[Complete genome analysis of the Batai virus (BATV) and the new Anadyr virus (ANADV) of the Bunyamwera group (Bunyaviridae, Orthobunyavirus) isolated in Russia]

Almost complete nucleotide sequences for the S, M, and L segments were obtained for three strains of the Batai virus (Bunyamwera serogroup, genus Orthobunyavirus, Bunyaviridae family). Based on the results of the phylogenetic analysis conducted forthe three genomic segments LEIV Ast507 and LEIV-Ast528 strains were grouped with other European BATV isolates and were found to be almost identical to the strain 42 isolated from Volgograd Region, Russia, 2003. Surprisingly, LEIV-13395 strain isolated from the Aedes sp. mosquitos in Magadan Oblast, 1987, turned out to be a novel genotype inside Bunyamwera serogroup. The highest nucleotide identity levels of LEIV-13395 genomicsegments (86.9%, 80.8%, 79.7% for S, M and L segments respectively) were observed with corresponding segments of the Batai virus.

Orthobunyavirus ultrastructure and the curious tripodal glycoprotein spike

The genus Orthobunyavirus within the family Bunyaviridae constitutes an expanding group of emerging viruses, which threaten human and animal health. Despite the medical importance, little is known about orthobunyavirus structure, a prerequisite for understanding virus assembly and entry. Here, using electron cryo-tomography, we report the ultrastructure of Bunyamwera virus, the prototypic member of this genus. Whilst Bunyamwera virions are pleomorphic in shape, they display a locally ordered lattice of glycoprotein spikes. Each spike protrudes 18 nm from the viral membrane and becomes disordered upon introduction to an acidic environment. Using sub-tomogram averaging, we derived a three-dimensional model of the trimeric pre-fusion glycoprotein spike to 3-nm resolution. The glycoprotein spike consists mainly of the putative class-II fusion glycoprotein and exhibits a unique tripod-like arrangement. Protein–protein contacts between neighbouring spikes occur at membrane-proximal regions and intra-spike contacts at membrane-distal regions. This trimeric assembly deviates from previously observed fusion glycoprotein arrangements, suggesting a greater than anticipated repertoire of viral fusion glycoprotein oligomerization. Our study provides evidence of a pH-dependent conformational change that occurs during orthobunyaviral entry into host cells and a blueprint for the structure of this group of emerging pathogens.

Orthobunyaviruses comprise a group of emerging arboviruses within the Bunyaviridae, the largest family of membrane-containing viruses. In spite of the continued medical impact upon human and animal health, little is known about orthobunyavirus structure or the process of host cell entry. Here, we address this paucity of information through electron cryo-microscopy analysis of Bunyamwera virus, the prototypic representative of this genus. We reveal that Bunyamwera virions are pleomorphic and display locally-ordered lattices of viral glycoprotein spikes on the envelope surface. The three-dimensional structure of the glycoprotein spike was resolved to 3.0-nm resolution. The spike is composed of the attachment and fusion glycoproteins and comprises a unique tripodal organization. This glycoprotein arrangement contrasts those observed in other virus families. Consistent with the established pH-dependent mechanism of membrane fusion during host cell entry, we provide evidence for the disruption of this tripodal assembly upon exposure to acidic environments. These data constitute a blueprint for orthobunyavirus architecture and support a case for broadened structural diversity within the Bunyaviridae family.

The transient nature of Bunyamwera orthobunyavirus NSs protein expression: effects of increased stability of NSs protein on virus replication

The NSs proteins of bunyaviruses are the viral interferon antagonists, counteracting the host's antiviral response to infection. During high-multiplicity infection of cultured mammalian cells with Bunyamwera orthobunyavirus (BUNV), NSs is rapidly degraded after reaching peak levels of expression at 12hpi. Through the use of inhibitors this was shown to be the result of proteasomal degradation. A recombinant virus (rBUN4KR), in which all four lysine residues in NSs were replaced by arginine residues, expresses an NSs protein (NSs4KR) that is resistant to degradation, confirming that degradation is lysine-dependent. However, despite repeated attempts, no direct ubiquitylation of NSs in infected cells could be demonstrated. This suggests that degradation of NSs, although lysine-dependent, may be achieved through an indirect mechanism. Infection of cultured mammalian cells or mice indicated no disadvantage for the virus in having a non-degradable NSs protein: in fact rBUN4KR had a slight growth advantage over wtBUNV in interferon-competent cells, presumably due to the increased and prolonged presence of NSs. In cultured mosquito cells there was no difference in growth between wild-type BUNV and rBUN4KR, but surprisingly NSs4KR was not stabilised compared to the wild-type NSs protein.

Investigating the specificity and stoichiometry of RNA binding by the nucleocapsid protein of Bunyamwera virus

Bunyamwera virus (BUNV) is the prototypic member of both the Orthobunyavirus genus and the Bunyaviridae family of negative stranded RNA viruses. In common with all negative stranded RNA viruses, the BUNV genomic and anti-genomic strands are not naked RNAs, but instead are encapsidated along their entire lengths with the virus-encoded nucleocapsid (N) protein to form a ribonucleoprotein (RNP) complex. This association is critical for the negative strand RNA virus life cycle because only RNPs are active for productive RNA synthesis and RNA packaging. We are interested in understanding the molecular details of how N and RNA components associate within the bunyavirus RNP, and what governs the apparently selective encapsidation of viral replication products. Toward this goal, we recently devised a protocol that allowed generation of native BUNV N protein that maintained solubility under physiological conditions and allowed formation of crystals that yielded high-resolution x-ray diffraction data. Here we extend this work to show that this soluble N protein is able to oligomerize and bind RNA to form a highly uniform RNP complex, which exhibits characteristics in common with the viral RNP. By extracting and sequencing RNAs bound to these model RNPs, we determined the stoichiometry of N-RNA association to be approximately 12 nucleotides per N monomer. In addition, we defined the minimal sequence requirement for BUNV RNA replication. By comparing this minimal sequence to those bound to our model RNP, we conclude that N protein does not obligatorily require a sequence or structure for RNA encapsidation.

Role of the cytoplasmic tail domains of Bunyamwera orthobunyavirus glycoproteins Gn and Gc in virus assembly and morphogenesis

The M RNA genome segment of Bunyamwera virus (BUNV), the prototype of the Bunyaviridae family, encodes a precursor polyprotein that is proteolytically cleaved to yield two structural proteins, Gn and Gc, and a nonstructural protein called NSm. Gn and Gc are type I integral transmembrane glycoproteins. The Gn protein contains a predicted cytoplasmic tail (CT) of 78 residues, and Gc has a shorter CT of 25 residues. Little is known about the role of the Gn and Gc CT domains in the virus replication cycle. We generated a series of mutant glycoprotein precursor constructs containing either deletions or alanine substitutions in the CT domains of Gn and Gc. We examined the effects of these mutations on glycoprotein maturation, cell surface expression, and low pH-induced syncytium formation. In addition, the effects of these mutations were also assessed using a reverse genetics-based virus assembly assay and a virus rescue system. Our results show that the CT domains of both Gn and Gc play crucial roles in BUNV-mediated membrane fusion, virus assembly, and morphogenesis.

Effects of a point mutation in the 3' end of the S genome segment of naturally occurring and engineered Bunyamwera viruses

The genome of Bunyamwera virus (BUN) consists of three segments of single-stranded RNA of negative polarity. The smallest segment, S, encodes the N protein and a nonstructural protein called NSs. We recently described a mutant virus (BUNdelNSs) that does not express NSs but overexpresses N and grows to lower titres than wild-type (wt) BUN. Here we report a BUNdelNSs variant that expresses lower levels of N protein and grows to higher titres. Sequencing of the 3' and 5' termini of the BUNdelNSs S RNA segment and analysis using a minireplicon system show that the N overexpressing phenotype results from a single nucleotide substitution at position 16 in the 3' terminus. This mutation could also be detected in wtBUN populations, and was isolated by plaquing a 'wt' variant carrying the mutation. This variant was found to express increased N and NSs levels, and grew to lower titres than wtBUN.

RNA binding properties of bunyamwera virus nucleocapsid protein and selective binding to an element in the 5' terminus of the negative-sense S segment

The genome of Bunyamwera virus (BUN) (family Bunyaviridae, genus Bunyavirus) comprises three negative-sense RNA segments which act as transcriptional templates for the viral polymerase only when encapsidated by the nucleocapsid protein (N). Previous studies have suggested that the encapsidation signal may reside within the 5' terminus of each segment. The BUN N protein was expressed as a 6-histidine-tagged fusion protein in Escherichia coli and purified by metal chelate chromatography. An RNA probe containing the 5'-terminal 32 and 3'-terminal 33 bases of the BUN S (small) genome segment was used to investigate binding by the N protein in vitro using gel mobility shift and filter binding assays. On acrylamide gels a number of discrete RNA-N complexes were resolved, and analysis of filter binding data indicated a degree of cooperativity in N protein binding. RNA-N complexes were resistant to digestion with up to 1 microg of RNase A per ml. Competition assays with a variety of viral and nonviral RNAs identified a region within the 5' terminus of the BUN S segment for which N had a high preference for binding. This site may constitute the signal for initiation of encapsidation by N.

Rescue of a segmented negative-strand RNA virus entirely from cloned complementary DNAs

We provide the first report, to our knowledge, of a helper-independent system for rescuing a segmented, negative-strand RNA genome virus entirely from cloned cDNAs. Plasmids were constructed containing full-length cDNA copies of the three Bunyamwera bunyavirus RNA genome segments flanked by bacteriophage T7 promoter and hepatitis delta virus ribozyme sequences. When cells expressing both bacteriophage T7 RNA polymerase and recombinant Bunyamwera bunyavirus proteins were transfected with these plasmids, full-length antigenome RNAs were transcribed intracellularly, and these in turn were replicated and packaged into infectious bunyavirus particles. The resulting progeny virus contained specific genetic tags characteristic of the parental cDNA clones. Reassortant viruses containing two genome segments of Bunyamwera bunyavirus and one segment of Maguari bunyavirus were also produced following transfection of appropriate plasmids. This accomplishment will allow the full application of recombinant DNA technology to manipulate the bunyavirus genome.

Localization of Bunyamwera bunyavirus G1 glycoprotein to the Golgi requires association with G2 but not with NSm

The Bunyamwera bunyavirus (BUN) M RNA genome segment encodes three proteins, two glycoproteins termed G1 and G2 and a non-structural protein called NSm, in the form of a polyprotein precursor that is co-translationally cleaved to give the mature proteins. Indirect immunofluorescence experiments have shown that these proteins localize to the Golgi complex in BUN-infected cells. We have used a recombinant vaccinia virus (vTF7-3), which expresses bacteriophage T7 RNA polymerase, to drive the expression of plasmids containing either the entire BUN M segment cDNA or fragments that encode the G1, G2 and NSm proteins separately under control of the T7 promoter. After transfection of these plasmids into vTF7-3-infected cells, correctly sized and processed proteins were detected by immunoprecipitation with BUN-specific antibodies. Immunofluorescence experiments showed that G1, G2 and NSm localized to the Golgi when transiently expressed from the full-length cDNA. When G2 or NSm were expressed separately they also localized to the Golgi, but when G1 was expressed alone a staining pattern typical for the endoplasmic reticulum was obtained. However coexpression of G2 and G1 from independent plasmids resulted in G1 localizing to the Golgi. In contrast translocation of G1 to the Golgi was not observed when G1 was coexpressed with NSm, although NSm itself was still detected in the Golgi. Similar results were obtained when the proteins were expressed from transfected plasmids containing the G2-, NSm- or G1-coding sequences under control of the cytomegalovirus immediate-early promoter. The localization of G1 to the Golgi when coexpressed with G2 was confirmed by the loss of endoglycosidase H (endo H) sensitivity of G1 after approximately 60 min in a pulse-chase experiment; G1 remained sensitive to endo H when expressed either alone or in combination with NSm. These results suggest that G2 contains the Golgi targeting and/or retention signals and that G1 has to interact with this protein to localize to this cellular compartment.

Expression of functional Bunyamwera virus L protein by recombinant vaccinia viruses

A cDNA containing the complete coding sequence of the Bunyamwera virus (family Bunyaviridae) L genome segment has been constructed and cloned into two recombinant vaccinia virus expression systems. In the first, the L gene is under control of vaccinia virus P7.5 promoter; in the second, the L gene is under control of the bacteriophage T7 phi 10 promoter, and expression of the L gene requires coinfection with a second recombinant vaccinia virus which synthesizes T7 RNA polymerase. Both systems express a protein which is the same size as the Bunyamwera virus L protein and is recognized by a monospecific L antiserum. The expressed L protein was shown to be functional in synthesizing Bunyamwera virus RNA in a nucleocapsid transfection assay: recombinant vaccinia virus-infected cells were transfected with purified Bunyamwera virus nucleocapsids, and subsequently, total cellular RNA was analyzed by Northern (RNA) blotting. No Bunyamwera virus RNA was detected in control transfections, but in cells which had previously been infected with recombinant vaccinia viruses expressing the L protein, both positive- and negative-sense Bunyamwera virus S segment RNA was detected. The suitability of this system to delineate functional domains within the Bunyamwera virus L protein is discussed.

Identification of four complementary RNA species in Akabane virus-infected cells

The analysis of RNA extracted from purified Akabane virus demonstrated the presence of three size classes of single-stranded RNAs with sedimentation coefficients of 31S (large, L), 26S (medium, M), and 13S (small, S). Molecular weights of these RNA species were estimated to be 2.15 X 10(6), 1.5 X 10(6), and 0.48 X 10(6) for the L, M, and S RNAs, respectively. Hybridization analysis involving viral genomic RNA and RNA from virus-infected cells resulted in the identification of four virus-specific cRNA species in infected cells. These cRNAs were found to be nonpolyadenylated by their inability to bind to oligodeoxythymidylate-cellulose. Kinetic analysis of cRNA synthesis in infected cells at various times postinfection suggested that cRNA synthesis could be detected as early as 2 h postinfection and that maximal synthesis occurred at 4 to 6 h postinfection. The RNAs synthesized in infected cells could be partially resolved by sucrose density gradient centrifugation. The RNA fraction that cosedimented with the S segment of viral genomic RNA yielded two duplex RNA species when hybridized with viral genomic RNA, suggesting the presence of two small cRNA species. Specific hybridization with individual viral genomic RNAs confirmed that two species of cRNA are coded by the S RNA segment. Analysis of cRNA synthesis in the presence of the protein synthesis inhibitors cycloheximide and puromycin indicated that cycloheximide completely inhibited virus-specific RNA synthesis early and late in infection, whereas a very low level of synthesis occurred in the presence of puromycin. The inhibitory effects of these drugs were found to be reversible when the drugs were washed from the cells. It is concluded that continued protein synthesis is required for cRNA synthesis to proceed in Akabane virus-infected cells.

Bunyamwera virus replication in cultured Aedes albopictus (mosquito) cells: establishment of a persistent viral infection

Bunyamwera virus replication was examined in Aedes albopictus (mosquito) cell cultures in which a persistent infection is established and in cytopathically infected BHK cells. During primary infection of A. albopictus cells, Bunyamwera virus reached relatively high titers ( approximately 10(7) PFU/ml), and autointerference was not observed. Three virus-specific RNAs (L, M, and S) and two virion proteins (N and G1) were detected in infected cells. Maximum rates of viral RNA synthesis and viral protein synthesis were extremely low, corresponding to <2% of the synthetic capacities of uninfected control cells. Viral protein synthesis was maximal at 12 h postinfection and was shut down to barely detectable levels at 24 h postinfection. Virus-specific RNA and nucleocapsid syntheses showed similar patterns of change, but later in infection. The proportions of cells able to release a single PFU at 3, 6, and 54 days postinfection were 100, 50, and 1.5%, respectively. Titers fell to 10(3) to 10(5) PFU/ml in carrier cultures. Persistently infected cultures were resistant to superinfection with homologous virus but not with heterologous virus. No changes in host cell protein synthesis or other cytopathic effects were observed at any stage of infection. Small-plaque variants of Bunyamwera virus appeared at approximately 7 days postinfection and increased gradually until they were 75 to 95% of the total infectious virus at 66 days postinfection. Temperature-sensitive mutants appeared between 23 and 49 days postinfection. No antiviral activity similar to that reported in A. albopictus cell cultures persistently infected with Sindbis virus (R. Riedel and D. T. Brown, J. Virol. 29: 51-60, 1979) was detected in culture fluids by 3 months after infection. Bunyamwera virus replicated more rapidly in BHK cells than in mosquito cells but reached lower titers. Autointerference occurred at multiplicities of infection of approximately 10. Virus-specific RNA and protein syntheses were at least 20% of the levels in uninfected control cells. Host cell protein synthesis was completely shut down, and nucleocapsid protein accumulated until it was 4% of the total cell protein. We discuss these results in relation to possible mechanisms involved in determining the outcome of arbovirus infection of vertebrate and mosquito cells.

Genome complexities of the three mRNA species of snowshoe hare bunyavirus and in vitro translation of S mRNA to viral N polypeptide

The genome complexities of the principal intracellular viral complementary RNA species of the snowshoe hare bunyavirus have been analyzed by duplex analyses involving hybridization of complementary RNA to individual 32P-labeled viral RNA species (large, L; medium, M; and small, S), recovery of nuclease-resistant duplexes, and determination of the oligonucleotide fingerprints of the protected 32P-labeled viral sequences. The result for the M RNA (which codes for the glycoproteins G1 and G2; J. R. Gentsch and D. H. L. Bishop, J. Virol. 30:767-770, 1979) indicates that there is a single polycistronic M mRNA. Similar results were obtained for the L and S RNA species. In vitro translation studies with the S complementary RNA species of snowshoe hare virus as well as melted purified S duplexes substantiate earlier genetic and molecular studies (J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978; J. Gentsch, D. H. L. Bishop, and J. F. Obijeski, J. Gen. Virol. 34-257-268, 1977), which indicate that S mRNA codes for the virion nucleocapsid protein N.

In vivo transcription and protein synthesis capabilities of bunyaviruses: wild-type snowshoe hare virus and its temperature-sensitive group I, group II, and group I/II mutants

The in vivo primary and secondary transcription capabilities of wild-type snowshoe hare (SSH) virus and certain of its temperature-sensitive (ts) mutants have been analyzed. The results obtained agree with in vitro studies (Bouloy et al., C.R. Acad. Sci. Paris 280:213-215, 1975; M. Bouloy and C. Hannoun, Virology 69:258-264, 1976; M. Ranki and R. Pettersson, J. Virol. 16:1420-1425, 1975) which have shown that bunyaviruses are negative-stranded RNA viruses with a virion RNA-directed RNA polymerase. The in vivo transcription studies have demonstrated that in the presence of protein synthesis inhibitors (puromycin or cycloheximide) SSH virus can synthesize viral complementary RNA (primary transcription) throughout the infection cycle. The increased levels of viral complementary RNA obtained in the absence of protein synthesis inhibitors (secondary transcription) were not markedly reduced if cells were pretreated with actinomycin D (5 mug/ml), alpha-amanitin (25 mug/ml), or rifampin (100 mug/ml), although progeny virus yields were reduced by up to 80% in the actinomycin D- and rifampin-treated cells. The in vivo transcription capabilities of SSH group I ts mutants at temperatures which were nonpermissive (40 degrees C) for virus replication gave values comparable to those obtained at permissive temperatures (33 degrees C). The SSH group I mutants appear, therefore, to be RNA-positive mutant types. When compared with their transcription capabilities at 33 degrees C, the in vivo transcription abilities of four SSH group II ts mutants (and one double group I/II ts mutant) were found to be more impaired at 40 degrees C than those of the SSH group I ts mutants or wild-type SSH virus at 40 degrees C, although the viral complementary RNA synthetic capabilities of these group II (and group I/II) mutants at 40 degrees C were significantly higher than their primary transcription capabilities (as measured at 33 degrees C in the presence of puromycin or cycloheximide). It was concluded, therefore, that these SSH group II (and double group I/II) ts mutants have an intermediate RNA phenotype. Hybridization studies using (32)P-labeled individual L, M, and S viral RNA species of SSH virus have demonstrated the presence of viral complementary RNA to all three species in extracts of cells infected with SSH ts II-30 and incubated at 33 degrees C (primary and secondary transcription) or 40 degrees C, a nonpermissive temperature for its replication. The results of pulse-labeled in vivo protein analyses indicated that greater quantities of intracellular N protein (coded for by S RNA [J. R. Gentsch and D. H. L. Bishop, J. Virol. 28:417-419, 1978]) than G1 and G2 polypeptides (coded for by M RNA [J. R. Gentsch and D. H. L. Bishop, J. Virol. 30:767-776, 1979]) were present in extracts of cells infected with wild-type SSH virus. In extracts of SSH group I, II, or I/II ts mutant-infected cells incubated at 33 degrees C, N and G1, and for the group II mutant-infected cells, G2, viral polypeptides were detected, whereas in extracts obtained from group I or II mutant virus-infected cells incubated at 40 degrees C, low levels of N and G1 polypeptides were evident.

Protein synthesis in Bunyamwera virus-infected cells

In Vero cells infected with Bunyamwera virus there is a rapid inhibition of cell RNA and protein synthesis to levels of 30 and 3% respectively of the control rate, both the rate of inhibition and the time lag before its initiation being multiplicity dependent. Using u.v.-irradiated virus, investigation of the mechanism of inhibition of host cell protein synthesis indicates that synthesis of new virus components is required for inhibition to occur. Quantitative comparison of the proteins synthesized in infected cells shows that at higher m.o.i. synthesis of virus, as well as cellular proteins, is inhibited. Bunyamwera virus-infected Vero cells synthesized three virus-specific proteins identified as the structural virion proteins. Nucleoprotein is synthesized predominantly early in infection while the major envelope glycoprotein and the minor glycoprotein are synthesized predominantly late in the infection cycle.

M viral RNA segment of bunyaviruses codes for two glycoproteins, G1 and G2

Tryptic peptide digests of the two viral glycoproteins (G1 and G2) of snowshow hare (SSH) virus, La Crosse, La Crosse (LAC) virus, and an SSH/LAC recombinant virus which has a large (L)/medium (M)/small (S) RNA segment genome composition of SSH/LAC/SSH were analyzed by ion-exchange column chromatography. The analyses prove that the M RNA species of bunyaviruses codes for the two viral glycoproteins.

Bunyamwera virus-induced polypeptide synthesis

Bunyamwera virus-induced polypeptide synthesis in BSC-1 cell has been studied using polyacrylamide gel electrophoresis and autoradiography. Four virus-induced polypeptides were identified. Their molecular weights were 200 X 10(6) (L), 128 X 10(6) (G1), 31 X 10(6) (G2), and 23 X 10(6) (N). Pulse-chase experiments, short labeling experiments, and experiments using amino acid analogs failed to show evidence of polypeptides processing by proteolytic cleavage. Analysis of the kinetics of synthesis of these polypeptides showed that a clear division into early and late categories could be made, the onset of synthesis of polypeptide N and L rapidly reached a peak and then declined. Polypeptides G1 and G2 were made for several hours; their rate of synthesis then declined. All four polypeptides then continued to be made in relatively small amounts for many hours.