Molecular characterization of the 3' terminus of the simian hemorrhagic fever virus genome

Selection and characterization of scFv antibody against nucleocapsid protein of Porcine reproductive and respiratory syndrome virus

Porcine reproductive and respiratory syndrome virus (PRRSV) is a widespread infectious agent in pigs. Nucleocapsid (N) protein of PRRSV has been identified as the most immunodominant viral protein. The main goal of the work was the selection and characterization of a single-chain antibody fragments (scFv) antibody specific to the N protein. Specific scFv antibody clone D5 was selected from the Tomlinson phagemid library and purified by immobilized metal affinity chromatography from the periplasmatic space of E. coli cells. The antibody was then characterized by sequencing and the ability to recognize the native virus N protein by Western blot and competitive ELISA. Pepscan analysis identified the position of the binding epitope between amino acids 62–84 of the N protein. Our study could help to improve the diagnostics and prevention of PRRSV in Central Europe.

Expanded subgenomic mRNA transcriptome and coding capacity of a nidovirus

Members of the order Nidovirales express their structural protein ORFs from a nested set of 3' subgenomic mRNAs (sg mRNAs), and for most of these ORFs, a single genomic transcription regulatory sequence (TRS) was identified. Nine TRSs were previously reported for the arterivirus Simian hemorrhagic fever virus (SHFV). In the present study, which was facilitated by next-generation sequencing, 96 SHFV body TRSs were identified that were functional in both infected MA104 cells and macaque macrophages. The abundance of sg mRNAs produced from individual TRSs was consistent over time in the two different cell types. Most of the TRSs are located in the genomic 3' region, but some are in the 5' ORF1a/1b region and provide alternative sources of nonstructural proteins. Multiple functional TRSs were identified for the majority of the SHFV 3' ORFs, and four previously identified TRSs were found not to be the predominant ones used. A third of the TRSs generated sg mRNAs with variant leader-body junction sequences. Sg mRNAs encoding E', GP2, or ORF5a as their 5' ORF as well as sg mRNAs encoding six previously unreported alternative frame ORFs or 14 previously unreported C-terminal ORFs of known proteins were also identified. Mutation of the start codon of two C-terminal ORFs in an infectious clone reduced virus yield. Mass spectrometry detected one previously unreported protein and suggested translation of some of the C-terminal ORFs. The results reveal the complexity of the transcriptional regulatory mechanism and expanded coding capacity for SHFV, which may also be characteristic of other nidoviruses.

Simian hemorrhagic fever virus cell entry is dependent on CD163 and uses a clathrin-mediated endocytosis-like pathway

Simian hemorrhagic fever virus (SHFV) causes a severe and almost uniformly fatal viral hemorrhagic fever in Asian macaques but is thought to be nonpathogenic for humans. To date, the SHFV life cycle is almost completely uncharacterized on the molecular level. Here, we describe the first steps of the SHFV life cycle. Our experiments indicate that SHFV enters target cells by low-pH-dependent endocytosis. Dynamin inhibitors, chlorpromazine, methyl-β-cyclodextrin, chloroquine, and concanamycin A dramatically reduced SHFV entry efficiency, whereas the macropinocytosis inhibitors EIPA, blebbistatin, and wortmannin and the caveolin-mediated endocytosis inhibitors nystatin and filipin III had no effect. Furthermore, overexpression and knockout study and electron microscopy results indicate that SHFV entry occurs by a dynamin-dependent clathrin-mediated endocytosis-like pathway. Experiments utilizing latrunculin B, cytochalasin B, and cytochalasin D indicate that SHFV does not hijack the actin polymerization pathway. Treatment of target cells with proteases (proteinase K, papain, α-chymotrypsin, and trypsin) abrogated entry, indicating that the SHFV cell surface receptor is a protein. Phospholipases A2 and D had no effect on SHFV entry. Finally, treatment of cells with antibodies targeting CD163, a cell surface molecule identified as an entry factor for the SHFV-related porcine reproductive and respiratory syndrome virus, diminished SHFV replication, identifying CD163 as an important SHFV entry component.

IMPORTANCE

Simian hemorrhagic fever virus (SHFV) causes highly lethal disease in Asian macaques resembling human illness caused by Ebola or Lassa virus. However, little is known about SHFV's ecology and molecular biology and the mechanism by which it causes disease. The results of this study shed light on how SHFV enters its target cells. Using electron microscopy and inhibitors for various cellular pathways, we demonstrate that SHFV invades cells by low-pH-dependent, actin-independent endocytosis, likely with the help of a cellular surface protein.

Functional analyses of the three simian hemorrhagic fever virus nonstructural protein 1 papain-like proteases

The N-terminal region of simian hemorrhagic fever virus (SHFV) nonstructural polyprotein 1a is predicted to encode three papain-like proteases (PLP1α, PLP1β, and PLP1γ). Catalytic residues and cleavage sites for each of the SHFV PLP1s were predicted by alignment of the SHFV PLP1 region sequences with each other as well as with those of other arteriviruses, and the predicted catalytic residues were shown to be proximal by homology modeling of the SHFV nsp1s on porcine respiratory and reproductive syndrome virus (PRRSV) nsp1 crystal structures. The functionality of the predicted catalytic Cys residues and cleavage sites was tested by analysis of the autoproteolytic products generated in in vitro transcription/translation reactions done with wild-type or mutant SHFV nsp1 constructs. Cleavage sites were also analyzed by mass spectroscopy analysis of selected immunoprecipitated cleavage products. The data showed that each of the three SHFV PLP1s is an active protease. Cys63 was identified as the catalytic Cys of SHFV PLP1α and is adjacent to an Ala instead of the canonical Tyr observed in other arterivirus PLP1s. SHFV PLP1γ is able to cleave at both downstream and upstream nsp1 junction sites. Although intermediate precursor polyproteins as well as alternative products generated by each of the SHFV PLP1s cleaving at sites within the N-terminal region of nsp1β were produced in the in vitro reactions, Western blotting of SHFV-infected, MA104 cell lysates with SHFV nsp1 protein-specific antibodies detected only the three mature nsp1 proteins.

IMPORTANCE

SHFV is unique among arteriviruses in having three N-terminal papain-like protease 1 (PLP1) domains. Other arteriviruses encode one or two active PLP1s. This is the first functional study of the SHFV PLP1s. Analysis of the products of in vitro autoprocessing of an N-terminal SHFV nonstructural 1a polypeptide fragment showed that each of the three SHFV PLP1s is active, and the predicted catalytic Cys residues and cleavage sites for each PLP1 were confirmed by testing mutant constructs. Several unique features of the SHFV PLP1s were discovered. The SHFV PLP1α catalytic Cys63 is unique among arterivirus PLP1s in being adjacent to an Ala instead of a Trp. Other arterivirus PLP1s cleave only in cis at a single downstream site, but SHFV PLP1γ can cleave at both the downstream nsp1γ-nsp2 and upstream nsp1β-nsp1γ junctions. The three mature nsp1 proteins were produced both in the in vitro reactions and in infected cells.

Each of the eight simian hemorrhagic fever virus minor structural proteins is functionally important

The simian hemorrhagic fever virus (SHFV) genome differs from those of other members of the family Arterivirus in encoding two adjacent sets of four minor structural protein open reading frames (ORFs). A stable, full-length, infectious SHFV-LVR cDNA clone was constructed. Virus produced from this clone had replication characteristics similar to those of the parental virus. A subgenomic mRNA was identified for the SHFV ORF previously identified as 2b. As an initial means of analyzing the functional relevance of each of the SHFV minor structural proteins, a set of mutant infectious clones was generated, each with the start codon of one minor structural protein ORF mutated. Different phenotypes were observed for each ortholog of the pairs of minor glycoproteins and all of the eight minor structural proteins were required for the production of infectious extracellular virus indicating that the duplicated sets of SHFV minor structural proteins are not functionally redundant.

Disulfide linkages mediating nucleocapsid protein dimerization are not required for porcine arterivirus infectivity

The nucleocapsid (N) proteins of the North American (type II) and European (type I) genotypes of porcine reproductive and respiratory syndrome virus (PRRSV) share only approximately 60% genetic identity, and the functionality of N in both genotypes, especially its role in virion assembly, is still poorly understood. In this study, we demonstrated that the ORF7 3' untranslated region or ORF7 of type I is functional in the type II PRRSV background. Based on these results, we postulated that the cysteine at position 90 (Cys90) of the type II N protein, which corresponds to an alanine in the type I protein, is nonessential for virus infectivity. The replacement of Cys90 with alanine confirmed this hypothesis. We then hypothesized that all of the cysteines in the N protein could be replaced by alanines. Mutational analysis revealed that, in contradiction to previously reported findings, the replacement of all of the cysteines, either singly or in combination, did not impair the growth of either type II or type I PRRSV. Treatment with the alkylating agent N-ethylmaleimide inhibited cysteine-mediated N dimerization in living cells but not in released virions. Additionally, bimolecular fluorescence complementation assays revealed noncovalent interactions in living cells among the N and C termini and between the N-terminal and C-terminal regions of the N proteins of both genotypes of PRRSV. These results demonstrate that the disulfide linkages mediating the N dimerization are not required for PRRSV viability and help to promote our understanding of the mechanism underlying arterivirus particle assembly.

Using hidden Markov models and observed evolution to annotate viral genomes

MOTIVATION

ssRNA (single stranded) viral genomes are generally constrained in length and utilize overlapping reading frames to maximally exploit the coding potential within the genome length restrictions. This overlapping coding phenomenon leads to complex evolutionary constraints operating on the genome. In regions which code for more than one protein, silent mutations in one reading frame generally have a protein coding effect in another. To maximize coding flexibility in all reading frames, overlapping regions are often compositionally biased towards amino acids which are 6-fold degenerate with respect to the 64 codon alphabet. Previous methodologies have used this fact in an ad hoc manner to look for overlapping genes by motif matching. In this paper differentiated nucleotide compositional patterns in overlapping regions are incorporated into a probabilistic hidden Markov model (HMM) framework which is used to annotate ssRNA viral genomes. This work focuses on single sequence annotation and applies an HMM framework to ssRNA viral annotation. A description of how the HMM is parameterized, whilst annotating within a missing data framework is given. A Phylogenetic HMM (Phylo-HMM) extension, as applied to 14 aligned HIV2 sequences is also presented. This evolutionary extension serves as an illustration of the potential of the Phylo-HMM framework for ssRNA viral genomic annotation.

RESULTS

The single sequence annotation procedure (SSA) is applied to 14 different strains of the HIV2 virus. Further results on alternative ssRNA viral genomes are presented to illustrate more generally the performance of the method. The results of the SSA method are encouraging however there is still room for improvement, and since there is overwhelming evidence to indicate that comparative methods can improve coding sequence (CDS) annotation, the SSA method is extended to a Phylo-HMM to incorporate evolutionary information. The Phylo-HMM extension is applied to the same set of 14 HIV2 sequences which are pre-aligned. The performance improvement that results from including the evolutionary information in the analysis is illustrated.

A DNA-launched reverse genetics system for porcine reproductive and respiratory syndrome virus reveals that homodimerization of the nucleocapsid protein is essential for virus infectivity

Reverse genetic systems were developed for a highly virulent 'atypical' porcine reproductive and respiratory syndrome virus (PRRSV). The full-length genome of 15395 nucleotides was assembled as a single cDNA clone and placed under either the prokaryotic T7 or eukaryotic CMV promoter. Transfection of cells with the RNA transcripts or the DNA clone induced cytopathic effects and produced infectious progeny. The reconstituted virus was stable and grew to the titer of the parental virus in cells. Upon infection, pigs produced clinical signs and lung pathology typical for PRRSV and induced viremia and specific antibodies. Previously, we showed that the PRRSV nucleocapsid (N) protein forms homodimers via both noncovalent and covalent interactions and that cysteine at position 23 is responsible for the covalent interaction. The functional significance of cysteines of N for PRRSV infectivity was assessed using the infectious cDNA clone. Each cysteine of N at positions 23, 75, and 90 was replaced with serine and the individual mutation was incorporated into the cDNA clone such that three independent cysteine mutants were constructed. When transfected, the wild type and C75S clones induced cytopathic effects and produced infectious virus with indistinguishable plaque morphology. In contrast, the C23S mutation completely abolished infectivity of the clone, indicating that C23-mediated N protein homodimerization plays a critical role in PRRSV infectivity. Unexpectedly, the C90S mutation also appeared to be lethal for virus infectivity. Genome replication and mRNA transcription were both positive for the replication-defective C23S and C90S mutants. The data suggest that, in addition to homodimerization, the PRRSV N protein may also undergo heterodimerization with another structural protein using cysteine 90 and that the N protein heterodimerization is essential for PRRSV infectivity.

The immune response to equine arteritis virus: potential lessons for other arteriviruses

The members of the family Arteriviridae, genus Arterivirus, include equine arteritis virus (EAV), porcine reproductive and respiratory syndrome virus (PRRSV), lactate dehydrogenase-elevating virus (LDV) of mice, and simian hemorrhagic fever virus (SHFV). PRRSV is the newest member of the family (first isolated in North America and Europe in the early 1990s), whereas the other three viruses were recognized earlier (EAV in 1953, LDV in 1960, and SHFV in 1964). Although arterivirus infections are strictly species-specific, the causative agents share many biological and molecular properties, including their virion morphology, replication strategy, unique properties of their structural proteins, and their ability to establish distinctive persistent infections in their natural hosts. The arteriviruses are each antigenically distinct and cause different disease syndromes in their natural hosts. Similarly, the mechanism(s) responsible for the prolonged and/or persistent infections that characterize infections with each arterivirus in their natural hosts are remarkably different. The objective of this review is to compare and contrast the immune response to EAV with that to the other three arteriviruses, and emphasize the potential relevance of apparent similarities and differences in the neutralization characteristics of each virus.

Two cellular proteins that interact with a stem loop in the simian hemorrhagic fever virus 3'(+)NCR RNA

Both full-length and subgenomic negative-strand RNAs are initiated at the 3′ terminus of the positive-strand genomic RNA of the arterivirus, simian hemorrhagic fever virus (SHFV). The SHFV 3′(+) non-coding region (NCR) is 76 nts in length and forms a stem loop (SL) structure that was confirmed by ribonuclease structure probing. Two cell proteins, p56 and p42, bound specifically to a probe consisting of the SHFV 3′(+)NCR RNA. The 3′(+)NCR RNAs of two additional members of the arterivirus genus specifically interacted with two cell proteins of the same size. p56 was identified as polypyrimidine tract-binding protein (PTB) and p42 was identified as fructose bisphosphate aldolase A. PTB binding sites were mapped to a terminal loop and to a bulged region of the SHFV 3′SL structure. Deletion of either of the PTB binding sites in the viral RNA significantly reduced PTB binding activity, suggesting that both sites are required for efficient binding of this protein. Changes in the top portion of the SHFV 3′SL structure eliminated aldolase binding, suggesting that the binding site for this protein is located near the top of the SL. These cell proteins may play roles in regulating the functions of the genomic 3′ NCR.

Characterization of two new structural glycoproteins, GP(3) and GP(4), of equine arteritis virus

Equine arteritis virus (EAV) is an enveloped, positive-stranded RNA virus belonging to the family Arteriviridae of the order Nidovirales. Four envelope proteins have hitherto been identified in EAV particles: the predominant membrane proteins M and G(L), the unglycosylated small envelope protein E, and the nonabundant membrane glycoprotein G(S). In this study, we established that the products of EAV open reading frame 3 (ORF3) and ORF4 (designated GP(3) and GP(4), respectively) are also minor structural glycoproteins. The proteins were first characterized by various analyses after in vitro translation of RNA transcripts in a rabbit reticulocyte lysate in the presence and absence of microsomal membranes. We subsequently expressed ORF3 and -4 in baby hamster kidney cells by using the vaccinia virus expression system and, finally, analyzed the GP(3) and GP(4) proteins synthesized in EAV-infected cells. The results showed that GP(4) is a class I integral membrane protein of 28 kDa with three functional N-glycosylation sites and with little, if any, of its carboxy terminus exposed. Both after independent expression and in EAV-infected cells, the protein localizes in the endoplasmic reticulum (ER), as demonstrated biochemically by analysis of its oligosaccharide side chains and as visualized directly by immunofluorescence studies. GP(3), on the other hand, is a heavily glycosylated protein whose hydrophobic amino terminus is not cleaved off. It is an integral membrane protein anchored by either or both of its hydrophobic terminal domains and with no parts detectably exposed cytoplasmically. Also, GP(3) localizes in the ER when expressed independently and in the context of an EAV infection. Only a small fraction of the GP(3) and GP(4) proteins synthesized in infected cells ends up in virions. Most, but not all, of the oligosaccharides of these virion glycoproteins are biochemically mature. Our results bring the number of EAV envelope proteins to six.

The Genome Organization of the Nidovirales: Similarities and Differences between Arteri-, Toro-, and Coronaviruses

Viruses in the families Arteriviridae and Coronaviridae have enveloped virions which contain nonsegmented, positive-stranded RNA, but the constituent genera differ markedly in genetic complexity and virion structure. Nevertheless, there are striking resemblances among the viruses in the organization and expression of their genomes, and sequence conservation among the polymerase polyproteins strongly suggests that they have a common ancestry. On this basis, the International Committee on Taxonomy of Viruses recently established a new order, Nidovirales, to contain the two families. Here, the common traits and distinguishing features of the Nidovirales are reviewed.

Recombinant equine arteritis virus as an expression vector

Equine arteritis virus (EAV) is the prototypic member of the family Arteriviridae, which together with the Corona- and Toroviridae constitutes the order Nidovirales. A common trait of these positive-stranded RNA viruses is the 3'-coterminal nested set of six to eight leader-containing subgenomic mRNAs which are generated by a discontinuous transcription mechanism and from which the viral open reading frames downstream of the polymerase gene are expressed. In this study, we investigated whether the unique gene expression strategy of the Nidovirales could be utilized to convert them into viral expression vectors by introduction of an additional transcription unit into the EAV genome directing the synthesis of an extra subgenomic mRNA. To this end, an expression cassette consisting of the gene for a green fluorescent protein (GFP) flanked at its 3' end by EAV-specific transcription-regulating sequences was constructed. This genetic module was inserted into the recently obtained mutant infectious EAV cDNA clone pBRNX1.38-5/6 (A. A. F. de Vries, et al., 2000, Virology 270, 84-97) between the genes for the M and the G(L) proteins. Confocal fluorescence microscopy of BHK-21 cells electroporated with capped RNA transcripts derived from the resulting plasmid (pBRNX1.38-5/6-GFP) demonstrated that the GFP gene was expressed in the transfected cells, while the gradual spread of the infection through the cell monolayer showed that the recombinant virus was replication competent. The development of the cytopathic effect was, however, much slower than in cells that had received equivalent amounts of pBRNX1.38-5/6 RNA, indicating that the vector virus had a clear growth disadvantage compared to its direct precursor. Immunoprecipitation analyses of proteins from metabolically labeled BHK-21 cells infected with supernatant of the transfected cultures confirmed that the recombinant virus vector was viable and expressed viral genes as well as the GFP gene. Reverse transcription-PCR of the viral mRNAs extracted from cells infected with the vector virus revealed that it directed the synthesis of nine instead of eight different EAV RNAs. These findings were corroborated by hybridization analyses. Mapping of the leader-to-body junctions of the ninth mRNA indicated that the 3' part of the GFP gene contains cryptic transcription signals which gave rise to at least five different RNA species ranging in size from 1277 to 1439 nt [without oligo(A) tract]. Furthermore, translation of the unintended mRNA resulted in the production of an extended version of the EAV M protein. Serial passage of the recombinant virus vector led to its gradual replacement by viral mutants carrying deletions in the GFP gene. The reduction in viral fitness associated with the insertion of the expression cassette into the EAV genome apparently caused genetic instability of the recombinant virus.

Identification of a novel structural protein of arteriviruses

Arteriviruses are positive-stranded RNA viruses with an efficiently organized, polycistronic genome. A short region between the replicase gene and open reading frame (ORF) 2 of the equine arteritis virus (EAV) genome was previously assumed to be untranslated. However, here we report that this segment of the EAV genome contains the 5' part of a novel gene (ORF 2a) which is conserved in all arteriviruses. The 3' part of EAV ORF 2a overlaps with the 5' part of the former ORF 2 (now renamed ORF 2b), which encodes the GS glycoprotein. Both ORF 2a and ORF 2b appear to be expressed from mRNA 2, which thereby constitutes the first proven example of a bicistronic mRNA in arteriviruses. The 67-amino-acid protein encoded by EAV ORF 2a, which we have provisionally named the envelope (E) protein, is very hydrophobic and has a basic C terminus. An E protein-specific antiserum was raised and used to demonstrate the expression of the novel gene in EAV-infected cells. The EAV E protein proved to be very stable, did not form disulfide-linked oligomers, and was not N-glycosylated. Immunofluorescence and immunoelectron microscopy studies showed that the E protein associates with intracellular membranes both in EAV-infected cells and upon independent expression. An analysis of purified EAV particles revealed that the E protein is a structural protein. By using reverse genetics, we demonstrated that both the EAV E and GS proteins are essential for the production of infectious progeny virus.

Cell proteins bind to a 67 nucleotide sequence within the 3' noncoding region (NCR) of simian hemorrhagic fever virus (SHFV) negative-strand RNA

The 3'NCR of the SHFV negative-strand RNA [SHFV 3'(-)NCR RNA] is thought to be the initiation site of full-length and possibly also subgenomic positive-strand RNA and so is likely to contain cis-acting signals for viral RNA replication. Cellular and viral proteins may specifically interact with this region to form replication complexes. When in vitro transcribed SHFV 3'(-)NCR RNA was used as a probe in gel mobility shift assays, two RNA-protein complexes were detected with MA104 S100 cytoplasmic extracts. The specificity of thes RNA-protein interactions was demonstrated by competition gel mobility shift assays. Four MA104 protein (103, 86, 55, and 36 kDa) were detected by UV-induced cross-linking assays and three proteins (103, 55, and 36 kDa) were detected by northwestern blotting assays. The binding sites for these proteins were mapped to the region between nucleotides 117 to 184 on the SHFV 3'(-)NCR RNA. Four cellular proteins with identical molecular masses to those of the proteins that bind to the SHFV 3'(-)NCR RNA were detected by the 3'(-)NCR of another arterivirus, LDV-C, suggesting that divergent arteriviruses utilize the same set of conserved cell protein domains.

Organization of the simian hemorrhagic fever virus genome and identification of the sgRNA junction sequences

SHFV is a member of the Arteriviridae family. Viruses within this family encode eight open reading frames (ORFs), two of which are translated from the full-length genome RNA. The remaining six ORFs are translated from a nested set of six or seven 3' co-terminal, subgenomic RNAs (sgRNAs). We have cloned and sequenced approximately 6000 nucleotides (nt) from the 3' end of the SHFV genome. Eleven ORFs, numbered ORFs 1a, 1b, 2a, 2b, 3, 4, 5, 6, 7, 8, and 9, were identified, three more than the other arteriviruses. The characteristics of the peptides encoded by ORFs 2a through 9 were determined from their computer-generated amino acid sequences. We also amplified the junction sequences from each of the SHFV subgenomic RNAs (sgRNAs) using RT-PCR analysis. Eight separate junction sequences were found which suggests that SHFV produces eight sgRNAs during replication. ORFs 2a and 2b appear to be encoded on the same sgRNA implying that RNA 2 is polycistronic. Sequence analysis identified the conserved SHFV junction sequence as 5'-(U/C)(C/U)N(U/C)(U/C)(A/C/G)AC(C/U)-3'. Since SHFV encodes additional ORFs and produces additional sgRNAs during replication, these data suggest that SHFV may be more complex than the other arteriviruses.

A 68-nucleotide sequence within the 3' noncoding region of simian hemorrhagic fever virus negative-strand RNA binds to four MA104 cell proteins

The 3' noncoding region (NCR) of the negative-strand RNA [3'(-)NCR RNA] of the arterivirus simian hemorrhagic fever virus (SHFV) is 209 nucleotides (nt) in length. Since this 3' region, designated 3'(-)209, is the site of initiation of full-length positive-strand RNA and is the template for the synthesis of the 5' leader sequence, which is found on both full-length and subgenomic mRNAs, it is likely to contain cis-acting signals for RNA synthesis and to interact with cellular and viral proteins to form replication complexes. Gel mobility shift assays showed that cellular proteins in MA104 S100 cytoplasmic extracts formed two complexes with the SHFV 3'(-)209 RNA, and results from competition gel mobility shift assays demonstrated that these interactions were specific. Four proteins with molecular masses of 103, 86, 55, and 36 kDa were detected in UV-induced cross-linking assays, and three of these proteins (103, 55, and 36 kDa) were also detected by Northwestern blotting assays. Identical gel mobility shift and UV-induced cross-linking patterns were obtained with uninfected and SHFV-infected extracts, indicating that the four proteins detected are cellular, not viral, proteins. The binding sites for the four cellular proteins were mapped to the region between nt 117 and 184 (68-nt sequence) from the 3' end of the SHFV negative-strand RNA. This 68-nt sequence was predicted to form two stem-loops, SL4 and SL5. The 3'(-)NCR RNA of another arterivirus, lactate dehydrogenase-elevating virus C (LDV-C), competed with the SHFV 3'(-)209 RNA in competition gel mobility shift assays. UV-induced cross-linking assays showed that four MA104 cellular proteins with the same molecular masses as those that bind to the SHFV 3'(-)209 RNA also bind to the LDV-C 3'(-)NCR RNA and equine arteritis virus 3'(-)NCR RNA. However, each of these viral RNAs also bound to an additional MA104 protein. The binding sites for the MA104 cellular proteins were shown to be located in similar positions in the LDV-C 3'(-)NCR and SHFV 3'(-)209 RNAs. These data suggest that the binding sites for a set of the cellular proteins are conserved in all arterivirus RNAs and that these cell proteins may be utilized as components of viral replication complexes.

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

Simian hemorrhagic fever virus (SHFV) was recently reclassified and assigned to the new virus family Arteriviridae. During replication, arteriviruses produce a 3' coterminal, nested set of subgenomic mRNAs (sgRNAs). These sgRNAs arise by discontinuous transcription, and each contains a 5' leader sequence which is joined to the body of the mRNA through a conserved junction sequence. Only the 5'-most open reading frame (ORF) is believed to be transcribed from each sgRNA. The SHFV genome encodes nine ORFs that are presumed to be expressed from sgRNAs. However, reverse transcription-PCR analysis with leader- and ORF-specific primers identified only eight sgRNA species. The consensus sequence 5'-UCNUUAACC-3' was identified as the junction motif. Our data suggest that sgRNA 2 may be bicistronic, expressing both ORF 2a and ORF 2b. SHFV encodes three more ORFs on its genome than the other arteriviruses. Comparative sequence analysis suggested that SHFV ORFs 2a, 2b, and 3 are related to ORFs 2 through 4 of the other arteriviruses. Evidence which suggests that SHFV ORFs 4 through 6 are related to ORFs 2a through 3 and may have resulted from a recombination event during virus evolution is presented.

Sequence of the 3' end of the simian hemorrhagic fever virus genome

SHFV is a member of a new virus family which includes the genus arterivirus. We have cloned and sequenced 6,314 nt from the 3' end of the SHFV genome. This sequence encompasses nine complete ORFs which is three additional ORFs as compared to the other arteriviruses. We have numbered these ORFs 2a, 2b, 3, 4, 5, 6, 7, 8 and 9. At the 5' end of this sequence is a partial ORF (ORF 1b) of 1590 nt and at the 3' end is a poly(A) tract preceded by a 76 nt noncoding region. The coding capacity for each of the SHFV ORFs as well as the potential mass, pI and number of N-linked glycosylation sites for each of the encoded peptides was determined.

Processing of the equine arteritis virus replicase ORF1b protein: identification of cleavage products containing the putative viral polymerase and helicase domains

The replicase open reading frame lb (ORF1b) protein of equine arteritis virus (EAV) is expressed from the viral genome as an ORF1ab fusion protein (345 kDa) by ribosomal frameshifting. Processing of the ORF1b polyprotein was predicted to be mediated by the nsp4 serine protease, the main EAV protease. Several putative cleavage sites for this protease were detected in the ORF1b polyprotein. On the basis of this tentative processing scheme, peptides were selected to raise rabbit antisera that were used to study the processing of the EAV replicase ORF1b polyprotein (158 kDa). In immunoprecipitation and immunoblotting experiments, processing products of 80, 50, 26, and 12 kDa were detected. Of these, the 80-kDa and the 50-kDa proteins contain the putative viral polymerase and helicase domains, respectively. Together, the four cleavage products probably cover the entire ORF1b-encoded region of the EAV replicase, thereby representing the first complete processing scheme of a coronaviruslike ORF1b polyprotein. Pulse-chase analysis revealed that processing of the ORF1b polyprotein is slow and that several large precursor proteins containing both ORF1a- and ORF1b-encoded regions are generated. The localization of ORF1b-specific proteins in the infected cell was studied by immunofluorescence. A perinuclear staining was observed, which suggests association with a membranous compartment.

Structural polypeptides of the American (VR-2332) strain of porcine reproductive and respiratory syndrome virus

The structural polypeptides of the isolate VR-2332 of porcine reproductive and respiratory syndrome virus were analyzed in sucrose gradient-purified virions. The virus had an average density of 1.15 g/cm3 and contained, by SDS-PAGE, three major polypeptides with apparent molecular weights of 15, 19 and 26-30 kDa, which were designated as nucleocapsid (N), matrix (M) and envelope (E), respectively. The predominant structural protein was N. N-glycosidase F digestion only affected E whereas O-glycosidase or endoglycosidase H digestion had no effect, suggesting that the viral glycoproteins contain only complex N-linked carbohydrates.

Equine arteritis virus subgenomic mRNA synthesis: analysis of leader-body junctions and replicative-form RNAs

In addition to the genomic RNA, a 3' coterminal nested set of six subgenomic mRNAs is produced in equine arteritis virus (EAV)-infected cells. The seven viral RNAs are also 5' coterminal, since they all contain a 206-nucleotide common leader sequence which is identical to the 5' end of the genome. A conserved penta-nucleotide sequence motif, 5' UCAAC 3', was shown to be present at the junctions between the leader and body sequences in each of the mRNAs. In addition, two alternative junction sites were detected for mRNA 3. Seven replicative-form (RF) RNAs (RFs I to VII), corresponding to the genomic RNA and each of the subgenomic EAV mRNAs, could be prepared from lysates of infected cells. The minus-strand RNA contents of these RF RNAs were analyzed by using an RNase protection assay with an RNA probe containing the mRNA 2 leader-body junction. It was established that RF II contained a negative-stranded copy of mRNA 2, including a complementary leader sequence. The presence of subgenomic minus-strand RNA in RFs is indicative of a function as a transcription template during the production of EAV subgenomic mRNAs.

The arterivirus nsp4 protease is the prototype of a novel group of chymotrypsin-like enzymes, the 3C-like serine proteases

The replicase of equine arteritis virus, an arterivirus, is processed by at least three viral proteases. Comparative sequence analysis suggested that nonstructural protein 4 (Nsp4) is a serine protease (SP) that shares properties with chymotrypsin-like enzymes belonging to two different groups. The SP was predicted to utilize the canonical His-Asp-Ser catalytic triad found in classical chymotrypsin-like proteases. On the other hand, its putative substrate-binding region contains Thr and His residues, which are conserved in viral 3C-like cysteine proteases and determine their specificity for (Gln/Glu) downward arrow(Gly/Ala/Ser) cleavage sites. The replacement of the members of the predicted catalytic triad (His-1103, Asp-1129, and Ser-1184) confirmed their indispensability. The putative role of Thr-1179 and His-1199 in substrate recognition was also supported by the results of mutagenesis. A set of conserved candidate cleavage sites, strikingly similar to junctions cleaved by 3C-like cysteine proteases, was identified. These were tested by mutagenesis and expression of truncated replicase proteins. The results support a replicase processing model in which the SP cleaves multiple Glu downward arrow(Gly/Ser/Ala) sites. Collectively, our data characterize the arterivirus SP as a representative of a novel group of chymotrypsin-like enzymes, the 3C-like serine proteases.

Detection of related positive-strand RNA virus genomes by reverse transcription/polymerase chain reaction using degenerate primers for common replicase sequences

A set of degenerate sense and antisense primers were designed on the basis of short segments with identical amino acids in the predicted ORF 1b replicase proteins of lactate dehydrogenase-elevating virus (LDV), equine arteritis virus (EAV) and porcine reproductive and respiratory syndrome virus, strain Lelystad virus (PRRSV-LV), which are members of a new group of positive-strand RNA viruses. Reverse transcription/polymerase chain reaction amplification using this set of degenerate primers yielded products of the expected size from the genomes of all three viruses. It also yielded a product of appropriate size from the genome of another strain of PRRSV (VR2332), the ORF 1b sequence of which is unknown, but the 3' end of the genome of which differs from that of the PRRSV-LV genome by about 50%. No products were generated from the genome of simian hemorrhagic fever virus (SHFV), another member of this virus group. However, an appropriate product was generated with a second set of degenerate primers which was designed from the same ORF 1b segments of LDV, EAV and PRRSV-LV as the first set but on the basis of human codon preferences. Sequence analysis showed that the amplified SHFV ORF 1b segment exhibited about 50% nucleotide identity with the corresponding segments of ORF 1b of LDV, EAV and PRRSV. The results show that these and other degenerate primer sets might be useful for the search of related viruses in other mammalian species.