Different classes of ribonucleic acid isolated from lymphocytic choriomeningitis virus

Ribosomal control in RNA virus-infected cells

Viruses are strictly intracellular parasites requiring host cellular functions to complete their reproduction cycle involving virus infection of host cell, viral genome replication, viral protein translation, and virion release. Ribosomes are protein synthesis factories in cells, and viruses need to manipulate ribosomes to complete their protein synthesis. Viruses use translation initiation factors through their own RNA structures or cap structures, thereby inducing ribosomes to synthesize viral proteins. Viruses also affect ribosome production and the assembly of mature ribosomes, and regulate the recognition of mRNA by ribosomes, thereby promoting viral protein synthesis and inhibiting the synthesis of host antiviral immune proteins. Here, we review the remarkable mechanisms used by RNA viruses to regulate ribosomes, in particular, the mechanisms by which RNA viruses induce the formation of specific heterogeneous ribosomes required for viral protein translation. This review provides valuable insights into the control of viral infection and diseases from the perspective of viral protein synthesis.

RT-PCR assay for detection of Lassa virus and related Old World arenaviruses targeting the L gene

This study describes an RT-PCR assay targeting the L RNA segment of arenaviruses. Conserved regions were identified in the polymerase domain of the L gene on the basis of published sequences for Lassa virus, lymphocytic choriomeningitis virus (LCMV), Pichinde virus and Tacaribe virus, as well as 15 novel sequences for Lassa virus, LCMV, Ippy virus, Mobala virus and Mopeia virus determined in this study. Using these regions as target sites, a PCR assay for detection of all known Old World arenaviruses was developed and optimized. The concentration that yields 95% positive results in a set of replicate tests (95% detection limit) was determined to be 4290 copies of Lassa virus L RNA per ml of serum, corresponding to 30 copies per reaction. The ability of the assay to detect various Old World arenaviruses was demonstrated with in vitro transcribed RNA, material from infected cell cultures and samples from patients with Lassa fever and monkeys with LCMV-associated callitrichid hepatitis. The L gene PCR assay may be applicable: (i) as a complementary diagnostic test for Lassa virus and LCMV; (ii) to identify unknown Old World arenaviruses suspected as aetiological agents of disease; and (iii) for screening of potential reservoir hosts for unknown Old World arenaviruses.

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.

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.

Size and secondary structure of avian myeloblastosis virus associated ribosomal RNA: comparison with cellular and precursor ribosomal RNA

Ribosomal RNA isolated from ribosomes present inside avian myeloblastosis virus (AMV) was characterized by electron microscopy using the formamide-urea spreading technique. The molecular weight and the secondary structures were compared with those of r-RNA and precursor r-NA isolated from host cells, the leukemic myeloblasts. The molecular weight of viral r-RNA (1.62 +/- 0.18 X 10(6) and 0.69 +/- 0.10 X 10(6)) and the molecular weight of cellular r-RNA (1.63 +/- 0.18 X 10(6) and 0.67 +/- 0.09 X 10(6)), the latter obtained from avian myeloblasts, were found to be identical and comparable with the molecular weight of chicken liver r-RNA. Likewise, the secondary structures of viral r-RNA were identical to those of cellular r-RNA. The postulated possible precursor character of viral r-RNA was excluded, since the molecules of viral r-RNA do not show any similarity to those of precursor r-RNA. Previously observed differences in behavior of viral and cellular (myeloblastic) r-RNA in sedimentation and electrophoretic mobility are discussed.

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

The principal RNA species isolated from labeled preparations of the arenavirus Pichinde usually include a large viral RNA species L (apparent molecular weight = 3.2 X 10(6)), and a smaller viral RNA species S (apparent molecular weight = 1.6 X 10(6)). In addition, either little or considerable quantities of 28S rRNA as well as 18S rRNA can also be obtained in virus extracts, depending on the virus stock and growth conditions used to generate virus preparations. Similar RNA species have been identified in RNA extracted from Tacaribe and Tamiami arenavirus preparations. Oligonucleotide fingerprint analyses have confirmed the host ribosomal origin of the 28S and 18S species. Such analyses have also indicated that the Pichinde viral L and S RNA species each contain unique nucleotide sequences. Viral RNA preparations isolated by conventional phenol-sodium dodecyl sulfate extraction often have much of their L and S RNA species in the form of aggregates as visualized by either electron microscopy or oligonucleotide fingerprinting of material recovered from the top of gels (run by using undenatured RNA preparations). Circular and linear RNA forms have also been seen in electron micrographs of undenatured RNA preparations, although denatured viral RNA preparations have yielded mostly linear RNA species with few RNA aggregates or circular forms.

Recombination between temperature-sensitive mutants of the arenavirus Pichinde

High-frequency recombination was obtained with temperature-sensitive, conditionally lethal mutants of the arenavirus Pichinde.

Structural components of the arenavirus Pichinde

Purified Pichinde virions grown in monolayers of BHK-21 cells were found to contain three major species of virion proteins as described previously (Ramos et al., J. Virol. 10:661-667, 1972). Two of the proteins were glycosylated (G1, molecular weight = 64,000; G2, molecular weight = 38,000) and were present in similar proportions on the outer surface of the virions. A third protein (N, molecular weight = 66,000) was not glycosylated and, in association with the viral RNA species, was the major protein component of the viral nucleocapsids. An estimate of the approximate number of molecules of these three major proteins per virion was made. Minor amounts of other proteins were also routinely observed in Pichinde virus preparations. None of the three major protein species were phosphorylated to any significant exten, nor did they contain sulfated components. Two virion RNA species (L and S), but no 18S rRNA species, were detected in Pichinde virus preparations obtained from infected BHK-21 cells.

Strandedness of Pichinde virus RNA

The Pichinde virus RNA did not possess the following characteristics of eucaryotic mRNA: polyadenylic acid sequence, capped methylated structure, and ability to direct protein synthesis in vitro. Polysomal RNA extracted from cells infected with Pichinde virus reannealed with 32P-labeled virus RNA, protecting about 60% of the latter against RNase degestion. The polyadenylic acid-containing polysomal RNA also reannealed to the 32P-labeled virus RNA to approximately the same extent. These indicate that the major part of the genomic RNA of Pichinde virus is negative stranded.

Characterization of ribonucleoproteins and ribosomes isolated from lymphocytic choriomeningitis virus

Disruption of purified lymphocytic choriomeningitis (LCM) virus with Nonidet P-40 in 0.5 M KCl followed by sucrose gradient centrifugation in 0.3 M KCl led to the isolation of two viral nucleoproteins (RNPs) as well as 40S and 60S ribosomal subunits. The largest viral RNP sedimented heterogenously at 123S to 148S and was associated with 23S and 31S viral RNA. The other viral RNP sedimented at 83S and was associated with 23S viral RNA. The buoyant density in CsCl was determined to be 1.32 g/cm3 for the viral RNP. Densities of 1.52 and 1.60 g/cm3 were determined for the 40S and 60S subunits, similar to those of the BHK-21 cells subunits dissociated by 0.5 M KCl. The viral RNPs were partly sensitive to RNase.

RNA composition of Junin virus

Junin virus grown in BHK-21 cells was labeled with [3H]uridine and highly purified by differential and isopycnic centrifugation. The RNAs extracted with phenol and analyzed by polyacrylamide gel electrophoresis were shown to be composed of four large species (33, 28, and 18S) and three small ones (4, 5, and 5.5S). This pattern was similar to ones already reported for other arenaviruses. However, there was a striking difference when the virus labeling was performed in the presence of actinomycin D. Labeling of viral rRNA was as much as 60% of the levels obtained in the absence of the drug under conditions in which cellular rRNA's were inhibited by 95% or more.

Lymphocytic Choriomeningitis virus. I. Concentration and purification of the infectious virus

Two procedures for the purification of infectious lymphocytic choriomeningitis virus from cell culture fluid have been developed. If large quantities of very pure virus are to be prepared, infected L cells are maintained with a medium supplemented with calf serum, the proteins of which have been largely removed by pretreatment with polyethylene glycol. Two days after infection of the cultures, the media are collected and the virus is concentrated by treatment with polyethylene glycol 40,000. Purification with a 10,000-fold increase of specific infectivity is achieved with steric chromatography on controlled-pore glass beads with pore sizes of 42 to 44 nm and centrifugation in density gradients prepared with amido trizoate. An alternative method begins with precipitation of the virus from infected cell cuture medium with zinc acetate, followed by controlled-pore glass chromatography and density centrifugation in a discontinuous sucrose gradient. Purification thus obtained is 200-fold in terms of specific infectivity.

Effects of actinomycin D and ultraviolet and ionizing radiation on Pichinde virus

Actinomycin D (0.05 mug/ml) suppresses the synthesis of ribosomal RNA of baby hamster kidney (BHK21) cells. The production of infectious Pichinde virus was enhanced in the presence of actinomycin D, although the production of virus particles was not substantially different from cultures inoculated in the absence of the drug. By prelabeling BHK21 cells with (3)H-uridine and then allowing the virus to replicate in the presence of actinomycin D, it was possible to show that ribosomal RNA synthesized prior to infection was incorporated into the virion. A single-hit kinetics of inactivation of Pichinde virus was observed with ultraviolet light, suggesting that the virus contains only a single copy of genome per virion. Comparison of the inactivation kinetics by gamma irradiation of Pichinde virus with Sindbis and rubella virus indicated that the radiosensitive genome of Pichinde virus was about 6 x 10(6) to 8 x 10(6) daltons. This value is greater than the 3.2 x 10(6) daltons which was estimated by biochemical analysis. One possible explanation considered is that the ribosomal RNA of host cell origin is functional and accounts for the differences in genome size estimated by the two methods.