Diversity and evolution of a newly emerged North American Type 1 porcine arterivirus: analysis of isolates collected between 1999 and 2004.

European-like Type 1 porcine reproductive and respiratory syndrome virus (PRRSV) isolates, known as North American (NA) Type 1 PRRSV, appeared in United States (U.S.) swine herds in 1999. Their diversity and evolution were studied over a five-year period by constructing phylogenetic trees using nsp2 and ORF5 sequences of 20 NA Type 1 isolates, including the only known isolate from Hawaii. All but two of the isolates possessed the same 51-nt deletion in nsp2, suggesting a clonal origin. Parsimony and distance analysis showed that viruses could be placed into two distinct sub-clades, which were similar for both nsp2 and ORF5. An incongruity between the two trees identified one isolate, 04-41, as the product of recombination. Recombination analysis using SimPlot identified a break point located downstream of the nsp2/3 junction. Results from this study suggest that NA Type 1 PRRSV in the U.S. is a well-established and rapidly evolving group. However, the forces driving genetic diversity and separation are complex and remain to be elucidated.

Generation of an infectious clone of VR-2332, a highly virulent North American-type isolate of porcine reproductive and respiratory syndrome virus.

A full-length cDNA clone of the prototypical North American porcine reproductive and respiratory syndrome virus (PRRSV) isolate VR-2332 was assembled in the plasmid vector pOK(12). To rescue infectious virus, capped RNA was transcribed in vitro from the pOK(12) clone and transfected into BHK-21C cells. The supernatant from transfected monolayers were serially passaged on Marc-145 cells and porcine pulmonary alveolar macrophages. Infectious PRRSV was recovered on Marc-145 cells as well as porcine pulmonary macrophages; thus, the cloned virus exhibited the same cell tropism as the parental VR-2332 strain. However, the cloned virus was clearly distinguishable from the parental VR-2332 strain by an engineered marker, a BstZ17I restriction site. The full-length cDNA clone had 11 nucleotide changes, 2 of which affected coding, compared to the parental VR-2332 strain. Additionally, the transcribed RNA had an extra G at the 5' end. To examine whether these changes influenced viral replication, we examined the growth kinetics of the cloned virus in vitro. In Marc-145 cells, the growth kinetics of the cloned virus reflected those of the parental isolate, even though the titers of the cloned virus were consistently slightly lower. In experimentally infected 5.5-week-old pigs, the cloned virus produced blue discoloration of the ears, a classical clinical symptom of PRRSV. Also, the seroconversion kinetics of pigs infected with the cloned virus and VR-2332 were very similar. Hence, virus derived from the full-length cDNA clone appeared to recapitulate the biological properties of the highly virulent parental VR-2332 strain. This is the first report of an infectious cDNA clone based on American-type PRRSV. The availability of this cDNA clone will allow examination of the molecular mechanisms behind PRRSV virulence and attenuation, which might in turn allow the production of second-generation, genetically engineered PRRSV vaccines.

The primary neutralization epitope of porcine respiratory and reproductive syndrome virus strain VR-2332 is located in the middle of the GP5 ectodomain.

Pigs infected with porcine respiratory and reproductive syndrome virus (PRRSV) strain VR-2332 were found to generate high levels of antibodies (Abs) that bound in an indirect ELISA to synthetic peptides representing segments of the primary envelope glycoprotein (GP5) ectodomain of this virus. Use of overlapping GP5 ectodomain peptides of various length indicated that the epitope recognized by the Abs was located in the middle of the ectodomain (amino acids 36-52), in the same relative segment that contains the single linear neutralization epitope of the closely related mouse arterivirus, lactate dehydrogenase-elevating virus (LDV). The VR-2332 GP5 segment exhibits 77% amino acid homology with the corresponding GP5 ectodomain segments of both the European PRRSV strain Lelystad virus (LV) and LDV. This explains some observed crossreaction between the pig Abs and neutralizing anti-LDV monoclonal Abs with peptides representing the GP5 ectodomains of VR-2332, LV and LDV. The GP5 binding Abs of pigs seem to be the primary PRRSV neutralizing Abs, since the well timed appearance in sera of all VR-2332 infected pigs of GP5 peptide binding Abs correlated 100% with the appearance of neutralizing Abs and earlier studies indicated that GP5 of PRRSV, like that of other arteriviruses, contains the main neutralization epitope of PRRSV. In addition, one neutralizing anti-LDV monoclonal Ab that is specific for the GP5 ectodomain epitope of LDV also strongly neutralized both PRRSV strains, VR-2332 and LV. The PRRSV GP5 epitope is associated with an N-glycan that is conserved in both PRRSV genotypes and all LDV isolates. This N-glycan may impede the humoral immune control of PRRSV in infected pigs and might be responsible for the low immunogenicity of PRRSV when injected into mice.

Complete genome comparison of porcine reproductive and respiratory syndrome virus parental and attenuated strains.

Two full-length porcine reproductive and respiratory syndrome virus (PRRSV) genomes, strain VR-2332 and its cell culture passaged descendent RespPRRS vaccine strain, were compared and analyzed in order to identify possible sites of attenuation. Of the 41 nucleotide changes, 12 resulted in conservative changes and 18 produced non-conservative changes. The results suggest that key amino acids in ORF1 may contribute to the phenotype of RespPRRS, which includes increased growth rate on MA-104 cells and decreased virulence in swine. The results provide a genetic basis for future manipulation of a PRRSV reverse genetics system.

Complete genome comparison of porcine reproductive and respiratory syndrome virus parental and attenuated strains.

Two full-length porcine reproductive and respiratory syndrome virus (PRRSV) genomes, strain VR-2332 and its cell culture passaged descendent RespPRRS vaccine strain, were compared and analyzed in order to identify possible sites of attenuation. Of the 44 nucleotide changes, 13 resulted in conservative changes and 18 produced non-conservative changes. The results suggest that key amino acids in ORF1 may contribute to the phenotype of RespPRRS, which includes increased growth rate on MA-104 cells and decreased virulence in swine. The results provide a genetic basis for future manipulation of a PRRSV reverse genetics system.

Heteroclite subgenomic RNAs are produced in porcine reproductive and respiratory syndrome virus infection.

Porcine reproductive and respiratory syndrome virus (PRRSV) was shown to produce atypical subgenomic RNAs that contain open reading frame la nucleotides and are present under a wide variety of culture conditions, including high and low multiplicities of infection, in simian and porcine host cells, and during infection with cell-adapted and wild-type PRIRSV strains. Sequence analysis demonstrated that they are heterogeneous in 5-3' junction sequence and size and may code for different predicted fusion proteins. This is the first report of these novel RNA5 in arteriviruses and we have termed them heteroclite (meaning 'deviating from common forms or rules") subgenomic RNAs. The unique properties of these subgenomic RNAs include (a) apparent association with normal virus infection and stability during serial passage, (b) packaging of heteroclite RNAs into virus-like particles, (c) short, heterogeneous sequences which may mediate the generation of these RNAs, (d) a primary structure which consists of the two genomic termini with one large internal deletion, and (eJ little apparent interference with parental virus replication. These subgenomic RNA5 may be critical to, or a necessary side product of, viral replication. The expression of these novel RNA species support the template-switching model of similarity-assisted RNA recombination. In summary, PRRSV readily undergoes nonhomologous RNA recombination to generate heteroclite sub-genomic RNA5.

Recombination between North American strains of porcine reproductive and respiratory syndrome virus.

Porcine reproductive and respiratory syndrome virus (PRRSV), a recently discovered arterivirus swine pathogen, was shown to undergo homologous recombination. Co-infection of MA-104 cells with two culture-adapted North American PRRSV strains resulted in recombinant viral particles containing chimeric ORF 3 and ORF 4 proteins. Nucleotide sequence analysis of cloned recombinant PCR products, encompassing 1182 bases of the 15.4 kb viral genome, revealed six independent recombination events. Recombinant products persisted in culture for at least three passages, indicating continuous formation of recombinant viruses, growth of recombinant viruses in competition with parental viruses, or both. The frequency of recombination was estimated from <2% up to 10% in the 1182 b fragment analyzed, which is similar to recombination frequencies observed in coronaviruses. An apparent example of natural ORF 5 recombination between naturally occurring wild type viruses was also found, indicating that recombination is likely an important genetic mechanism contributing to PRRSV evolution.

Porcine reproductive and respiratory syndrome virus comparison: divergent evolution on two continents.

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.

Subgenomic RNA7 is transcribed with different leader-body junction sites in PRRSV (strain VR2332) infection of CL2621 cells.

Porcine reproductive and respiratory syndrome virus (PRRSV), like all members of the order Nidoviridae, is expressed in the infected cell as a nested set of subgenomic (sg) RNAs with a common 5'-leader sequence. We have determined that the 5'-leader sequence for the US prototype strain (VR2332, Collins, et al., 1992) is distinct from the European prototype strain [Lelystad (LV); Wensvoort, et al., 1991, Meulenberg et al., 1993a], yet these two strains use almost the same sequence for downstream sites of 5'-leader-body junction formation. Analysis of VR2332 genomic sequence identified several potential 5'-leader-body junction sequences upstream of open reading frame (ORF) 7, coding for the nucleocapsid protein, that could be used for generation of VR2332 sgRNA7 transcripts. Sequence determinations of RT-PCR-generated cDNA clones of sgRNA7 identified two species of RNA7 transcripts in infected cells, one utilizing a leader-body junction sequence (AUAACC) 123 nucleotides upstream of the AUG start site and one utilizing a sequence (UAAACC) 9 nucleotides upstream of the AUG start site for ORF7 translation.

Genetic variation in the PRRS virus.

Porcine reproductive and respiratory syndrome (PRRS) is characterized by late-term abortions and stillbirths in sows and respiratory difficulties in nursery pigs. The disease appeared in Europe and North America at approximately the same time between 1985 and 1990. The PRRS virus was isolated shortly thereafter and demonstrated unexpectedly profound differences between European (Lelystad) and North American (VR2332) isolates as measured by serological crossreactivity and nucleotide sequence similarity. In order to determine the amount of genetic variation in the PRRS virus and to understand the molecular mechanisms of viral evolution, nucleotide sequences of PRRS virus strains were determined. Comparisons among ten U.S. strains showed that variation in primary nucleotide sequence between isolates ranged from 2.5% to 7.9% for ORFs 2-7. In contrast, Lelystad virus was, on average, 35% different from US clones. These results provided direct molecular evidence that US and European PRRSV isolates represented genetically distinct groups of the same viral family. A further analysis of more than 150 isolates in the United States and Canada demonstrated that the PRRS virus in North America represents a single large and diverse genetic group that is distinct from European forms of the virus.

ORF 3 of lactate dehydrogenase-elevating virus encodes a soluble, nonstructural, highly glycosylated, and antigenic protein.

Open reading frame (ORF) 3 of the genome of lactate dehydrogenase-elevating virus (LDV), strain P, was cloned into the plasmid pcDNAI/Amp and in vitro transcribed and translated. Translation of ORF 3 yielded a soluble protein of the expected size (about 21 kDa). When synthesized in the presence of endoplasmic reticulum (ER) membranes the resulting glycoprotein of about 36 kDa became associated with the membranes. However, disruption of the ER vesicles by incubation in carbonate buffer, pH 11.5, resulted in the release of the protein from the membranes. Hydrophobic moment analysis of the ORF 3 protein indicated the absence of any potential transmembrane segments, except for a N-terminal signal peptide, but no cleavage of the signal peptide was observed during membrane-associated in vitro synthesis. The ORF 3 protein elicited a strong antibody response in infected mice. The antibodies from infected mice as well as a monoclonal antibody specifically precipitated the in vitro-synthesized ORF 3 protein, but no protein from LDV virions. The overall results suggest that the ORF 3 protein is a nonstructural, highly glycosylated, and antigenic glycoprotein that is probably soluble and secreted or at most only weakly associated with membranes via the signal peptide.

Membrane association of the C-terminal half of the open reading frame 1a protein of lactate dehydrogenase-elevating virus.

ORF 1a of lactate dehydrogenase-elevating virus, strain P (LDV-P), encodes a protein of 2206 amino acids. Eisenberg hydrophobic moment analysis of the protein predicted the presence of eleven transmembrane segments in the C-terminal half of the molecule (amino acids 980-1852) that flank the serine protease domain. cDNAs encoding ORF 1a protein segments encompassing transmembrane segments 5 to 11 and its amphipathic C-terminal end as well as the N-terminal 80 amino acids of the downstream ORF 1b protein were transcribed and the transcripts in vitro translated in the absence and presence of microsomal membranes. The synthesis of the protein products with putative transmembrane segments was enhanced by the presence of the microsomal membranes and the proteins became membrane associated. When synthesized in the absence of membranes they were recovered in the supernatant upon ultracentrifugation of the translation reaction mixtures, whereas they were recovered in the membrane pellet when synthesized in the presence of membranes. Furthermore, the latter proteins were not released from the membranes by disruption of the membrane vesicles in carbonate buffer, pH 11.5, and large portions of the proteins were resistant to digestion by trypsin, chymotrypsin and proteinase K. No N-glycosylation was observed and only little, if any, processing of the protein by the putative serine protease. The results indicate that the C-terminal half of the ORF 1a protein represents a non-glycosylated integral membrane protein. Potential modes of synthesis and function of the protein are discussed. In addition, the results showed that the synthesis of the ORF 1a protein was generally terminated at its termination codon, but that read-through into the ORF 1b gene occurred with low frequency.

Differential glycosylation of the ectodomain of the primary envelope glycoprotein of two strains of lactate dehydrogenase-elevating virus that differ in neuropathogenicity.

ORF 5 encoding the primary envelope glycoprotein, VP-3P, of a highly neuropathogenic isolate of lactate dehydrogenase-elevating virus (LDV-v) has been sequenced. It exhibits 92% nucleotide identity with the ORF 5 of an LDV isolate that lacks neuropathogenicity, LDV-P, and the amino acid identities of the predicted VP-3Ps of the two strains is 90%. Most striking, however, is the absence in the ectodomain of LDV-v VP-3P of two out of three potential N-glycosylation sites present in the ectodomain of VP-3P of LDV-P. The ectodomain of VP-3P has been implicated to play an important role in host receptor interaction. VP-3P of another neuropathogenic LDV strain, LDV-C, lacks the same two N-glycosylation sites (Godeny et al., 1993). In vitro transcription/translation of the ORFs 5 of LDV-P and LDV-v indicated that all three N-glycosylation sites in the ectodomain of LDV-P VP-3P became glycosylated when synthesized in the presence of microsomal membranes, whereas the glycosylation of the ORF 5 proteins of LDV-v and LDV-C was consistent with glycosylation at a single site. No other biological differences between the neuropathogenic and non-neuropathogenic strains have been detected. They replicate with equal efficiency in mice and in primary macrophage cultures.

The envelope proteins of lactate dehydrogenase-elevating virus and their membrane topography.

We have studied the membrane topography and N-glycosylation of the envelope proteins of lactate dehydrogenase-elevating virus (LDV, strain P). Transcripts of open reading frames (ORFs) 2, 5, and 6 were in vitro translated in the absence and presence of microsomal membranes, and the products analyzed for molecular weight, sensitivity to endoglycosidase F/N-glycosidase F and proteinases, and reaction with anti-LDV antibodies. The ORF 6 mRNA translation was enhanced in the presence of microsomal membranes. ORF 6 encodes a polytopic class III membrane protein identified as the nonglycosylated virion envelope protein (M/VP-2; approximately 18 kDa). The protein has a very short (about 11 amino acids) ectodomain, a longer (about 79 amino acids) C-terminal endodomain, and crosses the membrane three times between these domains. ORF 5 encodes the primary virion envelope glycoprotein (VP-3P) (25-42 kDa). Our results suggest that it is a polytopic class I glycoprotein. After removal of a signal peptide, the processed protein of about 171 amino acids consists of a short (approximately 30 amino acids) N-terminal ectodomain with three asparagine residues that appear to be N-glycosylated, a segment that crosses the membrane three times, and an about 74 amino acid long C-terminal endodomain. Neutralizing anti-LDV antibodies are probably directed to an epitope(s) in the N-terminal ectodomain. The ORF 2 protein is a standard class I glycoprotein with a single C-terminal membrane anchor segment and its signal peptide is removed during membrane-associated synthesis. The remaining ectodomain (about 165 amino acids) contains three asparagine residues which appear to be N-glycosylated. Our results suggest that the ORF 2 protein may be present in a low concentration in LDV virions (VP-3M).

Processing and evolution of the N-terminal region of the arterivirus replicase ORF1a protein: identification of two papainlike cysteine proteases.

Two adjacent papainlike cysteine protease (PCP) domains, PCP alpha and PCP beta, were identified in the N-terminal region of the open reading frame 1a replicase proteins of the arteriviruses porcine reproductive and respiratory syndrome virus and lactate dehydrogenase-elevating virus. The replicase of the related virus equine arteritis virus contains only one active PCP in the corresponding region. Sequence comparison revealed that the equine arteritis virus PCP alpha counterpart probably was inactivated by loss of its catalytic Cys residue. For both porcine reproductive and respiratory syndrome virus and lactate dehydrogenase-elevating virus, the generation of two processing products, nsp1 alpha and nsp1 beta, was demonstrated by in vitro translation. Site-directed mutagenesis and sequence comparison were used to identify the putative active-site residues of the PCP alpha and PCP beta protease domains and to show that they mediate the nsp1 alpha/1 beta and nsp1 beta/2 cleavages, respectively.

Sequence of the genome of lactate dehydrogenase-elevating virus: heterogenicity between strains P and C.

The complete nucleotide sequence of genomic RNA (14104 nt) of one strain of lactate dehydrogenase-elevating virus (LDV), LDV-P, is reported. It exhibits only about 80% nucleotide identity with the sequence reported for another LDV strain, LDV-C (Godeny et al., Virology 194, 585-596 (1993), and is 68 nucleotides shorter than the reported LDV-C sequence. The difference in length is largely due to the lack of a 59-nucleotide-long direct repeat in ORF 1a of the reported LDV-C sequence. Sequence analysis of a total of 1.4 kb of ORF 1a of LDV-C via reverse transcription/polymerase chain reaction (RT/PCR) technology failed to confirm the presence of this repeat in the LDV-C genome as well as of 24 deletions/insertions of single nucleotides that give rise to apparent transient reading frame differences between the LDV-P and LDV-C genomes and might have represented frameshift mutations. An additional 35 nucleotides in ORF 1a of the RT/PCR LDV-C products were the same as in the LDV-P rather than the reported LDV-C genome. The nucleotide sequences of the 5' leader and the 3' noncoding ends of the two genomes and the heptanucleotides involved in joining the 5' leader to the bodies of the subgenomic mRNAs were highly conserved or identical. The predicted LDV-P proteins, however, differed from those predicted for the LDV-C proteins between 25% for the ORF 2 protein and 1% for the ORF 7 nucleocapsid protein. All functional motifs of the ORF 1a and ORF 1b proteins were conserved. The ORF 1a protein possesses 11 potential transmembrane segments that flank the serine protease domain.

Disulfide bonds between two envelope proteins of lactate dehydrogenase-elevating virus are essential for viral infectivity.

Disulfide bonds were found to link the nonglycosylated envelope protein VP-2/M (19 kDa), encoded by open reading frame 6, and the major envelope glycoprotein VP-3 (25 to 42 kDa), encoded by open reading frame 5, of lactate dehydrogenase-elevating virus (LDV). The two proteins comigrated in a complex of 45 to 55 kDa when the virion proteins were electrophoresed under nonreducing conditions but dissociated under reducing conditions. Furthermore, VP-2/M was quantitatively precipitated along with VP-3 in this complex by three neutralizing monoclonal antibodies to VP-3. The infectivity of LDV was rapidly and irreversibly lost during incubation with 5 to 10 mM dithiothreitol (> 99% in 6 h at room temperature), which is known to reduce disulfide bonds. LDV inactivation correlated with dissociation of VP-2/M and VP-3. The results suggest that disulfide bonds between VP-2/M and VP-3 are important for LDV infectivity. Hydrophobic moment analyses of the predicted proteins suggest that VP-2/M and VP-3 both possess three adjacent transmembrane segments and only very short ectodomains (10 and 32 amino acids, respectively) with one and two cysteines, respectively. Inactivation of LDV by dithiothreitol and dissociation of the two envelope proteins were not associated with alterations in LDV's density or sedimentation coefficient.