Defective interfering influenza viruses and host cells: establishment and maintenance of persistent influenza virus infection in MDBK and HeLa cells.

WSN (H0N1) influenza virus upon undiluted passages in different species of cells, namely, bovine kidney (MDBK), chicken embryo (CEF), and HeLa cells, produced a varying amount of defective interfering (DI) virus which correlated well with the ability of the species of cell to produce infectious virus. However, the nature of the influenza DI viral RNA produced from a single clonal stock was essentially identical in all three cells types, suggesting that these cells do not exert a great selective pressure in the amplification of specific DI viral RNAs either at early or late passages. DI viruses produced from one subtype (H0N1) could interfere with the replication of infectious viruses belonging to other subtypes (H1N1, H3N2). DI viral RNAs could also replicate with the helper function of other subtype viruses. The persistent infection of MDBK and HeLa cells could be initiated by coinfecting cells with both temperature-sensitive mutants (ts-) and DI influenza viruses. Persistently infected cultures cultures at early passages (up to passage 7) showed a cyclical pattern of cell lysis and virus production (crisis), whereas, at later passages (after passage 20), they produced little or no virus and were resistant to infection by homologous virus but not by heterologous virus. The majority of persistently infected cells, however, contained the complete viral genome since they expressed viral antigens and produced infectious centers. Selection of a slow-growing temperature-sensitive variant rather than the presence of DI virus or interferon appears to be critical in maintaining persistent influenza infection in these cells.     

Complex dynamics of defective interfering baculoviruses during serial passage in insect cells

Defective interfering (DI) viruses are thought to cause oscillations in virus levels, known as the ‘Von Magnus effect’. Interference by DI viruses has been proposed to underlie these dynamics, although experimental tests of this idea have not been forthcoming. For the baculoviruses, insect viruses commonly used for the expression of heterologous proteins in insect cells, the molecular mechanisms underlying DI generation have been investigated. However, the dynamics of baculovirus populations harboring DIs have not been studied in detail. In order to address this issue, we used quantitative real-time PCR to determine the levels of helper and DI viruses during 50 serial passages of Autographa californica multiple nucleopolyhedrovirus (AcMNPV) in Sf21 cells. Unexpectedly, the helper and DI viruses changed levels largely in phase, and oscillations were highly irregular, suggesting the presence of chaos. We therefore developed a simple mathematical model of baculovirus-DI dynamics. This theoretical model reproduced patterns qualitatively similar to the experimental data. Although we cannot exclude that experimental variation (noise) plays an important role in generating the observed patterns, the presence of chaos in the model dynamics was confirmed with the computation of the maximal Lyapunov exponent, and a Ruelle-Takens-Newhouse route to chaos was identified at decreasing production of DI viruses, using mutation as a control parameter. Our results contribute to a better understanding of the dynamics of DI baculoviruses, and suggest that changes in virus levels over passages may exhibit chaos.     

Bovine viral diarrhea virus: characterization of a cytopathogenic defective interfering particle with two internal deletions.

Molecular characterization of bovine viral diarrhea virus pair 13 revealed that isolate CP13 is composed of a cytopathogenic (cp) defective interfering particle (DI13) and a noncytopathogenic (noncp) helper virus. The DI13 genome possesses two internal deletions of 1,611 and 3,102 nucleotides. Except for a small fragment of the gene coding for glycoprotein E1, all structural protein genes are deleted together with most of the Npro gene, the region coding for nonstructural proteins p7 and NS2. While the amino terminus of NS3 seems to be strictly conserved for all other cp bovine viral diarrhea viruses, NS3 of DI13 is amino-terminally truncated and fused to 23 amino acids derived from Npro and E1. Characterization of the DI-helper virus system revealed a striking discrepancy between RNA production and generation of infectious viruses.     

Sequential addition of temperature-sensitive missense mutations into the PB2 gene of influenza A transfectant viruses can effect an increase in temperature sensitivity and attenuation and permits the rational design of a genetically engineered live influenza A virus vaccine.

We have previously described a strategy for the recovery of a synthetic influenza A virus wild-type (wt) PB2 gene (derived from influenza A/Ann Arbor/6/60 [AA] virus) into an infectious virus. It was possible to introduce an attenuating temperature-sensitive (ts) mutation at amino acid residue 265 of the AA wt PB2 gene and to rescue this mutant gene into infectious virus. Application of this new technology to influenza A virus vaccine development requires that multiple attenuating mutations be introduced to achieve a satisfactorily attenuated virus that retains the attenuation (att) phenotype following replication in vivo. In this report, we demonstrate that putative ts mutations at amino acids 112, 556, and 658 each indeed specify the ts and att phenotypes. Each of these mutations was introduced into a cDNA copy of the AA mutant mt265 PB2 gene to produce three double-mutant PB2 genes, each of which was rescued into an infectious virus. In general, the double-mutant PB2 transfectant viruses were more ts and attenuated in the lower respiratory tracts of hamsters than the single-mutant transfectant viruses, and the ts phenotype of two of three double-mutant PB2 transfectant viruses was stable even after prolonged replication in the upper respiratory tracts of immunocompromised mice. Two triple-mutant PB2 transfectant viruses with three predicted amino acid substitutions resulting from five nucleotide substitutions in the cDNA were then generated. The triple-mutant PB2 transfectant viruses were more ts and more attenuated than the double-mutant PB2 transfectant viruses. These results indicate that sequential introduction of additional ts mutations into the PB2 gene can yield mutants that exhibit a stepwise increase in temperature sensitivity and attenuation compared with the preceding mutant(s) in the series. Furthermore, the level of temperature sensitivity of the transfectant viruses correlated significantly with the level of attenuation of these viruses in hamsters. Although the triple-mutant PB2 transfectant viruses were attenuated in hamsters, intranasal administration of these viruses elicited a vigorous serum hemagglutination-inhibiting antibody response, and this was associated with resistance of the lower respiratory tract to subsequent wt virus challenge. These observations suggest the feasibility of using PB2 reverse genetics to generate a live influenza A virus vaccine donor strain that contains three attenuating mutations in one gene. It is predicted that reassortant viruses derived from such a donor virus would have the properties of attenuation, genetic stability, immunogenicity, and protective efficacy against challenge with wt virus.     

Segment-specific noncoding sequences of the influenza virus genome RNA are involved in the specific competition between defective interfering RNA and its progenitor RNA segment at the virion assembly step.

The generation of influenza A virus defective interfering (DI) particles was studied by using an NS2 mutant which produces, in a single cycle of virus replication, a large amount of DI particles lacking the PA polymerase gene. The decrease in PA gene replication has been shown to occur primarily at the cRNA synthesis step, with preferential amplification of PA DI RNA species present in a marginal amount in the virus stock. In addition, at the assembly step the PA DI RNAs were preferentially incorporated into virions, resulting in selective reduction in the packaging of the PA gene into virions. Similarly, in cells dually infected with the NS2 mutant and wild-type viruses, packaging of the wild-type PA gene was also greatly suppressed. In contrast, incorporation of other RNA segments, i.e., the PB2 and NS genes, was not affected, suggesting that the PA DI RNAs competed only with the PA gene in a segment-specific manner. Experiments involving rescue of recombinant chloramphenicol acetyltransferase (CAT) RNA flanked by the noncoding regions of the PA (PA/CAT RNA) and PB2 (PB2/CAT RNA) genes into viral particles showed that only PA/CAT RNA was not rescued by infection with the NS2 mutant virus containing the PA DI RNAs. However, recombinant PA/CAT RNA in which either the 3' or 5' noncoding region was replaced with that of the PB2 gene was rescued by the NS2 mutant. These results suggest that the noncoding regions of the PA gene are responsible for the competition with PA DI RNA species at the virus assembly step and that coexistence of the both noncoding regions would be a prerequisite for this phenomenon. Decreased packaging of the progenitor RNA by the DI RNA, in addition to the suppression of cRNA synthesis, is likely involved in the production of DI particles.     

Defective Interfering Influenza Virus RNAs: Time To Reevaluate Their Clinical Potential as Broad-Spectrum Antivirals?

Defective interfering (DI) RNAs are highly deleted forms of the infectious genome that are made by most families of RNA viruses. DI RNAs retain replication and packaging signals, are synthesized preferentially over infectious genomes, and are packaged as DI virus particles which can be transmitted to susceptible cells. Their ability to interfere with the replication of infectious virus in cell culture and their potential as antivirals in the clinic have long been known. However, until now, no realistic formulation has been described. In this review, we consider the early evidence of antiviral activity by DI viruses and, using the example of DI influenza A virus, outline developments that have led to the production of a cloned DI RNA that is highly active in preclinical studies not only against different subtypes of influenza A virus but also against heterologous respiratory viruses. These data suggest the timeliness of reassessing the potential of DI viruses as a novel class of antivirals that may have general applicability.     

Defective Influenza Viral Ribonucleoproteins Cause Interference

Ribonucleoproteins (RNPs) isolated from infectious and defective interfering (DI) influenza virus (WSN) contained three major RNP peaks when analyzed in a glycerol gradient. Peak I RNP was predominant in infectious virus but was greatly reduced in DI virus preparations. Conversely, peak III RNP was elevated in DI virus, suggesting a large increase in DI RNA in this fraction. Labeled [(32)P]RNA was isolated from each RNP region and analyzed by electrophoresis on polyacrylamide gels. Peak I RNP contained primarily the polymerase and some HA genes, peak II contained some HA gene but mostly the NP and NA genes, and peak III contained the M and NS genes. In addition, peak III RNP from DI virus also contained the characteristic DI RNA segments. Interference activity of RNP fractions isolated from infectious and DI virus was tested using infectious center reduction assay. RNP peaks (I, II, and III) from infectious virus did not show any interference activity, whereas the peak III DI RNP caused a reduction in the number of infectious centers as compared to controls. Similar interference was not demonstrable with peak I RNP of DI virus nor with any RNP fractions from infectious virus alone. The interference activity of RNP fractions was RNase sensitive, suggesting that the DI RNA contained in DI RNPs was the interfering agent, and dilution experiments supported the conclusion that a single DI RNP could cause interference. The interfering RNPs were heterogeneous, and the majority migrated slower than viral RNPs containing M and NS genes. These results suggest that DI RNP (or DI RNA) is also responsible for interference in segmented, negative-stranded viruses.     

Genetic engineering of rotaviruses by reverse genetics

The rotavirus genome is composed of 11 gene segments of dsRNA. A recent breakthrough in the field of rotaviruses is the development of a reverse genetics system for generating recombinant rotaviruses possessing a gene segment derived from cloned cDNA. Although this approach is a helper virus‐driven system that is technically limited and gives low levels of recombinant viruses, it allows alteration of the rotavirus genome, thus contributing to our understanding of these medically important viruses. So far, this approach has successfully been applied to three of the 11 viral segments in our laboratory and others, and the efficiency of recovery of recombinant viruses has been improved. However, we are still waiting for the development of a helper virus‐free reverse genetics system for generating an infectious rotavirus entirely from cDNAs, as has been achieved for other members of the Reoviridae family.     

Origin of the 1918 pandemic H1N1 influenza A virus as studied by codon usage patterns and phylogenetic analysis

The pandemic of 1918 was caused by an H1N1 influenza A virus, which is a negative strand RNA virus; however, little is known about the nature of its direct ancestral strains. Here we applied a broad genetic and phylogenetic analysis of a wide range of influenza virus genes, in particular the PB1 gene, to gain information about the phylogenetic relatedness of the 1918 H1N1 virus. We compared the RNA genome of the 1918 strain to many other influenza strains of different origin by several means, including relative synonymous codon usage (RSCU), effective number of codons (ENC), and phylogenetic relationship. We found that the PB1 gene of the 1918 pandemic virus had ENC values similar to the H1N1 classical swine and human viruses, but different ENC values from avian as well as H2N2 and H3N2 human viruses. Also, according to the RSCU of the PB1 gene, the 1918 virus grouped with all human isolates and "classical" swine H1N1 viruses. The phylogenetic studies of all eight RNA gene segments of influenza A viruses may indicate that the 1918 pandemic strain originated from a H1N1 swine virus, which itself might be derived from a H1N1 avian precursor, which was separated from the bulk of other avian viruses in toto a long time ago. The high stability of the RSCU pattern of the PB1 gene indicated that the integrity of RNA structure is more important for influenza virus evolution than previously thought.     

Four viral genes independently contribute to attenuation of live influenza A/Ann Arbor/6/60 (H2N2) cold-adapted reassortant virus vaccines.

Clinical studies previously demonstrated that live influenza A virus vaccines derived by genetic reassortment from the mating of influenza A/Ann Arbor/6/60 (H2N2) cold-adapted (ca) donor virus with epidemic wild-type influenza A viruses are reproducibly safe, infectious, immunogenic, and efficacious in the prevention of illness caused by challenge with virulent wild-type virus. These influenza A reassortant virus vaccines also express the ca and temperature sensitivity (ts) phenotypes in vitro, but the genes of the ca virus parent which specify the ca, ts, and attenuation (att) phenotypes have not adequately been defined. To identify the genes associated with each of these phenotypes, we isolated six single-gene substitution reassortant viruses, each of which inherited only one RNA segment from the ca parent virus and the remaining seven RNA segments from the A/Korea/1/82 (H3N2) wild-type virus parent. These were evaluated in vitro for their ca and ts phenotypes and in ferrets, hamsters, and seronegative adult volunteers for the att phenotype. We found that the polymerase PA gene of the ca parent specifies the ca phenotype and that the PB2 and PB1 genes independently specify the ts phenotype. The PA, M, PB2, and PB1 genes of the ca donor virus each contribute to the att phenotype. The finding that four genes of the ca donor virus contribute to the att phenotype provides a partial explanation for the observed phenotypic stability of ca reassortant viruses following replication in humans.     

Homologous interference mediated by defective interfering influenza virus derived from a temperature-sensitive mutant of influenza virus.

A temperature-sensitive group II mutant of influenza virus, ts-52, with a presumed defect in viral RNA synthesis, readily produced von Magnus-type defective interfering virus (DI virus) when passed serially (four times) at high multiplicity in MDBK cells. The defective virus (ts-52 DI virus) had a high hemagglutinin and a low infectivity titer, and strongly interfered with the replication of standard infectious viruses (both ts-52 and wild-type ts+) in co-infected cells. Progeny virus particles produced by co-infection of DI virus and infectious virus were also defective and also had low infectivity, high hemagglutinating activity, and a strong interfering property. Infectious viruses ts+ and ts-52 were indistinguishable from ts-52 DI viruses by sucrose velocity or density gradient analysis. Additionally, these viruses all possessed similar morphology. However, when the RNA of DI viruses was analyzed by use of polyacrylamide gels containing 6 M urea, there was a reduction in the amount of large RNA species (V1 to V4), and a number of new smaller RNA species (D1 to D6) with molecular weights ranging from 2.9 X 10(5) to 1.05 X 10(5) appeared. Since these smaller RNA species (D1 to D6) were absent in some clones of infectious viruses, but were consistently associated with DI viruses and increased during undiluted passages and during co-infection of ts-52 with DI virus, they appeared to be a characteristic of DI viruses. Additionally, the UV target size of interfering activity and infectivity of DI virus indicated that interfering activity was 40 times more resistant to UV irradiation than was infectivity, further implicating small RNA molecules in interference. Our data suggest that the loss of infectivity observed among DI viruses may be due to nonspecific loss of a viral RNA segment(s), and the interfering property of DI viruses may be due to interfering RNA segments (DIRNA, D1 to D6). ts-52 DI virus interfered with the replication of standard virus (ts+) at both permissive (34 degrees C) and nonpermissive temperatures. The infectivity of the progeny virus was reduced to 0.2% for ts+ and 0.05% for ts-52 virus without a reduction in hemagglutinin titer. Interference was dependent on the concentration of DI virus. A particle ratio of 1 between DI virus (0.001 PFU/cell) and infectious virus (1.0 PFU/cell) produced a maximal amount of interference. Infectious virus yield was reduced 99.9% without any reduction of the yield of DI viruses Interference was also dependent on the time of addition of DI virus. Interference was most effective within the first 3 h of infection by infectious virus, indicating interference with an early function during viral replication.     

广州地区新型H1N1流感病毒PB1-F2基因进化和变异分析

比较和分析2009～2011年广州地区分离到的甲型H1N1流感病毒PB1-F2基因和世界各地甲型H1N1流感病毒PB1-F2基因的变异情况,为该蛋白的功能和作用机制奠定基础。对分离自中国广州地区2009～2011年人类感染的17株新型H1N1和1株季节性H1N1流感病毒进行了PB1-F2基因克隆和序列测定,通过与GenBank数据库中68株人类新型H1N1和季节性H1N1流感病毒参考株的PB1-F2基因进行比对。结果表明,甲型流感病毒的PB1-F2基因进化树形成了2个不同的进化分支。全部2009～2011年新型H1N1流感病毒为一分支。广州地区PB1-F2基因与其它地区分离到的新型H1N1流感病毒具有高度的同源性,均为截短型变异。本实验室分离的1株季节性H1N1流感病毒也发生了第12位氨基酸截短突变。广州地区新型H1N1流感病毒PB1-F2截短蛋白与其它地区病毒相比未发生氨基酸变异,季节性H1N1流感病毒发现类似新型H1N1流感病毒PB1-F2的截短变异,提示新型H1N1流感病毒和季节性H1N1流感病毒PB1-F2可能发生早期重组。     

登革2型PrM基因的重组病毒对不同型别登革病毒复制的阻断作用

观察登革 2型PrM基因的pSFV重组甲病毒抗该型病毒的作用 ,进一步探讨登革 2型PrM基因的这种重组病毒对其它 3个血清型登革病毒复制的阻断作用 .采用体外转录和电穿孔 ,分别将构建的含正、反义PrM基因的重组质粒DNA和辅助载体DNA转录成RNA ,然后将这两种RNA共转染BHK细胞 ,进而包装成重组病毒颗粒 .再将激活的重组病毒感染细胞 ,分别用不同型病毒进行攻击 .然后通过免疫荧光法 ,观察对登革病毒复制的阻断作用 .结果表明 ,含登革 2型PrM基因的重组病毒不仅可阻断登革 2型病毒的复制 ,同样具有抑制其他 3个型病毒复制的能力 ,且抗登革 1、4型病毒的复制作用强于抗登革 3型病毒的作用 .用 10 3 TCID50 剂量的登革病毒攻击 ,含反义PrM基因的重组病毒可完全阻断登革 1、3、4型病毒的复制 .但含正义PrM基因的重组病毒对登革 3型病毒的复制不能完全阻断 .为探讨登革病毒防治新途径奠定了基础     

The D253N Mutation in the Polymerase Basic 2 Gene in Avian Influenza (H9N2) Virus Contributes to the Pathogenesis of the Virus in Mammalian Hosts

Mutations in the polymerase basic 2 (PB2) gene of avian influenza viruses are important signatures for their adaptation to mammalian hosts. Various adaptive mutations have been identified around the 627 and nuclear localization sequence (NLS) domains of PB2 protein, and these mutations contribute to the replicative ability of avian influenza viruses. However, few studies have focused on adaptive mutations in other regions of PB2. In this study, we investigated the functional roles of the D253N mutation in PB2 in an H9N2 virus. This mutation was found to affect an amino acid residue in the middle domain of the PB2 protein. The virus with the D253N mutation showed higher polymerase activity and transiently increased viral replication in human cells. However, the mutant did not show significant differences in viral replication in the respiratory tract of mice upon infection. Our results supported that the D253N mutation in the middle domain of PB2, similar to mutations at the 627 and NLS domains, specifically contributed to the replication of avian influenza viruses in human cells.     

Cloned Defective Interfering Influenza Virus Protects Ferrets from Pandemic 2009 Influenza A Virus and Allows Protective Immunity to Be Established

Influenza A viruses are a major cause of morbidity and mortality in the human population, causing epidemics in the winter, and occasional worldwide pandemics. In addition there are periodic outbreaks in domestic poultry, horses, pigs, dogs, and cats. Infections of domestic birds can be fatal for the birds and their human contacts. Control in man operates through vaccines and antivirals, but both have their limitations. In the search for an alternative treatment we have focussed on defective interfering (DI) influenza A virus. Such a DI virus is superficially indistinguishable from a normal virus but has a large deletion in one of the eight RNAs that make up the viral genome. Antiviral activity resides in the deleted RNA. We have cloned one such highly active DI RNA derived from segment 1 (244 DI virus) and shown earlier that intranasal administration protects mice from lethal disease caused by a number of different influenza A viruses. A more cogent model of human influenza is the ferret. Here we found that intranasal treatment with a single dose of 2 or 0.2 µg 244 RNA delivered as A/PR/8/34 virus particles protected ferrets from disease caused by pandemic virus A/California/04/09 (A/Cal; H1N1). Specifically, 244 DI virus significantly reduced fever, weight loss, respiratory symptoms, and infectious load. 244 DI RNA, the active principle, was amplified in nasal washes following infection with A/Cal, consistent with its amelioration of clinical disease. Animals that were treated with 244 DI RNA cleared infectious and DI viruses without delay. Despite the attenuation of infection and disease by DI virus, ferrets formed high levels of A/Cal-specific serum haemagglutination-inhibiting antibodies and were solidly immune to rechallenge with A/Cal. Together with earlier data from mouse studies, we conclude that 244 DI virus is a highly effective antiviral with activity potentially against all influenza A subtypes.     

Pathogenesis of mucosal disease: a cytopathogenic pestivirus generated by an internal deletion.

Cytopathogenic bovine viral diarrhea virus (BVDV) arises by RNA recombination in animals persistently infected with noncytopathogenic BVDV. Such animals develop fatal mucosal disease. In this report, the genome of a cytopathogenic BVDV isolate, termed CP9, is characterized. CP9-infected cells contained not only viral genomic RNA of 12.3 kb but also a BVDV-specific RNA of 8 kb. cDNA cloning and sequencing revealed that the 8-kb RNA is a BVDV genome with an internal deletion of 4.3 kb. The 8-kb RNA represents the genome of a typical defective interfering particle (DI), since its replication was strictly dependent on the presence of a helper virus and strongly interfered with the replication of the helper. Cell culture experiments demonstrated that the CP9 virus stock contains two viruses, namely, a helper virus and DI9. While the helper virus alone was noncytopathogenic, the presence of the DI conferred cytopathogenicity. Expression experiments demonstrated that p80, the marker protein of cytopathogenic BVDV, is translated from the defective genome. The occurrence of this cytopathogenic DI is linked to a fatal disease in cattle.     

Characterization of the Molecular Mechanism of Defective Interfering RNA-Mediated Symptom Attenuation in Tombusvirus-Infected Plants

Different tombusviruses were able to support the replication of either homologous or heterologous defective interfering (DI) RNAs, and those infected plants usually developed typical attenuated symptoms. However, in some helper virus-DI RNA combinations the inoculated plants were necrotized, although they contained a high level of DI RNA, suggesting that the accumulation of DI RNA and the resulting suppression of genomic RNA replication were not directly responsible for the symptom attenuation. Moreover, the 19-kDa protein product of ORF 5, which is known to play a crucial role in necrotic symptom development, accumulated at the same level in the infected plants in the presence of protective homologous DI RNA and in the presence of nonprotective heterologous DI RNA. It was also demonstrated, by chimeric helper viruses, that the ability of heterologous DI RNA to protect the virus-infected plants against systemic necrosis is determined by the 5′-proximal region of the helper virus genome. The results presented suggest that DI RNA-mediated protection did not operate via the specific inhibition of 19-kDa protein expression but, more likely, DI RNAs in protective DI-helper virus combinations specifically interacted with viral products, preventing the induction of necrotic symptoms.