Sequences of the N and M genes of the sigma virus of Drosophila and evolutionary comparison

Sigma viruses from three species of Drosophila form a major new clade in the rhabdovirus phylogeny

The sigma virus (DMelSV), which is a natural pathogen of Drosophila melanogaster, is the only Drosophila-specific rhabdovirus that has been described. We have discovered two new rhabdoviruses, D. obscura and D. affinis, which we have named DObsSV and DAffSV, respectively. We sequenced the complete genomes of DObsSV and DMelSV, and the L gene from DAffSV. Combining these data with sequences from a wide range of other rhabdoviruses, we found that the three sigma viruses form a distinct clade which is a sister group to the Dimarhabdovirus supergroup, and the high levels of divergence between these viruses suggest that they deserve to be recognized as a new genus. Furthermore, our analysis produced the most robustly supported phylogeny of the Rhabdoviridae to date, allowing us to reconstruct the major transitions that have occurred during the evolution of the family. Our data suggest that the bias towards research into plants and vertebrates means that much of the diversity of rhabdoviruses has been missed, and rhabdoviruses may be common pathogens of insects.

Drosophila viruses and the study of antiviral host-defense

The fruit fly Drosophila melanogaster is a powerful model to study host-pathogen interactions. Most studies so far have focused on extracellular pathogens such as bacteria and fungi. More recently, viruses have come to the front, and RNA interference was shown to play a critical role in the control of viral infections in drosophila. We review here our current knowledge on drosophila viruses. A diverse set of RNA viruses belonging to several families (Rhabdoviridae, Dicistroviridae, Birnaviridae, Reoviridae, Errantiviridae) has been reported in D. melanogaster. By contrast, no DNA virus has been recovered up to now. The drosophila viruses represent powerful tools to study virus-cell interactions in vivo. Analysis of the literature however reveals that for many of them, important gaps exist in our understanding of their replication cycle, genome organization, morphology or pathogenesis. The data obtained in the past few years on antiviral defense mechanisms in drosophila, which point to evolutionary conserved pathways, highlight the potential of the D. melanogaster model to study antiviral innate immunity and to better understand the complex interaction between arthropod-borne viruses and their insect vectors.

Characterization of the Tupaia rhabdovirus genome reveals a long open reading frame overlapping with P and a novel gene encoding a small hydrophobic protein

Rhabdoviruses are negative-stranded RNA viruses of the order Mononegavirales and have been isolated from vertebrates, insects, and plants. Members of the genus Lyssavirus cause the invariably fatal disease rabies, and a member of the genus Vesiculovirus, Chandipura virus, has recently been associated with acute encephalitis in children. We present here the complete genome sequence and transcription map of a rhabdovirus isolated from cultivated cells of hepatocellular carcinoma tissue from a moribund tree shrew. The negative-strand genome of tupaia rhabdovirus is composed of 11,440 nucleotides and encodes six genes that are separated by one or two intergenic nucleotides. In addition to the typical rhabdovirus genes in the order N-P-M-G-L, a gene encoding a small hydrophobic putative type I transmembrane protein of approximately 11 kDa was identified between the M and G genes, and the corresponding transcript was detected in infected cells. Similar to some Vesiculoviruses and many Paramyxovirinae, the P gene has a second overlapping reading frame that can be accessed by ribosomal choice and encodes a protein of 26 kDa, predicted to be the largest C protein of these virus families. Phylogenetic analyses of the tupaia rhabdovirus N and L genes show that the virus is distantly related to the Vesiculoviruses, Ephemeroviruses, and the recently characterized Flanders virus and Oita virus and further extends the sequence territory occupied by animal rhabdoviruses.

The gene 4 of rice yellow stunt rhabdovirus encodes the matrix protein

The complete nucleotide sequence of the gene 4 of rice yellow stunt rhabdovirus (RYSV) was determined from cDNAs corresponding to the viral genomic RNA. Gene 4 is 913 nucleotides (nt) long, comprising a 17-nt untranslated 5' region, a 786-nt open reading frame encoding a polypeptide with a molecular mass of 29,125 Da, and a 110-nt untranslated 3' region. Western blot analysis of the RYSV proteins using the antiserum raised against the protein expressed from the cloned gene in Escherichia coli indicates that gene 4 encodes the M protein of RYSV. Comparisons of the deduced amino acid sequence of the M protein of RYSV with those of other rhabdoviruses revealed no significant homologies. However, it shared a similar basic property and a similar distribution of charges with the other rhabdovirus matrix proteins and showed a relatively closer relationship to the sonchus yellow net virus (SYNV) M1 protein.

Isolation and characterization of vesicular stomatitis virus PoIR revertants: polymerase readthrough of the leader-N gene junction is linked to an ATP-dependent function

The switch from transcription to replication of the VSV genome is coupled to assembly of nascent chains and involves an unspecified change in the P-L polymerase complex when it reaches the leader-N gene junction. PoIR VSV mutants, in contrast to wild-type virus, read through this first gene junction at high frequency without concurrent assembly, and they show altered ATP requirements for transcription in vitro. The mutation(s) responsible for the poIR phenotype segregates to the N-RNA template fraction. We report here that both poIR1 and poIR2 mutants display severe growth restriction in mouse L cells but not in BHK cells. Four of six poIR1 revertant viruses, originating from rare plaques on L cells, showed wild-type characteristics for growth, readthrough of leader-N gene junction, and ATP utilization, while two showed partial and quantitatively parallel coreversion of all properties. Sequence analysis of N and P genes of poIR mutants and revertants provided proof that a single mutation in the N protein, Arg179 to His, is responsible for the poIR phenotype. PoIR1, but not poIR2, also displayed a phenotypically silent GA-to-GG change in the N-P intergenic dinucleotide sequence Five of six revertants retained the poIR1 N protein mutation and showed no change in their P gene. We conclude that the L protein likely contains second-site suppressors of the poIR phenotype, and we propose that the switch from transcription to replication is modulated by an ATP-dependent interaction between the template-associated N protein and the L subunit of the P L polymerase complex.

Characterization of the components and activity of Sonchus yellow net rhabdovirus polymerase

Sonchus yellow net virus (SYNV) is the best-characterized member of a group of plant rhabdoviruses that replicate in the host cell nucleus. Using a recently developed method for partial purification of active SYNV polymerase by salt extraction of nuclei from infected plant tissue (J. D. O. Wagner et al, J. Virol. 70:468-477, 1996), we have identified the nucleocapsid (N), M2, and L proteins as polymerase complex components (based on copurification with the polymerase activity and by coimmunoprecipitation assays). Furthermore, the L protein was shown by antibody inhibition analysis to be a functional component of the polymerase. A second complex of M2 and L proteins, thought to be a precursor to the polymerase complex, was also identified. In addition, we conducted a detailed characterization of SYNV RNA synthesis in vitro. The results demonstrate that the RNAs are transcribed sequentially, beginning with the N mRNA and followed successively by the remaining five mRNAs in the order of their genome organization. Gene expression conforms to a cascade pattern, with synthesis of the 3'-proximal N mRNA occurring at the highest level, followed by consecutively lower levels of transcription from each subsequent gene. The reaction conditions favor transcription over minus-sense RNA replication, which, we posit, is inhibited near specific signal sequences located on the antigenomic template. The results support the concept that the mechanism of transcription is highly conserved among diverse rhabdoviruses and are compatible with a unified model for the regulation of genomic and antigenomic RNA synthesis.

The BamHI fragment 9 of pseudorabies virus contains genes homologous to the UL24, UL25, UL26, and UL 26.5 genes of herpes simplex virus type 1

The genomes of pseudorabies virus (PrV) and of herpes simplex virus type 1 (HSV1) are colinear, excepting an inversion in the unique long region, of which one extremity resides within the BamHI fragment 9. This fragment (4088 bp) encodes the counterparts of HSV1 UL24, UL25, UL26 and UL26.5 that are transcribed into four 3'-coterminal mRNAs. Multiple alignments of UL24, UL25 and UL26 protein homologs from alpha-, beta- and gamma-herpesviruses were performed. The PrV UL24 protein is shorter than its counterparts, missing the non-conserved COOH-terminal region. The region which is common to all viruses contains a basic NH2-terminus and a hydrophobic COOH-end, suggesting that UL24 may function as a matrix protein. The UL25 proteins are well conserved, particularly among the alpha-herpesviruses. All the domains involved in the proteolytic activity of theUL26 protein are highly conserved, as well as the two cleavage sites. Thus, its function and processing may be similar in PrV as in other herpesviruses. Due to the fact that in PrV the UL26 and UL44 genes are adjacent and their ends are conserved, the right border of the inversion must lie within their intergenic region.

Extraction of nuclei from sonchus yellow net rhabdovirus-infected plants yields a polymerase that synthesizes viral mRNAs and polyadenylated plus-strand leader RNA

Although the primary sequence of the genome of the plant rhabdovirus sonchus yellow net virus (SYNV) has been determined, little is known about the composition of the viral polymerase or the mechanics of viral transcription and replication. In this paper, we report the partial isolation and characterization of an active SYNV polymerase from nuclei of SYNV-infected leaf tissue. A salt extraction procedure is shown to be an effective purification step for recovery of the polymerase from the nuclei. Full-length, polyadenylated SYNV N and M2 mRNAs and plus-strand leader RNA are among the products of the in vitro polymerase reactions. Polyadenylation of the plus-strand leader RNA in vitro is shown with RNase H and specific oligonucleotides. This is the first report of a polyadenylated plus-strand leader RNA for a minus-strand RNA virus, a feature that may reflect adaptation of SYNV to replication in the nucleus. Analysis of the SYNV proteins present in the polymerase extract suggests that the N, M2, and L proteins are components of the transcription complex. Overall, the system we developed promises to be useful for an in-depth characterization of the mechanics of SYNV RNA synthesis.

The complete genome structure and phylogenetic relationship of infectious hematopoietic necrosis virus

Infectious hematopoietic necrosis virus (IHNV), a member of the family Rhabdoviridae, causes a severe disease with high mortality in salmonid fish. The nucleotide sequence (11,131 bases) of the entire genome was determined for the pathogenic WRAC strain of IHNV from southern Idaho. This allowed detailed analysis of all 6 genes, the deduced amino acid sequences of their encoded proteins, and important control motifs including leader, trailer and gene junction regions. Sequence analysis revealed that the 6 virus genes are located along the genome in the 3' to 5' order: nucleocapsid (N), polymerase-associated phosphoprotein (P or M1), matrix protein (M or M2), surface glycoprotein (G), a unique non-virion protein (NV) and virus polymerase (L). The IHNV genome RNA was found to have highly complementary termini (15 of 16 nucleotides). The gene junction regions display the highly conserved sequence UCURUC(U)7RCCGUG(N)4CACR (in the vRNA sense), which includes the typical rhabdovirus transcription termination/polyadenylation signal and a novel putative transcription initiation signal. Phylogenetic analysis of M, G and L protein sequences allowed insights into the evolutionary and taxonomic relationship of rhabdoviruses of fish relative to those of insects or mammals, and a broader sense of the relationship of non-segmented negative-strand RNA viruses. Based on these data, a new genus, piscivirus, is proposed which will initially contain IHNV, viral hemorrhagic septicemia virus and Hirame rhabdovirus.

Localization of domains within the Drosophila Ref(2)P protein involved in the intracellular control of sigma rhabdovirus multiplication

The ref(2)P gene of Drosophila melanogaster interferes with sigma rhabdovirus multiplication. This gene is highly variable, and the different alleles are considered permissive or restrictive according to their effects on virus replication. In all cases, the mechanisms involve intracellular interactions between the sigma virus and Ref(2)P proteins. We showed that the N-terminal domain of the Ref(2)P protein was required for its activity in vivo. The protein was inactive in the null p(od)2 mutant when its first 82 amino acids were deleted. The p delta n gene was constructed so that the first 91 amino acids coded for by the restrictive alleles could be expressed in vivo. It was active in a transformed line. This sequence was sufficient to impart a restrictive phenotype to an adult D. melanogaster fly after it was injected with the virus. However, the truncated protein expressed by p delta n did not have an effect on the hereditary transmission of the sigma virus to the offspring of the infected flies, even though it contained the restriction site. The native Ref(2)P protein has been previously shown to have conformation-dependent epitopes common with some of those of the viral N protein. We demonstrated the following. (i) These epitopes were found in a domain of the Ref(2)P protein distinct from the site involved in restriction. (ii) They were modified in the N protein of the haP7 sigma virus mutant selected as being adapted to the restrictive alleles of the ref(2)P gene; only one mutation in the N gene, leading to an amino acid substitution, distinguished the haP7 mutant from the original virus. (iii) The virus strains partially or totally adapted to the effects of the full restrictive protein expressed by pp were always found to multiply to a lesser extent in the presence of the protein expressed by p delta n. These data suggest that two distinct domains of the Ref(2)P protein are involved in the control of sigma virus multiplication.