Molecular cloning and sequencing of the La Crosse virus S RNA

Comparative sequence analyses of La Crosse virus strain isolated from patient with fatal encephalitis, Tennessee, USA

We characterized a La Crosse virus (LACV) isolate from the brain of a child who died of encephalitis-associated complications in eastern Tennessee, USA, during summer 2012. We compared the isolate with LACV sequences from mosquitoes collected near the child's home just after his postmortem diagnosis. In addition, we conducted phylogenetic analyses of these and other sequences derived from LACV strains representing varied temporal, geographic, and ecologic origins. Consistent with historical findings, results of these analyses indicate that a limited range of LACV lineage I genotypes is associated with severe clinical outcomes.

Viral RNA silencing suppressors (RSS): novel strategy of viruses to ablate the host RNA interference (RNAi) defense system

Pathogenic viruses have developed a molecular defense arsenal for their survival by counteracting the host anti-viral system known as RNA interference (RNAi). Cellular RNAi, in addition to regulating gene expression through microRNAs, also serves as a barrier against invasive foreign nucleic acids. RNAi is conserved across the biological species, including plants, animals and invertebrates. Viruses in turn, have evolved mechanisms that can counteract this anti-viral defense of the host. Recent studies of mammalian viruses exhibiting RNA silencing suppressor (RSS) activity have further advanced our understanding of RNAi in terms of host-virus interactions. Viral proteins and non-coding viral RNAs can inhibit the RNAi (miRNA/siRNA) pathway through different mechanisms. Mammalian viruses having dsRNA-binding regions and GW/WG motifs appear to have a high chance of conferring RSS activity. Although, RSSs of plant and invertebrate viruses have been well characterized, mammalian viral RSSs still need in-depth investigations to present the concrete evidences supporting their RNAi ablation characteristics. The information presented in this review together with any perspective research should help to predict and identify the RSS activity-endowed new viral proteins that could be the potential targets for designing novel anti-viral therapeutics.

California serogroup Gc (G1) glycoprotein is the principal determinant of pH-dependent cell fusion and entry

Members of the California serogroup of orthobunyaviruses, particularly La Crosse (LAC) and Tahyna (TAH) viruses, are significant human pathogens in areas where their mosquito vectors are endemic. Previous studies using wild-type LAC and TAH181/57, a highly neurovirulent strain with low neuroinvasiveness (Janssen, R., Gonzalez-Scarano, F., Nathanson, N., 1984. Mechanisms of bunyavirus virulence. Comparative pathogenesis of a virulent strain of La Crosse and an avirulent strain of Tahyna virus. Lab. Invest. 50 (4), 447-455), have demonstrated that the neuroinvasive phenotype maps to the M segment, the segment that encodes the two viral glycoproteins Gn (G2) and Gc (G1), as well as a non-structural protein NSm. To further define the role of Gn and Gc in fusion and entry, we prepared a panel of recombinant M segment constructs using LAC, TAH181/57, and V22F, a monoclonal-resistant variant of LAC with deficient fusion function. These M segment constructs were then tested in two surrogate assays for virus entry: a cell-to-cell fusion assay based on T7-luciferase expression, and a pseudotype transduction assay based on the incorporation of the bunyavirus glycoproteins on an MLV backbone. Both assays demonstrated that Gc is the principal determinant of virus fusion and cell entry, and furthermore that the region delineated by amino acids 860-1442, corresponding to the membrane proximal two-thirds of Gc, is key to these processes. These results, coupled with structural modeling suggesting homologies between the carboxy region of Gc and Sindbis virus E1, suggest that the LAC Gc functions as a type II fusion protein.

La Crosse virus nonstructural protein NSs counteracts the effects of short interfering RNA

Through a process known as RNA interference (RNAi), double-stranded short interfering RNAs (siRNAs) silence gene expression in a sequence-specific manner. Recently, several viral proteins, including the nonstructural protein NSs of tomato spotted wilt virus (a plant-infecting bunyavirus), the interferon antagonist protein NS1 of influenza virus, and the E3L protein of vaccinia virus, have been shown to function as suppressors of RNAi, presumably as a counterdefense against cellular mechanisms that decrease viral production. La Crosse virus (LACV), a member of the California serogroup of orthobunyaviruses, has a trisegmented negative-stranded genome comprised of large (L), medium (M), and small (S) segments. To develop a strategy for segment-specific inhibition of transcription, we designed 13 synthetic siRNAs targeting specific RNA segments of the LACV genome that decreased LACV replication and antigen expression in mammalian (293T) and insect (C6/36) cells. Furthermore, NSs, a LACV nonstructural protein, markedly inhibited RNAi directed both against an LACV M segment construct and against a host gene (glyeraldehyde-3-phosphate dehydrogenase), suggesting a possible role for this viral protein in the suppression of RNA silencing. Segment-specific siRNAs will be useful as a tool to analyze LACV transcription and replication and to obtain recombinant viruses. Additionally, NSs will help us to identify molecular pathways involved in RNAi and further define its role in the innate immune system.

Sequence comparisons of medium RNA segment among 15 California serogroup viruses

The complete nucleotide sequences have been determined for the M segment of 12 California (CAL) serogroup bunyaviruses. A method is described here of long reverse transcription-polymerase chain reaction (RT-PCR) that yields the full-length medium (M) RNA genomic segment. A phylogenetic tree was constructed by comparison of the open reading frames (ORFs) in the M RNA segment of 15 CAL serogroup viruses. Three distinct branches were identified and they are represented by the California encephalitis (CE), Melao (MEL), and Trivittatus (TVT) complexes. These groups correspond to those previously established by small (S) RNA genomic sequences. In addition, except for Inkoo virus, the predicted relationship among these viruses agreed with those found by serology.

Analysis of LaCrosse virus S mRNA 5' termini in infected mosquito cells and Aedes triseriatus mosquitoes

Nucleotide sequences were determined for the 5' termini of La Crosse virus (LAC) S segment mRNA from persistently infected mosquito cell cultures (C6/36 from Aedes albopictus) and embryos (Aedes triseriatus). LAC primes transcription of its mRNA with "scavenged" 5' caps and adjacent oligonucleotides from host mRNAs, and these non-virus-encoded 5'-terminal extensions are heterogeneous in infected mammalian cells. The nature of mosquito host-derived primers has not been previously investigated. During early C6/36 cell infection, LAC mRNA 5'-terminal sequences were heterogeneous, but variability decreased as infection persisted. One predominant sequence, 5' CCACTCGCCACT (sequence 1), was observed throughout C6/36 cell infection but was more prevalent after 15 days postinfection. This LAC mRNA 5'-terminal sequence comprised 81% of the scavenged host oligonucleotides from vertically infected A. triseriatus eggs during embryogenesis. As these embryos progressed in the dormant overwintering stage (diapause), the predominant scavenged sequence became 5' AGGAAAAGATGGT (sequence 2), and sequence 1 became less prevalent. As the eggs emerged from diapause, the LAC mRNA 5' termini were more variable; 33% had sequence 1, and the remainder were heterogeneous. In post-diapausing eggs, 100% of viral mRNAs had sequence 1 at their 5' termini. Molecular analyses thus revealed continuous but selective LAC cap scavenging during persistent C6/36 cell infection and during embryogenesis and diapause in A. triseriatus eggs. The variety of host-derived sequences was limited in both biosynthetically active (embryonating) and dormant (diapausing) eggs.

Completion of the La Crosse virus genome sequence and genetic comparisons of the L proteins of the Bunyaviridae

La Crosse virus is a member of the Bunyavirus genus in the family Bunyaviridae, viruses with trisegmented RNA genomes of mostly negative polarity composed of large (L), medium (M), and small (S) segments. The sequences of the La Crosse/original M and S RNA segments have been previously characterized. Using reverse transcriptase in conjunction with PCR amplification, we have obtained the nucleotide sequence of the L RNA segment, which encodes the viral polymerase in a single large open reading frame. Comparison of the amino acid sequence of the LAC L protein with the sequence of other polymerases from members of the Bunyaviridae, demonstrated the presence of several conserved motifs, some of which are characteristic of many polymerase proteins. A genetic tree comparing the available polymerase proteins of the Bunyaviridae provides insights into the phylogenetic relationships within this large family. Members of the genus Bunyavirus, which are mosquito-borne and infect mammals, have a closer relationship to the plant viruses represented by tomato spotted wilt virus (Tospovirus genus) than to viruses of other genera in the family Bunyaviridae.

Reassortment of La Crosse and Tahyna bunyaviruses in Aedes triseriatus mosquitoes

Experiments were conducted to determine if La Crosse (LAC) and Tahyna (TAH) viruses reassort in Aedes triseriatus mosquitoes and to determine the genotypic frequencies of viruses selected by in vivo vector interactions. A molecular hybridization technique was used to analyze progeny viruses. Probes specific for the La Crosse L, M and S segments (pLAC4.16: LAC L RNA; pLAC4.27: LAC M RNA; pLAC4C-26: LAC S RNA) were used to determine the parental origin of the progeny RNA segments. Following infection with a mixture of LAC and TAH viruses, mosquitoes were held for 23 days extrinsic incubation, then assayed for reassortment. Individual progeny viruses were isolated by plaque assay and propagated in BHK-21 cells. Cytoplasmic RNA was extracted from the cells, blotted in triplicate to Nytran, and each blot was hybridized with 32P-labelled pLAC4.16, pLAC4.27 or pLAC4C-26 to determine the parental origin of each RNA segment. High frequency reassortment occurred in these mosquitoes. All of the expected genotypes resulting from a cross of LAC and TAH were obtained from these mosquitoes. Genotypic frequencies of 708 virus isolates from 39 mosquitoes were: LLL, 150 (21%); LLT, 71 (10%); LTL, 39 (5.5%); LTT, 109 (15%); TTT, 259 (36%); TTL, 16 (2.2%); TLT, 55 (7.8%); TLL, 9 (1.2%).

Identification and characterization of a Hantavirus strain of unknown origin by nucleotide sequence analysis of the cDNA derived from the viral S RNA segment

The genetic characterization of a serologically Hantaan-like virus but of unknown origin (termed DX) was carried out by molecular cloning and nucleotide sequencing of the corresponding cDNA of the viral S RNA segment. The S RNA was found to be 1765 nucleotides long with 3' and 5' termini being complementary for 24 bases. The virus messenger-sense RNA contains one major open reading frame (ORF) encoding 428 amino acids or a 50 kD polypeptide. A comparison of the DX S RNA segment to those of Sapporo rat, Hantaan, Puumala/Hällnäs B1, and Prospect Hill viruses reveals 95.4, 71.3, 55.3, and 60.9% homology at the nucleotide sequence level, and 94.7, 80.1, 58.4, and 59.8% at the deduced amino acid sequence level. Thus Hantavirus strain DX is very closely related to Sapporo rat virus. We also analyzed the S RNA segments of these Hantaviruses for the presence of a second ORF encoding a potential nonstructural NSs protein. All potential second ORFs detected in the different S RNA segments differ substantially in length and position among the viruses, despite the high conservation of the nucleotide sequences and the overall structure of the nucleocapsid proteins. This suggests that the nucleocapsid protein is the only polypeptide encoded by Hantavirus S RNA segments, setting them apart from the other members of the Bunyaviridae family.

Anti-mRNAs in La Crosse bunyavirus-infected cells

Unlike some members of the family Bunyaviridae which contain ambisense genomes, all La Crosse virus reading frames are translated from antigenome sense mRNAs. Nevertheless, La Crosse virus genome sense mRNAs or anti-mRNAs are initiated from antigenome templates. These are characterized by the same range of capped, nontemplated sequences at their 5' ends as mRNAs, but their 3' ends are presumed to be heterogenous, as they were not seen on RNA blots. The anti-mRNAs are estimated to be 15 to 30 times less abundant than mRNAs, but remarkably, this ratio is similar to that of functional genome sense mRNAs made from other bona fide ambisense segments. A role for these anti-mRNAs during infection is unclear.

Nucleotide sequence analysis of the S genomic segment of Prospect Hill virus: comparison with the prototype Hantavirus

The genomic S RNA segment of Prospect Hill virus (PHV), a member of the Hantavirus genus, was molecularly cloned and the nucleotide sequence of the cDNA determined. The PHV S RNA segment is 1675 nucleotides long. A long open reading frame was identified in the viral complementary-sense RNA that could encode a 433 amino acid (49K) nucleocapsid (N) protein. Comparison with the sequence of the related Hantavirus (Hantaan 76-118) S RNA segment indicated that there was 57% nucleotide sequence homology between the two S RNA segments. A higher degree of conservation in amino acid sequence homology (62%) was observed in the N proteins of these viruses. At the N-terminus 147 of 225 amino acids are homologous, while approximately 82% of the 124 amino acids at the C-terminus are homologous between the two N proteins. The longest stretch of homologous amino acid sequence is found in this region, and is 17 amino acids in length. Also, many of the differences in amino acid sequence between the two N proteins resulted from conservative substitutions. Hydropathy plots of the two N proteins also reveal many similarities including a conserved potential antigenic site. Unlike Hantaan virus, a second smaller overlapping open reading frame was observed in the viral complementary-sense RNA of PHV and could potentially encode a 90 amino acid (10.5K) protein. Our data indicate that the N proteins of PHV and Hantaan virus are closely related despite divergence in the nucleotide sequence of their S RNA segments.

Molecular characterization of the RNA S segment of nephropathia epidemica virus strain Hällnäs B1

The S segment RNA of nephropathia epidemica virus (NEV) strain Hällnäs B1 was isolated by molecular cloning of the corresponding cDNA. The RNA is 1785 nucleotides long with the 3' and 5' termini being complementary for 23 bases. The viral messenger-sense RNA contains one major open reading frame (ORF) with a coding capacity of 433 amino acids encoding a 49-kDa polypeptide. Compared to the Hantaan S segment cDNA sequence there is a nucleotide homology of 60 and 61% at the amino acid level. Many of the amino acid differences are conservative exchanges. The C-termini of the NEV and Hantaan nucleocapsid proteins are nearly identical and the hydrophilicity profiles are very similar. In contrast, the following differences are significant: The calculated isoelectric points of the NEV and Hantaan nucleocapsid proteins are 5.6 and 6.7, respectively. The most prominent antigenic determinants predicted by the hydrophilicity profiles are located close to the C-terminus of NEV and close to the N-terminus of Hantaan virus nucleocapsid polypeptides.

The translational requirement for complete La Crosse virus mRNA synthesis is cell-type dependent

The translational requirement to prevent premature termination during La Crosse virus S mRNA synthesis was found to be cell-type dependent. This requirement was present in the BHK, HEL, and Vero cell lines we examined, but not in C6/36 mosquito cells. The cell-dependent translational requirement could be reproduced in vitro by using either cell extracts or purified virions of BHK and C6/36 cells. In the BHK reactions, the polymerase terminated predominantly at nucleotide 175 in the absence of concurrent translation and required translation to read through this position. In the C6/36 reactions, however, the polymerase reads through nucleotide 175 efficiently independent of translation. Reconstitution studies suggested that the translational requirement was due to a factor(s) present in BHK, but not in C6/36, cells.

La Crosse virus nucleocapsid protein controls its own synthesis in mosquito cells by encapsidating its mRNA

Within 24 to 48 h of La Crosse virus infection of mosquito cells, greater than 75% of the S mRNA was found to band in CsCl density gradients at the position of genome or antigenome nucleocapsids. The encapsidation of the S mRNA correlates with the repression of N protein synthesis in vivo, and the encapsidated S mRNA cannot be translated in vitro. Unlike genome and antigenome assembly, S mRNA assembly is a relatively slow process, which is not coupled to its synthesis. Within the encapsidated S mRNA population, three forms could be distinguished, those with intact primers which were or were not also assembled with N protein and those in which the primer and up to 3 template bases had been lost. We suggest that genome replication, but not transcription, is down regulated with time in mosquito cells for reasons that are unclear. The pool of unassembled N protein then increased to the point at which it began to interact with its own mRNA, as this mRNA also contains what is considered to be the assembly site, i.e., the conserved sequences at the 5' ends of all genome and antigenome chains. This lead to the assembly of the entire mRNA, except for the nontemplate primer. Some of the primers were then also assembled with N protein, whereas others were digested to produce truncated mRNAs.

Mechanism of La Crosse virus inhibition by ribavirin

The effect of ribavirin on the growth and replication of La Crosse virus was examined. The data suggest that low concentrations of ribavirin have a marked effect on the initial steps of La Crosse virus transcription. The therapeutic potential of ribavirin in the treatment of human California encephalitis serotype infections is discussed in light of these findings.

The 3'-terminal sequence of a wound tumor virus transcript can influence conformational and functional properties associated with the 5'-terminus

We recently reported the presence of segment-specific inverted repeats within the terminal regions of wound tumor virus genomic segments (J. V. Anzol, Z. Xu, T. Asamizu, and D. L. Nuss, 1987, Proc. Natl. Acad. Sci. USA, 84, 8301-8305). This report describes a series of experiments designed to investigate potential intramolecular interactions involving the 5'- and 3'-terminal domains of wound tumor virus transcripts. A series of transcription vectors were constructed which allowed the synthesis of an exact copy of the transcript corresponding to genomic segment S8 and four analogs that differed from the authentic sequence only at the immediate 3'-terminus. Modifications designed to extend or alter the 3'-terminal inverted repeat altered the in vitro translational efficiency of the transcript and the sensitivity of phosphodiester bonds within the immediate 5'-terminal domain to digestion by nuclease T1. These results were consistent with computer-assisted secondary structure analyses of the complete nucleotide sequence of transcripts corresponding to six genomic segments which predicted intramolecular interactions involving the terminal inverted repeats. Potential roles of the terminal domains in expression, sorting and packaging of a segmented RNA genome are considered.

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.

Intracellular accumulation of Punta Toro virus glycoproteins expressed from cloned cDNA

The Punta Toro virus (PTV) middle size (M) RNA encodes two glycoproteins, G1 and G2, and possibly a nonstructural protein, NSM. A partial cDNA clone of the M segment which contains G1 and G2 glycoprotein coding sequences but lacks most of the NSM sequences was inserted into the genome of vaccinia virus under the control of an early vaccinia promoter. Cells infected with the recombinant virus were found to synthesize two polypeptides with molecular weights of 65,000 (G1) and 55,000 (G2) that reacted specifically with antibody against PTV. Studies using indirect immunofluorescence microscopy revealed that these proteins accumulated intracellularly in the perinuclear region. The results of endoglycosidase H digestion of these glycoproteins suggested that both G1 and G2 glycoproteins were transported from the RER to the Golgi complex. These proteins were not chased out from the Golgi region during a 6-hr incubation in the presence of cycloheximide. Surface immune precipitation and 125I-protein A binding assays also demonstrated that the majority of the G1 and G2 glycoproteins are retained intracellularly. These results indicate that the PTV glycoproteins contain the necessary information for retention in the Golgi apparatus.

Nucleotide sequence of the M segment of Germiston virus: comparison of the M gene product of several bunyaviruses

The complete nucleotide sequence of the M RNA segment of Germiston bunyavirus was determined from plasmids containing overlapping M cDNA inserts. The M segment is 4534 nucleotides long and contains a 50-base-long inverted terminal repeat which can form a stable hydrogen-bonded secondary structure with a delta G of -45.8 kcal/mol. The RNA molecule complementary to viral RNA contains a single large open reading frame that encodes a 1437 amino acid-long protein with hydrophobic amino and carboxy terminal regions, which could represent signal and anchor sequences, respectively. It is presumed that this gene product is the polyprotein precursor to glycoproteins G1 and G2 and to the nonstructural polypeptide NSM. The nucleotide and amino acid sequences of the M RNA of Bunyamwera virus (prototype of the serogroup) and snowshow hare and La Crosse viruses (California serogroup) (Lees et al., 1986; Eshita and Bishop, 1984; Grady et al., 1987) were compared to those of Germiston virus. An overall amino acid sequence homology of 44% was found between Germiston and snowshoe hare viruses and of 61% between Germiston and Bunyamwera viruses. Most of the cysteines, three out of seven of the potential glycosylation sites, as well as the N and C terminal hydrophobic domains, are conserved between the four viruses.

LaCrosse virus gene expression in mammalian and mosquito cells

LaCrosse virus infection of mammalian BHK cells is highly cytopathic, whereas that of mosquito C6/36 cells is asymptomatic and persistent. When the individual mRNAs and their genome segments are followed in parallel infections, cytopathic effects were found to correlate with the rate of synthesis, but not the accumulation, of the viral RNAs. The change from the acute to the persistent phase of the infection in C6/36 cells was found to take place at 24 hr p.i., at which time genome and N protein synthesis was severely reduced, even though mRNA levels remained high. When the persistent infection was followed for 72 days, the total amounts of genomes and their relative proportions were found to fluctuate greatly, whereas mRNA levels were either severely reduced or undetectable. DI genomes could not be detected during this time. The self-limiting nature of the mosquito cell infection appears to be due the translational control of N protein synthesis.

Rift Valley fever virus M segment: cell-free transcription and translation of virus-complementary RNA

A cell-free system has been used to study gene expression of the M segment RNA of the Phlebovirus Rift Valley fever virus (RVFV). RVFV sequence-containing plasmids were used to synthesize M segment mRNA-like transcripts. These transcripts were then translated in vitro in the absence or presence of microsomal membranes. Cell-free translation of a transcript which closely resembled authentic M segment mRNA (RNA-7) yielded a primary translation product of 133 kilodaltons (kDa), the size expected of a polypeptide encompassing the entire open reading frame (ORF) of the M segment. When translations were conducted in the presence of microsomal membranes, this primary protein was cotranslationally processed to yield the two viral glycoproteins, G1 and G2, as well as proteins of 78, 21, and 14 kDa. With one exception, these in vitro processed polypeptides comigrated with M segment-encoded proteins found in RVFV-infected cell lysates. A polypeptide corresponding to the in vitro 21-kDa protein was not detected in vivo. To investigate translational initiation and processing of the protein products of the M segment, additional transcripts were generated in which varying portions of the amino-terminal "preglycoprotein" region of the M segment ORF were deleted. Translation results indicated that the 78- and 21-kDa proteins were initiated from the first methionine codon of the ORF, and the 14-kDa polypeptide began from the second in-phase ATG. These products and a major portion of the preglycoprotein region sequence were not required for the proper synthesis and processing of the viral glycoproteins in vitro. In light of these results, possible expression strategies used by this Phlebovirus M segment RNA are discussed.

Rift Valley fever virus M segment: use of recombinant vaccinia viruses to study Phlebovirus gene expression

Recombinant vaccinia viruses were constructed and used in conjunction with site-specific antisera to study the coding capacity and detailed expression strategy of the M segment of the Phlebovirus Rift Valley fever virus (RVFV). The M segment could be completely and faithfully expressed in recombinant RVFV-vaccinia virus-infected cells, the gene products apparently being correctly processed and modified in the absence of the RVFV L and S genomic segments. The proteins encoded by the RVFV M segment included, in addition to the viral glycoproteins G2 and G1, two previously uncharacterized polypeptides of 78 and 14 kilodaltons (kDa). By manipulation of RVFV sequences present in the recombinant vaccinia viruses and use of specific antibody reagents, it was found that the 78-kDa protein initiated at the first initiation codon of the open reading frame and encompassed the entire preglycoprotein and glycoprotein G2 coding sequences. The 14-kDa protein appeared to begin from the second in-phase ATG and was composed of only the preglycoprotein sequences. Both viral glycoproteins G2 and G1 could be synthesized and correctly processed in the absence of the 78- and 14-kDa proteins, as well as a large portion of the preglycoprotein sequences. However, the hydrophobic amino acid sequence immediately preceding the mature glycoprotein coding sequences was required for authentic glycoprotein production. The M-segment expression strategy involving aspects of translational initiation and protein processing are discussed. The functional roles of the 78- and 14-kDa proteins remain unclear.

Viral RNA polymerases

Recent progress in molecular biological techniques revealed that genomes of animal viruses are complex in structure, for example, with respect to the chemical nature (DNA or RNA), strandedness (double or single), genetic sense (positive or negative), circularity (circle or linear), and so on. In agreement with this complexity in the genome structure, the modes of transcription and replication are various among virus families. The purpose of this article is to review and bring up to date the literature on viral RNA polymerases involved in transcription of animal DNA viruses and in both transcription and replication of RNA viruses. This review shows that the viral RNA polymerases are complex in both structure and function, being composed of multiple subunits and carrying multiple functions. The functions exposed seem to be controlled through structural interconversion.

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.

The S segment of the Germiston virus RNA genome can code for three proteins

The complete sequence of the S segment of Germiston bunyavirus has been determined from plasmids containing S cDNA inserts. The S segment is 980 nucleotides long with the first 15 bases at the 3' end complementary to the first 15 bases at the 5' end. Three overlapping open reading frames (ORF) were identified in the viral complementary RNA strand. The first ORF codes for a polypeptide of 233 amino acids (Mr 26,600) which is the nucleoprotein N. The second ORF codes for a polypeptide of 109 amino acids (Mr 11,800) which corresponds to the NSS protein, also called p12. Following this ORF, in the same frame, a third ORF which could encode a polypeptide of 75 amino acids was identified. Such a polypeptide has not yet been detected in infected cells. The N and NSS proteins of Germiston virus were compared with the corresponding proteins of La Crosse, snowshoe hare, and Aino viruses, and show a high extent of homology.

Hantaan virus M RNA: coding strategy, nucleotide sequence, and gene order

The M genome segment of Hantaan virus was molecularly cloned and the nucleotide sequence of cDNA was determined. The virion RNA is 3616 bases long with 3'- and 5'-terminal nucleotide sequences complementary for 18 bases. A single long open reading frame in the viral complementary-sense RNA had the potential to encode 1135 amino acids or a polypeptide of 126,000 Da. Amino-terminal sequences of isolated G1 and G2 envelope glycoproteins were determined, revealing a gene order with respect to message sense RNA of 5'-G1-G2-3'. Mature G1 begins 18 amino acids beyond the first AUG of the open reading frame, preceded by a short, hydrophobic leader sequence. G2 begins at the 649th amino acid of the open reading frame and also follows a hydrophobic sequence. Carboxy termini of G1 and G2 were localized and gene order was verified by immune precipitation of Hantaan proteins with antisera to synthetic peptides generated by using amino acid sequences derived from the cDNA sequence. The antipeptide sera were also reactive by immunoblotting with SDS-denatured G1 and G2. Molecular weights of 64,000 and 53,700 were calculated for the G1 and G2 glycoproteins, respectively, from their predicted amino acid sequences. Five potential asparagine-linked glycosylation sites were contained within the G1 amino acid sequence and two within the G2 sequence. These data are consistent with our previous estimates of the molecular weights and extent of glycosylation of the Hantaan envelope glycoproteins.

Interferon induction by transfection of Sendai virus C gene cDNA

To elucidate the mechanism of interferon (IFN) induction on virus infection, we constructed two types of plasmids by inserting a part of the cDNA of the Sendai virus into a simian virus 40-derived expression vector (pSV2-0). One, pSV2-PC, contained the P + C gene, which codes for the P and C proteins in overlapping reading frames, and the other, pSV2-C, contained only the C gene. After transfecting the plasmids into mammalian cells, we determined the IFN activity in the culture medium. We found that the level obtained with pSV2-PC was significantly positive but very low, whereas that obtained with pSV2-C was as high as or even higher than that observed in the culture medium after Sendai virus infection. By cleaving pSV2-C between the simian virus 40 promotor and the C gene or by inserting a stop codon within the C gene [pSV2-C(stop)], induction of IFN was greatly diminished. In Northern blot analyses of the transcripts obtained from the cells transfected with the plasmids with cDNA to the P + C gene as a probe, the transcript having the expected size was detected with both pSV2-C and pSV2-C(stop), whereas none was detected with cleaved pSV2-C or pSV2-0. The results indicate that both transcription and translation of the C gene seem to be required for IFN induction after Sendai virus infection.

Translational requirement of La Crosse virus S-mRNA synthesis: in vivo studies

By using methods to isolate cytoplasmic RNAs which limit degradation, the effect of drugs which inhibit protein synthesis on the accumulation of La Crosse virus plus-strand S RNAs in vivo has been studied. Cycloheximide and puromycin treatment of infected cultures caused an abortive transcript of ca. 205 nucleotides (nt) to accumulate, whereas pactamycin led to the appearance of an RNA which was slightly shorter (ca. 200 nt). Both the 205- and 200-nt RNAs contained the same range of host primers at their 5' end, but their 3' ends mapped at ca. positions 175 and 165, respectively. Examination of the sequence in this region and at the mature mRNA termination site (position 886) suggests that the sequence YAAAAAT(A)GCAG is involved in transcription termination.

Coding strategy of the S genome segment of Hantaan virus

Hantaan virus is the type species of the recently recognized Hantavirus genus of Bunyaviridae. The small (S) RNA segment of the negative-sense, tripartite genome was molecularly cloned and the nucleotide sequence was determined. The RNA sequence derived from the cDNA copy was found to contain 1696 nucleotides. A single open reading frame of sufficient size to encode the virus nucleocapsid protein was detected in the cDNA corresponding to viral complementary-sense RNA. RNA transcripts of the cDNA were synthesized with SP6 polymerase and were used to program cell-free reticulocyte lysate translation systems. Viral complementary-sense transcripts served as efficient messages in translation systems and generated Hantaan nucleocapsid protein. No translation products were detected when lysates were programmed with viral-sense transcripts. This coding assignment of the nucleocapsid protein to the viral complementary-sense RNA of the S genome segment is consistent with those of other members of this family. Unlike other Bunyaviridae, which encode both a nucleocapsid protein and a nonstructural (NSs) protein of similar sizes, a NSs protein has not been identified for Hantaan virus. Furthermore, other than the nucleocapsid protein gene sequence, the only potential open reading frame in Hantaan S RNA encoded a short, 48-amino acid polypeptide which initiated two codons beyond the termination of the nucleocapsid protein in the same reading frame. These data demonstrate that the coding strategy of the Hantaan virus S RNA is different than those reported for other viruses in this family.

Messenger RNA encoding the phosphoprotein (P) gene of human parainfluenza virus 3 is bicistronic

The complete nucleotide sequence of the phosphoprotein (P) mRNA of human parainfluenza virus 3 (PIV-3) was derived from two cDNA clones spanning almost the entire P gene. The mRNA, excluding the poly(A) tail, is 2014 nucleotides long and is bicistronic. The first open reading frame (ORF) codes for the phosphoprotein (P) of mol wt 68,860. Seven nucleotides downstream from the first AUG codon, in a +1 reading frame, there is an additional ORF which can code for a polypeptide of mol wt 23,266. The latter protein appears to be similar to the C proteins found in cells infected with several paramyxoviruses. Comparison of the predicted amino acid sequence of the P and C proteins of PIV-3 with the corresponding Sendai virus proteins reveals considerable homology at the C-terminal half. In contrast, the P and C proteins of PIV-3 share very little homology with the measles virus P and C proteins, respectively.

Messenger RNA of the M segment RNA of Rift Valley fever virus

The putative messenger RNA (mRNA) of the M segment RNA of the phlebovirus Rift Valley fever virus (RVFV) has been characterized using S1 nuclease mapping and oligonucleotide primer extension procedures. These experiments revealed that the 3' end of the mRNA lacks approximately 112 nucleotides of the M genomic RNA sequences, and that the 5' end of the mRNA possesses all of the sequences present at the 3' end of the M RNA but is further extended beyond the end of the genome by some 12-14 nucleotides of unknown origin. The implications of these data are discussed in relation to the replication and expression strategy of this virus.

Nucleotide sequence of the Bunyamwera virus M RNA segment: conservation of structural features in the Bunyavirus glycoprotein gene product

The complete nucleotide sequence of the Bunyamwera virus M RNA segment was determined from four overlapping cDNA clones and by primer extension. The RNA segment is 4458 bases in length, and encodes a single gene product in the viral complementary RNA. The predicted protein is 1433 amino acids long (mol wt 162,065), contains four potential glycosylation sites, and is relatively cysteine rich. It is presumed that the three proteins G1, G2, and NSM which have been mapped to the M RNA segment are synthesized as a precursor polyprotein which is subsequently proteolytically cleaved. A putative hydrophobic signal sequence at the amino terminus and a hydrophobic anchor sequence at the carboxy terminus of the predicted protein have been identified, in addition to internal regions of hydrophobicity of unknown function. The nucleotide and amino acid sequences of the Bunyamwera virus M segment have been compared with those of the snowshoe hare virus M segment (Y. Eshita and D. H. L. Bishop, Virology 137, 227-240, 1984). Common features include the overall architecture of the RNAs, single cysteine-rich primary gene products, and conservation of hydrophobic domains in the gene products. When aligned the amino acid sequences are 43% homologous, and 66 of 70 cysteine residues can be matched. The evolutionary significance of these findings is discussed.

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 nucleotide sequence of the M RNA segment of Rift Valley fever virus

The entire M RNA segment of the phlebovirus Rift Valley fever virus (RVFV) has been molecularly cloned and the complete nucleotide sequence determined. The RNA is 3884 nucleotides in length, corresponding to a molecular weight of 1.38 X 10(6), having a base composition of 27.3% A, 25.4% G, 27.2% U, and 20.1% C. Sequences present at the 3' and 5' termini of the molecule are largely complementary for some 51 residues and can form a stable duplex structure when the potential secondary structure of the entire molecule is considered. A single major open reading frame, capable of encoding 1206 amino acids (131,845 Da), was found in the viral-complementary sequence ("positive" polarity). Amino-terminal amino acid sequencing of the purified viral glycoproteins G1 and G2 allowed for the positioning of the coding sequences for these polypeptides within this major open reading frame in the following orientation with respect to the genomic M RNA: 3'-G2-G1-5'. From the predicted amino acid composition of the two mature viral glycoproteins, both were found to have a high cysteine content (G2, 6%; G1, 5%). Sequences within the open reading frame capable of encoding up to 23,000 Da of polypeptide were found in addition to those required for the viral glycoproteins. The potential contribution of these sequences to the coding capacity of the M RNA, viral protein processing, and intracellular protein distribution is discussed.

Identification of nonstructural proteins encoded by viruses of the Bunyamwera serogroup (family Bunyaviridae)

The proteins synthesized in BHK cells infected with nine members of the Bunyamwera serogroup (family Bunyaviridae, Bunyavirus genus) were analyzed by polyacrylamide gel electrophoresis. In addition to the virus structural proteins, a number of virus-coded nonstructural proteins were detected. One protein, designated NS1, was shown to be related to the nucleocapsid protein by one-dimensional peptide mapping. A second protein, NS2, was mapped to the M RNA segment by gel electrophoretic analysis of the proteins synthesized in cells infected with reassortants of Batai, Bunyamwera, and Maguari viruses of known genotype. A third protein, NS3, was mapped to the S RNA segment by its pattern of labeling with [35S]cysteine in cells infected with reassortant viruses: the NS3 protein was only labeled when the S RNA segment of Bunyamwera virus was present. The mapping of NS3 was confirmed by in vitro translation of mRNAs which hybridized to recombinant plasmids containing S gene-specific sequences.

Measles virus P gene codes for two proteins

The entirety of the phosphoprotein gene of measles virus has been sequenced. The gene is composed of 1,657 nucleotides and specifies a 507-amino-acid protein (P). A second overlapping reading frame was predicted from the sequence and specifies a 186-amino-acid protein (C). Through the use of antisynthetic peptide antibodies, we show that both proteins are expressed in virally infected cells. Both proteins are expressed from a functionally bicistronic mRNA through independent initiation of ribosomes at the respective AUG codons. Using immunofluorescent microscopy, we localized the C protein in the nucleus and in cytoplasmic inclusions within the infected cells.

Sequence analysis of the respiratory syncytial virus phosphoprotein gene

A recombinant cDNA plasmid (pRSA3) containing an almost full-length copy of the mRNA encoding respiratory syncytial virus phosphoprotein was identified in a cDNA library prepared with mRNA from respiratory syncytial virus-infected cells. The cDNA insert was sequenced, and a protein of 27,150 daltons was deduced from the DNA sequence. The protein is relatively acidic, containing two clusters of acidic amino acids, one in the middle of the molecule and the other at the C-terminus. It is devoid of both cysteine and tryptophan. There was no other potential reading frame within the phosphoprotein gene of respiratory syncytial virus. This situation is unlike that with Sendai virus, a paramyxovirus, which has a nonstructural C protein encoded by a second overlapping reading frame near the 5' end of the mRNA for phosphoprotein.

La Crosse virions contain a primer-stimulated RNA polymerase and a methylated cap-dependent endonuclease

Purified La Crosse virions in vitro were found to transcribe their negative polarity (-)RNA genomes. This polymerase activity was stimulated by oligonucleotides such as (A)nG, cap analogs such as m7GpppAm, and natural mRNAs such as alfalfa mosaic virus RNA 4. For (A)nG- and alfalfa mosaic virus RNA 4-stimulated reactions, evidence is presented that these RNAs stimulate activity by acting as primers for viral transcription. The cap analogs appear to stimulate activity via an alternative mechanism. Purified La Crosse virions were also found to contain an endonuclease which specifically cleaves alfalfa mosaic virus RNA 4 when this RNA contains a methylated cap group.

Genome subunit reassortment among Bunyaviruses analysed by dot hybridization using molecularly cloned complementary DNA probes

A simple and rapid procedure for determining the genotypes of viruses has been applied to analysis of genome subunit reassortment in heterologous crosses of Batai virus, Bunyamwera virus, and Maguari virus, three members of the Bunyamwera serogroup of bunyaviruses. The procedure for determining genotype made use of specific molecular probes to identify the parental origin of the L and M RNA subunits. Complementary DNA copies of the three RNA segments of Bunyamwera virus were prepared by reverse transcription using synthetic oligonucleotide primers for first and second strand synthesis. The cDNA transcripts were inserted into a pBR322 vector and gene-specific probes prepared from nick-translated plasmid DNA. L and M gene-specific probes were identified which could unequivocally discriminate Bunyamwera virus genome subunits in a dot-hybridization test using cytoplasmic RNA extracts immobilised on nitrocellulose filters. None of the S gene-specific probes were sufficiently discriminatory for use in this test. Instead the parental origin of the S RNA subunit was inferred from the electrophoretic mobility of the virion N protein. It was observed that reassortment did not occur at random in heterologous crosses of is mutants of the three viruses, and only the M RNA subunit appeared to segregate freely. However, unrestricted reassortment was observed when recombinant viruses with nonhomologous subunit combinations were used as the parental viruses. It was concluded, therefore, that restriction was mediated at the gene product level and that nonrandom reassortment was not due to incompatibility of genome subunits.

Characterization of La Crosse virus small-genome transcripts

With restriction fragments from DNA clones of the La Crosse virus S genome segment, the 3' end of the S mRNA was located by S1 nuclease mapping near a polyuridine tract, approximately 100 nucleotides, from the end of the S genome. Genome replication in La Crosse virus-infected cells was abolished by the drug cycloheximide, similar to other negative-strand RNA viruses. However, the synthesis of S mRNA could not be detected in cells pretreated with cycloheximide, suggesting that ongoing protein synthesis is required for La Crosse virus genome transcription and replication. Primer extension experiments in the presence of chain-terminating nucleoside triphosphates demonstrated that the 5' end of the La Crosse virus S mRNA begins 10 to 14 nucleotides before the 3' end of the S genome segment, suggesting that the La Crosse virus S mRNA is initiated on a host primer. A hypothesis consistent with these unexpected findings is presented.

Sendai virus contains overlapping genes expressed from a single mRNA

The mRNA coding for the Sendai virus P and C proteins was located on the viral genome using cloned DNA and the relevant regions of the DNA were sequenced. The nucleotide sequence revealed two overlapping open reading frames that could code for proteins of 568 and 204 amino acids. Primer extension and S1 nuclease mapping studies detected only a single 1.894 kb mRNA from this region. Hybrid arrest of translation studies using restriction fragments verified the overlapping nature of these genes. Sequence homologies at the beginning of three Sendai virus cistrons suggest that these genes may have arisen by duplication from a common ancestor, possibly an influenza-like virus gene.