Intrinsic Interference: a New Type of Viral Interference

The hemadsorption-negative plaque test has revealed a new type of viral interference, termed intrinsic interference. Several unrelated types of noncytopathic viruses were shown to induce in infected host cells a state of interference unique in being directed solely against superinfection by Newcastle disease virus (NDV). The NDV-refractory state arises only in those individual cells of a population actually infected by the inducing virus, and presumably results from the action of a protein(s) coded for by the viral genome. Thus, intrinsic interference differs fundamentally from that mediated by an extrinsic protein detectable under conditions favoring resistance to a broad spectrum of viruses and characteristic of interference induced by interferon, the latter being coded for by the cell genome. Intrinsic interference is defined as a viral genome-induced cellular state of resistance to challenge by high multiplicities of NDV, coexistent with a state of susceptibility to a broad spectrum of other viruses, similarly tested at high multiplicities. The capacity to induce intrinsic interference was demonstrated with rubella virus, Sindbis virus (arbovirus, group A), West Nile virus (arbovirus, group B), poliovirus (MEF, type 2), the lactic dehydrogenase virus (Riley's agent), and an unidentified nonhemadsorbing, noncytopathic adventitious virus. A state of intrinsic interference was also observed in the V5 line of mouse cells carrying a murine leukemia virus, probably resulting from some heretofore unsuspected contaminating virus. The molecular basis for intrinsic interference is not known, but it appears to involve a step in the NDV growth cycle beyond that of viral attachment, entry, and eclipse.     

Temperature-Sensitive Defect of Mutants Isolated from L Cells Persistently Infected with Newcastle Disease Virus

The temperature-sensitive defects of virus mutants isolated from L cells persistently infected with Newcastle disease virus (NDV) were analyzed. Genetic grouping of the mutants by complementation tests was attempted by using several different methods, including yield analysis, RNA synthesis, and heterozygote formation at 42 to 43 C, the nonpermissive temperature. In each case, specific interference prevented detection of complementation. This interference was shown to occur prior to or at the level of virus RNA synthesis. Temperature-shift experiments with five different NDV(pi) clones showed that virus replication begun at 37 C could not be completed at the nonpermissive temperature. The activity of the NDV-specific RNA-dependent RNA polymerase in the cytoplasm of infected chicken embryo cells was not stable and could not be demonstrated directly. However, indirect measurement of RNA polymerase activity at the nonpermissive temperature was accomplished by studying the kinetics of virus-specific RNA synthesis in infected cells after temperature shift. Two types of response were obtained: with three NDV(pi) clones, virus-specific RNA synthesis ceased immediately upon transfer of infected cells to 42 to 43 C, whereas in cells infected with two other NDV(pi) clones, RNA synthesis continued for several hours at this temperature. These results suggested that there may be two types of ts defects in NDV(pi), both associated with virus-specific RNA polymerase activity.     

Improvement of PVX/CMV CP expression tool for display of short foreign antigens

We have previously reported that Potato virus X-expressed coat protein of Cucumber mosaic virus (CMV) formed virus-like particles (VLPs), which served as carriers for display of different neutralizing epitopes of Newcastle disease virus (NDV). In this work, we further modified the purification protocol of recombinant VLPs carrying short neutralizing epitopes of the NDV proteins and demonstrated that self-contained capsid protein subunits of CMV transiently expressed from heterologous virus packaged into individual virions morphologically resembling and/or indistinguishable from wild type CMV particles. Homogeneity of the final preparation represents an advance over our previous study, where VLPs were found to be of variable size. Chickens immunized with purified VLPs developed antigen-specific response.     

Autophagy Benefits the Replication of Newcastle Disease Virus in Chicken Cells and Tissues

Newcastle disease virus (NDV) is an important avian pathogen. We previously reported that NDV triggers autophagy in U251 glioma cells, resulting in enhanced virus replication. In this study, we investigated whether NDV triggers autophagy in chicken cells and tissues to enhance virus replication. We demonstrated that NDV infection induced steady-state autophagy in chicken-derived DF-1 cells and in primary chicken embryo fibroblast (CEF) cells, evident through increased double- or single-membrane vesicles, the accumulation of green fluorescent protein (GFP)-LC3 dots, and the conversion of LC3-I to LC3-II. In addition, we measured autophagic flux by monitoring p62/SQSTM1 degradation, LC3-II turnover, and GFP-LC3 lysosomal delivery and proteolysis, to confirm that NDV infection induced the complete autophagic process. Inhibition of autophagy by pharmacological inhibitors and RNA interference reduced virus replication, indicating an important role for autophagy in NDV infection. Furthermore, we conducted in vivo experiments and observed the conversion of LC3-I to LC3-II in heart, liver, spleen, lung, and kidney of NDV-infected chickens. Regulation of the induction of autophagy with wortmannin, chloroquine, or starvation treatment affects NDV production and pathogenesis in tissues of both lung and intestine; however, treatment with rapamycin, an autophagy inducer of mammalian cells, showed no detectable changes in chicken cells and tissues. Moreover, administration of the autophagy inhibitor wortmannin increased the survival rate of NDV-infected chickens. Our studies provide strong evidence that NDV infection induces autophagy which benefits NDV replication in chicken cells and tissues.     

Cytomegalovirus-antibody-negative lymphocytes have increased permissiveness for human immunodeficiency virus

Synergistic activity between cytomegalovirus (CMV) and human immunodeficiency virus (HIV) was observed. In vitro, lymphocytes which were CMV-antibody-negative showed greater cytopathic effects due to HIV than those which were antibody-positive. These cytopathic effects included increased cell death and greater virus production. In vitro stimulation of host lymphocytes with CMV was found to be analogous to that of interleukin-2 stimulation in terms of HIV production and cytopathic effects.     

Partial antiviral activities of the Asn631 chicken Mx against newcastle disease virus and vesicular stomatitis virus

Conflicting data existed for the antiviral potential of the chicken Mx protein and the importance of the Asn631 polymorphism in determination of the antiviral activity. In this study we modified the chicken Mx cDNA from the Ser631 to Asn631 genotype and transfected them into COS-I cells, chicken embryonic fibroblast (CEF) or NIH 3T3 cells. The Mx protein was mainly located at the cytoplasm. The transfected cell cultures were challenged with newcastle disease virus (NDV) or vesicular stomatitis virus (VSV), cytopathic affect (CPE) inhibition assay showed that the times for development of visible and full CPE were significantly postponed by the Asn631 cDNA transfection at 48 h transfection, but not by the Ser631 cDNA transfection. Viral titration assay showed that the virus titers were significantly reduced before 72 h postinfection. CEF cells was incubated by the cell lysates extracted from the COS-I cells transfected with pcDNA-Mx/Asn631, could resist and delayed NDV infection. These data suggested the importance of the Asn631 polymorphism of the chicken Mx in determination of the antiviral activities against NDV and VSV at early stage of viral infection, which were relatively weak and not sufficient to inhibit the viral replication at late stage of viral infection.     

Microculture System for Detection of Newcastle Disease Virus Antibodies

A microculture system utilizing cytopathic effect (CPE) and hemadsorption (HAd) end points was effective in determining the level of Newcastle disease virus (NDV) antibodies. The microculture system was of comparable sensitivity to the plaque reduction test for the detection of NDV antibodies. The standards by which the CPE and HAd microculture tests would be considered reproducible were defined. The results indicate that the CPE and HAd microculture tests are reproducible within one twofold dilution.     

Distinct superinfection interference properties yet similar receptor utilization by cytopathic and noncytopathic feline leukemia viruses.

Cell killing by cytopathic retroviruses is often associated with a delay or failure in the establishment of superinfection interference. Superinfection has been observed during T-cell killing and fatal immunodeficiency disease induction by the feline leukemia virus (FeLV) chimera FeLV-FAIDS-EECC, containing the surface envelope glycoprotein (SU) of FeLV-FAIDS clone 61C. We demonstrate here that 61C SU has a defect that results in a nearly complete failure to establish superinfection interference against homologous virus challenge. This failure was evident only in feline T (FeT) cell clones expressing envelope protein, not in the rare cells that have survived cytopathic infection to become chronically infected. The regions of SU responsible for this defect were the same as those previously identified as responsible for T-cell killing. The superinfection interference properties of a noncytophatic molecular clone, FeLV-FAIDS-61E, were different in that 61E established interference to homologous virus challenge, both in SU-expressing cell clones and in chronically infected cells. Neither 61E nor EECC established interference against heterologous virus challenge. Viruses expressing chimeric SU proteins displayed varied and intermediate interference properties. Purified 61E and 61C SU competed for binding sites on FeT cell surfaces, and purified 61E SU blocked infection of virus bearing 61E or 61C SU. In addition, purified 61E and 61C SU each coprecipitated 70-kDa FeT cell surface proteins. Our data are consistent with the hypothesis that there are multiple cellular components necessary for 61E and 61C attachment to and penetration of FeT cells, a primary receptor that is utilized by both 61E and 61C, and secondary receptors that are likely to be virus specific.     

Establishment of rat brain endothelial cells susceptible to rat cytomegalovirus ALL-03 infection

Endothelial cells have been implicated as key cells in promoting the pathogenesis and spread of cytomegalovirus (CMV) infection. This study describes the isolation and culture of rat brain endothelial cells (RBEC) and further evaluates the infectious potential of a Malaysian rat CMV (RCMV ALL-03) in these cultured cells. Brain tissues were mechanically fragmented, exposed to enzymatic digestion, purified by gradient density centrifugation, and cultured in vitro. Morphological characteristics and expression of von Willebrand factor (factor VIII-related antigen) verified the cells were of endothelial origin. RBEC were found to be permissive to the virus by cytopathic effects with detectable plaques formed within 7 d of infection. This was confirmed by electron microscopy examination which proved the existence of the viral particles in the infected cells. The susceptibility of the virus to these target cells under the experimental conditions described in this report provides a platform for developing a cell-culture-based experimental model for studies of RCMV pathogenesis and allows stimulation of further studies on host cell responses imposed by congenital viral infections.     

Selection of Temperature-Sensitive Mutants During Persistent Infection: Role in Maintenance of Persistent Newcastle Disease Virus Infections of L Cells

Virus mutants (NDV(pi)) recovered from L cells persistently infected with Newcastle disease virus (NDV, Herts strain) are temperature-sensitive (ts) at 43 C, although the wild-type virus (NDV(o)) which initiated the persistent infection replicates normally at that temperature. To study the relationship between the ts marker of NDV(pi) and the other properties which distinguish this virus from NDV(o), NDV(pi) ts(+) revertants were selected at the nonpermissive temperature and NDV(o) ts mutants were generated by treating NDV(o) with nitrous acid. Spontaneously-occurring ts mutants in the Herts NDV population were also isolated. The different virus populations were characterized with regard to plaque size, virulence for eggs, and thermal stability of infectivity, hemagglutinin, and neuraminidase. The NDV(pi) ts(+) revertants, although no longer temperature-sensitive, retained NDV(pi) properties, whereas both spontaneously-occurring and mutagen-induced ts mutants remained wild-type in their other properties. These findings showed that the properties which characterized NDV(pi) were independent of the ts marker. However, the ts marker and the other markers of NDV(pi) were coselected during the persistent infection, and the combination of those markers appeared to be important in the outcome of NDV infection of L cells. NDV(pi) replicated productively in L cells, whereas NDV(o), the NDV(pi) ts(+) revertants, and the spontaneously-occurring ts mutants all yielded covert infections in L cells. The role of the selection of ts mutants in persistent infection was confirmed as follows: L cells were persistently infected with NDV(pi) ts(+) revertants and NDV(o) ts mutants. Virus recovered from the persistently infected cultures after eight cell passages was always temperature-sensitive and of smaller plaque size than the parental virus in chicken embryo cell cultures. Similar results were obtained with virus recovered from L-cell cultures persistently infected with two other velogenic strains of NDV, the Texas-GB and Kansas-Man strains. These results strongly suggest that selection of ts mutants during the persistent infection was not random and played a role in establishment or maintenance of the persistent infection, or both.     

Infectious Mononucleosis and Mononucleosis Syndromes: Clinical,Virological and Immunological Features

Infectious mononucleosis (IM) and cytomegalovirus (CMV) mononucleosis are caused by a primary infection with related viruses, Epstein-Barr virus (EBV) and CMV. Despite the similarity of clinical manifestations, basic differences exist: (1) The heterophil antibody (HA) response is absent in CMV mononucleosis, whereas it is present in IM. (2) In IM atypical lymphocytosis reflects proliferation of B cells early and of T cells later in the disease course; in CMV mononucleosis the situation appears complex. (3) In blood, EBV is restricted to B lymphocytes, whereas CMV is found in polymorphonuclear and mononuclear leukocytes. (4) Complications of CMV mononucleosis such as hepatitis and pneumonitis may be due to virus cytopathic effect in target organs. Prominent tonsillopharyngitis with adenopathy, and visceral complications of IM are related to lymphoproliferation which is self-limited except in males with a rare familial defect in defense against EBV. Immune complex-mediated pathology may occur in both diseases. (5) CMV is frequently transmitted to a fetus in utero or to an infant during or after birth, and this occasionally leads to severe cytomegalic inclusion disease; vertical transmission of EBV appears to be exceptional. (6) Secondary EBV infections are associated with certain malignancies whereas such an association has not been recognized in the case of CMV.Toxoplasma gondii is another cause of HA-negative mononucleosis. Its complications in the heart, in skeletal muscle and in the central nervous system are related to direct invasion by the parasite. Cellular immunity plays an important role in defense against all three agents.     

Detection and quantitation of Newcastle disease virus proteins in infected chicken embryo cells.

A technique was analyzed by which Newcastle disease virus (NDV) proteins could be quantitatively detected in the presence of chicken embryo cellular proteins in NDV-infected cells. The technique involved removal of electropho-proteins from a sodium dodecyl sulfate-polyacrylamide-agarose gel matrix by chemical cleavage of the acrylamide gel cross-linker. The proteins were subsequently transferred and covalently bound to diazobenzyloxymethyl paper. By incubating the paper with unlabeled antisera and 125I-labeled Staphylococcus aureus protein A, the specificity of the antisera and the sensitivity of this method of quantitative antigen detection were tested. The results demonstrated that as little as 1 ng of an individual NDV protein could be detected. Furthermore, this technique can simultaneously quantitate the synthesis of multiple NDV proteins under experimental conditions in which immunofluorescence, hemadsorption, and plaque assays failed to show virus protein synthesis or the formation of virus progeny.     

Interaction of cucumber mosaic virus and potato virus y with tobacco mosaic virus

A study was performed on the interaction of cucumber mosaic virus (CMV) of potato virus Y (PVY) with tobacco mosaic virus (TMV). Interference was evaluated using tobacco plantsNicotiana tabacum cv. Java responding to CMV and PVY with a systemic infection and to TMV with local necrotic lesions. The decrease in TMV — induced lesion number gave evidence of a decrease in susceptibility caused by the previous infection with CMV or PVY, the decrease of lesion enlargement demonstrated a decreased TMV reproduction in the plants previously infected with CMV or PVY. The interference concerned was incomplete, as evaluated from reproduction of the challenging TMV and from the decrease in susceptibility of the host to TMV brought about by the first infection with CMV or PVY.     

D,L-alpha-difluoromethylornithine inhibits human cytomegalovirus replication.

D,L-alpha-Difluoromethylornithine (DFMO) is an inhibitor of ornithine decarboxylase, the first enzyme in the polyamine biosynthetic pathway. Exposure of human foreskin fibroblast cells to DFMO before their infection with human strains of cytomegalovirus (CMV) resulted in a reduction in the amount of infectious virus produced. A 3-day exposure to the drug was required to elicit maximal antiviral effect. Cells exposed to DFMO at the time of infection produced normal amounts of infectious virus. Preexposure to the drug for 1, 2, or 3 days before infection resulted in at least 10-, 100-, or 1,000-fold decreases, respectively, in the amount of infectious virus produced. This decrease paralleled the loss of intracellular spermidine and was partially spared by the addition of exogenous putrescine, spermidine, or spermine (10 microM). When added 3 days before infection, DFMO depressed production of herpes simplex virus and simian CMV, as well as wild-type and laboratory prototype strains of human CMV. Although some antiviral effect was observed at a drug concentration of 1 mM, 10 mM gave a stronger effect and was the amount routinely used. At 30 mM DFMO, growth of noninfected cells was slowed but not arrested. Studies to investigate the level at which DFMO interferes with CMV replication showed that DFMO-treated, infected cells (i) exhibit a typical CMV-specific cytopathic effect, (ii) synthesize both viral proteins and viral DNA, (iii) contain at least some capsid forms, and (iv) shed greatly reduced amounts of virus particles into the growth medium. Since CMV virions, like those of herpes simplex virus, contain the polyamines spermidine and spermine, and since DFMO essentially eliminates the pool of intracellular spermidine, the possibility is suggested that this drug may exert its antiviral effect by interfering with virus assembly, perhaps at the level of DNA packaging or capsid envelopment or both.     

Co-electroporation of rice protoplasts with RNAs of cucumber mosaic and tobacco mosaic viruses

Cucumber mosaic virus (CMV) RNA was used to study electroporation conditions suitable for protoplasts from rice suspension cultures. Rice protoplasts required a stronger and shorter electric pulse than tobacco protoplasts for introduction of viral RNA. Under optimized conditions, CMV infection was established in 65 % of electroporated protoplasts. In contrast, electroporation with tobacco mosaic virus (TMV) RNA did not result in infection of rice protoplasts. However, when TMV RNA was electroporated into rice protoplasts together with CMV RNA, TMV production was demonstrated in 15 % of protoplasts. Differential staining with fluorescent antibodies against the two viruses showed that the protoplasts producing TMV were without exception also infected by CMV. The results show that CMV replicates in rice protoplasts by itself, whereas TMV does so only with the aid of CMV.Abbreviations CMV cucumber mosaiv virus - PBS phosphate buffered saline - TMV tobacco mosaic virus.     

Cells Persistently Infected with Newcastle Disease Virus: II. Ribonucleic Acid and Protein Synthesis in Cells Infected with Mutants Isolated from Persistently Infected L Cells

A comparison of the replication patterns in L cells and in chick embryo (CE) cell cultures was carried out with the Herts strain of Newcastle disease virus (NDV(o)) and with a mutant (NDV(pi)) isolated from persistently infected L cells. A significant amount of virus progeny, 11 plaque-forming units (PFU)/cell, was synthesized in L cells infected with NDV(o), but the infectivity remained cell-associated and disappeared without being detectable in the medium. In contrast, in L cells infected with NDV(pi), progeny virus (30 PFU/cell) was released efficiently upon maturation. It is suggested that the term "covert" rather than "abortive" be used to describe the infection of L cells with NDV(o). In both L and CE cells, the latent period of NDV(pi) was 2 to 4 hr longer than for NDV(o). The delay in synthesis of viral ribonucleic acid (RNA) in the case of NDV(pi) coincided with the delay in the inhibition of host RNA and protein synthesis. Although both NDV(o) and NDV(pi) produced more progeny and more severe cell damage in CE cells than in L cells, the shut-off of host functions was significantly less efficient in CE cells than in L cells. Paradoxically, no detectable interferon was produced in CE cells by either of the viruses, whereas in L cells most of the interferon appeared in the medium after more than 90% of host protein synthesis was inhibited. These results suggest that the absence of induction of interferon synthesis in CE cells infected with NDV is not related to the general shut-off of host cell synthetic mechanisms but rather to the failure of some more specific event to occur. In spite of the fact that NDV(pi) RNA synthesis commenced 2 to 4 hr later than that of NDV(o), interferon was first detected in the medium 8 hr after infection with both viruses. This finding suggests that there is no relation between viral RNA synthesis and the induction of interferon synthesis.     

Factors Affecting the Sensitivity of Different Viruses to Interferon

When the sensitivities to interferon of Newcastle disease virus (NDV) and vesicular stomatitis virus (VSV) were compared by the plaque reduction method in chick embryo cell cultures, NDV was found to be 45-fold more resistant than VSV. This difference was exaggerated when a multiple-cycle yield inhibition method was employed. In marked contrast, when the same viruses were tested by a single-cycle yield inhibition method, the difference in sensitivity to interferon of the two viruses was virtually eliminated. Further investigation showed that, in chick embryo cells exposed to interferon, the resistance to NDV decayed more rapidly than resistance to VSV. This finding explained the divergent results obtained with the two viruses when single- or multiple-cycle replication techniques were employed. Experiments carried out with L cells showed that cellular antiviral resistance decayed much more slowly in these cells than in chick embryo cells. Consequently, when measured by the plaque reduction method in L cells, no difference was observed in the sensitivity to interferon of VSV and NDV(pi), a mutant of NDV which replicates efficiently in L cells. A procedure is suggested for determining the relative sensitivities to interferon of different viruses under conditions which minimize the role of decay of antiviral resistance in the host cells.