Synthesis of viral mRNA and polyadenylate by a ribonucleoprotein complex from extracts of VSV-infected cells

Novel insights into the regulation of the viral polymerase complex of neurotropic Borna disease virus

Borna disease virus (BDV) genetic information is encoded in a highly condensed non-segmented RNA genome of negative polarity. Replication and transcription of the genome occurs in the nucleus, enabling the virus to employ the cellular splicing machinery to process primary transcripts and to regulate expression of viral gene products. BDV establishes a non-cytolytic, persistent infection that in animals is mainly restricted to neurons of the central nervous system. Based on these unique properties, BDV represents the prototype member of the virus family Bornaviridae in the order Mononegavirales. Analysis of molecular aspects of BDV replication has long been hampered by the lack of a reverse genetics system. Only recently, artificial BDV minigenomes permitted the reconstitution of the viral polymerase complex, allowing finally the recovery of BDV from cDNA. As in other families of the Mononegavirales, the active polymerase complex of BDV is composed of the polymerase (L), the nucleoprotein (N) and the phosphoprotein (P). In addition, the viral X protein was identified as potent negative regulator of polymerase activity. Protein interaction studies combined with minireplicon assays suggested that P is a central regulatory element of BDV replication that directs the assembly of the polymerase complex. Most intriguingly, BDV obtained from cDNA with variable genomic termini suggests a novel strategy for viral replication-control. BDV seems to restrict its propagation efficacy by defined 5' terminal trimming of genomic and antigenomic RNA molecules. This review will summarize these novel findings and will discuss them in the context of BDV neurotropism and persistence.

Overlap of interaction domains indicates a central role of the P protein in assembly and regulation of the Borna disease virus polymerase complex

The active polymerase complex of Borna disease virus is composed of the viral proteins N, P, and L. The viral X (negative regulatory factor) protein acts as a regulator of polymerase activity. Interactions of P with N and X were previously studied, but interactions with L were poorly defined. Using a mammalian two-hybrid system, we observed that L specifically interacts with P but not with N, X, or itself. Mapping of the L-binding domain in the P molecule revealed that it overlaps with two adjacent domains required for multimerization and interaction with N. Competition experiments showed that the interaction between L and P was inefficient when N was present, indicating that L may preferentially interact with free P in infected cells. Interestingly, a multimerization-defective P mutant maintained the ability to interact with L, N, and X but failed to support reporter gene expression from an artificial Borna disease virus minigenome. Furthermore, dominant negative effects on minigenome activity were only observed when P mutants with an intact multimerization domain were used, suggesting that P multimers, rather than monomers, exhibit biological activity. P mutants lacking functional interaction domains for L or N still formed complexes with these viral proteins when wild-type P was available as a bridging molecule, indicating that P multimers have the potential to act as scaffolds on which the RNA polymerase complex is assembled.

Aberrant polyadenylation by a vesicular stomatitis virus mutant is due to an altered L protein

TsG16(I) is a temperature-sensitive mutant of vesicular stomatitis virus, Indiana serotype. Our stocks of this mutant overproduce polyadenylic acid in an in vitro transcription system. The overproduction of polyadenylic acid occurs at all temperatures tested (27, 31, 35, and 39 degrees C) and is apparently not due to an alternation in the N protein-RNA template. To characterize the altered moiety in tsG16(I) responsible for this phenotype, virions were fractionated and the polyadenylation phenotype in homologous and heterologous reconstitution assays was determined. The aberrant polyadenylation phenotype correlated with the presence of ts L protein but not ts NS or ts M protein fractions. Results of experiments in which solubilized tsG16(I) and wild-type virion components were mixed indicated that the altered moiety behaved as if present in stoichiometric amounts relative to active L protein. The effects of raising the temperature from 31 to 39 degrees C in such mixes were as would be predicted upon the assumption that the polyadenylation phenotype was associated with a thermosensitive transcriptase component [the L protein of tsG16(I) is known to be thermosensitive]. We conclude that the data strongly support the hypothesis that L is the altered protein responsible for the aberrant polyadenylation phenotype of tsG16(I).

Primary structure of the vesicular stomatitis virus polymerase (L) gene: evidence for a high frequency of mutations

A consensus sequence of the polymerase (L) gene of vesicular stomatitis virus, derived from three genomic cDNA copies, is presented. This analysis completes the primary structure of the vesicular stomatitis virus genome, totaling 11,162 bases. The L gene alone spans 6,380 nucleotides and codes for a basic 2,109-amino-acid protein with a molecular weight of 241,012. Sixteen point mutations were detected among cDNA clones prepared from viral RNA of the same strain, representing direct evidence for either the high mutability of vesicular stomatitis virus, the infidelity of reverse transcription during cDNA synthesis, or a combination of both. Some mutation, if present in the viral genome, would result in the translation of incomplete L proteins. For example, two out of four cDNA copies which covered the same region of the L gene had a single-base deletion in the exact same position, whereas the other two clones did not, strongly suggesting that a subpopulation of the genomic RNA may contain this lethal mutation. These lethal mutants define a new class of defective and most likely interfering particles which are indistinguishable in size from the parental virus and can be distinguished only by direct sequencing. We suggest that because of its infidelity, the viral polymerase itself introduces mutations and because of its size, most of these mutations are localized within the polymerase gene. In persistently infected cells in which the selective pressures on the polymerase are different, some of these L gene mutations may further erode the accuracy of the polymerase and thereby lead to the increased mutation rate that is characteristic of this type of infection.

Vesicular stomatitis virus mutant with altered polyadenylic acid polymerase activity in vitro

In vitro RNA synthesis by purified virions of a stock of tsG16(I) was aberrant compared with that of wild-type (wt) vesicular stomatitis virus. RNA made in vitro by tsG16(I) contained a larger proportion of A residues in polyadenylic acid [poly(A)] tracts than did RNA synthesized by wt virus, tsG13(I), tsG21(II) or tsG41(IV). Experiments to determine whether the aberrant polyadenylation was correlated with the known thermolability of the tsG16(I) L protein were inconclusive. Total product RNA made by tsG16(I) was methylated to almost the same extent as wt RNA, contained the same major methylated 5' cap structure as wt RNA, and was translated as well in a reticulocyte cell-free system, yielding the same molecular weight proteins in similar ratios. Most polyadenylated [poly(A)+] RNA made by tsG16(I) was considerably larger than wt poly(A)+ RNA and richer in AMP:UMP residues; however, the protein-coding capacities of mutant and wt poly(A)+ RNAs were similar. This suggested that most mRNAs made in vitro by tsG16(I) might possess very long poly(A)+ tracts, and digestion of RNA by T1 RNase supported this. It appeared, therefore, that a virally coded component of vesicular stomatitis virus could affect polyadenylation. This could be the poly(A) polymerase itself, a protein involved in control of polyadenylation, or a protein which affects an event spatially and temporally connected with polyadenylation (such as initiation of the subsequent mRNA).

In vivo transcription of the 5'-terminal extracistronic region of vesicular stomatitis virus RNA

In vivo transcription and polyadenylation at the junction of the L cistron and the 5'-terminal extracistronic region of vesicular stomatitis virus RNA was investigated. Annealing of 5'32P-labeled RNA representing the 5'-terminal noncoding 77 nucleotides of vesicular stomatitis virus genomic RNA to L gene mRNA resulted in specific duplex formation. Two specific RNase T1- and RNase A resistant duplexes, 66 and 77 nucleotides long, bound to oligodeoxythymidylic acid cellulose. The specific sizes of the duplexes and their selection by oligodeoxythymidylic acid cellulose chromatography demonstrated that they were covalently linked to the polyadenylic acid tail of L gene mRNA. These data strongly suggest that the viral polymerase polyadenylates L gene mRNA in vivo by using the stretch of seven uridine residues at the end of the L cistron and that the polymerase can resume transcribing the 5'-terminal extracistronic region, resulting in a covalent linkage of the transcript to the polyadenylic acid tail of L gene mRNA.

Structure and origin of a snapback defective interfering particle RNA of vesicular stomatitis virus

The nucleotide sequence of the region which covalently links the complementary strands of the "snapback" RNA of vesicular stomatitis virus, DI011, is (Formula: see text). Both strands of the defective interfering (DI) particle RNA were complementary for their full length and were covalently linked by a single phosphate group. Because the strands were exactly the same length and complementary, template strand and daughter strand nucleocapsids generated during replication of DI 011 were undistinguishable on the basis of sequence, a property not shared by other types of DI particle RNAs. Treatment of the RNA with RNase T1 in high-ionic-strength solutions cleaved the RNA only between positions 1 and 1'. These results and the availability of the guanosine residue in position 1' to kethoxal, a reagent that specifically derivatizes guanosines of single-stranded RNA, suggest that steric constraints keep a small portion of the "turnaround" region in an open configuration. The sequence of the turnaround region was not related in any obvious way to the sequences at the 3' and 5' termini and limited the number of possible models for the origin of this type of DI particle RNA. Two models for the genesis of DI 011 RNA are discussed. We favor one in which the progenitor DI 011 RNA was generated by replication across a nascent replication fork.

Polycistronic vesicular stomatitis virus RNA transcripts

A procedure to enrich for the sequences present at the junction between the linked messages in the polycistronic RNAs symthesized in vitro by vesicular stomatitis virus (VSV) is described. Analyses of these sequences show that they contain a precise transcript of both the intercistronic dinucleotide and the pentanucleotide 5'--C-U-G-U-U--3', common to the 5'-end of all VSV cistrons, covalently linked to the 3'-side of the intervening poly(A). The data strongly suggest that the VSV transcriptase polyadenylylates the mRNAs and can then resume direct and precise transcription of the genome-without reinitiation and without skipping nucleotides.

Site on the vesicular stomatitis virus genome specifying polyadenylation and the end of the L gene mRNA

The 5'-terminal nucleotide sequence from positions 50 to 130 of vesicular stomatitis virus RNA was determined indirectly by using a defective interfering particle RNA which contains covalently linked genomic minus and antigenomic plus sense RNAs. The last 18 nucleotides of the L gene coding for in the viral polymerase were identified and isolated by specific duplex formation between 5' terminally labeled oligonucleotides from a small single-stranded defective interfering particle RNA and L gene mRNA. The L gene ends at position 60 from the 5' terminus of the vesicular stomatitis genome. The data demonstrated that the first seven adenine residues in the polyadenylic acid tail of L gene mRNA may be coded for in the genome and suggested that the viral transcriptase itself may carry out polyadenylation, possibly by chattering at the uridine-rich sequence at the end of the L gene. Analysis of the 5'-terminal sequence of vesicular stomatitis virus genomic RNA revealed that it might fold into a complex secondary structure with possibly 62% of the bases paired.

The effect of cordycepin on the multiplication of Semliki Forest virus and on polyadenylation of viral RNA

Cordycepin (3'-deoxyadenosine), at a concentration of 20 microgram/ml, has a marked effect on Semliki Forest virus multiplication. The appearance of plaque forming units is delayed by about 2 hours and the yield greatly reduced. The incorporation of [3H] uridine into intracellular viral RNAs reaches less than 50 per cent of controls. However, no specific effect on poly (A) synthesis could be detected. The binding efficiency of viral RNAs on nitrocellulose membranes and poly (U) sepharose is not affected by cordycepin. The average poly (A) length of total intracellular viral RNA was calculated on the basis of the ratio of the radioactivity of adenosine-monophosphate: adenosine and found to be about 35 nucleotides in treated and untreated cells.

The action of cordycepin on nascent nuclear RNA and poly(A) synthesis in regenerating liver

Following a 5 min pulse of [5- 3H]orotic acid via the protal vein, the specific radioactivity of non-poly(A)heterogeneous nuclear RNA (HnRNA) reaches a peak at 12 h after partial hepatectomy. In contrast, poly(A)-HnRNA was maximally elevated only at 2 h after operation. After intraportal injection of cordycepin (3'-deoxyadenosine) 1 min before [5-3H]orotic acid, a dose-dependent inhibition of nuclear HnRNA and rRNA occurred. Fractionation of HnRNA on poly(U)-Sepharose following 20 mg/kg of cordycepin revealed that a 65% reduction occurred in the labeling of poly(A)-HnRNA while non-polyactivity of UTP in control and cordycepin-treated animals indicated no significant alterations in these parameters. Assessment of poly(A) size using poly(A)-HnRNA annealed with oligo(dT)10 as template primer for Escherichia coli DNA polymerase I, showed that 20 mg/kg of cordycepin inhibited nuclear polyadenylylation by 43%; no alteration in the binding of poly(A)-HnRNA to Millipore filters occurred at this dose of cordycepin. These results indicate that cordycepin is a non-selective inhibitor of nuclear RNA and poly(A)synthesis in regenerating rat liver.