Virion RNA species of the arenaviruses Pichinde, Tacaribe, and Tamiami

Isolation of Reconstructed Functional Ribonucleoprotein Complexes of Machupo Virus

Arenaviruses initiate infection by delivering a transcriptionally competent ribonucleoprotein (RNP) complex into the cytosol of host cells. The arenavirus RNP consists of the large (L) RNA-dependent RNA polymerase (RdRP) bound to a nucleoprotein (NP)-encapsidated genomic RNA (viral RNA [vRNA]) template. During transcription and replication, L must transiently displace RNA-bound NP to allow for template access into the RdRP active site. Concomitant with RNA replication, new subunits of NP must be added to the nascent complementary RNAs (cRNA) as they emerge from the product exit channel of L. Interactions between L and NP thus play a central role in arenavirus gene expression. We developed an approach to purify recombinant functional RNPs from mammalian cells in culture using a synthetic vRNA and affinity-tagged L and NP. Negative-stain electron microscopy of purified RNPs revealed they adopt diverse and flexible structures, like RNPs of other Bunyavirales members. Monodispersed L-NP and trimeric ring-like NP complexes were also obtained in excess of flexible RNPs, suggesting that these heterodimeric structures self-assemble in the absence of suitable RNA templates. This work allows for further biochemical analysis of the interaction between arenavirus L and NP proteins and provides a framework for future high-resolution structural analyses of this replication-associated complex. IMPORTANCE Arenaviruses are rodent-borne pathogens that can cause severe disease in humans. All arenaviruses begin the infection cycle with delivery of the virus replication machinery into the cytoplasm of the host cell. This machinery consists of an RNA-dependent RNA polymerase-which copies the viral genome segments and synthesizes all four viral mRNAs-bound to the two nucleoprotein-encapsidated genomic RNAs. How this complex assembles remains a mystery. Our findings provide direct evidence for the formation of diverse intracellular arenavirus replication complexes using purification strategies for the polymerase, nucleoprotein, and genomic RNA of Machupo virus, which causes Bolivian hemorrhagic fever in humans. We demonstrate that the polymerase and nucleoprotein assemble into higher-order structures within cells, providing a model for the molecular events of arenavirus RNA synthesis. These findings provide a framework for probing the architectures and functions of the arenavirus replication machinery and thus advancing antiviral strategies targeting this essential complex.

An attenuated Machupo virus with a disrupted L-segment intergenic region protects guinea pigs against lethal Guanarito virus infection

Machupo virus (MACV) is a New World (NW) arenavirus and causative agent of Bolivian hemorrhagic fever (HF). Here, we identified a variant of MACV strain Carvallo termed Car91 that was attenuated in guinea pigs. Infection of guinea pigs with an earlier passage of Carvallo, termed Car68, resulted in a lethal disease with a 63% mortality rate. Sequencing analysis revealed that compared to Car68, Car91 had a 35 nucleotide (nt) deletion and a point mutation within the L-segment intergenic region (IGR), and three silent changes in the polymerase gene that did not impact amino acid coding. No changes were found on the S-segment. Because it was apathogenic, we determined if Car91 could protect guinea pigs against Guanarito virus (GTOV), a distantly related NW arenavirus. While naïve animals succumbed to GTOV infection, 88% of the Car91-exposed guinea pigs were protected. These findings indicate that attenuated MACV vaccines can provide heterologous protection against NW arenaviruses. The disruption in the L-segment IGR, including a single point mutant and 35 nt partial deletion, were the only major variance detected between virulent and avirulent isolates, implicating its role in attenuation. Overall, our data support the development of live-attenuated arenaviruses as broadly protective pan-arenavirus vaccines.

Reverse genetics recovery of Lujo virus and role of virus RNA secondary structures in efficient virus growth

Arenaviruses are rodent-borne viruses with a bisegmented RNA genome. A genetically unique arenavirus, Lujo virus, was recently discovered as the causal agent of a nosocomial outbreak of acute febrile illness with hemorrhagic manifestations in Zambia and South Africa. The outbreak had a case fatality rate of 80%. A reverse genetics system to rescue infectious Lujo virus from cDNA was established to investigate the biological properties of this virus. Sequencing the genomic termini showed unique nucleotides at the 3' terminus of the S segment promoter element. While developing this system, we discovered that reconstructing infectious Lujo virus using the previously reported L segment intergenic region (IGR), comprising the arenaviral transcription termination signal, yielded an attenuated Lujo virus. Resequencing revealed that the correct L segment IGR was 36 nucleotides longer, and incorporating it into the reconstructed Lujo virus restored the growth rate to that of the authentic clinical virus isolate. These additional nucleotides were predicted to more than double the free energy of the IGR main stem-loop structure. In addition, incorporating the newly determined L-IGR into a replicon reporter system enhanced the expression of a luciferase reporter L segment. Overall, these results imply that an extremely stable secondary structure within the L-IGR is critical for Lujo virus propagation and viral protein production. The technology for producing recombinant Lujo virus now provides a method to precisely investigate the molecular determinants of virulence of this newly identified pathogen.

Sequence analysis of the S RNA of the African arenavirus Mopeia: an unusual secondary structure feature in the intergenic region

Mopeia virus is an apparently nonpathogenic African arenavirus which can protect animals from subsequent challenge by the closely related Lassa virus. As a step toward understanding these differences in pathogenicity and the means by which Mopeia virus infection can protect against subsequent Lassa virus infection, cDNA clones corresponding to 3419 nucleotides of Mopeia virus S RNA were isolated and sequenced. Two open reading frames, encoding the glycoprotein precursor (GPC) and nucleocapsid (N) proteins, were located in the ambisense arrangement characteristic of the arenaviruses. Comparison of the amino acid sequences of the translation products with those of two Lassa virus strains showed considerable conservation, with 74 and 80% identity for the two glycoproteins G1 and G2, and 74% identity for the N protein. The putative dibasic site of GPC cleavage (R-R) was conserved, as were the potential N-linked glycosylation sites. A striking difference between Mopeia virus and Lassa virus was identified in the noncoding intergenic region. Instead of the single hairpin structure formed by base-pairing of complementary sequences which is usually found, the Mopeia virus S RNA has the potential to form two hairpins. These hairpins were similar in sequence and may have been formed in a duplication event during RNA replication. The possible contribution of this secondary structure feature to differences in pathogenicity between Mopeia and Lassa viruses is discussed.

The completed sequence of lymphocytic choriomeningitis virus reveals a unique RNA structure and a gene for a zinc finger protein

The arenavirus, lymphocytic choriomeningitis virus (LCMV) has a single-stranded RNA genome composed of a large (L) and a small (S) RNA segment. The completed sequence of LCMV, presented here, reveals a formerly unknown gene (Z) on the L genomic segment. This gene is encoded in the positive or message-sense of the viral genomic RNA, whereas the adjacent gene (L) is in the genome-complementary, or negative sense. The ambisense polarity of the genes on the L RNA reiterates the polarity of genes on the small (S) genomic segment. The Z gene encodes a 10-kDa protein containing a single zinc-finger sequence (Cys2His2). A small RNA representing the message sense of the Z gene is found in infected cells and within virions. In contrast to the known LCMV proteins having structural or enzymatic functions, the predicted Z gene product is most likely to be an RNA-binding protein with a regulatory role. The encapsidation of a message sense Z RNA suggests a role for this gene immediately following virus penetration. The L/Z intergenic region is rich in cytidylic acid (C) and presents an unusual RNA structure. All cDNA clones of the intergenic region differ from each other within a certain poly(C) stretch and lack a 30-base region present in the direct RNA sequence. Finally, the completed sequence establishes that the L RNA 5' end is complementary to its 3' end. The L RNA termini, similar to the S RNA termini, have a small but potentially important asymmetry of sequence. LCMV is the first arenavirus to be completely sequenced.

Detection of virus-specific RNA-dependent RNA polymerase activity in extracts from cells infected with lymphocytic choriomeningitis virus: in vitro synthesis of full-length viral RNA species

We have developed an in vitro assay for the lymphocytic choriomeningitis virus (LCMV) RNA-dependent RNA polymerase with ribonucleoprotein complexes extracted from acutely infected tissue culture cells. The RNA products synthesized in vitro corresponded in size to the full-length genomic L and S RNAs and subgenomic NP and GP mRNAs normally produced in vivo during acute LCMV infection. In a temporal analysis spanning the first 72 h of acute infection, the in vitro polymerase activity of ribonucleoprotein complexes was maximal at 16 h and declined significantly at later times. In contrast, the intracellular levels of the viral L protein (the putative polymerase protein) appeared to be maximal at 48 to 72 h postinfection. Our results suggest that the accumulation of L protein correlates with reduced viral replication and transcription at later times in acute infection and may be involved in the transition from acute to persistent LCMV infection.

Homologous interference of lymphocytic choriomeningitis virus involves a ribavirin-susceptible block in virus replication

Depending on the multiplicity of infection (MOI), infection of L929 cells results in either productive lymphocytic choriomeningitis virus replication or homologous interference M. Bruns, A. Gessner, H. Lother, and F. Lehmann-Grube, Virology 166:133-139, 1988). As shown in this communication, productive lymphocytic choriomeningitis virus replication as observed at a low MOI was effectively inhibited by ribavirin. In contrast, virus yields increased if cells were infected with a high MOI and in the presence of 5 microM of the antiviral compound. This drug-dependent release of infectious virus was preceded by enhanced nucleoprotein (NP) synthesis, a change in intracellular NP distribution, and by an onset of glycoprotein synthesis. It is therefore proposed that this block in viral replication is brought about by a posttranslational effect on a viral gene product, probably the NP, present in reasonably large quantities both during homologous interference as well as persistent infection.

The ends of La Crosse virus genome and antigenome RNAs within nucleocapsids are base paired

The three La Crosse virus genomes are found as circular structures in the electron microscope, and the RNA ends of at least the small (S) and medium (M) segments are highly complementary. When examined for psoralen cross-linking, about half of the S, at most 1 to 2% of the M, and none of the large (L) nucleocapsid RNAs could be cross-linked in virions or at late times intracellularly, under conditions in which each free RNA reacted completely. For the S segment, genomes and antigenomes first detected intracellularly could not be cross-linked at all, and their cross-linkability increased gradually with time. Antigenomes behaved similarly to genomes in all respects. It appears that the majority of all three segments are base paired at their ends and that the limited cross-linkability reflects the accessability of the RNA within nucleocapsids to psoralen. The gradual increase in cross-linkability may be important in persistent mosquito cell infection, in which it correlates with decreased S mRNA synthesis rates, and may be part of the mechanism which this infection becomes self-limiting. The implications of double-stranded RNA panhandles within nucleocapsids are discussed.

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.

Genomic RNAs of influenza viruses are held in a circular conformation in virions and in infected cells by a terminal panhandle

The viral RNA segments in influenza virions were shown to be circular in conformation by using psoralen crosslinking methods. Electron microscopy of purified RNA following treatment of virus with the psoralen reagent 4'-aminomethyltrioxsalen (AMT) revealed circles with lengths corresponding to the individual segments. RNA blot analysis using polyacrylamide gels demonstrated that RNA from AMT-treated virus had a slowed migration, consistent with it being a single-stranded circle. Furthermore, nuclease S1 protection assays indicated that the termini of the RNA segments form an approximately 15-base-pair-long panhandle. This structure is consistent with the partial sequence complementarity that has been observed for the termini of all influenza virus RNAs. By RNA blot analysis, circular structures of viral sense RNA were also found in influenza virus-infected cells at early and late time points. The circular RNA was the predominant species at the time when the major transcription product is message RNA. This finding and the observation that the termination signal for mRNA synthesis directly abuts the panhandle suggest that a panhandle in the template viral RNA is a cis regulatory signal promoting the synthesis of mRNA instead of plus-sense template. Also, since the panhandle is present in high concentration in virions, we suggest that it is required for packaging and that the input RNA after infection is in the proper conformation for synthesis of primary transcripts.

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.

L and S species of Machupo virion RNA contain a mixture of complementary strands. Brief report

RNase resistance analyses of native, heat-denatured and self-annealed L and S species of Machupo virion RNA revealed the presence of complementary sequences. Self-annealing was concentration-dependent. The data indicate, that complementary sequences were present in separate RNA strands.

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.

Synthesis of Tacaribe virus polypeptides in an in vitro coupled transcription and translation system

We have analyzed polypeptides synthesized in a coupled in vitro transcription and translation system in response to detergent-disrupted Tacaribe virus. Analysis of the major Tacaribe virus-specified product by two-dimensional polyacrylamide gel electrophoresis indicated that it had an isoelectric point similar to that of the Tacaribe nucleocapsid polypeptide N; however, the in vitro product had an approximate mol. wt. of 73 000, compared to a mol. wt. of 68 000 for the N protein. The 73 000 dalton product was found to yield proteolytic cleavage products with similar electrophoretic mobilities to those obtained from the virion P and N proteins. These results, as well as pulse-chase experiments in Tacaribe virus-infected cells, suggest that a 73 000 dalton polypeptide may be processed to yield the N polypeptide. The polypeptides synthesized in the coupled system depended on the amount and type of virus added; addition of purified Shark River (SR) virus, a member of the Patois group of bunyaviruses, resulted in synthesis of a polypeptide of mol. wt. 22 000 which corresponds to the SR nucleocapsid protein.

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.

Lymphocytic choriomeningitis virus. IV. Electron microscopic investigation of the virion

The structure of lymphocytic choriomeningitis virus (LCM virus) was investigated by a variety of conventional as well as novel electron microscopic procedures. Thin sections of infected cells revealed the characteristic arenavirus entities whose interiors contain ribosome-like granules but look otherwise empty. In contrast, most thin-sectioned virus particles from infectious cell culture fluid, both untreated and highly purified with little loss of initial infectivity, appeared to be filled with rather homogeneous cores. Cores rather than granules were also found in positively contrasted whole and thin-sectioned virus particles. We favor the explanation that the sandy grains, which have given this group of viruses its name, are altered cores that happen to look like ribosomes. However, the alternative cannot yet be excluded, namely, that LCM virus-infected cells produce two types of particles, of which only the core-containing ones represent virions.

Tick-borne viruses structurally similar to Orthomyxoviruses

Members of the Orthomyxoviridae are characterized at the structural level as enveloped, negative sense, RNA viruses that bud from the outer plasma membranes of infected cells and have seven or eight species of single-stranded RNA. None of the three types of orthomyxoviruses (influenza A, B, C) has been shown to be transmitted by arthropods; rather, the viruses are transmitted directly or indirectly from one infected vertebrate to another. Analyses of the virion RNA species and polypeptides of the tick-borne Thogoto and Dhori viruses indicate that they have structural characteristics similar to accepted members of the Orthomyxoviridae. For example, the viruses have seven size classes of single-stranded RNA with 3' end consensus sequences of HOUCGUUG (or U or A) UUGUUC. . . . The viruses contain 54-56 X 10(3) Da nucleocapsid protein, an internal 28 X 10(3) Da putative matrix protein plus minor 85-90 X 10(3) Da proteins, and a major outer 65 X 10(3) Da glycoprotein. In addition to their sensitivity to actinomycin D and alpha-amanitin the viruses morphologically and morphogenetically resemble orthomyxoviruses.

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.

Pichinde virus L and S RNAs contain unique sequences

Using oligodeoxyribonucleotides produced by limited DNase I digestion of calf thymus DNA as a primer, we synthesized complementary DNA (cDNA) from the L and the S RNAs of Pichinde virus. The reaction conditions for in vitro cDNA synthesis were optimized to allow transcription of about 90% of either L or S RNA. No significant hybridization was observed when the L cDNA was hybridized to the S RNA, or when the S cDNA was hybridized to the L RNA. The results indicate that the L and S RNAs of Pichinde virus contain unique nucleotide sequences.

Assignment of the large oligonucleotides of vesicular stomatitis virus to the N, NS, M, G, and L genes and oligonucleotide gene ordering within the L gene

Analyses of prototype vesicular stomatitis (VSV, Indiana serotype) mRNA-32P-labeled viral RNA duplexes have established the assignments of 65 of the 72 large oligonucleotides that are recovered by two-dimensional electrophoresis of RNase T1 digests of the viral RNA. Fifty of the oligonucleotides are recovered in the L RNA duplex, four each in the N, M, and NS duplexes, and three in the G RNA duplex. Studies of three small defective-particle RNA species indicate that they have only L gene oligonucleotides in addition to three of the seven unassigned oligonucleotides. Some L gene ordering of oligonucleotides can be postulated from the defective-particle RNA sequence analyses. Analyses of naturally occurring alternate isolates of VSV Indiana have established that by comparison to the prototype virus strain, the alternate isolates minimally have genome sequence differences in L, G, N, NS and/or unassigned regions of the genome. Changes in the genome have also been induced by vitro high-level mutagenesis of the prototype virus.

Distinctive RNA transcriptase, polyadenylic acid polymerase, and polyuridylic acid polymerase activities associated with Pichinde virus

Three RNA polymerase activities were found and associated with purified Pichinde virus, a member of the Arenaviridae. A heat-labile polymerase activity which required all four ribonucleoside triphosphates for optimal activity co-sedimented on sucrose gradient centrifugation with the viral ribonucleoprotein complex from detergent-disrupted virus preparations. This enzyme synthesized heteropolymers which represented about 23% of the genome RNA as determined by nucleic acid hybridization. Two relatively heat-stable polymerase activities which differed in their cation requirement and substrate specificity were recovered with the virus-associated ribosomes. These polymerase activities synthesized homopolymers of limited chain length: in the presence of 10 mM Mg2%, polyuridylic acid was made, whereas in the presence of 1 mM Mn2%, polyadenylic acid was made. The addition of complementary RNA synthesized with the viral transcriptase in vitro to the reaction mixture containing the polyadenylic acid polymerase activity resulted in the terminal addition of polyadenylic acid to the complementary RNA. The possible function of the ribosome-associated polymerase activities in the replication of the virus is discussed.