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.     

Guanidine-resistant defective interfering particles of poliovirus.

A mixture containing standard poliovirus and D3 particles (mutants with deletions in the capsid locus) was serially passaged in the presence of guanidine. Within five growth cycles, the standard virus was guanidine resistant, but the D3 particles were guanidine sensitive, even after 21 passages with the inhibitor. By passage 40 with guanidine, D3 particles were eliminated, and a new deletion mutant (DX) appeared in the virus population. D3 particles contained a 15% deletion, and DX particles contained a 6% deletion in the capsid locus. Although neither mutant induced the synthesis of NCVP1a or a complete complement of capsid proteins after infection, cells infected with DX particles produced two novel proteins, which had molecular weights of approximately 68,000 and 25,000.     

Host function-dependent induction of defective interfering particles of vesicular stomatitis virus.

Suppression of host cell function by treatment with actinomycin D prior to infection prevented the induction of defective interfering particles of vesicular stomatitis virus, which had been cloned and propagated in cell pretreated with actinomycin D. Replication of defective interfering particles already present in an infecting virus stock, however, was not affected by pretreatment of cells with actinomycin D. Thus, the induction, but not the replication, of defective interfering particles appears to be a host cell function-dependent phenomenon. The implications of this phenomenon for host defense mechanisms against virus infections are discussed.     

Structure of the intracellular defective viral RNAs of defective interfering particles of mouse hepatitis virus.

The intracellular defective RNAs generated during high-multiplicity serial passages of mouse hepatitis virus JHM strain on DBT cells were examined. Seven novel species of single-stranded polyadenylic acid-containing defective RNAs were identified from passages 3 through 22. The largest of these RNAs, DIssA (molecular weight [mw], 5.2 X 10(6)), is identical to the genomic RNA packaged in the defective interfering particles produced from these cells. Other RNA species, DIssB1 (mw, 1.9 X 10(6) to 1.6 X 10(6)), DIssB2 (mw, 1.6 X 10(6)), DIssC (mw, 2.8 X 10(6)) DIssD (mw, 0.82 X 10(6)), DIssE (mw, 0.78 X 10(6)), and DIssF (mw, 1.3 X 10(6)) were detected at different passage levels. RNase T1-resistant oligonucleotide fingerprinting demonstrated that all these RNAs were related and had multiple deletions of the genomic sequences. They contained different subsets of the genomic sequences from those of the standard intracellular mRNAs of nondefective mouse hepatitis virus JHM strain. Thus these novel intracellular viral RNAs were identified as defective interfering RNAs of mouse hepatitis virus JHM strain. The synthesis of six of the seven normal mRNA species specific to mouse hepatitis virus JHM strain was completely inhibited when cells were infected with viruses of late-passage levels. However, the synthesis of RNA7 and its product, viral nucleoprotein, was not significantly altered in late passages. The possible mechanism for the generation of defective interfering RNAs was discussed.     

Mokola virus glycoprotein and chimeric proteins can replace rabies virus glycoprotein in the rescue of infectious defective rabies virus particles.

A reverse genetics approach which allows the generation of infectious defective rabies virus (RV) particles entirely from plasmid-encoded genomes and proteins (K.-K. Conzelmann and M. Schnell, J. Virol. 68:713-719, 1994) was used to investigate the ability of a heterologous lyssavirus glycoprotein (G) and chimeric G constructs to function in the formation of infectious RV-like particles. Virions containing a chloramphenicol acetyltransferase (CAT) reporter gene (SDI-CAT) were generated in cells simultaneously expressing the genomic RNA analog, the RV N, P, M, and L proteins, and engineered G constructs from transfected plasmids. The infectivity of particles was determined by a CAT assay after passage to helper virus-infected cells. The heterologous G protein from Eth-16 virus (Mokola virus, lyssavirus serotype 3) as well as a construct in which the ectodomain of RV G was fused to the cytoplasmic and transmembrane domains of the Eth-16 virus G rescued infectious SDI-CAT particles. In contrast, a chimeric protein composed of the amino-terminal half of the Eth-16 virus G and the carboxy-terminal half of RV G failed to produce infectious particles. Site-directed mutagenesis was used to convert the antigenic site III of RV G to the corresponding sequence of Eth-16 G. This chimeric protein rescued infectious SDI-CAT particles as efficiently as RV G. Virions containing the chimeric protein were specifically neutralized by an anti-Eth-16 virus serum and escaped neutralization by a monoclonal antibody directed against RV antigenic site III. The results show that entire structural domains as well as short surface epitopes of lyssavirus G proteins may be exchanged without affecting the structure required to mediate infection of cells.     

Inhibition of pseudorabies virus replication by vesicular stomatitis virus. II Activity of defective interfering particles.

Purified defective interfering (DI) particles of vesicular stomatitis virus (VSV) inhibit the replication of a heterologous virus, pseudorabies virus (PSR), in hamster (BHK-21) and rabbit (RC-60) cell lines. In contrast to infectious B particles of VSV, UV irradiation of DI particles does not reduce their ability to inhibit PSR replication. However, UV irradiation progressively reduces the ability of DI particles to cause homologous interference with B particle replication. Pretreatment with interferon does not affect the ability of DI particles to inhibit PSR replication in a rabbit cell line (RC-60) in which RNA, but not DNA, viruses are sensitive to the action of interferon. Under similar conditions of interferon pretreatment, the inhibition of PSR by B particles is blocked. These data suggest that de novo VSV RNA or protein synthesis is not required for the inhibition of PSR replication by DI particles. DI particles that inhibit PSR replication also inhibit host RNA and protein synthesis in BHK-21 and RC-60 cells. Based on the results described and data in the literature, it is proposed that the same component of VSV B and DI particles is responsible for most, if not all, of the inhibitory activities of VSV, except homologous interference.     

Continuing coevolution of virus and defective interfering particles and of viral genome sequences during undiluted passages: virus mutants exhibiting nearly complete resistance to formerly dominant defective interfering particles

We quantitatively analyzed the interference interactions between defective interfering (DI) particles and mutants of cloned vesicular stomatitis virus passaged undiluted hundreds of times in BHK-21 cells. DI particles which predominated at different times in these serial passages always interfered most strongly (and very efficiently) with virus isolated a number of passages before the isolation of the DI particles. Virus isolated at the same passage level as the predominant DI particles usually exhibited severalfold resistance to these DI particles. Virus mutants (Sdi- mutants) isolated during subsequent passages always showed increasing resistance to these DI particles, followed by decreasing resistance as new DI particles arose to predominate and exert their own selective pressures on the virus mutant population. It appears that such coevolution of virus and DI particle populations proceeds indefinitely through multiple cycles of selection of virus mutants resistant to a certain DI particle (or DI particle class), followed by mutants resistant to a newly predominant DI particle, etc. At the peak of resistance, virus mutants were isolated which were essentially completely resistant to a particular DI particle; i.e., they were several hundred thousand-fold resistant, and they formed plaques of normal size and numbers in the presence of extremely high multiplicities of the DI particle. However, they were sensitive to interference by other DI particles. Recurring population interactions of this kind can promote rapid virus evolution. Complete sequencing of the N (nucleocapsid) and NS (polymerase associated) genes of numerous Sdi- mutants collected at passage intervals showed very few changes in the NS protein, but the N gene gradually accumulated a series of stable nucleotide and amino acid substitutions, some of which correlated with extensive changes in the Sdi- phenotype. Likewise, the 5' termini (and their complementary plus-strand 3' termini) continued to accumulate extensive base substitutions which were strikingly confined to the first 47 nucleotides. We also observed addition and deletion mutations in noncoding regions of the viral genome at a level suggesting that they probably occur at a high frequency throughout the genome, but usually with lethal or debilitating consequences when they occur in coding regions.     

In vitro construction of poliovirus defective interfering particles.

To construct poliovirus defective interfering (DI) particles in vitro, we synthesized an RNA from a cloned poliovirus cDNA, pSM1(T7)1, which carried a deletion in the genome region corresponding to nucleotide positions 1663 to 2478 encoding viral capsid proteins, by using bacteriophage T7 RNA polymerase. The RNA was designed to retain the correct reading frame in nucleotide sequence downstream of the deletion. HeLa S3 monolayer cells were transfected with the deletion RNA and then superinfected with standard virus as a helper. The DI RNA was observed in the infected cells after three passages at high multiplicity of infection. The sequence analysis of RNA extracted from the purified DI particle clearly showed that this DI RNA had the same deletion in size and location as that in the RNA used for the transfection. Thus, we succeeded in construction of a poliovirus DI particle in vitro. To gain insight into the mechanism for DI generation, we constructed poliovirus cDNAs pSM1(T7)1a and pSM1(T7)1b that, in addition to the same deletion as that in pSM1(T7)1, had insertion sequences of 4 bases and 12 bases, respectively, at the corresponding nucleotide position, 2978. The RNA transcribed from pSM1(T7)1a was not a template for synthesis of poliovirus nonstructural proteins and therefore was inactive as an RNA replicon. On the other hand, the RNA from pSM1(T7)1b replicated properly in the transfected cells. Superinfection of the transfected cells with standard virus resulted in production of DI particles derived from pSM1(T7)1b and not from pSM1(T7)1a. These observations indicate that deletion RNAs that are inactive replicons have little or no possibility of being genomes of DI particles suggesting the existence of a nonstructural protein(s) that has an inclination to function as a cis-acting protein(s). The method described here will provide a useful technique to investigate genetic information essential for poliovirus replication.     

Molecular basis for interference of defective interfering particles of pseudorabies virus with replication of standard virus.

Serial passage of pseudorabies virus (PrV) at high multiplicity yields defective interfering particles (DIPs), but the sharp cyclical increases and decreases in titer of infectious virus that are observed upon continued passage at high multiplicity of most DIPs of other viruses are not observed with DIPs of PrV (T. Ben-Porat and A. S. Kaplan, Virology 72:471-479). We have studied the dynamics of the interactions of the virions present in a population of DIPs to assess the cis functions for which the genomes of the DIPs are enriched. The defective genomes present in one population of DIPs, [PrV(1)42], replicate preferentially over the nondefective genomes present in that virion population at early stages of infection, indicating that the DIP DNA is enriched for sequences that can serve as origins of replication at early stages of infection. This replicative advantage of the DIP DNA is transient and disappears at later stages of infection. The defective DNA does not appear to be encapsidated preferentially over the nondefective DNA present in this virion population, which might indicate that it is not enriched for cleavage-encapsidation sites. However, the nondefective DNA in the DIP virion population has become modified and has acquired reiterations of sequences originating from the end of the unique long (UL) region of the genome. Furthermore, both the infectious and defective genomes present in the DIP population compete for encapsidation more effectively than do the genomes of standard PrV. These results indicate that the defective genomes in the population of virions studied are enriched not only for an origin of replication but probably also for sequences necessary for efficient cleavage-encapsidation. Furthermore, the nondefective genomes present in this population of DIPs have also been modified and have acquired the ability to compete with the defective genomes for cleavage-encapsidation.     

Within-host spatial dynamics of viruses and defective interfering particles

Defective-interfering (DI) viruses arise spontaneously by deletion mutations. The shortened genomes of the DI particles cannot replicate unless they coinfect a cell with a wild-type virus. Upon coinfection, the DI genome replicates more quickly and outcompetes the wild type. The coinfected cell produces mostly DI viruses. At the population level, the abundances of DI and wild-type viruses fluctuate dramatically under some conditions. In other cases, the DI viruses appear to mediate persistent infections with relatively low levels of host cell death. This moderation of viral damage has led some to suggest DI particles as therapeutic agents. Previous mathematical models have shown that either fluctuation or persistence can occur for plausible parameter values. I develop new mathematical models for the population dynamics of DI and wild-type viruses. My work extends the theory by developing specific predictions that can be tested in the laboratory. These predictions, if borne out by experiment, will explain the key processes that control the diversity of observed outcomes. The most interesting prediction concerns the rate at which killed host cells are replaced. A low rate of replacement causes powerful epidemics followed by a crash in viral abundance. As the rate of replacement increases, the frequency of oscillations increases in DI and wild-type viral abundances, but the severity (amplitude) of the fluctuations declines. At higher replacement rates for host cells, nearly all cells become infected by DI particles and a low level of fluctuating, wild-type viremia persists.     

Characterization of a new isolate of poliovirus defective interfering particles.

An independent isolate of poliovirus defective interfering particles has been analyzed. These particles, designated DI(A), are apparently analogous to the DI particles described by Baltimore and co-investigators. Electron microscopic heteroduplex analysis reveals that the DI(A) isolate is a mixture of deletion mutants which changes with passage level. The DI(A) population consists of at least five distinct deletion mutants, including one double deletion. Electron microscopic mapping of the deleted regions indicates that most, if not all, of the viral capsid region can be deleted. Despite this heterogeneity, the mutant genomes are quite similar in physical size. We propose a model which suggests that the observed properties of poliovirus DI genomes reflect selective pressures extant during the amplification of the mutant genome. According to this model, only those deleted genomes which retain a minimal size and the capacity to synthesize a functional viral polymerase will replicate successfully in a mixed infection. Furthermore, this model proposes a mechanism for the enrichment of poliovirus DI genomes and an explanation for the low level of complementation observed in mixed infections of picornaviruses.     

Generation of measles virus defective interfering particles and their presence in a preparation of attenuated live-virus vaccine.

By starting from a thrice-purified wild-type measles virus plaque, the generation of detectable subgenomic RNAs was achieved within a series of five serial infections of Vero cells. The evolution of these subgenomic RNAs was followed for seven serial passages and ended with the preparation of a highly interfering viral stock. On the other hand, the detection of discrete subgenomic RNAs was achieved during the first infection of Vero cells with at least one of three measles virus vaccine preparations tested. These subgenomic RNAs, which interfered very efficiently with the replication of the endogenous standard genomes upon vaccine infection but showed a moderate interfering activity with a standard virus stock derived by plaque purification from the vaccine preparation, resulted from the presence of defective interfering particles in the vaccine preparation. The relevance of this finding for the attenuation, stability, and potential capacity for persistent infection of such a vaccine is discussed.     

Defective interfering virus particles modulate virulence.

To determine whether defective interfering (DI) particles modulate virulence by initiating a cyclic pattern of virus growth in vivo, adult mice were infected with vesicular stomatitis virus (VSV), both with and without DI particles. A total of 184 mice divided into groups were inoculated intranasally. A majority of mice inoculated only with standard VSV developed paralysis, most of them between days 7 and 9. The addition of DI particles altered the development of paralysis in several ways. When there was significant protection, a few still became paralyzed on days 7 and 9. When overall mortality was unaffected or even slightly increased, the majority of mice became paralyzed between days 7 and 9 as well. Protection could not be predicted based on a single ratio of standard VSV to DI particles or on the absolute amount of DI particles inoculated. Infectious virus recovered from mouse brains at the time of paralysis and incipient death showed considerable variation, although the titer in a majority of the animals was between 10(5) and 10(7) PFU/ml. When the brains of these paralyzed mice were examined for hybridizable VSV RNA, the detection of standard VSV RNA correlated well with infectivity. The amount of DI RNA in the coinfected mice was more variable and independent of the amount of 40S RNA, although DI RNA was usually found when standard RNA was present. Survivors examined between days 14 and 21 did not contain infectious virus or any detectable viral RNA in their brains. Because these results were consistent with the hypothesis of viral cycling in vivo, rather than a gradual accumulation of total infectious virus, mice were coinfected with 10(8) PFU of standard VSV and 10(5) PFU equivalents of DI particles and sacrificed daily thereafter, irrespective of whether they developed paralysis. Infectivity measurements indicated a reproducible cycling pattern of VSV in the mouse brains with a periodicity of about 5 days. This cycling and the detection of DI RNA in brains several days after intranasal inoculation suggest that there is a dynamic continuous interaction between standard VSV and its DI particle beyond the initial site of replication as the virus population spreads into the host animal. Such cycling of virus production before the full development of specific immune responses from the host may have important implications for viral diagnostics and disease transmission.     

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.     

In vivo proteins of defective interfering particles of poliovirus

DX particles of poliovirus are deletion mutants that do not induce synthesis of capsid proteins or the precursor of capsid proteins (NCVPla) during infection. However, cells infected with DX particles synthesize two proteins, p68 and p25, that are not detected during growth of standard virus, and a protein of 27 000 (p27) which is comparable in molecular weight to VP3. Peptide maps of these proteins were obtained by partial digestion with Staphylococcus aureus V8 protease and elastase. The peptide map of p68 corresponded approximately 70% with the peptide map of NCVPla, and antiserum against virions reacted with p68. These data suggest that p68 is a large fragment of NCVPla. Digestion of purified structural proteins VP1, VP2, and VP3 yielded distinct peptide maps, but p25 was resistant to both V8 protease and elastase and did not react noticeably with anticapsid antibody. Peptide maps obtained for in vivo viral proteins migrating with a molecular weight of 27 000 were complex, indicating the presence of at least two and possibly three proteins. Cells infected with standard gs and gr viruses produced authentic VP3, but cells infected with defective interfering particles did not. However, one gr variant of standard virus contained a mutation in structural protein VP2.     

Comparison of ribonucleotide sequences from the genome of vesicular stomatitis virus and two of its defective interfering particles.

RNA genomes from standard vesicular stomatitis virus and two defective interfering (DI) particles dI 0.33 (DI-T) and DI 0.52, were purified and digested with RNase T1. The resulting oligonucleotides were labeled at the 5' end with [32P]ATP and separated by two-dimensional electrophoresis in polyacrylamide gels. All of the major oligonucleotides containing 20 or more nucleotides were sequenced. Those oligonucleotides that were thought to be in common by their migration on polyacrylamide gels actually did have identical sequences. Those oligonucleotides thought to be unique to the DI RNAs either differed by only one nucleotide from oligonucleotides of the standard RNA or contained new sequences which were complementary to known sequences at the 5' end. These data indicate that RNAs from DI particles are not simple deletions but contain point mutations and additional complementary sequences.