Structure and origin of a novel class of defective interfering particle of vesicular stomatitis virus

The genome structure and terminal sequences of a 'copyback' defective interfering (DI) particle ST1, and a novel complexly rearranged 'snapback' DI particle ST2 of vesicular stomatitis virus have been determined. The ST1 DI genome RNA possesses 54 base long inverted complementary termini, the 5' end of which is homologous to the standard virus genome 5' end. Following this region of inverted complementarity the DI RNA 5' end continues to be homologous to standard virus RNA 5' sequences, whereas the 3' end diverges into sequences within the virus L gene internal sequences. ST2 DI genome RNA does not contain colinear covalently linked plus and minus sense RNA copies of the standard infectious virus RNA 5' terminus as predicted from the prototype snapback DI structure, but instead appears to be a hairpin copy of the ST1 DI RNA genome. This is the first evidence suggesting that DI particles may be generated from RNA templates other than the standard virus RNA. Generation models and the implications of these findings for RNA virus evolution are discussed.     

The complete sequence of a unique RNA species synthesized by a DI particle of VSV.

The 2S RNA synthesized in vitro by the RNA polymerase of a defective interfering (DI) particle of vesicular stomatitis virus was labeled at its 3' terminus with 32P-cytidine 3', 5' bisphosphate and RNA ligase. Analysis of the labeled RNA showed that it was a family of RNAs of different length but all sharing the same 5' terminal sequence. The largest labeled RNA was purified by gel electrophoresis, and the sequence of 41 of its 46 nucleotides was determined by rapid RNA sequencing methods. The assignment of the remaining 5 nucleotides was made on the basis of an analysis of one of the smaller RNAs and published data. A new approach in RNA sequencing based on the identification of 3' terminal nucleotides of rna fragments originally present in the DI product or generated during the ligation reaction confirmed most of the sequence. The complete sequence of this 46 nucleotide long plus-sense RNA is: ppACGAAGACCACAAAACCAGAUAAAAAA UAAAAACCACAAGAGGGUC-OH. This RNA anneals to the RNA of the DI particle from which it was synthesized, indicating that its synthesis is template-specified. At least the first 17 and possibly all of the nucleotides are also complementary to sequences at the 3' end of two other VSV DI particles which were derived independently and whose genomes differ significantly in length. These data suggest a common 3' terminal sequence among all VSV DI particles which contain part of the Lgene region of the parental genome.     

The nucleotide sequence of the 5'' terminus of vesicular stomatitis virus RNA.

We have determined the nucleotide sequence for the first 50 nucleotides at the 5' terminus of vesicular stomatitis virus (VSV) genome RNA. This sequence is identical to that of the in vitro RNA polymerase product synthesized by defective interfering (DI) particles of VSV. These results confirm previous conclusions rengarding DI and standard viral terminal sequences based on hybridization studies and earlier sequencing of the DI polymerase product RNA.     

Analysis of the recombination event generating a vesicular stomatitis virus deletion defective interfering particle.

cDNA clones of different portions of the L cistron and 5'-terminal region of the vesicular stomatitis virus genome have been prepared and used to identify the exact site of the deletion in the defective interfering particle, DI-LT. The deletion extends from nucleotide 251 from the beginning of the L gene to a position 342 nucleotides from the end of the genome. The nucleotide sequences flanking the deletion site, as well as those at the ends of the deleted segment, did not contain any obvious vesicular stomatitis virus initiation or termination signals as had been found near the recombination sites in other defective interfering particle RNAs. The results best fit a model for the origin of this type of defective interfering particle in which the polymerase interrupts its synthesis and moves with its nascent daughter strand to a new position on the template and resumes synthesis there, further extending the nascent strand. Neither the interruption nor the resumption of synthesis appears to be in response to the template nucleotide sequence. The sequences of two partial L cistron clones also reveal open reading frames that code for amino acid sequences likely to be the amino and carboxy termini of the L protein.     

Terminal sequences of vesicular stomatitis virus RNA are both complementary and conserved.

The nucleotide sequences at the 5' and 3' termini of RNA isolated from the New Jersey serotype of vesicular stomatitis virus [vsV(NJ)] and two of its defective interfering (DI) particles have been determined. The sequence differs from that previously demonstrated for the RNA from the Indiana serotype of VSV at only 1 of the first 17 positions from the 3' terminus and at only 2 of the first 17 positions from the 5' terminus. The 5'-terminal sequence of VSV(NJ) RNA is the complement of the 3'-terminal sequence, and duplexes which are 20 bases long and contain the 3' and 5' termini have been isolated from this RNA. The RNAs isolated from DI particles of VSV(NJ) have the same base sequences as do the RNAs from the parental virus. These results are in sharp contrast to those obtained with the Indiana serotype of VSV and its DI particles, in which the 3'-terminal sequences differ in 3 positions within the first 17. However, with both serotypes, the 3'-terminal sequence of the DI RNA is the complement of the 5'-terminal sequence of the RNA from the infectious virus. These findings suggest that the 3' and 5' RNA termini are highly conserved in both serotypes and that the 3' terminus of DI RNA is ultimately derived by copying the 5' end of the VSV genome, as recently proposed (D. Kolakofsky, M. Leppert, and L. Kort, in B. W. J. Mahy and R. D. Barry, ed., Negative-Strand Virus and the Host Cell, 1977; M. Leppert, L. Kort, and D. Kolakofsky, Cell 12:539-552, 1977; A. S. Huang, Bacteriol. Rev. 41:811-8218 1977).     

Persistent vesicular stomatitis virus infection mediates base substitutions in viral RNA termini.

We have sequenced (via a product RNA) the 3' RNA terminus of a defective interfering particle that was generated from the standard virus isolated from a culture of BHK-21 cells persistently infected with vesicular stomatitis virus for over 5 years. By hybridization and RNA sequencing, seven mutations were identified in the 46 nucleotides at the terminus of this defective-interfering-particle RNA. It is likely that these mutations are a reflection of altered protein-nucleic acid interactions that the virus has evolved to maintain its persistently infected carrier state in vitro.     

Isolation of vesicular stomatitis virus defective interfering genomes with different amounts of 5''-terminal complementarity.

I isolated at least 30 different vesicular stomatitis virus defective interfering (DI) genomes, distinguished by chain length, by five independent undiluted passages of a repeatedly cloned virus plaque. Labeling of the 3' hydroxyl ends of these DI genomes and RNase digestion studies demonstrated that the ends of these DI genomes were terminally complementary to different extents (approximately 46 to 200 nucleotides). Mapping studies showed that the complementary ends of all of the DI genomes were derived from the 5' ends of the nondefective minus-strand genome. Regardless of the extent of terminal complementarity, all of the DI genomes synthesized the same 46-nucleotide minus-strand leader RNA.     

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.     

Interference among defective interfering particles of vesicular stomatitis virus

Three defective interfering (DI) particles of vesicular stomatitis virus (VSV), all derived from the same parental standard San Juan strain (Indiana serotype), were used in various combinations to infect cells together with the parental virus. The replication of their RNA genomes in the presence of other competing genomes was described by the hierarchical sequence: DI 0.52 particles greater than DI 0.45 particles less than or equal to DI-T particles greater than standard VSV. The advantage of one DI particle over another was not due simply to multiplicity effects nor to the irreversible occupation of limited cellular sites. Interference, however, did correlate with a change in the ratio of plus and minus RNA templates that accumulated intracellularly and with the presence of new sequences at the 3' end of the DI genomes. DI 0.52 particles contained significantly more nucleotides at the 3' end that were complementary to those at the 5' end of its RNA than did DI-T or DI 0.45 particles. The first 45 nucleotides at the 3' ends of all of the DI RNAs were identical. VSV and its DI particles can be separated into three classes, depending on their terminal RNA sequences. These sequences suggest two mechanisms, one based on the affinity of polymerase binding and the other on the affinity of N-protein binding, that may account for interference by DI particles against standard VSV and among DI particles themselves.     

Viruses isolated from cells persistently infected with vesicular stomatitis virus show altered interactions with defective interfering particles.

Virus mutants isolated from persistent infections of vesicular stomatitis virus in BHK-21 cells were much less susceptible to interference mediated by the defective interfering particle used to establish the persistent infection. This mutational change occurred as early as 34 days in the persistent infection and continued for over 5 years. The earliest variants showed no oligonucleotide map changes and no difference in the temperature-sensitive phenotype from the original virus, but the later variants exhibited extensive map changes. These results suggest a possible role for defective interfering particles in the selection of the mutants.     

Vesicular stomatitis virus defective interfering particles can contain extensive genomic sequence rearrangements and base substitutions

We sequenced the 5' and 3' RNA termini of 16 defective interfering (DI) particles of vesicular stomatitis virus (VSV) isolated at intervals from persistent infections and from a series of undiluted lytic passages. All DI RNAs exhibited complementary termini, but sequences internal to these termini were extensively rearranged in a variety of ways. Despite extensive rearrangement, these internal sequences (in addition to the termini) apparently are important for DI particle interference properties. Some of these DI particles are derived from multiple intrastrand and interstrand recombination events, and the generation of each can be explained by current replicase error models. During viral evolution in persistent and acute infections, DI particles with specific termini base substitutions are selected. One DI particle exhibits a remarkable clustering of specific A----G (and complementary U----C) substitutions, apparently as a result of repetitive misincorporations by an error-prone viral polymerase complex.