Arenavirus recombination: the formation of recombinants between prototype pichinde and pichinde munchique viruses and evidence that arenavirus S RNA codes for N polypeptide

Mutations in the RNA-binding domains of tombusvirus replicase proteins affect RNA recombination in vivo

RNA recombination, which is thought to occur due to replicase errors during viral replication, is one of the major driving forces of virus evolution. In this article, we show evidence that the replicase proteins of Cucumber necrosis virus, a tombusvirus, are directly involved in RNA recombination in vivo. Mutations within the RNA-binding domains of the replicase proteins affected the frequency of recombination observed with a prototypical defective-interfering (DI) RNA, a model template for recombination studies. Five of the 17 replicase mutants tested showed delay in the formation of recombinants when compared to the wild-type helper virus. Interestingly, two replicase mutants accelerated recombinant formation and, in addition, these mutants also increased the level of subgenomic RNA synthesis (Virology 308 (2003), 191-205). A trans-complementation system was used to demonstrate that mutation in the p33 replicase protein resulted in altered recombination rate. Isolated recombinants were mostly imprecise (nonhomologous), with the recombination sites clustered around a replication enhancer region and a putative cis-acting element, respectively. These RNA elements might facilitate the proposed template switching events by the tombusvirus replicase. Together with data in the article cited above, results presented here firmly establish that the conserved RNA-binding motif of the replicase proteins is involved in RNA replication, subgenomic RNA synthesis, and RNA recombination.

Genetic variability: the key problem in the prevention and therapy of RNA-based virus infections

Despite extraordinary progress that has recently been made in biomedical sciences, viral infectious diseases still remain one of the most serious world health problems. Among the different types of viruses, those using RNA as their genetic material (RNA viruses and retroviruses) are especially dangerous. At present there is no medicine allowing an effective treatment of RNA-based virus infections. Many RNA viruses and retroviruses need only a few weeks to escape immune response or to produce drug-resistant mutants. This seems to be the obvious consequence of the unusual genetic variability of RNA-based viruses. An individual virus does not form a homogenous population but rather a set of similar but not identical variants. In consequence, RNA-based viruses can easily adapt to environmental changes, also those resulting from immune system response or therapy. The modifications identified within viral genes can be divided into two groups: point mutations and complex genome rearrangements. The former arises mainly during error-prone replication, whereas RNA recombination and generic reassortment are responsible for the latter. This article shortly describes major strategies used to control virus infections. Then, it presents the various mechanisms generating the genetic diversity of RNA-based viruses, which are most probably the main cause of clinical problems.

Reassortant analysis of guinea pig virulence of pichinde virus variants

The new world arenavirus Pichinde (PIC) is the basis of an accepted small animal model for human Lassa fever. PIC (Munchique strain) variant P2 is attenuated in guinea pigs, whereas variant P18 is extremely virulent. Previous sequence analysis of the S segments of these two viruses indicated a small number of possible virulence markers in the glycoprotein precursor (GPC) and nucleoprotein (NP) genes. In order to determine the role of these S segment genes in guinea pig virulence in this system, we have generated reassortant viruses. When tested in outbred guinea pigs, the reassortant containing the S segment from the virulent parent P18 (S18L2) caused significantly higher morbidity than the reciprocal reassortant. This increased morbidity was associated with higher viral titers in serum and spleen. However, the S18L2 reassortant was not as fully virulent in this system as the P18 parent, indicating a role for L segment genes in virulence.

Characterization of temperature-sensitive mutants of Pichinde virus

The synthesis of viral proteins and S RNAs in cells infected with 12 temperature-sensitive (ts) mutants of Pichinde virus was characterized. The mutants could be divided into five groups on the basis of the patterns of radiolabeled proteins immunoprecipitated from infected-cell lysates. Markedly reduced nucleoprotein levels and undetectable amounts of glycoprotein precursor and L protein were synthesized at the nonpermissive temperature in cells infected with five of the mutants. Reduced but detectable amounts of the viral proteins were synthesized at the nonpermissive temperature in cells infected with a single mutant. Two mutants were associated with the intracellular accumulation of glycoprotein precursor, which was apparently not transported across the cell membrane in cells incubated at the nonpermissive temperature. The synthesis of viral proteins in cells infected with two mutants was indistinguishable from those produced by wild-type virus. Two additional mutants were associated with markedly reduced amounts of immunoprecipitable proteins in infected cells incubated at both the permissive and nonpermissive temperatures. Analysis of viral RNA with radiolabeled single-stranded cDNA probes representing complementary and genomic-sense sequences corresponding to the 3' region of S RNA revealed two basic patterns of viral RNA synthesis. At the nonpermissive temperature, the synthesis of complementary- and genomic-sense sequences and mRNA of the S RNA segment was markedly reduced in cells infected with representative members of these mutant groups, suggesting the presence of mutations altering transcriptase activity. Viral-complementary- and genomic-sense sequence and RNA synthesis, as well as nucleoprotein mRNA in cells, was detected in reduced amounts for mutants associated with reduced levels of proteins at both temperatures. Interestingly, RNA species larger than the S RNA segment were detected in cells infected with some of the mutants, especially those with putative transcriptase lesions. These molecules suggest a possible oligomeric intermediate in the synthesis of S RNA of Pichinde virus.

Genetic variation among Lassa and Lassa-related arenaviruses analysed by T1-oligonucleotide mapping

Total RNA and small RNA species of several African arenavirus strains have been studied by T1-oligonucleotide mapping. Genetic heterogeneity is observed and discussed on the basis of evolutionary biology of the Lassa complex.

Analysis of the genomic L RNA segment from lymphocytic choriomeningitis virus

The arenavirus genomic L RNA segment represents approximately 70% of the viral genetic material but current understanding of the organization, regulation, and functioning of the viral L products remains limited. Biological studies with reassortant viruses have implicated the L RNA segment in the lethal infection of adult guinea pigs produced by LCMV-WE but no further explanation of the pathogenic process is presently available. We have initiated a detailed molecular analysis of LCMV L products based on construction and characterization of L-specific cDNA clones and synthesis of L-specific hybridization probes. Nucleotide sequencing studies have allowed the derivation of a partial amino acid sequence for a predicted L protein and antisera raised against synthetic peptides have demonstrated an L protein in Western blotting experiments. Using this approach we have identified a single high molecular weight protein (approximately 200,000 Da) in purified virions and in viral ribonucleoprotein complexes extracted from acutely infected tissue culture cells. This L protein is translated from a nonpolyadenylated, genomic complementary L mRNA and potentially represents part or all of the viral RNA-dependent RNA polymerase.

Nucleotide sequence of the glycoprotein gene and intergenic region of the Lassa virus S genome RNA

Two overlapping cDNA clones corresponding to the 5' region of the Lassa virus S genome RNA were isolated and their nucleotide sequences determined. Similar to Pichinde and lymphocytic choriomeningitis viruses (LCMV), Lassa virus has an ambisense S RNA. The precursor to the viral glycoproteins (GPC) is encoded in viral RNA sequence originating at position 56 and terminating at position 1529 from the 5' terminus of the S RNA. A short, noncoding, intergenic region capable of forming a hairpin structure separates the termination codons of the nucleoprotein (N) and GPC genes. Hydropathic analysis of the GPC gene product of Lassa virus indicates the presence of hydrophobic domains near the amino and carboxy termini as previously noted in the corresponding proteins of Pichinde and LCM viruses. A comparison of the nucleotide sequences on the 3' termini of the viral and viral-complimentary S RNA species of Lassa, LCM, and Pichinde viruses reveals slight sequence differences that may possibly be involved in the regulation of RNA synthesis and gene expression.

Ambisense RNA genomes of arenaviruses and phleboviruses

This chapter reviews the evidence that shows that arenaviruses and members of one genus of the Bunyaviridae (phleboviruses) have some proteins coded in subgenomic, viral-sense mRNA species and other proteins coded in subgenomic, viral-complementary mRNA sequences. This unique feature is discussed in relation to the implications it has on the intracellular infection process and how such a coding arrangement may have evolved. The chapter presents a list of the known members of the arenaviridae, their origins, and the vertebrate hosts from which isolates have been reported. It discusses the structural components, the infection cycle, and genetic attributes of arenaviruses. In order to determine how arenaviruses code for gene products, the S RNA species of Pichinde virus and that of a viscerotropic strain of LCM virus (LCM-WE) have been cloned into DNA and sequenced. The arenavirus S RNA is described as having an ambisense strategy, to denote the fact that both viral and viral-complementary sequences are used to make gene products. The chapter discusses the infection cycle, the structural and genetic properties of bunyaviridae member.

Complete sequence of the S RNA of lymphocytic choriomeningitis virus (WE strain) compared to that of Pichinde arenavirus

Previous studies have reported that the 3' half of the small, S, RNA species of the WE strain of lymphocytic choriomeningitis (LCM) virus codes for the viral nucleoprotein in a subgenomic, viral-complementary, mRNA species (Romanowski, V. and Bishop, D.H.L. (1985) Virus Res. 2, 35-51). The complete sequence of the LCM-WE S RNA has now been obtained, indicating that the 5' half of the RNA codes for the viral glycoprotein precursor in a viral-sense sequence that does not overlap the N gene. It is concluded that, like Pichinde virus (Auperin, D. et al. (1984) J. Virol. 52, 897-904), LCM has an ambisense S RNA coding strategy. The LCM-WE S RNA is 3375 nucleotides in length, has a size of 1.14 X 10(6) Da and base composition of 26.1% A, 23.2% C, 21.5% G, 29.2% U. The 3' and 5' end sequences of the S RNA are complementary for some 30 nucleotides, depending on the arrangement. The non-coding regions at the two ends are 77 (5') and 60 (3') nucleotides long. The glycoprotein precursor has a primary amino acid size of 56293 Da and is rich in potential glycosylation sites as well as histidine and cysteine residues. It has both amino and carboxy proximal hydrophobic regions. The LCM-WE S RNA and predicted protein sequence data have been compared to those of Pichinde arena-virus. Extensive RNA and protein sequence homology exists for the two S RNA species, although the homology for the glycoprotein sequences of the two viruses (39%) is less than the 50% observed for the two viral nucleoproteins.

The S RNA segment of lymphocytic choriomeningitis virus codes for the nucleoprotein and glycoproteins 1 and 2

The lymphocytic choriomeningitis virus (LCMV) genome consists of a large RNA segment and a small RNA segment. The three major structural proteins of this virus are an internal nucleoprotein and two surface glycoproteins. Intertypic reassortants between the Armstrong and WE strains of LCMV were made to map proteins encoded by the LCMV genome segments. Using monoclonal antibodies specific for the nucleoprotein and the glycoproteins of WE and Armstrong, we showed that the small RNA segment of LCMV codes for the three major structural polypeptides.

Conserved sequences and coding of two strains of lymphocytic choriomeningitis virus (WE and ARM) and Pichinde arenavirus

Analyses of the 3' end sequences of the small, S, and large, L, RNA species of lymphocytic choriomeningitis (LCM) virus isolates ARM and WE, and DNA clones of LCM-WE, have shown that there are extensive RNA sequence homologies between the 3' ends of the two RNA species of both LCM strains. Limited sequence data of DNA clones representing the LCM-WE L RNA species indicate that a gene product (presumably the minor 200 kdalton virion protein) is coded in a viral-complementary mRNA species. Sequence analyses of LCM-WE S DNA clones indicate that approximately 50% of the 2040 nucleotides representing the 3' half of the viral RNA species (and its encoded 558 amino acid gene product) are identical in type and position to those of Pichinde arenavirus (Auperin, D., et al. (1984a), Virology 134, 208-219). For Pichinde virus, it has been shown that the 3' proximal gene product (the nucleoprotein, N) is translated from a subgenomic, viral-complementary mRNA (Auperin et al., 1984a). Data have recently been obtained (Auperin, D., et al. (1984b) J. Virol., in press) that indicate that the Pichinde glycoprotein precursor, GPC, is coded in a viral-sense subgenomic mRNA species corresponding to the 5' half of the S RNA. The nucleotide sequence that immediately follows the N coding region of both LCM-WE and Pichinde viruses can be arranged in a hairpin configuration. In view of this, and if, like Pichinde virus, LCM has an ambisense S RNA coding strategy, then it is probable that the intergenic hairpins function as transcription terminators for the N and GPC mRNA species of both viruses.

Sequencing studies of pichinde arenavirus S RNA indicate a novel coding strategy, an ambisense viral S RNA

Analyses of the complete sequence of the 1.1 X 10(6)-dalton, small (S) RNA of the arenavirus Pichinde and virus-induced cellular RNA species have revealed that the viral nucleoprotein, N, is coded in a subgenomic, non-polyadenylated, virus-complementary mRNA corresponding to the 3' half of the viral RNA (Auperin et al., Virology 134:208-219, 1984). By contrast, a second S-coded product, presumably the viral glycoprotein precursor (GPC), is coded in a subgenomic, virus-sense mRNA corresponding to the 5' half of the RNA. Between the two genes is a unique RNA sequence that can be arranged in a hairpin configuration and may function as a transcription terminator for both genes. The term ambisense RNA is coined to describe this novel coding strategy of a viral RNA. The unique feature of the strategy is that the presumptive GPC mRNA and its translation product cannot be made until viral RNA replication has commenced. In addition, it allows the two subgenomic mRNA species to be regulated independently from each other or from other viral mRNA species. The implications of this strategy on possible mechanisms for the induction and maintenance of viral persistence, an important attribute of arenavirus infections, are discussed.

Ribonucleic acids of Machupo and Lassa viruses

Sucrose gradient velocity centrifugation, polyacrylamide gel electrophoresis and RNA-RNA hybridization were used to characterize Lassa and Machupo virion RNAs as well as virus-specific RNAs from cells infected with Pichinde and Machupo viruses. Five RNA species: 30-31S, 28S, 22-24S, 18S and 4-6S have been detected in Lassa, Machupo, and Pichinde virion RNAs. Among them 28S, 18S and 4-6S RNAs cosediment and comigrate with respectively cell RNAs. RNase resistance analyses suggest the presence of extensive secondary structures and complementary RNAs in Lassa, Machupo, and Pichinde virion RNAs. Annealing with poly(A)-containing RNA from infected cells has revealed that the bulk of "minus" strands of Machupo virion RNA is located in 22-24S and 28-31S fractions of sucrose gradient. Thus Machupo and Lassa viruses as well as Pichinde virus contain two genomic RNA fragments: "large" (molecular weight of about 2.2 X 10(6] and "small" (molecular weight of about 1.3 X 10(6]. In the cells infected with Pichinde virus and treated with actinomycin D (1.0 microgram/ml) synthesis of 18S, 22-24S and 30-31S RNAs has been registered. At least 22-24S and 30-31S classes comprise "plus" and "minus" strands. In cells infected with Machupo virus in the presence of actinomycin D the synthesis of similar sedimentation classes of RNAs and certain amounts of 28S RNA have been detected.

The sequences of the N protein gene and intergenic region of the S RNA of pichinde arenavirus

Two overlapping DNA clones representing more than half of the Pichinde arenavirus S RNA segment were cloned into pBR322 and their nucleotide sequences were determined. The analyses predict that the viral nucleocapsid protein (N) is encoded in a reading frame in the viral complementary RNA sequence starting at viral S RNA nucleotide residue 84 from the 3' end and terminating with an opal codon at residues 1767-1769. The position of the termination codon has been confirmed by primer directed dideoxynucleotide sequencing. The N protein has a calculated size of 62,911 Da and a net positive charge of +9. Viral complementary 15 S mRNA that directs the synthesis of N protein and hybridizes to the predicted N gene DNA has been identified in infected cell extracts. A second nonoverlapping reading frame in the viral complementary sequence originates at nucleotide position 1827 and remains open for at least 71 amino acids (i.e., the extent of the second clone). A long stretch of hydrophobic amino acids is near the amino terminus of this predicted gene product. Between the two reading frames is a 60-nucleotide-long noncoding intergenic region. This nucleotide sequence can be arranged in hairpin configuration involving 14 G-C and 4 A-U base pairs. The possible function of this intergenic region in the regulation of transcription and/or translation is discussed.

Applications of Oligonucleotide Fingerprinting to the Identification of Viruses

This chapter focuses on applications of oligonucleotide fingerprinting to the identification of viruses. Fingerprinting is a technique by which oligonucleotides, produced by cleavage of RNA molecules with specific ribonucleases, are separated in two dimensions. It is a definitive method of identifying RNA viruses according to their genotypes. It is not subject to the problems of antigenic drift or antigenic convergence that complicate serological identification. Furthermore, it provides a semiquantitative means of following the evolution of viral genomes in nature. Because all regions of the genome are represented by the large diagnostic oligonucleotides, a survey of the total genomic changes can be monitored. Fingerprinting has two limitations as a diagnostic tool. First, although highly definitive, fingerprinting is not as rapid or inexpensive as serological techniques and cannot be as easily scaled up for routine identification of a large number of samples. Second, the evolutionary range of fingerprinting is short and relationships may not be evident for isolates of rapidly evolving viruses obtained over long intervals. However, these limitations are not large, compared to the full benefits offered to the virologist by the fingerprinting method.

Gene mapping in Pichinde virus: assignment of viral polypeptides to genomic L and S RNAs

Previous studies have demonstrated that Pichinde virus encodes at least three primary translation products. Using wild-type Pichinde and Munchique viruses and a reassortant between the two, designated RE-2, we were able to assign polypeptides L, GPC, and NP to viral L and S RNAs. The RE-2 virus contains the L RNA of Pichinde virus and the S RNA of Munchique virus. Two-dimensional tryptic peptide mapping of L-[35S]methionine-containing peptides demonstrated that NP and GPC were identical in Munchique and RE-2 viruses, and both differed from the corresponding Pichinde virus tryptic profiles. On the basis of this, NP and GPC must be encoded by viral S RNA. Similar comparisons for L polypeptide demonstrated that L is a virus-specific polypeptide encoded by L RNA.

The formation of arenaviruses that are genetically diploid

Analyses of RNA extracted from preparations of arenaviruses indicate that the relative molar proportions of the genomic L and S RNA species are frequently far from equal. In order to investigate the genetic significance of this observation temperature-sensitive (ts) mutants of two lymphocytic choriomeningitis (LCM) virus strains (ARM and WE) have been recovered and categorized into recombination groups (Groups I and II). Fingerprint analyses of wild-type progeny viruses obtained from dual infections with ARM Group II and WE Group I ts viruses indicate that they have L/S RNA genotypes of WE/ARM. It is concluded that the ARM Group II ts viruses have mutations in their L RNA species and that the WE Group I ts viruses have mutations in their S RNA species. Correspondingly it is deduced that the ARM Group I ts viruses have S RNA mutations and the WE Group II ts viruses mutations in their L RNA species. Cells coinfected with certain WE Group I mutants, or an ARM Group I and certain WE Group I ts mutants, have also yielded wild-type viruses. Fingerprint analyses have shown that the wild-type viruses obtained from the latter crosses are diploid with respect to their S RNA species. On subsequent passage these wild-type viruses shed high proportions of ts mutants. We interpret the data to indicate that the original Group I ts mutants that yielded the diploid viruses have mutations in different S RNA gene products so that the progeny produce plaques at the nonpermissive temperature by gene product complementation. No wild-type recombinant viruses have been obtained from crosses involving Pichinde and LCM ts mutants.

Synthesis of virus-specific polypeptides and genomic RNA during the replicative cycle of Pichinde virus

A stock of plaque-purified Pichinde virus, prepared under conditions designed to limit the amounts of defective interfering virus, was used to infect BHK cells. At daily intervals after infection, cells were examined for infectious and radiolabeled virus particle production and for the synthesis of virus-specific polypeptides. Quantitative comparisons were also made of the concentrations of genomic Pichinde virus L and S RNAs in the cytoplasm of infected cells on different days after infection. Our results showed that virus particle production, rates of protein synthesis, and the intracellular levels of viral genomic RNAs all increased and decreased with similar kinetics, and that this regulation was independent of the cell growth cycle. We were unable to relate these changes in viral macromolecule and virus production to the appearance of readily identifiable defective interfering particles. Our findings suggest that regulation of virus replication early during the replicative cycle of Pichinde virus may not be dependent upon the generation of defective interfering virus.

Pathogenesis of a pichinde virus strain adapted to produce lethal infections in guinea pigs

A model for studying the pathogenesis of virulent arenavirus infection was developed by adapting Pichinde virus to produce lethal infections of inbred guinea pigs. This adapted Pichinde virus retained low virulence for primates, thus potentially reducing the biohazard to investigators. Whereas all inbred (strain 13) guinea pigs were infected and killed by 3 plaque-forming units or more of adapted Pichinde virus injected subcutaneously, outbred (Hartley strain) guinea pigs were relatively resistant. All infected, inbred guinea pigs died at 13 to 19 days after inoculation, with viremias in excess of 5 log(10) plaque-forming units/ml, severe lymphopenia (<1,000/mm(3)), and elevated serum glutamic oxaloacetic acid transaminase levels. Immunofluorescent antibody examination of tissues and infectivity titrations of tissue homogenates obtained at 3- to 4-day intervals demonstrated significant viral replication in all visceral tissues examined, but not in brain. Livers of all moribund guinea pigs contained moderate to severe hepatocellular necrosis and diffuse fatty change. Splenic red pulp and adrenal cortical tissues were engorged with blood and contained necrotic foci. Pancreatic acinar tissues were atrophied and vacuolated; lung sections typically contained areas of moderate to severe interstitial pneumonia. Inflammatory cells were conspicuously absent from all lesions. The virological and pathological features of adapted Pichinde infection in guinea pigs are remarkably similar to those described for Lassa virus infections in rhesus monkeys and humans, suggesting that this model might provide insight into the pathogenesis and treatment of Lassa fever in humans.