The antiviral activity exerted by vaccinia virus on the growth of herpes simplex virus in BS-C-1 cells.

The growth of herpes simplex virus type 2 (HSV-2) in BS-C-1 cells, was inhibited following super-infection with vaccinia virus. This inhibition was efficiently induced by both the intracellular mature virus (IMV) form of vaccinia virus and the extracellular enveloped virus (EEV), containing an additional external viral membrane. Treatment of vaccinia IMV with the detergents NP-40, Brij-58 or n-octyl-alpha-D-glucopyranoside, abolished its ability to inhibit the growth of HSV-2. Ultraviolet irradiation of vaccinia virus, that completely inactivated the infectivity of the virus, resulted in partial loss of the capability to inhibit the growth of HSV-2: 16-fold more irradiated virus was needed for the inhibition. Electron microscopy showed that the irradiated vaccinia virus adsorbed and penetrated into the HSV-infected cells but remained morphologically intact within the cells for at least 22 h. When the steps in the growth of HSV affected by the irradiated vaccinia virus were followed, it was found that while the synthesis of HSV DNA was partially decreased, the synthesis of HSV proteins was very strongly inhibited and virus particles were not formed.

Mechanism of interference between influenza A/WSN and B/Kanagawa viruses.

Simultaneous infection of MDCK cells with influenza viruses A/WSN and B/Kanagawa resulted in mutual interference with virus protein synthesis and in significant suppression of A/WSN growth. When infection by one virus preceded the other by 1 or 2 h, growth of the superinfecting virus was selectively inhibited at the level of transcription. Interference by the pre-infecting virus was strongly dependent on the expression of the viral genome but not on haemagglutinin activity. When the replication of both virus types was restricted to primary transcription by cycloheximide, the only translation products following removal of the drug were those of the preinfecting virus. This result was not affected by blocking secondary transcription by actinomycin D. These findings suggest that intertypic interference occurs at the level of primary transcription. This concept was supported further by the observation that a ts mutant of A/WSN (ts-65) with a defect in primary transcription interfered only with superinfection by B/Kanagawa at the permissive temperature.

Mediators of protection against lethal systemic vesicular stomatitis virus infection in hamsters: defective interfering particles, polyinosinate-polycytidylate, and interferon.

Homologous defective interfering (DI) particles protected adult Syrian hamsters against lethal systemic infection with vesicular stomatitis virus (VSV) serotype Indiana. The DI particles had to be biologically active, but did not have to be administered at the same inoculation site as the infectious virus. Serum and tissue levels of VSV postinoculation were significantly lower in DI-protected animals than in unprotected controls, suggesting that true autointerference was occurring. However, some aspects of protection also must be mediated through nonspecific mechanisms, since susceptible hamsters could be protected against VSV Indiana by coinjection with heterologous DI particles prepared from VSV serotype New Jersey or by simultaneous administration of polyinosinic acid-polycytidylic acid. By measuring serum levels of putative hamster interferon (type 1), we found that animals coinjected with VSV and DI particles or polyinosinic acid-polycytidylic acid produced significant levels of interferon. Since similarly high serum levels of interferon were measured in recipients of VSV alone (animals that eventually died from infection), there appeared to be no correlation between protection against lethal disease and induced levels of serum interferon. Instead, serum interferon levels correlated positively with amounts of VSV PFU found in serum and tissues of infected animals, the lowest levels being found in serum of animals protected with homologous DI particles. The data are consistent with the hypothesis that autointerference by DI particles as well as various host defense mechanisms (possibly including induction of interferon) participates in protecting hamsters against lethal VSV infection.

Interference between virulent and avirulent strains of Sendai virus.

Interference between a virulent and an avirulent strain of Sendai virus was studied by plaque morphology and analysis of viral protein and RNA. On simultaneous infection a virulent, large plaque-forming strain (RL) was inhibited by an avirulent, small plaque-forming strain (RS). The interference was dose-dependent and decreased with u.v. irradiation of RS. One infectious particle was sufficient to induce the interference. SDS-polyacrylamide gel electrophoresis showed that interference was detectable in the synthesis of viral P protein; this was abolished when RS was u.v.-irradiated. Both growth and P protein synthesis of RL was restricted by superinfection with RS when this was done within 4 h after infection of RL, but the interference decreased gradually after this period and was not detectable after 8 h. Cycloheximide prolonged the period susceptible to superinfection by RS.

Inactivation by u.v.-irradiation of interfering herpes simplex virus particles: interference requires a functional genome.

The sensitivity of interfering herpes simplex virus (HSV) particles to u.v.-irradiation was studied in a virus stock of HSV-1 strain ANG that contained an excess of interfering over infectious particles. Following u.v.-irradiation, samples of this virus stock were assayed for their plaque-forming capacity and their capacity to interfere with the replication of unirradiated standard virus. Depending on the assay conditions, interfering particles appeared to be less, equally, or more sensitive to u.v. light than infectious particles. It is concluded that interference is a gene function of interfering particles rather than being exerted directly by structural constituents of these particles.

[Interrelationships between the interfering capacity of an "incomplete" virus and its infectivity]. / Vzaimootnosheniia mezhdu interferiruiushchei sposobnost'iu "nepolnogo" virusa grippa i infektsionnost'iu.

A comparative analysis of UV inactivation curves of the interfering activity of "incomplete" influenza virus and infectivity showed certain differences in the structures responsible for these functions. All the data exclude the role of virus protein and virus-induced interferon of "incomplete" influenza virus and suggest that RNA is responsible for this interference. The size of the "target" of the "incomplete" virus interfering capacity calculated on the basis of sensitivity to UV-light is approximately 40 times as small as that of the "target" responsible for infectivity. The analogous pattern of UV inactivation in the standard influenza virus and the so-called Magnus virus suggests that in the latter the infectivity is due to the presence of complete virions in the preparation.

Defective interfering particles of parvovirus H-1.

Defective interfering particles of the parvovirus H-1 were produced by serial propagation at high multiplicities of infection. Such particles interfere with the synthesis of capsid proteins and infectious virus of standard H-1. The interference is sensitive to UV irradiation, dependent on the multiplicity of the challenge virus, and is active in heterotypic infections against parvovirus H-3 or LuIII. Defective interfering particle genomes have alterations characterized by integral numbers (1 to 10 or more) of a 60-base-pair addition in the neighborhood of the origin of replicative-form DNA replication and deletions that are located primarily within two regions, 32 to 44 or 80 to 90 on the genome map. Some of the implications of these findings are discussed.

Inhibitory effect of herpes simplex virus type 1 on type 2 virus replication.

Simultaneous infection with herpes simplex type I and type 2 viruses of chick embryo fibroblasts (CEF), which are only permissive for type 2 virus, or rabbit embryo fibroblasts (REF), which are permissive for both virus types, resulted in a marked reduction of type 2 virus production. This effect was dependent on the m.o.i. of type I, being expressed at a high rather than a low m.o.i. The rate of interference decreased with the prolongation of the interval between infection with type 2 and type I viruses. No evidence suggestive of interferon involvement was obtained. Partial inactivation of type 2 virus by ultraviolet irradiation enhanced the inhibitory effect of type I virus. On the other hand, u.v. irradiation of type I virus resulted in a progressive loss of inhibitory activity. The results of the present experiments suggest that a type I genome function is responsible for the interfering effect, and that an early step in the growth of type 2 virus is sensitive to the particular type I virus product involved.

Homologous interference induced by a temperature-sensitive mutant derived from an HVJ (Sendai virus) carrier culture.

Homologous interference between a temperature-sensitive small plaque mutant (HVJ-pB) derived from an HVJ (haemagglutinating virus of Japan - the Sendai strain of parainfluenza I virus) carrier culture of BHK cells and the original wild-type virus (HVJ-W) has been investigated. Prior infection of LLCMK2, HeLa, BHK or mouse L cells with HVJ-pB, both at permissive and non-permissive temperatures, for 24 h resulted in a reduced yield of superinfecting HVJ-W, reflecting a smaller number of cells capable of producing the superinfecting virus. However, HVJ-pB did not interfere with the replication of vesicular stomatitis virus, Sindbis virus or Newcastle disease virus. Interference in this system seems to be due to inhibition of the attachment of superinfecting HVJ-W as a result of intracellular mechanisms operating at a late stage in the replication of the interfering virus. There is also blocking or destruction of cellular receptors by extra-cellular particles of the interfering virus. Protein synthesis coded for by the complete virus genome is required to establish and maintain the interference, and treatment with actinomycin D has no effect on the interference phenomenon.

Inhibition of pseudorabies virus replication by vesicular stomicles virus I. Activity of infectious and inactivated B particles.

Infectious B particles of vesicular stomatitis virus (VSV) are capable of inhibiting the replication of pseudorabies virus (PSR) in a variety of cell lines. Even under conditions of an abortive infection in a continuous line of rabbit cornea cells (RC-6O), B particles interfere with the replication of PSR with high efficiency. Particle per cell dose-response analysis of B particle populations revealed that the number of VSV particles capable of inhibiting PSR replication exceeds the number of PFU by a factor of 32 to 64. When B particles are treated with UV irradiation, a drastic increase in the multiplicity of infection is required to inhibit PSR replication. Whereas one infective B particles per cell is sufficient to prevent replication of PSR, 800 to 1,000 VSV particles rendered noninfective by UV irradiation are required to compensate for the loss of VSV synthetic activity that results from irradiation. Temperature-sensitive mutants representing five complementation groups of VSV were tested at low multiplicities of infection for their effect on PSR replication at the nonpermissive temperature. Generally, the ability of the different complementation groups to amplify virion products at the nonpermissive temperature is associated with their ability to inhibit PSR replication. These results imply that at low multiplicities of infection, amplification of infecting VSV components is necessary for inhibition of PSR replication., but at high multiplicities of infection with VSV, a virion component can prevent PSR replication in the absence of de novo VSV RNA or protein synthesis.

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.

Homologous interference induced by Sindbis virus.

Homologous interference during Sindbis virus infection has been investigated. Prior infection of either chicken embryo fibroblast or BHK(21) cell cultures results in reduced yields of progeny virions of the superinfecting genotype. This reduction in yield results from a reduction in the number of cells in the cultures capable of producing the superinfecting genotype. The development of interference parallels the attachment kinetics of Sindbis virus. Interference requires an active viral genome since the activity is sensitive to inactivation by ultraviolet light, and an RNA(-) mutant, ts-24, fails to induce interference under nonpermissive conditions. However, ts-6, an RNA(-) mutant belonging to a different complementation group, and the RNA(+) mutants, ts-2 and ts-20, interfere at both permissive and nonpermissive temperatures.