Intergenic sequences of the vesicular stomatitis virus genome (New Jersey serotype): evidence for two transcription initiation sites within the L gene

Hyaluronic acid pretreatment for Sendai virus-mediated cochlear gene transfer

Gene therapy with viral vectors is one of the most promising strategies for sensorineural hearing loss. However, safe and effective administration of the viral vector into cochlear tissue is difficult because of the anatomical isolation of the cochlea. We investigated the efficiency and safety of round window membrane (RWM) application of Sendai virus, one of the most promising non-genotoxic vectors, after pretreatment with hyaluronic acid (HA) on the RWM to promote efficient viral translocation into the cochlea. Sendai virus expressing the green fluorescent protein reporter gene was detected throughout cochlear tissues following application combined with HA pretreatment. Quantitative analysis revealed that maximum expression was reached 3 days after treatment. The efficiency of transgene expression was several 100-fold greater with HA pretreatment than that without. Furthermore, unlike the conventional intracochlear delivery methods, this approach did not cause hearing loss. These findings reveal the potential utility of gene therapy with Sendai virus and HA for treatment of sensorineural hearing loss.

Complete genomic sequence and taxonomic position of eel virus European X (EVEX), a rhabdovirus of European eel

Eel virus European X (EVEX) was first isolated from diseased European eel Anguilla anguilla in Japan at the end of seventies. The virus was tentatively classified into the Rhabdoviridae family on the basis of morphology and serological cross reactivity. This family of viruses is organized into six genera and currently comprises approximately 200 members, many of which are still unassigned because of the lack of molecular data. This work presents the morphological, biochemical and genetic characterizations of EVEX, and proposes a taxonomic classification for this virus. We provide its complete genome sequence, plus a comprehensive sequence comparison between isolates from different geographical origins. The genome encodes the five classical structural proteins plus an overlapping open reading frame in the phosphoprotein gene, coding for a putative C protein. Phylogenic relationship with other rhabdoviruses indicates that EVEX is most closely related to the Vesiculovirus genus and shares the highest identity with trout rhabdovirus 903/87.

Characterization of the complete genome sequence of pike fry rhabdovirus

The complete genome sequence of pike fry rhabdovirus (PFRV), consisting of 11,097 nucleotides, was determined. The genome contains five genes, encoding the nucleoprotein (N), phosphoprotein (P), matrix protein (M), glycoprotein (G), and RNA-dependent RNA polymerase (L) protein in the order 3'-N-P-M-G-L-5'. 3' leader- and 5' trailer-sequences in the PFRV genome show inverse complementarity. The PFRV proteins share the highest homology to the proteins of spring viremia of carp virus (SVCV), ranging from 55.3 to 91.4%. Phylogenetic analysis of the five proteins showed that PFRV clusters with SVCV and is closely related to the mammalian vesiculoviruses, 903/87, STRV and SCRV.

Selection for gene junction sequences important for VSV transcription

The heptauridine tract at each gene end and intergenic region (IGR) at the gene junctions of vesicular stomatitis virus (VSV) have effects on synthesis of the downstream mRNA, independent of their respective roles in termination of the upstream mRNA. To investigate the role of the U tract and the IGR in downstream gene transcription, we altered the N/P gene junction of infectious VSV such that transcription levels would be affected and result in altered molar ratios of the N and P proteins, which are critical for optimal viral RNA replication. The changes included extended IGRs between the N and P genes and shortening the length of the heptauridine tract upstream of the P gene start. Viruses having various combinations of these changes were recovered from cDNA and selective pressure for efficient viral replication was applied by sequential passage in cell culture. The replicative ability and sequence at the altered intergenic junctions were monitored throughout the passages to compare the effects of the changes at the IGR and U tract. VSV variants with wild-type U tracts upstream of the P gene replicated to levels similar to wt VSV. Variants with shortened U tracts were reduced in their ability to replicate. With passage, populations emerged that replicated to higher levels. Sequence analysis revealed that mutations had been selected for in these populations that increased the length of the U tract. This correlated with an increase in abundance of P mRNA and protein to provide improved N:P protein molar ratios. Extended IGRs resulted in decreased downstream transcription but the effect was not as extensive as that caused by shortened U tracts. Extended IGRs were not selected against in 5 passages. Our results indicate that the size of the upstream gene end U tract is an important determinant of efficient downstream gene transcription in infectious virus.

Identification of an upstream sequence element required for vesicular stomatitis virus mRNA transcription

Vesicular stomatitis virus (VSV), the prototypic rhabdovirus, has a nonsegmented negative-sense RNA genome with five genes flanked by 3' leader and 5' trailer sequences. Transcription of VSV mRNAs is obligatorily sequential, starting from a single 3' polymerase entry site, and termination of an upstream mRNA is essential for transcription of a downstream gene. cis-acting signals for transcription of VSV mRNAs are present within the leader region, at the leader-N junction, and at the internal gene junctions. The gene junctions of VSV consist of a conserved 23-nucleotide region that includes the gene end sequence of the upstream gene, 3'-AUACU7-5', a nontranscribed intergenic dinucleotide, 3'-G/CA-5', and the gene start sequence, 3'-UUGUCNNUAG-5', at the beginning of the gene immediately downstream. Previous work has shown that the gene end sequence and intergenic region are sufficient to signal polyadenylation and termination of VSV transcripts. Mutagenesis of the gene start sequence has determined the importance of this region in the processes of initiation and 5'-end modification of mRNAs. However, because the gene end sequence is positioned directly upstream of the gene start sequence in the gene junction, and because of the requirement for termination of the upstream gene prior to transcription of the downstream gene, it has not been possible to investigate whether the gene end sequence contributes to transcription of the downstream gene. In this study, we inserted an additional gene end sequence upstream of the gene junction in a subgenomic replicon of VSV, which extended the intergenic region from 2 to 88 nucleotides. This duplication of termination signals allowed us to separate the signals required for termination from those required for initiation. We investigated the effect that the upstream gene end sequences had on downstream mRNA transcription. Our data show that the U7 tract of the upstream gene end sequence is necessary for optimal transcription of the downstream gene, independent of its role in termination of the upstream gene. Altering the sequence or changing the length of the U tract directly upstream of the gene start sequence significantly decreased transcription of the downstream gene. These results show that the U tract is a multifunctional region that is required not only for polyadenylation and termination of the upstream mRNA but also for efficient transcription of the downstream gene.

Recombinant Sendai viruses expressing different levels of a foreign reporter gene

Sendai virus (SeV) is an enveloped virus with a nonsegmented negative strand RNA genome. The recovery of infectious virus from cDNA and generation of recombinant SeV carrying a foreign gene at the promoter proximal position has been demonstrated. In this study, we constructed a series of recombinant SeVs carrying a reporter human secreted alkaline phosphatase (SEAP) gene at each viral gene junction or the 5' distal end in order to measure the expression level of the foreign gene. We demonstrated that there was a gradient in the reporter gene expression level that depended on location, due to the polarity of transcription. In contrast, the growth and final titers of these recombinant viruses showed an opposite gradient to the foreign gene expression level. This suggests the potential for matching therapeutic gene expression level to individual therapy programs by changing the position of the foreign gene when SeVs are used as vectors for human gene therapy.

Sendai virus gene start signals are not equivalent in reinitiation capacity: moderation at the fusion protein gene

In paramyxovirus transcription, viral RNA polymerase synthesizes each monocistronic mRNA by recognizing the gene start (S) and end (E) signals flanking each gene. These signal sequences are well conserved in the virus family; nevertheless, they do exhibit some variations even within a virus species. In Sendai virus (SeV) Z strain, the E signals are identical for all six genes but there are four (N, P/M/HN, F, and L) different S signals with one or two nucleotide variations. The significance of these variations for in vitro and in vivo replication has been unknown. We addressed this issue by SeV reverse genetics. The luciferase gene was placed between the N and P gene so that recombinant SeVs expressed luciferase under the control of each of the four different S signals. The S signal for the F gene was found to drive a lower level of transcription than that of the other three, which exhibited comparable reinitiation capacities. The polar attenuation of SeV transcription thus appeared to be not linear but biphasic. Then, a mutant SeV whose F gene S signal was replaced with that used for the P, M, and HN genes was created, and its replication capability was examined. The mutant produced a larger amount of F protein and downstream gene-encoded proteins and replicated faster than wild-type SeV in cultured cells and in embryonated eggs. Compared with the wild type, the mutant virus also replicated faster in mice and was more virulent, requiring a dose 20 times lower to kill 50% of mice. On the other hand, the unique F start sequence as well as the other start sequences are perfectly conserved in all SeV isolates sequenced to date, including highly virulent fresh isolates as well as egg-adapted strains, with a virulence several magnitudes lower than that of the fresh isolates. This moderation of transcription at the F gene may therefore be relevant to viral fitness in nature.

Transcript initiation and 5'-end modifications are separable events during vesicular stomatitis virus transcription

In this report we describe a novel, bipartite vesicular stomatitis virus (VSV) replication system which was used to study the effect of mutations in the transcription start sequence on transcript initiation and 5'-mRNA modifications. The bipartite replication system consisted of two genomic RNAs, one of which (VSVDeltaG) was a recombinant VSV genome with the G gene deleted and the other (GFC) contained the G gene and two non-VSV reporter genes (green fluorescent protein [GFP] and chloramphenicol acetyltransferase [CAT]). Coinfection of cells with these two components resulted in high-level virus production and gave titers similar to that from wild-type-VSV-infected cells. Mutations were introduced within the first 3 nucleotides of the transcription start sequence of the third gene (CAT) of GFC. The effects of these changes on the synthesis and accumulation of CAT transcripts during in vivo transcription (e.g., in infected cells), and during in vitro transcription were determined. As we had reported previously (E. A. Stillman and M. A. Whitt, J. Virol. 71:2127-2137, 1997), changing the first and third nucleotides (NT-1 and NT-3) reduced CAT transcript levels in vivo to near undetectable levels. Similarly, changing NT-2 to a purine also resulted in the detection of very small amounts of CAT mRNA from infected cells. In contrast to the results in vivo, the NT-1C mutant and all of the second-position mutants produced near-wild-type amounts of CAT mRNA in the in vitro system, indicating that the mutations did not prevent transcript initiation per se but, rather, generated transcripts that were unstable in vivo. Oligo (dT) selection and Northern blot analysis revealed that the transcripts produced from these mutants did not contain a poly(A)(+) tail and were truncated, ranging in size from 40 to 200 nucleotides. Immunoprecipitation analysis of cDNA-RNA hybrids with an antibody that recognizes trimethylguanosine revealed that the truncated mutant transcripts were not properly modified at the 5' end, indicating the transcripts either were not capped or were not methylated. This is the first demonstration that transcript initiation and capping/methylation are separable events during VSV transcription. A model is proposed in which polymerase processivity is linked to proper 5'-end modification. The model suggests that a proofreading mechanism exists for VSV and possibly other nonsegmented minus-strand RNA viruses, whereby if some transcripts do not become capped during transcription in a normal infection, a signal is transduced such that the polymerase undergoes abortive elongation and the defective transcript is terminated prematurely and subsequently degraded.

The length and sequence composition of vesicular stomatitis virus intergenic regions affect mRNA levels and the site of transcript initiation

In this study, we used a dicistronic vesicular stomatitis virus (VSV) minigenome to investigate the effects of either single or multiple nucleotide insertions placed immediately after the nontranscribed intergenic dinucleotide of the M gene on VSV transcription. Both Northern blot and primer extension analysis showed that the polymerase responded to the inserted nucleotides in a sequence-specific manner such that some insertions had no effect on mRNA synthesis from the downstream G gene, nor on the site of transcript initiation, whereas other insertions resulted in dramatic reductions in transcript accumulation. Some of these transcripts were initiated at the wild-type site, while others initiated within the inserted sequence. We also examined the transcriptional events that occurred when a natural, 21-nucleotide intergenic region located between the G and L genes from the New Jersey (NJ) serotype of VSV was inserted into the minigenome gene junction. In contrast to the normal 25 to 30% attenuation observed for downstream transcription at gene junctions containing the typical dinucleotide (3'-GA-5') intergenic region, the NJ variant showed greater than 75% attenuation at the gene junction. In addition, the polymerase initiated transcription at two major start sites, one of which was located within the intergenic sequence. Collectively, these data suggest that the polymerase "samples" the intergenic sequences following polyadenylation and termination of the upstream transcript by scanning until an appropriate start site is found. One implication of a scanning polymerase is that the polymerase presumably switches states from a processive elongation mode to a stuttering mode for polyadenylation to one in which no transcription occurs, before it reinitiates at the downstream gene. Our data support the hypothesis that sequences surrounding the intergenic region modulate these events such that appropriate amounts of each mRNA are synthesized.

Polyadenylation of vesicular stomatitis virus mRNA dictates efficient transcription termination at the intercistronic gene junctions

The intercistronic gene junctions of vesicular stomatitis virus (VSV) contain conserved sequence elements that are important for polyadenylation and transcription termination of upstream transcript as well as reinitiation of transcription of downstream transcript. To examine the role of the putative polyadenylation signal 3'AUACU(7)5' at the gene junctions in polyadenylation and transcription termination, we constructed plasmids encoding antigenomic minireplicons containing one or two transcription units. In plasmid-transfected cells, analyses of the bicistronic minireplicon containing the wild-type or mutant intercistronic gene junctions for the ability to direct synthesis of polyadenylated upstream, downstream, and readthrough mRNAs showed that the AUACU(7) sequence element is required for polyadenylation of VSV mRNA. Deletion of AUAC or U(7) resulted in templates that did not support polyadenylation of upstream mRNA. Interestingly, we found that the loss of polyadenylation function led to antitermination of the upstream transcript and resulted in a readthrough transcript that contained the upstream and downstream mRNA sequences. Mutations that blocked polyadenylation also blocked transcription termination and generated mostly readthrough transcript. Reverse transcription-PCR of readthrough transcripts and subsequent nucleotide sequencing of the amplified product revealed no extra adenosine residues at the junction of the readthrough transcript. These results indicate that polyadenylation is required for transcription termination of VSV mRNA. The intergenic dinucleotide GA did not appear to be necessary for transcription termination. Furthermore, we found that insertion of the polyadenylation signal sequence AUACU(7) alone was sufficient to direct polyadenylation and efficient transcription termination at the inserted site. Taken together, the data presented here support the conclusion that polyadenylation is the major determinant of transcription termination at the intercistronic gene junctions of VSV.

Role of the intergenic dinucleotide in vesicular stomatitis virus RNA transcription

To investigate the role played by the intergenic dinucleotide sequence of the conserved vesicular stomatitis virus (VSV) gene junction in modulation of polymerase activity, we analyzed the RNA synthesis activities of bicistrionic genomic analogs that contained either the authentic N/P gene junction or gene junctions that had been altered to contain either the 16 possible dinucleotide combinations, single nucleotide intergenic sequences, or no intergenic sequence at all. Quantitative measurements of the amounts of upstream, downstream, and readthrough mRNAs that were transcribed by these mutant templates showed that the behavior of the viral polymerase was profoundly affected by the nucleotide sequence that it encountered as it traversed the gene junction, although the polymerase was able to accommodate a remarkable degree of sequence variation without altogether losing the ability to terminate and reinitiate transcription. Alteration or removal of the intergenic sequence such that the U tract responsible for synthesis of the upstream mRNA poly(A) tail was effectively positioned adjacent to the consensus downstream gene start signal resulted in almost complete abrogation of downstream mRNA synthesis, thus defining the intergenic sequence as an essential sequence element of the gene junction. Many genome analogs with altered intergenic sequences directed abundant synthesis of a readthrough transcript without correspondingly high levels of downstream mRNA, an observation inconsistent with the shunting model of VSV transcription, which suggests that polymerase molecules are prepositioned at gene junctions, awaiting a push from upstream. Instead, the findings of this study support a model of sequential transcription in which initiation of downstream mRNA can occur only following termination of the preceding transcript.

The nucleotide sequences of intergenic regions between nine genes of pneumonia virus of mice establish the physical order of these genes in the viral genome

We have cloned eight intergenic regions from the Pneumovirus pneumonia virus of mice that link the nine small and medium sized genes previously described (Chambers et al., 1990). The nucleotide sequences of the clones confirm the locations of these genes and their mRNA transcripts in the viral genome. The intergenic regions vary in size from 2-56 nucleotides and show only faint homology to each other or to their analogues in respiratory syncytial virus. Sequence alignments suggest that the location of the transcriptional start site for the mRNA encoding the major nucleocapsid protein of pneumonia virus of mice and respiratory syncytial virus may have altered during virus evolution by gain or loss of a transcriptional start signal.

Nucleotide sequence analysis of the L gene of vesicular stomatitis virus (New Jersey serotype): identification of conserved domains in L proteins of nonsegmented negative-strand RNA viruses

We have determined the nucleotide sequence of the L gene of vesicular stomatitis virus (VSV), New Jersey serotype (Ogden strain) by primer extension dideoxy sequencing of the genomic RNA with reverse transcriptase. This analysis completes the entire genomic sequence of the VSVNJ (Ogden). Comparison of the deduced amino acid sequence of this L protein with those reported for L proteins of Indiana serotype and Hazelhurst strain of New Jersey serotype revealed an extensive sequence similarity among all three proteins. The comparison was further extended to the L proteins of other nonsegmented negative-strand RNA viruses, namely the rabies virus and four members of the paramyxovirus family: measles, Newcastle disease, human parainfluenza 3, and Sendai viruses. Our findings confirmed the existence of conserved as well as unique domains in the L proteins, suggesting an evolutionary relationship among these viruses.

Structure and expression of the glycoprotein gene of Chandipura virus

A cDNA copy of the mRNA for the glycoprotein G of Chandipura virus, a rhabdovirus, has been cloned, sequenced, and expressed in mammalian cells. The deduced amino acid sequence of G shows that the encoded protein is a typical transmembrane glycoprotein of 524 amino acids containing a cleavable amino-terminal signal peptide, two potential N-linked glycosylation sites, a hydrophobic membrane anchor domain near the carboxy terminus, and a cytoplasmic domain at the carboxy terminus. Somewhat unusual is the appearance of two charged amino acid residues, aspartate and arginine, within the putative membrane anchor sequence. Expression of the G gene in COS cells resulted in production of a glycosylated protein of mol wt 71,000 which was recognized by anti-Chandipura antibodies. Like the viral G protein, the expressed G contained covalently linked palmitic acid. However, unlike its vesicular stomatitis virus (Indiana serotype) counterpart, the Chandipura G protein has no potential palmitate-accepting cysteine residue within its cytoplasmic domain. Thus, the covalent attachment of fatty acid to this molecule may occur at one or both of the cysteines within the membrane anchor domain. The G protein was intracellularly transported to the cell surface and could induce cell fusion at low pH, showing that the expressed G protein was biologically active.

Nucleotide sequence of the L gene of vesicular stomatitis virus (New Jersey): identification of conserved domains in the New Jersey and Indiana L proteins

The nucleotide sequence of the L gene of vesicular stomatitis virus, New Jersey serotype (Hazelhurst subtype), was determined. Primer extension dideoxy sequencing of genomic RNA using reverse transcriptase initiated within the adjacent G gene provided a consensus sequence of 6522 nucleotides. The G/L intergenic junction spanned 21 nucleotides and contained a pseudo transcription start signal as well as two sequences (10 and 6 nucleotides in length) which are reiterated within the L coding region. The predicted L mRNA was 6398 nucleotides long and contained a single open reading frame corresponding to an L protein encompassing 2109 amino acids with a MW of 241,546. Comparison of the amino acid sequence of this New Jersey serotype L protein to that previously reported for the L protein of the serologically and genetically distinct Indiana serotype (M. Schubert, G. G. Harmison, and E. Meier (1984). J. Virol. 51, 505-514.) revealed a high degree of functional homology. In addition, six regions (43 to 103 amino acids in length) which displayed a high percentage of identical amino acids (85 to 96%) were identified. Five of these regions were clustered within the amino-terminal half of the L protein. Two of these regions contained sequences, 41 amino acids in length, which were significantly similar to corresponding regions of the L proteins of the paramyxoviruses Sendai and Newcastle disease virus. These structurally conserved regions may correspond to functional domains of the multifunctional L protein.