition, sgmRNA 7 leader-body junction
oligomer probes were used to detect
expression of each mRNA 7
species in infected cells. The VR-2332
leader-body junction site
1 probe (for the junction site 123 bases
upstream of the ORF 7
AUG) hybridized to a species of mRNA that
migrated with mRNA 7.1
in both populations of infected cells (Fig.
5B,
panel b). Similarly,
the junction site 2 probe (for the junction site 9 bases upstream
of the ORF 7 AUG) identified mRNA 7.2 in both cell
populations
(Fig.
5B, panel c), which migrated with LV mRNA 7 (Fig.
5B,
panel
d). The other leader-body junction site (VR-2332 nucleotide 14577
in Fig.
4) was not detected in VR-2332-infected cells, indicating
that
this species was expressed at very low levels or not at
all.
Therefore, both the North American strain VR-2332 and the European
strain LV possess genomic sequences containing three similar
leader-body junction motifs in the region preceding ORF 7. VR-2332
utilizes the site 123 bases upstream of the initiating ORF 7 AUG
for
the majority of mRNA 7 transcripts and the site 9 bases upstream
for a
minor fraction of them. LV, in contrast, utilizes only the
site 9 bases
upstream of ORF 7 for its mRNA 7 transcripts. No
obvious consensus
sequence or RNA structure surrounds the chosen
leader-body junction
motifs that are used (unpublished data).
It is interesting that neither
strain of PRRSV appears to utilize
the third potential junction site,
even though that putative junction
site was completely conserved in
both
strains.
| |
DISCUSSION |
The complete comparative genome analysis and
experimental data reported here confirm and extend the
remarkable differences between North American and European PRRSV
reported earlier from an analysis of the 3' structural gene and
noncoding region sequences (42). VR-2332, the North American
prototype, exhibits substantial nucleotide and amino acid sequence and
length divergence from the European prototype, LV, over the entire
length of the virus. The identified protease and polymerase motifs in
ORF 1, relatively well conserved during evolution, signify their
importance for the maintenance of viable PRRSV virus. Other than these
motifs, notably in the sequence and length of the 5' leader, most of
ORF 1a, and the region of ORF 1b corresponding to the C-terminal end of
the product, the strains exhibit inordinate divergence. It is striking
that these and other genotypic differences in ORFs 2 to 7 and the 3'
noncoding region do not manifest appreciable differences in disease
phenotype. The data suggest the divergent evolution of related viruses
on separate continents from a distant common ancestor and the
simultaneous emergence of a new disease in swine.
In this report, we have examined the subgenomic messages produced in
cells, and not only did we find that the leader-body junction
sequences used for each mRNA of strain VR-2332 are different from
those for LV mRNAs, but we also found evidence in infected swine
macrophages that the VR-2332 sgmRNA junction sites utilized are variable, particularly in the case of mRNA 7. Although both VR-2332
and LV genomic sequences naturally contain potential leader junction sequences for mRNA 7 at three sites, only one particular site is used preferentially for transcription in each isolate. It
appears that the leader sequence, ending in UUAACC, is joined to
downstream leader-body junction motifs by more than simple base pair
homology, since only a specific subset of potential leader-body motifs
are utilized. Thus, we suggest that another viral nucleotide or protein
sequence(s), secondary structure of the viral RNA, or other host
factors may play a role in site selection. The differences in PRRSV
polymerase proteins described in this report may play a key role in
determining the choice of junction site utilized.
Multiple species of mRNA 7 were not previously described for any
arterivirus. Multiple species of mRNA 3 were reported for EAV
(14) and for PRRSV ISU79, although ISU79 mRNA 3-1 is
predicted to encode a truncated ORF 3 protein (34). The ORF
3 protein is incorporated into the LV virion (65), but it
has not been detected in any North American isolate or in other
arteriviruses. The ORF 7 product, the N protein, is a fundamental
protein found in all viruses and functions to enclose and protect
the viral genome. Both LV and VR-2332 contain three potential
junction sites (ending 123, 23, and 9 bases upstream of the ORF 7 initiator AUG [Fig. 4]) for mRNA 7 formation at the same relative
positions in their genomes (38, 42), yet VR-2332 selects the
junction site ending 123 bases upstream of ORF 7 (AUAACC) to produce
most mRNA 7 while LV selects the site ending 9 bases upstream (UUAACC) to transcribe mRNA 7 (Fig. 4). This may indicate an essential need for
a U in the second position and a C in the fifth position, but
other mRNA junction sites (mRNAs 2, 4.2, and 5-1) indicate that
different nucleotides can be tolerated in these positions. The
significance of this difference among isolates of PRRSV is unknown.
The mechanism of leader-body junction site selection in
arteriviruses is not well studied. However, coronavirus transcription has been examined by several investigators (reviewed in references 29, 53, and
64), and these investigators have obtained diverse results. Specific selection may be influenced by the primary 5' leader
sequence (30, 54, 69), sequences flanking the
downstream consensus sequence (23, 24), the 3'
noncoding region (31), sequences in ORF 1 (63),
or sequences at some other location on the genome. Secondary and
tertiary structures of the RNA (18), viral replicase
proteins, or in some cellular gene or protein with which viral genes or
proteins interact during transcription may also influence junction site
selection (70). In mouse hepatitis virus (MHV) defective
interfering RNA studies, investigators found that the amount of
subgenomic defective interfering transcription was influenced by the
addition of novel intragenic (leader-body junction) sequences
(25). The investigators concluded that downstream intragenic
sequences suppressed transcription from the upstream intragenic region.
This seems unlikely to be the case in arterivirus transcription,
however, because both VR-2332 and LV genomic sequences naturally
contain potential leader-body junction sequences for mRNA 7 at three
sites, yet one particular site is used preferentially for transcription
in each isolate. Arteriviruses, in contrast to coronaviruses,
utilize a shorter leader-body junction sequence and have
overlapping ORFs, which suggests that the two virus families may not
use identical mechanisms to couple the leader to each junction site
for formation of their mRNAs. It is possible that the different
species of mRNA 7 detected in this study may instead be used to
produce different proteins. VR-2332 ORF 7 is predicted to code for two
smaller products (5.0 and 3.7 kDa) in addition to the N protein (13.6 kDa), whereas LV ORF 7 is predicted to code for only one additional
product (5.9 kDa) in addition to the LV N protein (13.8 kDa).
Alternatively, the two different mRNA 7 5' untranslated leader
sequences identified for VR-2332 may reflect different quantities of
nucleocapsid protein expression needed at different times during infection.
The evidence presented in this report suggests that the genotypic
differences between VR-2332 and LV and the simultaneous appearance of
frank disease do not appear to be the result of recent recombination
events between other viruses. If this were the case, the regions of
noted similarity (the ORF 1b product and some structural proteins, in
particular) would most likely be better conserved between VR-2332 and
LV. Rather, the genomic and biochemical differences are
considerable and extend throughout the genome of PRRSV, with
moderate conservation interspersed with dissimilarity. Computer
searches for sequences similar to PRRSV do not reveal a potential virus
family, other than arteriviruses, for such a recombination event. It is
possible that, because of very close similarity to LDV, the two strains
of PRRSV evolved from an LDV-like viral ancestor on separate
continents, as has been hypothesized previously (47).
However, divergent PRRSV evolution does not explain the simultaneous
appearance of similar diseases in the United States and Europe. The
association of distinct PRRSV genotypes with a similar, new disease
phenotype in swine might therefore be related to global changes in
commercial swine management and husbandry.
| |
ACKNOWLEDGMENTS |
We thank Margaret Elam, Thy Truong, Judy Laber, and Dan Strom for
excellent technical expertise and Vivek Kapur for a critical review of
this paper.
Boehringer Ingelheim Animal Health, Inc., University of Minnesota
Agricultural Experiment Station, and Minnesota Pork Producers Association provided financial support for the research.
| |
FOOTNOTES |
*
Corresponding author. Mailing address: Department of
Veterinary PathoBiology, University of Minnesota, 1971 Commonwealth
Ave., St. Paul, MN 55108. Phone: (612) 624-9746. Fax: (612) 625-5203. E-mail: kay{at}lenti.med.umn.edu.
| |
REFERENCES |
| 1.
|
Abrahams, J. P.,
M. van den Berg,
E. van Batenburg, and C. Pleu.
1990.
Prediction of RNA secondary structure, including pseudoknotting, by computer simulation.
Nucleic Acids Res.
18:3035-3044[Abstract/Free Full Text].
|
| 2.
|
Baarsch, M. J.,
M. J. Wannemuehler,
T. W. Molitor, and M. P. Murtaugh.
1991.
Detection of tumor necrosis factor alpha from porcine alveolar macrophages using an L929 fibroblast bioassay.
J. Immunol. Methods
140:15-22[Medline].
|
| 3.
|
Bautista, E. M.,
J. J. Meulenberg,
C. S. Choi, and T. W. Molitor.
1996.
Structural polypeptides of the American (VR-2332) strain of porcine reproductive and respiratory syndrome virus.
Arch. Virol.
141:1357-1365[Medline].
|
| 4.
|
Benfield, D. A.,
E. Nelson,
J. E. Collins,
L. Harris,
S. M. Goyal,
D. Robison,
W. T. Christianson,
R. B. Morrison,
D. E. Gorcyca, and D. W. Chladek.
1992.
Characterization of swine infertility and respiratory syndrome (SIRS) virus (isolate ATCC VR-2332).
J. Vet. Diagn. Investig.
4:127-133[Abstract/Free Full Text].
|
| 5.
|
Brinton, M. A.,
E. I. Gavin, and A. V. Fernandez.
1986.
Genotypic variation among six isolates of lactate dehydrogenase-elevating virus.
J. Gen. Virol.
67:2673-2684[Abstract/Free Full Text].
|
| 6.
|
Brown, T.
1993.
Analysis of RNA by northern and slot-blot hybridization, p. 4.9.1-4.9.14.
In
F. M. Ausubel, R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl (ed.), Current protocols in molecular biology. John Wiley & Sons, Inc., New York, N.Y.
|
| 7.
|
Cavanagh, D.,
D. A. Brian,
L. Enjuanes,
K. V. Holmes,
M. M. Lai,
H. Laude,
S. G. Siddell,
W. Spaan,
F. Taguchi, and P. J. Talbot.
1990.
Recommendations of the Coronavirus Study Group for the nomenclature of the structural proteins, mRNAs, and genes of coronaviruses.
Virology
176:306-307[Medline].
|
| 8.
|
Chen, Z.,
L. Kuo,
R. R. R. Rowland,
C. Even,
K. S. Faaberg, and P. G. W. Plagemann.
1993.
Sequences of 3' end of genome and of 5' end of open reading frame 1a of lactate dehydrogenase-elevating virus (LDV) and common junction motifs between 5' leader and bodies of seven subgenomic mRNAs.
J. Gen. Virol.
74:643-660[Abstract/Free Full Text].
|
| 9.
|
Chen, Z.,
K. S. Faaberg, and P. G. W. Plagemann.
1994.
Determination of the 5' end of the lactate dehydrogenase-elevating virus genome by two independent approaches.
J. Gen. Virol.
75:925-930[Abstract/Free Full Text].
|
| 10.
|
Collins, J. E.,
D. A. Benfield,
W. T. Christianson,
L. Harris,
J. C. Hennings,
D. P. Shaw,
S. M. Goyal,
S. McCullough,
R. B. Morrison,
H. S. Joo,
D. E. Gorcyca, and D. W. Chladek.
1992.
Isolation of swine infertility and respiratory syndrome virus (isolate ATCC VR-2332) in North America and experimental reproduction of the disease in gnotobiotic pigs.
J. Vet. Diagn. Investig.
4:117-126[Abstract/Free Full Text].
|
| 11.
|
Conzelmann, K.,
N. Visser,
P. van Woensel, and H. Thiel.
1993.
Molecular characterization of porcine reproductive and respiratory syndrome virus, a member of the arterivirus group.
Virology
193:329-339[Medline].
|
| 12.
|
den Boon, J. A.,
E. J. Snijder,
E. D. Chirnside,
A. A. F. de Vries,
M. C. Horzinek, and W. J. M. Spaan.
1991.
Equine arteritis virus is not a togavirus but belongs to the cornaviruslike superfamily.
J. Virol.
65:2910-2920[Abstract/Free Full Text].
|
| 13.
|
den Boon, J. A.,
K. S. Faaberg,
J. J. M. Meulenberg,
A. L. M. Wassenaar,
P. G. W. Plagemann,
A. E. Gorbalenya, and E. J. Snijder.
1995.
Processing and evolution of the N-terminal region of the arterivirus replicase ORF1a protein: identification of two papainlike cysteine proteases.
J. Virol.
69:4500-4505[Abstract/Free Full Text].
|
| 14.
|
den Boon, J. A.,
M. F. Kleijnen,
W. J. M. Spaan, and E. J. Snijder.
1996.
Equine arteritis virus subgenomic mRNA synthesis: analysis of leader-body junctions and replicative-form RNAs.
J. Virol.
70:4291-4298[Abstract/Free Full Text].
|
| 15.
|
de Vries, A. A.,
E. D. Chirnside,
P. J. Bredenbeek,
L. A. Gravestein,
M. C. Horzinek, and W. J. Spaan.
1990.
All subgenomic mRNAs of equine arteritis virus contain a common leader sequence.
Nucleic Acids Res.
18:3241-3247[Abstract/Free Full Text].
|
| 16.
|
Faaberg, K. S.,
M. R. Elam,
C. J. Nelsen, and M. P. Murtaugh.
1998.
Subgenomic RNA7 is transcribed with different leader-body junction sites in PRRSV (strain VR2332) infection of CL2621 cells.
Adv. Exp. Med. Biol.
440:275-279[Medline].
|
| 17.
|
Feinberg, A. P., and B. Vogelstein.
1983.
A technique for radiolabeling DNA restriction endonuclease fragments to high specific activity.
Anal. Biochem.
132:6-13[Medline].
|
| 18.
|
Fischer, F.,
C. F. Stegen,
C. A. Koetzner, and P. S. Masters.
1997.
Analysis of a recombinant mouse hepatitis virus expressing a foreign gene reveals a novel aspect of coronavirus transcription.
J. Virol.
71:5148-5160[Abstract/Free Full Text].
|
| 19.
|
Frohman, M. A.
1994.
On beyond classic RACE (rapid amplification of cDNA ends).
PCR Methods Appl.
4:S40-S58[Medline].
|
| 20.
|
Godeny, E. K.,
L. Chen,
S. N. Kumar,
S. L. Methven,
E. V. Koonin, and M. A. Brinton.
1990.
Complete genomic sequence and phylogenetic analysis of the lactate dehydrogenase-elevating virus (LDV).
Virology
194:585-596.
|
| 21.
|
Godeny, E. K.,
A. A. F. de Vries,
X. C. Wang,
S. L. Smith, and R. J. de Groot.
1998.
Identification of the leader-body junctions for the viral subgenomic mRNAs and organization of the simian hemorrhagic fever virus genome: evidence for gene duplication during arterivirus evolution.
J. Virol.
72:862-867[Abstract/Free Full Text].
|
| 22.
|
Habili, N., and R. H. Symons.
1989.
Evolutionary relationship between luteoviruses and other RNA plant viruses based on sequence motifs in their putative RNA polymerases and nucleic acid helicases.
Nucleic Acids Res.
17:9543-9555[Abstract/Free Full Text].
|
| 23.
|
Hiscox, J. A.,
K. L. Mawditt,
D. Cavanagh, and P. Britton.
1995.
Characterization of the transmissible gastroenteritis virus (TGEV) transcription initiation sequence.
Adv. Exp. Med. Biol.
380:529-535[Medline].
|
| 24.
|
Jeong, Y. S.,
J. F. Repass,
Y. N. Kim,
S. M. Hwang, and S. Makino.
1996.
Coronavirus transcription mediated by sequences flanking the transcription consensus sequence.
Virology
217:311-322[Medline].
|
| 25.
|
Joo, M., and S. Makino.
1995.
Analysis of coronavirus transcription regulation.
Adv. Exp. Med. Biol.
380:473-478[Medline].
|
| 26.
|
Kapur, V.,
M. R. Elam,
T. M. Pawlovich, and M. P. Murtaugh.
1996.
Genetic variation in porcine reproductive and respiratory syndrome virus isolates in the midwestern United States.
J. Gen. Virol.
77:1271-1276[Abstract/Free Full Text].
|
| 27.
|
Keffaber, K. K.
1989.
Reproductive failure of unknown etiology.
Am. Assoc. Swine Prac. Newsl.
1:1-9.
|
| 28.
|
Kuo, L.,
Z. Chen,
R. R. R. Rowland,
K. S. Faaberg, and P. G. W. Plagemann.
1992.
Lactate dehydrogenase-elevating virus (LDV): subgenomic mRNAs, mRNA leader and comparison of 3'-terminal sequences of two LDV isolates.
Virus Res.
23:55-72[Medline].
|
| 29.
|
Lai, M. M.
1995.
Transcription, replication, recombination, and engineering of coronavirus genes.
Adv. Exp. Med. Biol.
380:463-471[Medline].
|
| 30.
|
Liao, C.-L., and M. M. C. Lai.
1994.
Requirement of the 5'-end genomic sequence as an upstream cis-acting element for coronavirus subgenomic mRNA transcription.
J. Virol.
68:4727-4737[Abstract/Free Full Text].
|
| 31.
|
Lin, Y.-J.,
X. Zhang,
R.-C. Wu, and M. M. C. Lai.
1996.
The 3' untranslated region of coronavirus RNA is required for subgenomic mRNA transcription from a defective interfering RNA.
J. Virol.
70:7236-7240[Abstract/Free Full Text].
|
| 32.
|
Mardassi, H.,
B. Massive, and S. Dea.
1996.
Intracellular synthesis, processing, and transport of proteins encoded by ORFs 5 to 7 of porcine reproductive and respiratory syndrome virus.
Virology
221:98-112[Medline].
|
| 33.
|
Meng, X.-J.,
P. S. Paul, and P. G. Halbur.
1994.
Molecular cloning and nucleotide sequences of the 3'-terminal genomic RNA of the porcine reproductive and respiratory syndrome virus.
J. Gen. Virol.
75:1795-1801[Abstract/Free Full Text].
|
| 34.
|
Meng, X.-J.,
P. S. Paul,
I. Morozov, and P. G. Halbur.
1996.
A nested set of six or seven subgenomic mRNAs is formed in cells infected with different isolates of porcine reproductive and respiratory syndrome virus.
J. Gen. Virol.
77:1265-1270[Abstract/Free Full Text].
|
| 35.
|
Meulenberg, J. J.,
A. Petersen-den Besten,
E. P. De Kluyver,
R. J. Moormann,
W. M. Schaaper, and G. Wensvoort.
1995.
Characterization of proteins encoded by ORFs 2 to 7 of Lelystad virus.
Virology
206:155-163[Medline].
|
| 36.
|
Meulenberg, J. J., and A. Petersen-den Besten.
1996.
Identification and characterization of a sixth structural protein of Lelystad virus: the glycoprotein GP2 encoded by ORF2 is incorporated in virus particles.
Virology
225:44-51[Medline].
|
| 37.
|
Meulenberg, J. J. M.,
E. J. de Meijer, and R. J. M. Moormann.
1993.
Subgenomic RNAs of Lelystad virus contain a conserved leader-body junction sequence.
J. Gen. Virol.
74:1697-1701[Abstract/Free Full Text].
|
| 38.
|
Meulenberg, J. J. M.,
M. M. Hulst,
E. J. de Meijer,
P. L. J. M. Moonen,
A. den Besten,
E. P. de Kluyver,
G. Wensvoort, and R. J. M. Moormann.
1993.
Lelystad virus, the causative agent of porcine epidemic abortion and respiratory syndrome (PEARS), is related to LDV and EAV.
Virology
192:62-72[Medline].
|
| 39.
|
Meulenberg, J. J. M.,
J. N. A. Bos-de Ruijter,
R. van de Graaf,
G. Wensvoort, and R. J. M. Moormann.
1998.
Infectious transcripts from cloned genome-length cDNA of porcine reproductive and respiratory syndrome virus.
J. Virol.
72:380-387[Abstract/Free Full Text].
|
| 40.
|
Morozov, I.,
X. J. Meng, and P. S. Paul.
1995.
Sequence analysis of open reading frames (ORFs) 2 to 4 of a U.S. isolate of porcine reproductive and respiratory syndrome virus.
Arch. Virol.
140:1313-1319[Medline].
|
| 41.
|
Mounir, S.,
H. Mardassi, and S. Dea.
1995.
Identification and characterization of the porcine reproductive respiratory virus ORFs 7, 5 and 4 products.
Adv. Exp. Med. Biol.
80:317-320.
|
| 42.
|
Murtaugh, M. P.,
M. R. Elam, and L. T. Kakach.
1995.
Comparison of the structural protein coding sequences of the VR-2332 and Lelystad virus strains of the PRRS virus.
Arch. Virol.
140:1451-1460[Medline].
|
| 43.
|
Nelson, E. A.,
J. Christopher-Hennings, and D. A. Benfield.
1995.
Structural proteins of porcine reproductive and respiratory syndrome virus (PRRSV).
Adv. Exp. Med. Biol.
380:321-323[Medline].
|
| 44.
|
Palmer, G. A.,
L. Kuo,
Z. Chen,
K. S. Faaberg, and P. G. W. Plagemann.
1995.
Sequence of the genome of lactate dehydrogenase-elevating virus: heterogenicity between strains P and C.
Virology
209:637-642[Medline].
|
| 45.
|
Pirzadeh, B., and S. Dea.
1997.
Monoclonal antibodies to the ORF5 product of porcine reproductive and respiratory syndrome virus define linear neutralizing determinants.
J. Gen. Virol.
78:1867-1873[Abstract].
|
| 46.
|
Plagemann, P. G. W., and B. Moennig.
1992.
Lactate dehydrogenase-elevating virus, equine arteritis virus and simian hemorrhagic fever virus: a new group of positive stranded RNA viruses.
Adv. Virus Res.
41:99-192[Medline].
|
| 47.
|
Plagemann, P. G. W.
1996.
Lactate dehydrogenase-elevating virus and related viruses, p. 1105-1120.
In
B. N. Fields, D. M. Knipe, and P. M. Howley (ed.), Fields virology, 3rd ed. Lippincott-Raven Publishers, Philadelphia, Pa.
|
| 48.
|
Poch, O.,
I. Sauvaget,
M. Delarue, and N. Tordo.
1989.
Identification of four conserved motifs among the RNA dependent polymerase encoding elements.
EMBO J.
8:3867-3874[Medline].
|
| 49.
| Rossow, K. D., J. L. Shivers, P. E. Yeske, D. D. Polson, R. R. R. Rowland, S. R. Lawson, M. P. Murtaugh, E. A. Nelson, and J. E. Collins. Porcine reproductive and respiratory syndrome virus
infection in neonatal pigs characterized by marked neurovirulence.
Submitted for publication.
|
| 50.
|
Sagripanti, J. L.
1985.
Polyadenylic acid sequences in the genomic RNA of the togavirus of simian hemorrhagic fever.
Virology
145:350-355[Medline].
|
| 51.
|
Sagripanti, J. L.,
R. O. Zandomeni, and R. Weinmann.
1986.
The cap structure of simian hemorrhagic fever virion RNA.
Virology
151:146-150[Medline].
|
| 52.
|
Saito, A.,
T. Kanno,
Y. Murakami,
M. Muramatsu, and S. Yamaguchi.
1996.
Characteristics of major structural protein coding gene and leader-body sequence in subgenomic mRNA of porcine reproductive and respiratory syndrome virus isolated in Japan.
J. Vet. Med. Sci.
58:377-380[Medline].
|
| 53.
|
Sawicki, S. G., and D. L. Sawicki.
1995.
Coronaviruses use discontinuous extension for synthesis of subgenome-length negative strands.
Adv. Exp. Med. Biol.
380:499-506[Medline].
|
| 54.
|
Shieh, C. K.,
L. H. Soe,
S. Makino,
M. F. Chang,
S. A. Stohlman, and M. M. Lai.
1987.
The 5'-end sequence of the murine coronavirus genome: implications for multiple fusion sites in leader-primed transcription.
Virology
156:321-330[Medline].
|
| 55.
|
Smith, S. L.,
X. Wang, and E. K. Godeny.
1997.
Sequence of the 3' end of the simian hemorrhagic fever virus genome.
Gene
191:205-210[Medline].
|
| 56.
|
Snijder, E. J.,
A. L. M. Wassenaar, and W. J. M. Spaan.
1992.
The 5' end of the equine arteritis virus replicase gene encodes a papainlike cysteine protease.
J. Virol.
66:7040-7048[Abstract/Free Full Text].
|
| 57.
|
Snijder, E. J.,
A. L. M. Wassenaar, and W. J. M. Spaan.
1994.
Proteolytic processing of the replicase ORF1a protein of equine arteritis virus.
J. Virol.
68:5755-5764[Abstract/Free Full Text].
|
| 58.
|
Snijder, E. J.,
A. L. Wassenaar,
W. J. Spaan, and A. E. Gorbalenya.
1995.
The arterivirus Nsp2 protease. An unusual cysteine protease with primary structure similarities to both papain-like and chymotrypsin-like proteases.
J. Biol. Chem.
270:16671-16676[Abstract/Free Full Text].
|
| 59.
|
Snijder, E. J., and J. J. Meulenberg.
1998.
The molecular biology of arteriviruses.
J. Gen. Virol.
79:961-979[Medline].
|
| 60.
|
Triezenberg, S. J.
1992.
Primer extension, p. 4.8.1-4.8.5.
In
F. M. Ausubel, R. Brent, R. E. Kingston, D. D. Moore, J. G. Seidman, J. A. Smith, and K. Struhl (ed.), Current protocols in molecular biology. John Wiley & Sons, Inc., New York, N.Y.
|
| 61.
|
van Berlo, M. F.,
M. C. Horzinek, and B. A. van der Zeijst.
1982.
Equine arteritis virus-infected cells contain six polyadenylated virus-specific RNAs.
Virology
30:345-352.
|
| 62.
|
van Dinten, L. C.,
A. L. M. Wassenaar,
A. E. Gorbalenya,
W. J. M. Spaan, and E. J. Snijder.
1996.
Processing of the equine arteritis virus replicase ORF1b protein: identification of cleavage products containing the putative viral polymerase and helicase domains.
J. Virol.
70:6625-6633[Abstract/Free Full Text].
|
| 63.
|
van Dinten, L. C.,
J. A. den Boon,
A. L. Wassenaar,
W. J. Spaan, and E. J. Snijder.
1997.
An infectious arterivirus cDNA clone: identification of a replicase point mutation that abolishes discontinuous mRNA transcription.
Proc. Natl. Acad. Sci. USA
94:991-996[Abstract/Free Full Text].
|
| 64.
|
van Marle, G.,
R. G. van der Most,
T. van der Straaten,
W. Luytjes, and W. J. Spaan.
1995.
Regulation of transcription of coronaviruses.
Adv. Exp. Med. Biol.
380:507-510[Medline].
|
| 65.
|
van Nieuwstadt, A. P.,
J. J. M. Meulenberg,
A. van Essen-Zandbergen,
A. Petersen-den Besten,
R. J. Bende,
R. J. M. Moormann, and G. Wensvoort.
1996.
Proteins encoded by open reading frames 3 and 4 of the genome of Lelystad virus (Arteriviridae) are structural proteins of the virion.
J. Virol.
70:4767-4772[Abstract/Free Full Text].
|
| 66.
|
Wassenaar, A. L. M.,
W. J. M. Spaan,
A. E. Gorbalenya, and E. J. Snijder.
1997.
Alternative proteolytic processing of the arterivirus replicase ORF1a polyprotein: evidence that NSP2 acts as a cofactor for the NSP4 serine protease.
J. Virol.
71:9313-9322[Abstract/Free Full Text].
|
| 67.
|
Wensvoort, G.,
C. Terpstra,
J. M. A. Pol,
E. A. ter Laak,
M. Bloemraad,
E. P. de Kluyver,
C. Kragten,
L. van Buiten,
A. den Besten,
F. Wagenaar,
J. M. Broekhuijsen,
P. L. J. M. Moonen,
T. Zetstra,
E. A. de Boer,
H. J. Tibben,
M. F. de Jong,
P. van't Veld,
G. J. R. Groenland,
J. A. van Gennep,
M. T. Voets,
J. H. M. Verheijden, and J. Braamskamp.
1991.
Mystery swine disease in the Netherlands: the isolation of Lelystad virus.
Vet. Q.
13:121-130[Medline].
|
| 68.
|
Zeng, L.,
E. K. Godeny,
S. L. Methven, and M. A. Brinton.
1995.
Analysis of simian hemorrhagic fever virus (SHFV) subgenomic RNAs, junction sequences, and 5' leader.
Virology
207:543-548[Medline].
|
| 69.
|
Zhang, X.,
C.-L. Liao, and M. M. C. Lai.
1994.
Coronavirus leader RNA regulates and initiates subgenomic mRNA transcription both in trans and in cis.
J. Virol.
68:4738-4746[Abstract/Free Full Text].
|
| 70.
|
Zhang, X., and M. M. C. Lai.
1995.
Interactions between the cytoplasmic proteins and the intergenic (promoter) sequence of mouse hepatitis virus RNA: correlation with the amounts of subgenomic mRNA transcribed.
J. Virol.
69:1637-1644[Abstract/Free Full Text].
|
Journal of Virology, January 1999, p. 270-280, Vol. 73, No. 1
0022-538X/99/$04.00+0
Copyright © 1999, American Society for Microbiology. All rights reserved.
This article has been cited by other articles:
-
Drexler, C. S., Witvliet, M. H., Raes, M., van de Laar, M., Eggen, A. A. S., Thacker, E. L.
(2010). Efficacy of combined porcine reproductive and respiratory syndrome virus and Mycoplasma hyopneumoniae vaccination in piglets. Vet Rec.
166: 70-74
[Abstract]
[Full Text]
-
Cai, J.-P., Wang, Y.-D., Tse, H., Xiang, H., Yuen, K.-Y., Che, X.-Y.
(2009). Detection of Asymptomatic Antigenemia in Pigs Infected by Porcine Reproductive and Respiratory Syndrome Virus (PRRSV) by a Novel Capture Immunoassay with Monoclonal Antibodies against the Nucleocapsid Protein of PRRSV. CVI
16: 1822-1828
[Abstract]
[Full Text]
-
Sun, Y., Xue, F., Guo, Y., Ma, M., Hao, N., Zhang, X. C., Lou, Z., Li, X., Rao, Z.
(2009). Crystal Structure of Porcine Reproductive and Respiratory Syndrome Virus Leader Protease Nsp1{alpha}. J. Virol.
83: 10931-10940
[Abstract]
[Full Text]
-
Han, J., Rutherford, M. S., Faaberg, K. S.
(2009). The Porcine Reproductive and Respiratory Syndrome Virus nsp2 Cysteine Protease Domain Possesses both trans- and cis-Cleavage Activities. J. Virol.
83: 9449-9463
[Abstract]
[Full Text]
-
Brown, E., Lawson, S., Welbon, C., Gnanandarajah, J., Li, J., Murtaugh, M. P., Nelson, E. A., Molina, R. M., Zimmerman, J. J., Rowland, R. R. R., Fang, Y.
(2009). Antibody Response to Porcine Reproductive and Respiratory Syndrome Virus (PRRSV) Nonstructural Proteins and Implications for Diagnostic Detection and Differentiation of PRRSV Types I and II. CVI
16: 628-635
[Abstract]
[Full Text]
-
Okinaga, T., Yamagishi, T., Yoshii, M., Suzuki, T., Miyazaki, A., Takagi, M., Tsunemitsu, H.
(2009). Evaluation of unexpected positive results from a commercial ELISA for antibodies to PRRSV. Vet Rec.
164: 455-459
[Abstract]
[Full Text]
-
Spilman, M. S., Welbon, C., Nelson, E., Dokland, T.
(2009). Cryo-electron tomography of porcine reproductive and respiratory syndrome virus: organization of the nucleocapsid. J. Gen. Virol.
90: 527-535
[Abstract]
[Full Text]
-
Fang, Y., Christopher-Hennings, J., Brown, E., Liu, H., Chen, Z., Lawson, S. R., Breen, R., Clement, T., Gao, X., Bao, J., Knudsen, D., Daly, R., Nelson, E.
(2008). Development of genetic markers in the non-structural protein 2 region of a US type 1 porcine reproductive and respiratory syndrome virus: implications for future recombinant marker vaccine development. J. Gen. Virol.
89: 3086-3096
[Abstract]
[Full Text]
-
Molina, R. M., Chittick, W., Nelson, E. A., Christopher-Hennings, J., Rowland, R. R.R., Zimmerman, J. J.
(2008). Diagnostic performance of assays for the detection of anti-Porcine reproductive and respiratory syndrome virus antibodies in serum and muscle transudate ("meat juice") based on samples collected under experimental conditions. jvdi
20: 735-743
[Abstract]
[Full Text]
-
Lv, J., Zhang, J., Sun, Z., Liu, W., Yuan, S.
(2008). An infectious cDNA clone of a highly pathogenic porcine reproductive and respiratory syndrome virus variant associated with porcine high fever syndrome. J. Gen. Virol.
89: 2075-2079
[Abstract]
[Full Text]
-
Han, J., Liu, G., Wang, Y., Faaberg, K. S.
(2007). Identification of Nonessential Regions of the nsp2 Replicase Protein of Porcine Reproductive and Respiratory Syndrome Virus Strain VR-2332 for Replication in Cell Culture. J. Virol.
81: 9878-9890
[Abstract]
[Full Text]
-
Johnson, C. R., Yu, W., Murtaugh, M. P.
(2007). Cross-reactive antibody responses to nsp1 and nsp2 of Porcine reproductive and respiratory syndrome virus. J. Gen. Virol.
88: 1184-1195
[Abstract]
[Full Text]
-
Choi, Y.-J., Yun, S.-I., Kang, S.-Y., Lee, Y.-M.
(2006). Identification of 5' and 3' cis-Acting Elements of the Porcine Reproductive and Respiratory Syndrome Virus: Acquisition of Novel 5' AU-Rich Sequences Restored Replication of a 5'-Proximal 7-Nucleotide Deletion Mutant. J. Virol.
80: 723-736
[Abstract]
[Full Text]
-
Lee, C., Yoo, D.
(2005). Cysteine residues of the porcine reproductive and respiratory syndrome virus small envelope protein are non-essential for virus infectivity. J. Gen. Virol.
86: 3091-3096
[Abstract]
[Full Text]
-
Forsberg, R.
(2005). Divergence Time of Porcine Reproductive and Respiratory Syndrome Virus Subtypes. Mol Biol Evol
22: 2131-2134
[Abstract]
[Full Text]
-
Hanada, K., Suzuki, Y., Nakane, T., Hirose, O., Gojobori, T.
(2005). The Origin and Evolution of Porcine Reproductive and Respiratory Syndrome Viruses. Mol Biol Evol
22: 1024-1031
[Abstract]
[Full Text]
-
Cha, S.-H., Chang, C.-C., Yoon, K.-J.
(2004). Instability of the Restriction Fragment Length Polymorphism Pattern of Open Reading Frame 5 of Porcine Reproductive and Respiratory Syndrome Virus during Sequential Pig-to-Pig Passages. J. Clin. Microbiol.
42: 4462-4467
[Abstract]
[Full Text]
-
Pasternak, A. O., Spaan, W. J. M., Snijder, E. J.
(2004). Regulation of Relative Abundance of Arterivirus Subgenomic mRNAs. J. Virol.
78: 8102-8113
[Abstract]
[Full Text]
-
Ropp, S. L., Wees, C. E. M., Fang, Y., Nelson, E. A., Rossow, K. D., Bien, M., Arndt, B., Preszler, S., Steen, P., Christopher-Hennings, J., Collins, J. E., Benfield, D. A., Faaberg, K. S.
(2004). Characterization of Emerging European-Like Porcine Reproductive and Respiratory Syndrome Virus Isolates in the United States. J. Virol.
78: 3684-3703
[Abstract]
[Full Text]
-
VAN DEN BORN, E., GULTYAEV, A. P., SNIJDER, E. J.
(2004). Secondary structure and function of the 5'-proximal region of the equine arteritis virus RNA genome. RNA
10: 424-437
[Abstract]
[Full Text]
-
Balasuriya, U. B. R., Hedges, J. F., Smalley, V. L., Navarrette, A., McCollum, W. H., Timoney, P. J., Snijder, E. J., MacLachlan, N. J.
(2004). Genetic characterization of equine arteritis virus during persistent infection of stallions. J. Gen. Virol.
85: 379-390
[Abstract]
[Full Text]
-
Yoo, D., Wootton, S. K., Li, G., Song, C., Rowland, R. R.
(2003). Colocalization and Interaction of the Porcine Arterivirus Nucleocapsid Protein with the Small Nucleolar RNA-Associated Protein Fibrillarin. J. Virol.
77: 12173-12183
[Abstract]
[Full Text]
-
Key, K. F., Guenette, D. K., Yoon, K.-J., Halbur, P. G., Toth, T. E., Meng, X. J.
(2003). Development of a Heteroduplex Mobility Assay To Identify Field Isolates of Porcine Reproductive and Respiratory Syndrome Virus with Nucleotide Sequences Closely Related to Those of Modified Live-Attenuated Vaccines. J. Clin. Microbiol.
41: 2433-2439
[Abstract]
[Full Text]
-
Nielsen, H. S., Liu, G., Nielsen, J., Oleksiewicz, M. B., Botner, A., Storgaard, T., Faaberg, K. S.
(2003). Generation of an Infectious Clone of VR-2332, a Highly Virulent North American-Type Isolate of Porcine Reproductive and Respiratory Syndrome Virus. J. Virol.
77: 3702-3711
[Abstract]
[Full Text]
-
Pasternak, A. O., van den Born, E., Spaan, W. J. M., Snijder, E. J.
(2003). The Stability of the Duplex between Sense and Antisense Transcription-Regulating Sequences Is a Crucial Factor in Arterivirus Subgenomic mRNA Synthesis. J. Virol.
77: 1175-1183
[Abstract]
[Full Text]
-
Wootton, S. K., Rowland, R. R. R., Yoo, D.
(2002). Phosphorylation of the Porcine Reproductive and Respiratory Syndrome Virus Nucleocapsid Protein. J. Virol.
76: 10569-10576
[Abstract]
[Full Text]
-
Stadejek, T., Stankevicius, A., Storgaard, T., Oleksiewicz, M. B., Belak, S., Drew, T. W., Pejsak, Z.
(2002). Identification of radically different variants of porcine reproductive and respiratory syndrome virus in Eastern Europe: towards a common ancestor for European and American viruses. J. Gen. Virol.
83: 1861-1873
[Abstract]
[Full Text]
-
Oleksiewicz, M. B., Botner, A., Normann, P.
(2002). Porcine B-cells recognize epitopes that are conserved between the structural proteins of American- and European-type porcine reproductive and respiratory syndrome virus. J. Gen. Virol.
83: 1407-1418
[Abstract]
[Full Text]
-
Chang, C.-C., Yoon, K.-J., Zimmerman, J. J., Harmon, K. M., Dixon, P. M., Dvorak, C. M. T., Murtaugh, M. P.
(2002). Evolution of Porcine Reproductive and Respiratory Syndrome Virus during Sequential Passages in Pigs. J. Virol.
76: 4750-4763
[Abstract]
[Full Text]
-
Nielsen, H. S., Oleksiewicz, M. B., Forsberg, R., Stadejek, T., Bøtner, A., Storgaard, T.
(2001). Reversion of a live porcine reproductive and respiratory syndrome virus vaccine investigated by parallel mutations. J. Gen. Virol.
82: 1263-1272
[Abstract]
[Full Text]
-
Wootton, S., Koljesar, G., Yang, L., Yoon, K.-J., Yoo, D.
(2001). Antigenic Importance of the Carboxy-Terminal Beta-Strand of the Porcine Reproductive and Respiratory Syndrome Virus Nucleocapsid Protein. CVI
8: 598-603
[Abstract]
[Full Text]
-
Oleksiewicz, M. B., Botner, A., Toft, P., Normann, P., Storgaard, T.
(2001). Epitope Mapping Porcine Reproductive and Respiratory Syndrome Virus by Phage Display: the nsp2 Fragment of the Replicase Polyprotein Contains a Cluster of B-Cell Epitopes. J. Virol.
75: 3277-3290
[Abstract]
[Full Text]
-
Tijms, M. A., van Dinten, L. C., Gorbalenya, A. E., Snijder, E. J.
(2001). A zinc finger-containing papain-like protease couples subgenomic mRNA synthesis to genome translation in a positive-stranded RNA virus. Proc. Natl. Acad. Sci. USA
10.1073/pnas.041390398v1
[Abstract]
[Full Text]
-
Pasternak, A. O., Gultyaev, A. P., Spaan, W. J. M., Snijder, E. J.
(2000). Genetic Manipulation of Arterivirus Alternative mRNA Leader-Body Junction Sites Reveals Tight Regulation of Structural Protein Expression. J. Virol.
74: 11642-11653
[Abstract]
[Full Text]
-
Ziebuhr, J., Snijder, E. J., Gorbalenya, A. E.
(2000). Virus-encoded proteinases and proteolytic processing in the Nidovirales. J. Gen. Virol.
81: 853-879
[Full Text]
-
Goldberg, T. L., Hahn, E. C., Weigel, R. M., Scherba, G.
(2000). Genetic, geographical and temporal variation of porcine reproductive and respiratory syndrome virus in Illinois. J. Gen. Virol.
81: 171-179
[Abstract]
[Full Text]
-
Tijms, M. A., van Dinten, L. C., Gorbalenya, A. E., Snijder, E. J.
(2001). A zinc finger-containing papain-like protease couples subgenomic mRNA synthesis to genome translation in a positive-stranded RNA virus. Proc. Natl. Acad. Sci. USA
98: 1889-1894
[Abstract]
[Full Text]
Top
Abstract
Introduction
