Reversible repression and activation of measles virus infection in neural cells

Butyrate induces higher host transcriptional changes to inhibit porcine epidemic diarrhea virus strain CV777 infection in porcine intestine epithelial cells

Newborn piglets' health is seriously threatened by the porcine epidemic diarrhea virus (PEDV), which also has a significant effect on the pig industry. The gut microbiota produces butyrate, an abundant metabolite that modulates intestinal function through many methods to improve immunological and intestinal barrier function. The objective of this investigation was to ascertain how elevated butyrate concentrations impacted the host transcriptional profile of PEDV CV777 strain infection. Our findings showed that higher concentrations of butyrate have a stronger inhibitory effect on PEDV CV777 strain infection. According to RNA-seq data, higher concentrations of butyrate induced more significant transcriptional changes in IPEC-J2 cells, and signaling pathways such as PI3K-AKT may play a role in the inhibition of PEDV CV777 strain by high concentrations of butyrate. Ultimately, we offer a theoretical and experimental framework for future research and development of novel approaches to harness butyrate's antiviral infection properties.

Gut microbiota-derived butyrate promotes coronavirus TGEV infection through impairing RIG-I-triggered local type I interferon responses via class I HDAC inhibition

Gut microbiota-derived metabolites are important for the replication and pathogenesis of many viruses. However, the roles of bacterial metabolites in swine enteric coronavirus (SECoV) infection remain poorly understood. Recent studies show that SECoVs infection in vivo significantly alters the composition of short-chain fatty acids (SCFAs)-producing gut microbiota. This prompted us to investigate whether and how SCFAs impact SECoV infection. Employing alphacoronavirus transmissible gastroenteritis virus (TGEV), a major cause of diarrhea in piglets, as a model, we found that SCFAs, particularly butyrate, enhanced TGEV infection both in porcine intestinal epithelial cells and swine testicular (ST) cells at the late stage of viral infection. This effect depended on the inhibited productions of virus-induced type I interferon (IFN) and downstream antiviral IFN-stimulated genes (ISGs) by butyrate. Mechanistically, butyrate suppressed the expression of retinoic acid-inducible gene I (RIG-I), a key viral RNA sensor, and downstream mitochondrial antiviral-signaling (MAVS) aggregation, thereby impairing type I IFN responses and increasing TGEV replication. Using pharmacological and genetic approaches, we showed that butyrate inhibited RIG-I-induced type I IFN signaling by suppressing class I histone deacetylase (HDAC). In summary, we identified a novel mechanism where butyrate enhances TGEV infection by suppressing RIG-I-mediated type I IFN responses. Our findings highlight that gut microbiota-derived metabolites like butyrate can be exploited by SECoV to dampen innate antiviral immunity and establish infection in the intestine.IMPORTANCESwine enteric coronaviruses (SECoVs) infection in vivo alters the composition of short-chain fatty acids (SCFAs)-producing gut microbiota, but whether microbiota-derived SCFAs impact coronavirus gastrointestinal infection is largely unknown. Here, we demonstrated that SCFAs, particularly butyrate, substantially increased alphacoronavirus TGEV infection at the late stage of infection, without affecting viral attachment or internalization. Furthermore, enhancement of TGEV by butyrate depended on impeding virus-induced type I interferon (IFN) responses. Mechanistically, butyrate suppressed the cytoplasmic viral RNA sensor RIG-I expression and downstream type I IFN signaling activation by inhibiting class I HDAC, thereby promoting TGEV infection. Our work reveals novel functions of gut microbiota-derived SCFAs in enhancing enteric coronavirus infection by impairing RIG-I-dependent type I IFN responses. This implies that bacterial metabolites could be therapeutic targets against SECoV infection by modulating antiviral immunity in the intestine.

Butyrate Reprograms Expression of Specific Interferon-Stimulated Genes

Butyrate is an abundant metabolite produced by gut microbiota. While butyrate is a known histone deacetylase inhibitor that activates expression of many genes involved in immune system pathways, its effects on virus infections and on the antiviral type I interferon (IFN) response have not been adequately investigated. We found that butyrate increases cellular infection with viruses relevant to human and animal health, including influenza virus, reovirus, HIV-1, human metapneumovirus, and vesicular stomatitis virus. Mechanistically, butyrate suppresses levels of specific antiviral IFN-stimulated gene (ISG) products, such as RIG-I and IFITM3, in human and mouse cells without inhibiting IFN-induced phosphorylation or nuclear translocation of the STAT1 and STAT2 transcription factors. Accordingly, we discovered that although butyrate globally increases baseline expression of more than 800 cellular genes, it strongly represses IFN-induced expression of 60% of ISGs and upregulates 3% of ISGs. Our findings reveal that there are differences in the IFN responsiveness of major subsets of ISGs depending on the presence of butyrate in the cell environment, and overall, they identify a new mechanism by which butyrate influences virus infection of cells.IMPORTANCE Butyrate is a lipid produced by intestinal bacteria. Here, we newly show that butyrate reprograms the innate antiviral immune response mediated by type I interferons (IFNs). Many of the antiviral genes induced by type I IFNs are repressed in the presence of butyrate, resulting in increased virus infection and replication. Our research demonstrates that metabolites produced by the gut microbiome, such as butyrate, can have complex effects on cellular physiology, including dampening of an inflammatory innate immune pathway resulting in a proviral cellular environment. Our work further suggests that butyrate could be broadly used as a tool to increase growth of virus stocks for research and for the generation of vaccines.

Proteomic analysis for Type I interferon antagonism of Japanese encephalitis virus NS5 protein

Japanese encephalitis virus (JEV) nonstructural protein 5 (NS5) exhibits a Type I interferon (IFN) antagonistic function. This study characterizes Type I IFN antagonism mechanism of NS5 protein, using proteomic approach. In human neuroblastoma cells, NS5 expression would suppress IFNβ‐induced responses, for example, expression of IFN‐stimulated genes PKR and OAS as well as STAT1 nuclear translocation and phosphorylation. Proteomic analysis showed JEV NS5 downregulating calreticulin, while upregulating cyclophilin A, HSP 60 and stress‐induced‐phosphoprotein 1. Gene silence of calreticulin raised intracellular Ca²⁺ levels while inhibiting nuclear translocalization of STAT1 and NFAT‐1 in response to IFNβ, thus, indicating calreticulin downregulation linked with Type I IFN antagonism of JEV NS5 via activation of Ca²⁺/calicineurin. Calcineurin inhibitor cyclosporin A attenuated NS5‐mediated inhibition of IFNβ‐induced responses, for example, IFN‐sensitive response element driven luciferase, STAT1‐dependent PKR mRNA expression, as well as phosphorylation and nuclear translocation of STAT1. Transfection with calcineurin (vs. control) siRNA enhanced nuclear translocalization of STAT1 and upregulated PKR expression in NS5‐expressing cells in response to IFNβ. Results prove Ca²⁺, calreticulin, and calcineurin involvement in STAT1‐mediated signaling as well as a key role of JEV NS5 in Type I IFN antagonism. This study offers insights into the molecular mechanism of Type I interferon antagonism by JEV NS5.

Measles virus, immune control, and persistence

Measles remains one of the most important causes of child morbidity and mortality worldwide with the greatest burden in the youngest children. Most acute measles deaths are owing to secondary infections that result from a poorly understood measles-induced suppression of immune responses. Young children are also vulnerable to late development of subacute sclerosing panencephalitis, a progressive, uniformly fatal neurologic disease caused by persistent measles virus (MeV) infection. During acute infection, the rash marks the appearance of the adaptive immune response and CD8(+) T cell-mediated clearance of infectious virus. However, after clearance of infectious virus, MeV RNA persists and can be detected in blood, respiratory secretions, urine, and lymphoid tissue for many weeks to months. This prolonged period of virus clearance may help to explain measles immunosuppression and the development of lifelong immunity to re-infection, as well as occasional infection of the nervous system. Once MeV infects neurons, the virus can spread trans-synaptically and the envelope proteins needed to form infectious virus are unnecessary, accumulate mutations, and can establish persistent infection. Identification of the immune mechanisms required for the clearance of MeV RNA from multiple sites will enlighten our understanding of the development of disease owing to persistent infection.

ISG15 over-expression inhibits replication of the Japanese encephalitis virus in human medulloblastoma cells

IFN-stimulated gene 15 (ISG15), an ubiquitin-like protein, is rapidly induced by IFN-alpha/beta, and ISG15 conjugation is associated with the antiviral immune response. Japanese encephalitis virus (JEV), a mosquito-borne neurotropic flavivirus, causes severe central nervous system diseases. We investigated the potential anti-JEV effect of ISG15 over-expression. ISG15 over-expression in human medulloblastoma cells significantly reduced the JEV-induced cytopathic effect and inhibited JEV replication by reducing the viral titers and genomes (p<0.05, Student's t-test); it also increased activation of the interferon stimulatory response element (ISRE)-luciferase cis-acting reporter in JEV-infected cells (p<0.05, Chi-square test). Furthermore, Western blotting revealed that ISG15 over-expression increased phosphorylation of IRF-3 (Ser396), JAK2 (Tyr1007/1008) and STAT1 (Tyr701 and Ser727) in JEV-infected cells (P<0.05, Chi-square test). Confocal imaging indicated that nucleus translocation of transcription factor STAT1 occurred in ISG15-over-expressing cells but not in vector control cells post-JEV infection. ISG15 over-expression activated the expression of STAT1-dependent genes including IRF-3, IFN-beta, IL-8, PKR and OAS before and post-JEV infection (p=0.063, Student's t-test). The results enabled elucidation of the molecular mechanism of ISG15 over-expression against JEV, which will be useful for developing a novel treatment to combat JEV infection.

Poliovirus replication and spread in primary neuron cultures

While some neurotropic viruses cause rapid central nervous system (CNS) disease upon entry into the brain parenchyma, other viruses that are cytolytic in the periphery either result in little neuropathology or are associated with a protracted course of CNS disease consistent with persistent infection. One such virus, poliovirus (PV), is an extremely lytic RNA virus that requires the expression of CD155, the poliovirus receptor (PVR), for infection. To compare the kinetics of PV infection in neuronal and non-neuronal cell types, primary hippocampal neurons and fibroblasts were isolated from CD155+ transgenic embryos and infected with the Mahoney and Sabin strains of PV. Despite similar levels of infection in these ex vivo cultures, PV-infected neurons produced 100-fold fewer infectious particles as compared to fibroblasts throughout infection, and death of PV-infected neurons was delayed approximately 48 h. Spread in neurons occurred primarily by trans-synaptic transmission and was CD155-dependent. Together, these results demonstrate that the magnitude and speed with which PV replication, spread, and subsequent cell death occur in neurons is decreased as compared to non-neuronal cells, implicating cell-specific effects on replication that may then influence viral pathogenesis.

Molecular mechanisms of measles virus persistence

As measles virus causes subacute sclerosing panencephalitis and measles inclusion body encephalitis due to its ability to establish human persistent infection, without symptoms for the time between the acute infection and the onset of clinical symptoms, it has been the paradigm for a long term persistent as opposed to chronic infection by an RNA virus. We have reviewed the mechanisms of persistence of the virus and discuss specific mutations associated with CNS infection affecting the matrix and fusion protein genes. These are placed in the context of our current understanding of the viral replication cycle. We also consider the proposed mechanisms of persistence of the virus in replicating cell cultures and conclude that no general mechanistic model can be derived from our current state of knowledge. Finally, we indicate how reverse genetics approaches and the use of mouse models with specific knock-out and knock-in modifications can further our understanding of measles virus persistence.

Virus demyelination

A number of viruses can initiate central nervous system (CNS) diseases that include demyelination as a major feature of neuropathology. In humans, the most prominent demyelinating diseases are progressive multifocal leukoencephalopathy, caused by JC papovirus destruction of oligodendrocytes, and subacute sclerosing panencephalitis, an invariably fatal childhood disease caused by persistent measles virus. The most common neurological disease of young adults in the developed world, multiple sclerosis, is also characterized by lesions of inflammatory demyelination; however, the etiology of this disease remains an enigma. A viral etiology is possible, because most demyelinating diseases of known etiology in both man and animals are viral. Understanding of the pathogenesis of virus-induced demyelination derives for the most part from the study of animal models. Studies with neurotropic strains of mouse hepatitis virus, Theiler's virus, and Semliki Forest virus have been at the forefront of this research. These models demonstrate how viruses enter the brain, spread, persist, and interact with immune responses. Common features are an ability to infect and persist in glial cells, generation of predominantly CD8(+) responses, which control and clear the early phase of virus replication but which fail to eradicate the infection, and lesions of inflammatory demyelination. In most cases demyelination is to a limited extent the result of direct virus destruction of oligodendrocytes, but for the most part is the consequence of immune and inflammatory responses. These models illustrate the roles of age and genetic susceptibility and establish the concept that persistent CNS infection can lead to the generation of CNS autoimmune responses.

Infection of human oligodendroglioma cells by a recombinant measles virus expressing enhanced green fluorescent protein

One of the hallmarks of the human CNS disease subacute sclerosing panencephalitis (SSPE) is a high level of measles virus (MV) infection of oligodendrocytes. It is therefore surprising that there is only one previous report of MV infection of rat oligodendrocytes in culture and no reports of human oligodendrocyte infection in culture. In an attempt to develop a model system to study MV infection of oligodendrocytes, time-lapse confocal microscopy, immunocytochemistry, and electron microscopy (EM) were used to study infection of the human oligodendroglioma cell line, MO3.13. A rat oligodendrocyte cell line, OLN-93, was also studied as a control. MO3.13 cells were shown to be highly susceptible to MV infection and virus budding was observed from the surface of infected MO3.13 cells by EM. Analysis of the infection in real time and by immunocytochemistry revealed that virus spread occurred by cell-to-cell fusion and was also facilitated by virus transport in cell processes. MO3.13 cells were shown to express CD46, a MV receptor, but were negative for the recently discovered MV receptor, signaling leucocyte activation molecule (SLAM). Immunohistochemical studies on SSPE tissue sections demonstrated that CD46 was also expressed on populations of human oligodendrocytes. SLAM expression was not detected on oligodendrocytes. These studies, which are the first to show MV infection of human oligodendrocytes in culture, show that the cells are highly susceptible to MV infection and this model cell line has been used to further our understanding of MV spread in the CNS.

Age-related changes in susceptibility of rat brain slice cultures including hippocampus to encephalomyocarditis virus

Replication of the D variant of encephalomyocarditis virus (EMC-D) and its cytopathic effects were studied in the brain slice cultures including hippocampus (hippocampal slice) obtained from postnatal 1-, 4-, 7-, 14-, 28-and 56-day-old Fischer 344 rats. At 0, 12, 24, 36 and 48 h after infection, virus titres of the slices and culture media were assayed. Viral replication was observed in cultures from 1-to 28-day-old rats, and the highest titre was recorded in the slice and culture medium from the youngest rat. The peak of virus titre decreased with age and no distinct viral replication was observed in the cultures from 56-day-old rats. Light microscopy revealed that degenerative and necrotic changes appeared in the infected hippocampal slices from 1- to 28-day-old rats, and the changes became less prominent with age. In situ hybridization and indirect immunofluorescence staining showed that positive signals of viral RNA and antigen were prominent in younger rats and decreased with age. These results suggest that an age-related decrease in the susceptibility of rat brain to EMC-D is less related to the maturation of the immune system but possibly to that of the neurone.

'Brown sugar' heroin intoxication and improvement of surrogate immunologic markers in HIV infection

OBJECTIVE: To report on the unexpected improvement in major biological surrogate markers (CD4 T-cell count, HIV RNA viral load, and apoptosis level) during the periods of 'brown sugar' heroin intoxication (BSI) in 12 HIV-1-infected intravenous drug users, independently of their antiretroviral therapy, compared to the period of 'brown sugar' heroin withdrawal (BSW). METHODS: The patients were followed prospectively for a total of 417 months over 4 years. Twenty-four episodes of BSI and 24 periods of BSW were analyzed. RESULTS: (1) BSI: the mean (+/-SE) duration was 9+/-1.8 months; at onset, the mean +/-SE CD4 T-cell count was 401+/-88/mm3; at the end, an absolute increase of 346 CD4 T-cells/mm3 and a CD4 T-cell count relative variation of +131% was observed. Half of the patients showed an increase of CD4 T-cell count of more than 90% during their follow-up. The mean+/-SE of CD8 T-cell count increased significantly by 108%. (2) BSW: the mean +/- SE duration was 8.4+/-1.3 months; at onset, the mean +/-SE CD4 T-cell count was 695+/-78/mm3; at the end, an absolute decrease of 342 CD4 T-cells/mm3 and a CD4 T-cell count relative variation of -52% was observed. Half of the patients showed a decrease of CD4 T-cell count of more than 51%. (3) Circulating viral load appeared to be significantly higher during BSW (median: 452 000 Eq RNA/mL) than during BSI (median: 52 000 Eq RNA/mL); p<0.01. (4) Similarly, the apoptotic process affecting circulating lymphocytes was significantly lower during BSI than during BSW episodes. (5) The 4-year mortality rate was 7%, compared with 36% in HIV-positive former drug users (p<0.001). CONCLUSIONS: Taken together, these features suggest that 'brown sugar' heroin could have either immunomodulatory or antiretroviral properties. Confirmation of these findings and investigation of the role of the many substances in 'brown sugar' heroin are indicated.

Measles virus infection and replication in undifferentiated and differentiated human neuronal cells in culture

Measles virus (MV) infection of the human central nervous system (CNS) typically involves widespread infection of neurons. However, little is known about how they become infected, how defective virus arises and accumulates, or how virus spreads among the cells of the CNS. In vitro studies of viral interactions with human neuronal cells may contribute to the resolution of such issues. In mixed cultures containing differentiated human neuronal (hNT2) cells and neuroepithelial cells, immunofluorescence studies show that the neurons, unlike both their NT2 progenitors and the neuroepithelial cells, are not initially susceptible to MV infection. This is possibly due to their lack of expression of CD46, a known cell surface receptor for MV. Later in the course of infection, however, both MV proteins and genomic RNA become detectable in their processes, where they contact infected, fully permissive neuroepithelial cells. Such a mechanism of virus transfer may be involved in the initiation and spread of persistent MV infection in diseases such as subacute sclerosing panencephalitis. Furthermore, mutated defective virus may readily accumulate and spread without the need, at any stage, for viral maturation and budding.

Replication of lymphocytic choriomeningitis virus is restricted in terminally differentiated neurons

We have investigated the replication of lymphocytic choriomeningitis virus (LCMV) before and after the nerve growth factor (NGF)-induced transdifferentiation of PC12 cells from the chromaffin to the neuron-like phenotype. Untreated and NGF-treated cells were equally susceptible to LCMV infection; however, the viral yield was found to be 1,000-fold lower in NGF-differentiated PC12 cells. The reduced viral yield correlated with restricted LCMV replication and transcription within the infected cell, which was not caused by the lack of cell proliferation in the NGF-treated cells but rather was related to the induction or changes in expression levels of specific gene product(s) associated with the cell commitment to a neuronal phenotype. The return to the chromaffin phenotype after withdrawal of NGF restored normal LCMV yields as well as levels of viral replication and transcription. The finding of reduced viral replication in terminally differentiated neuronal cells has important implications for understanding the mechanism by which neurotropic viruses, such as LCMV, are able to establish a long-term persistent infection in the central nervous system in the absence of severe pathological changes.

Spontaneous and differentiation-dependent regulation of measles virus gene expression in human glial cells

The expression of measles virus (MV) in six different permanent human glioma cell lines (D-54, U-251, U-138, U-105, U-373, and D-32) was analyzed. Although all cell lines were permissive for productive replication of all MV strains tested, U-251, D-54, and D-32 cells spontaneously revealed restrictions of MV transcription similar to those observed for primary rat astroglial cells and brain tissue. In vitro differentiation of D-54 and U-251 cells by substances affecting the intracellular cyclic AMP level caused a significant reduction of the expression of the viral proteins after 18, 72, and 144 h of infection. This pronounced restriction was not paralleled to a comparable level by an inhibition of the synthesis and biological activity in vitro of virus-specific mRNAs as shown by quantitative Northern (RNA) blot analyses and in vitro translation. The block in viral protein synthesis could not be attributed to the induction of type I interferon by any of the substances tested. Our findings indicate that down-regulation of MV gene expression in human brain cells can occur by a cell type-dependent regulation of the viral mRNA transcription and a differentiation-dependent regulation of translation, both of which may be crucial for the establishment of persistent MV infections in the central nervous system.

Pathogenesis of virus-induced demyelination

Demyelination is a component of several viral diseases of humans. The best known of these are subacute sclerosing panencephalitis (SSPE) and progressive multifocal leukoencephalopathy (PML). There are a number of naturally occurring virus infections of animals that involve demyelination and many of these serve as instructive models for human demyelinating diseases. In addition to the naturally occurring diseases, many viruses have been shown to be capable of producing demyelination in experimental situations. In discussing virus-associated demyelinating disease, the chapter reviews the architecture and functional organization of the CNS and considers what is known of the interaction of viruses with CNS cells. It also discusses the immunology of the CNS that differs in several important aspects from that of the rest of the body. Experimental models of viral-induced demyelination have also been considered. Viruses capable of producing demyelinating disease have no common taxonomic features; they include both DNA and RNA viruses, enveloped and nonenveloped viruses. The chapter attempts to summarize the important factors influencing viral demyelination, their common features, and possible mechanisms.

Antibody-dependent transcriptional regulation of measles virus in persistently infected neural cells

Application of neutralizing anti-hemagglutinin antibodies to mouse neuroblastoma cells (NS20Y/MS) persistently infected with measles virus (MV) leads to a significant reduction of viral structural proteins within 6 days. While the transcriptional gradient for MV-specific mRNAs remained unaffected upon antibody treatment, the total amount of MV-specific transcripts dropped by 80% after 24 h. The expression of genomic RNA was affected similarly, with slightly slower time kinetics. Both transcription and expression of the viral structural proteins could be completely reactivated when viral antibodies were removed from the tissue culture. The same findings could be obtained in rat glioma cells persistently infected with subacute sclerosing panencephalitis virus (C6/SSPE) but not in cells of nonneural origin. The data indicate that antibody-induced antigenic modulation affects the early stages of viral transcription within a few hours after the addition of antibodies and leads to an almost complete repression of viral gene expression in cells of neural origin.

Antibody-induced restriction of viral gene expression in measles encephalitis in rats

After infection with the neurotropic CAM/RBH measles virus (MV) strain, newborn Lewis rats succumb to an acute necrotizing encephalopathy. Passive transfer of neutralizing monoclonal antibodies directed against MV hemagglutinin prevented this disease process. Instead, either an antibody-induced acute or subacute measles encephalitis developed after a prolonged incubation period with a restricted expression of MV structural proteins. The molecular biological analysis of MV gene expression in brain tissue of rats treated with MV-neutralizing antibodies revealed a transcriptional restriction of viral mRNAs, particularly for the envelope proteins, leading to a steep expression gradient. Based on in situ hybridization, it was concluded that the efficiency of transcription of viral genes at the single-cell level is reduced compared with that of controls. Passive immunization with monoclonal antibodies directed against other MV structural proteins proved to be ineffective. Similar results were obtained in MV-infected weanling Brown Norway rats. These rats developed a clinically silent encephalitis in the presence of high titers of neutralizing antibodies. In such animals, a pronounced attenuation of the viral gene transcription was observed. These findings indicated that neutralizing antibodies directed against a restricted set of specific antigenic sites on the viral hemagglutinin protein expressed on cell membranes exert a modulating effect on the viral gene expression at the level of transcription. This phenomenon contributes to the switch from the acute cytopathic effect to a persistent infection in the central nervous system.

Long-term effect of elevated temperatures on SSPE virus expression in persistently infected rat glial cells

Cultivation of measles virus (SSPE virus, Lec strain) persistently infected C6 rat glioma cells at 39 degrees C resulted in the loss of detectable expression of measles virus proteins. Temperature shift-back led to reactivation of measles virus even after maintenance of the cells at 39 degrees C for 15 days. In Northern blot analysis viral mRNA disappeared at 3 days after shift-up whereas 50 S viral genome-sized RNA was detectable until 6 days. The 50 S RNA decreased in quantity in rough correlation with dilution by cell passage at 39 degrees C. The 50 S viral RNA was found in the nucleocapsid fraction. On day 9 after shift-down of persistently infected cells, maintained at 39 degrees C for 15 days, 50 S viral RNA reappeared although mRNAs were not yet detected. Infectious center assays showed that the number of cells in the population at 39 degrees C, which contained an SSPE virus genome that could be reactivated, declined after temperature shift. Moreover, cell cloning experiments, in which single cells of cultures maintained for various lengths of time at 39 degrees C were incubated at 35 degrees C and examined by immunofluorescence, reconfirmed the above results. This indicates that the reactivation of SSPE virus described here was due to re-infection of virus-antigen negative cells with progeny virus produced by a few latently infected cells in the population. The biological significance of this phenomenon in the central nervous system virus infection is discussed.

Restriction of measles virus gene expression in acute and subacute encephalitis of Lewis rats

Measles virus (MV) replication in brain tissue of Lewis rats with acute (AE) and subacute (SAME) encephalitis was characterized by biochemical techniques. Messenger RNAs specific for measles virus nucleocapsid (N), phospho (P)-, matrix (M), fusion (F), and haemagglutinin (H) protein were detected in all brain extracts examined. The quantity of the individual MV mRNA species was quite different in comparison to lytically infected Vero cells. A steep gradient of MV transcripts was found in brain tissue which is most likely due to strongly attenuated transcription of mRNAs along the viral genome, representing particularly low transcription of the glycoprotein genes. In addition, in vitro translation assays only revealed synthesis of N and P protein in consistent fashion. The mRNAs for the glycoproteins did not direct the synthesis of detectable viral proteins whereas the M mRNA revealed some activity in animals with AE. The data indicate a strong restriction of the MV envelope gene expression in infected brain tissue, which is independent of the incubation time and type of the central nervous system (CNS) disease. This phenomenon which is similar to the findings observed in measles inclusion body encephalitis and subacute sclerosing panencephalitis suggest that host factors may initially be responsible for the initiation of transcriptional and translational alterations.

Inhibitory effect of papaverine on HIV replication in vitro

The ability of papaverine to inhibit human immunodeficiency virus (HIV) replication in H9 cell line and in peripheral blood mononuclear cell (PBMC) culture was examined. HIV-infected H9 cells were exposed to different concentrations of papaverine for 20 days. Reverse transcriptase (RT) activity and the presence of p24 in the supernatant were determined to assess the level of viral replication in treated and control cultures. The most effective concentration of papaverine in the culture medium was 10 micrograms/ml, a dose that did not significantly affect cell proliferation. At this drug concentration the treatment resulted in no RT activity or p24 expression in the supernatant and no virus antigen detection at the cellular level as demonstrated by Western blot (WB) analysis. The activity of the drug occurred in a short period of time (60 hours) as shown by radioimmunoprecipitation (RIP) assay and affected the synthesis of the env precursor protein gp160. The drug was also effective in inhibiting HIV replication in PBMC cultures and influenced specific viral markers, namely, RT and p24. Evidence of the efficacy of papaverine treatment was enforced by the finding in the treated PBMC cultures, compared with the untreated ones, of a reduced percentage of cells forming syncitia and of the inhibition of the virus-induced decrease in the number of cells. When an equal number of virus-infected H9 cells exposed or unexposed to papaverine was analyzed for HIV-specific proteins, a marked decrease in the expression of the viral proteins was observed in the treated cultures. At the same time, one cellular protein of molecular weight 69,000 was not inhibited by papaverine. This may indicate that, at least for one protein, synthesis may not be affected by the drug. Our data suggest that papaverine merits attention as a possible nontoxic candidate for the treatment of HIV infection.

Inability of translation of mRNA for HVJ (Sendai virus) M protein in a rat glioma cell line at nonpermissive temperatures

The synthesis of M protein of HVJ (Sendai virus) in rat glioma (C6) cells, as has previously been reported, is selectively reduced at a nonpermissive temperature of 39 degrees C. In this phenomenon no difference was found in the viral RNA synthesis and the stability of the viral RNAs between the permissive and nonpermissive temperatures. Oligo dT-selected RNA from the infected cells at either temperature similarly directed M protein synthesis in cell-free translation reactions even if the reaction was performed at 39 degrees C. These results suggest that the restriction of M protein synthesis in C6 cells at the nonpermissive temperature might be due to the inability of translation apparatus to interact with the mRNA coding for M protein.

In vivo and in vitro models of demyelinating disease: activation of the adenylate cyclase system influences JHM virus expression in explanted rat oligodendrocytes

The specificity of JHM virus (JHMV) tropism for rat oligodendrocytes, as one of the primary host cells in the central nervous system, is maintained after explanation (S. Beushausen and S. Dales, Virology 141:89-101, 1985). The temporal correlation between onset of resistance to JHMV infection in vivo, completion of myelination, and maturation of the central nervous system can be simulated in vitro by inducers of oligodendrocyte differentiation (Beushausen and Dales, Virology, 1985). Stimulation of differentiation through the elevation of intracellular cyclic AMP (cAMP) levels suggests a possible connection between activation of the adenylate cyclase system and coronavirus expression. Chromatographic analysis of cAMP-dependent protein kinase activity in cytosol extracts prepared from astrocytes or oligodendrocytes revealed that both glial cell types were deficient in protein kinase I, indicating that expression of coronavirus in differentiated cells was not contingent upon the presence of protein kinase I. However, treatment with N6,2'-O-dibutyryladenosine-3',5'-cyclic monophosphate (dbcAMP) resulted in a severalfold enhancement of the free regulatory subunit (RI) in oligodendrocytes but not in astrocytes. The RII subunit in both neural cell types was relatively unaffected. Rapid increase in RI due to dbcAMP treatment was correlated with inhibition of JHMV expression. Other differentiation inducers, including 8-Br cAMP and forskolin which, by contrast, caused a decrease in detectable RI, also blocked JHMV expression. This apparent anomaly can be attributed to an increased turnover of RI due to destabilization of the molecule which occurs upon site-specific binding of the cyclic nucleotides. On the basis of these observations, we conclude that the state of oligodendrocyte differentiation manifested with the modulation of RI regulates JHMV expression. The differentiation process did not affect either virus adsorption or sequestration but appeared to inhibit the expression of viral RNA and proteins, implying that replication was inhibited at some step between penetration and initiation of genomic functions, perhaps at the stage of uncoating. We therefore examined the possibility that protein kinases and phosphatases, which influence cellular regulation during cAMP-induced differentiation, may be responsible for the phenomenon of coronavirus suppression in oligodendrocytes. Evidence was obtained indicating that normal processing of the phosphorylated nucleocapsid protein is inhibited in differentiated oligodendrocytes, consistent with the notion that JHMV replication might be arrested during uncoating.

Identification of a nonproductive, cell-associated form of measles virus by its resistance to inhibition by recombinant human interferon

Subacute sclerosing panencephalitis (SSPE) is a fatal disease in children and young adults that is caused by persistent infection of the central nervous system (CNS) by a nonproductive, cell-associated form of measles virus. Using an experimental model for SSPE (LEC viral strain in newborn hamsters), we have shown previously that establishment of such CNS infections involves selective elimination from the CNS of productively infected cells by host defensive mechanisms, coupled with the selective sparing of cells carrying nonproductive viral forms. That interferon (IFN) may play a role in this process was suggested by the disappearance of productively infected cells from the CNS tissues prior to the appearance of antiviral antibodies and by the demonstration of cell-associated, IFN-resistant viral variants in the virus stocks that were used. Results of this study support these conclusions by showing that similar IFN-resistant viral variants are present in the HBS strain of SSPE-derived measles virus and that these variants, in the presence of IFN, have properties that are similar to those of naturally occurring cell-associated strains of SSPE viruses, e.g., DR, IP3, and Biken. These IFN-resistant forms of HBS virus were isolated and were shown to maintain their resistance to inhibition by IFN after cloning. However, on removal of IFN, they reverted to productive forms similar to the parental HBS virus. The potential role of such viral forms in the pathogenesis of SSPE is discussed.

Host-dependent temperature-sensitive growth of HVJ (Sendai virus) wild-type in rat glioma C 6 cells

At non-permissive temperature viral specific RNA synthesis was not restricted in rat glioma (C 6) cells infected with HVJ (Sendai virus) wild-type. However, as has previously been shown (J Gen Virol [1984] 65: 639-643), the synthesis of M protein was reduced at non-permissive temperature, in contrast to the L, P, HN, Fo and NP proteins which were synthesized in comparable amounts at permissive and non-permissive temperatures. In this report we show additionally that viral nucleocapsids (NC), which consist of L, P and NP proteins, were formed within the infected cells at both temperatures. Hemagglutinin and neuraminidase activities were also detected in samples incubated at non-permissive temperature. By membrane immunofluorescence and cell-surface immunoprecipitation it was shown that migration of HN and Fo proteins to the cell surface occurred normally at non-permissive temperature. Additionally, the L, P and NP proteins, which were associated with the plasma membrane isolated from the infected cells maintained at permissive temperature, were absent from the membrane of cells incubated at non-permissive temperature. These results suggest that NC and glycoproteins synthesized at non-permissive temperature could not assemble effectively at the plasma membrane because of a lack of M protein. Thus, the host-dependent ts lesion of HVJ in C 6 cells was considered to be mainly in M protein synthesis.

Restricted replication of mouse hepatitis virus A59 in primary mouse brain astrocytes correlates with reduced pathogenicity

Temperature-sensitive (ts) mutants of mouse hepatitis virus A59 (MHV-A59) are drastically attenuated in their pathogenic properties. Intracerebral inoculation of mice with 10(5) PFU of mutant ts342 results in prolonged infection of the central nervous system, whereas 100 PFU of wild-type virus are lethal (M. J. M. Koolen, A. D. M. E. Osterhaus, G. van Steenis, M. C. Horzinek, and B. A. M. van der Zeijst, Virology 125:393-402, 1983). In the Sac(-) cell line ts342 grows as well at 37 degrees C (the body temperature of mice) as at 31 degrees C (the permissive temperature). There is, however, a difference in primary cultures of mouse brain astrocytes. After infection with ts342, astrocytes produced low levels of infectious virus (5.2 +/- 3.7%) compared with virus yields after infection with wild-type virus. The fraction of wild-type virus- and ts342-infected cells was similar. Electron microscopy showed in wild-type virus-infected cells abundant virions in smooth vesicles usually closely associated with a well-developed Golgi apparatus. In mutant-infected cells no mature ts342 virus particles were found. There was no difference between ts342 and wild-type virus regarding the intracellular virus-specific RNAs. In ts342-infected cells the viral glycoproteins E2 and E1 were not detectable or were barely detectable. Either the mRNAs for the glycoproteins are not translated or the proteins are rapidly broken down. Revertants of ts342 were isolated. They grew as well as wild-type virus in astrocytes, indicating that they apparently produced sufficient amounts of E2 and E1, the ts defect itself rather than a second site mutation is responsible for the defect in replication, and the ts defect acts in unison with host-cell factors. The revertants also regained the lethal properties of wild-type virus.

Inhibitory effect of papaverine on RNA and protein synthesis of vesicular stomatitis virus

Papaverine, an inhibitor of cAMP phosphodiesterase, reduced yields of infectious vesicular stomatitis virus in HEp-2 cells approximately 100-fold if added to cultures at a concentration of 30 microM before and after virus infection. The extent of papaverine-induced suppression of viral growth was dependent on drug dose and treatment regimen. Cells progressively recovered their viral permissive state after removal of drug. The cyclic nucleotide, cGMP, nullified the inhibitory effect of papaverine if added to cells during drug treatment. Pulse labeling experiments with [35S]methionine showed that papaverine compromises production of all virus-specific proteins in infected cells without adversely affecting host cell protein synthesis. Treatment of cells with papaverine strongly inhibited the production of viral RNA and both cellular RNA and DNA. It was found that VSV causes an immediate but transient stimulation of DNA synthesis in HEp-2 cells which is prevented by papaverine treatment. This drug also selectively blocked primary transcription of VSV in vivo and to a lesser extent in vitro RNA polymerase activity of the virion-bound transcriptase. The finding that papaverine has a strong inhibitory effect on viral biosynthesis including early transcription suggests that VSV replication may depend on host factors that regulate intracellular levels of cyclic nucleotides such as cAMP.

In vivo and in vitro models of demyelinating disease. XI. Tropism and differentiation regulate the infectious process of coronaviruses in primary explants of the rat CNS

The coronaviruses, ubiquitous in mammals, including man, manifest serotype-related predeliction for different tissues. This presentation deals with specificity of the murine viscerotropic MHV3 and neurotropic JHMV for explanted cells from the CNS of newborn, inbred, Wistar-Furth rats. An unambiguous tropism of MHV3 for astrocytes and JHMV for oligodendrocytes is demonstrated. With the latter cell-virus interaction, relatively small differences in spatial density of oligodendrocytes influence profoundly the duration of persistence and virus yield. The in vitro temporal program of oligodendrocyte differentiation, monitored by induction of a myelin-related enzyme, 2':3'-cyclic nucleotide-3'-phosphohydrolase, corresponds to that occurring in vivo (F. A. McMorris, J. Neurochem. 41, 506-515, 1983). It is complete within 15-21 days and is coincident with the onset of insusceptibility to disease caused by JHMV. Experimental elevation of intracellular cyclic-AMP levels, presumed to reflect oligodendrocyte differentiation, likewise suppresses JHMV replication without affecting that of MHV3 in astrocytes. On the basis of these data it is concluded that in vitro interaction of JHMV with oligodendrocytes reflects accurately the in vivo host control over the tropism and expression of this virus, thereby effecting the progressive, demyelinative disease, process.

Isolation of cold-sensitive mutants of measles virus from persistently infected murine neuroblastoma cells

Clone NS20Y of the mouse neuroblastoma C1300 was infected with wild-type Edmonston measles virus, and, after a transition to a carrier culture, became persistently infected. Persistently infected clones were derived and characterized morphologically by the appearance of multinucleate giant cells and nucleocapsid matrices in cytoplasm and nucleus, but very few budding virus particles. Antimeasles antibodies markedly suppressed the expression of viral antigens and giant cells, and the effect was totally reversible. When the cells were cultured at 33 degrees C, the number of giant cells began to diminish and ultimately disappeared; in contrast, when cultured at 39 degrees C, the cultures invariably lysed. Yields at 33 degrees C were ca. 2 logs lower than those at 39 degrees C. Cells cultured at 33 degrees C produced relatively high levels of interferon, whereas those at 39 degrees C produced little or no interferon. When the persistently infected cultures were exposed to anti-interferon alpha/beta serum at a nonpermissive temperature, there was a marked increase in multinucleate cells, suggesting that maintenance of the persistence state and its regulation by temperature may be related to the production of interferon. Viral isolates from cells cultured at 39 degrees C were obtained, and 90% of viral clones were found to be cold sensitive. Complementation studies with different viral clones indicated that the cold-sensitive defect was probably associated with the same genetic function. Western blot analysis of the persistently infected cells indicated a significant diminution and expression of all measles-specific proteins at a nonpermissive temperature. Infection of NS20Y neuroblastoma cells with the cold-sensitive virus isolates resulted in the development of an immediate persistent infection, whereas infection of Vero or HeLa cells resulted in a characteristic lytic infection, suggesting that the cold-sensitive mutants may be selected or adapted for persistent infection in cells of neural origin.

Effect of papaverine treatment on replication of measles virus in human neural and nonneural cells

The replication of measles virus in human neural and nonneural cell lines in terms of growth and cytopathic effect was affected by treatment of the cells with papaverine, which increases endogenous cyclic AMP. Suppression of virus growth was most prominent in neuroblastoma cells, followed by that in epidermoid carcinoma and glioblastoma cells, whereas the suppressive effect was relatively weak in oligodendroglioma cells. The papaverine-induced suppression of virus growth in neuroblastoma cells was studied in detail. The suppression that occurred was dependent on the dose of papaverine and was reversible. By treatment with 10 microM papaverine, virus-cell interactions were modified as follows: (i) early replication steps such as adsorption, penetration, and uncoating of the virus were not affected; (ii) synthesis of viral RNAs, including genomic RNA and mRNA, was inhibited; (iii) translation of viral proteins from mRNA was not blocked; and (iv) glycosylation and transport of viral glycoproteins to the cell membrane were not inhibited, but phosphorylation was blocked. The significance of suppressed virus replication in neural cells is discussed in relation to the persistence mechanisms of measles virus in the central nervous system.

Characterization of four cell lines persistently infected with measles virus

Persistently infected cell lines were established by infecting Vero cells with four different strains of measles virus: Edmonston "wild type", Schwarz vaccine strain passaged at high multiplicity of infection, Hallé SSPE strain, and a temperature sensitive mutant of Edmonston strain, designated ts 841. The four cell lines have continued to produce virus at a constant low level over a period of more than two years, although cytopathology and hemagglutinating ability have varied with cell passage. Only virus from cells originally infected with ts 841 appears to be temperature sensitive. In each of the cell lines a sizable population of low density, interfering virus particles was generated, indicating that this is an important mechanism for these four cell lines in maintenance of the measles virus persistent infection.

Expression of five viral antigens in cells infected with wild-type and SSPE strains of measles virus: correlation with cytopathic effects and productivity of infections

Cells infected with four strains (LEC, Biken, IP-3 and DR) of subacute sclerosing panencephalitis (SSPE) virus were compared with wild type measles virus (Edmonston) with respect to titers of extracellular virus, morphology of the cytopathic effect (CPE) and occurrence of different measles virus antigens within infected cells as determined by immune fluorescence. Murine monoclonal antibodies with specifities for the nucleocapsid (NP), polymerase (P), matrix (M), hemagglutinin (H), and fusion (F) proteins as well as specific hyperimmune sera prepared in rabbits against the NP, H and M proteins were used in immune fluorescence analyses of the various strains. All of the strains produced large amounts of NP and P. Only the NP antigen occurred in nuclei of cells. The Edmonston and LEC strains also showed bright fluorescence with the antibodies against the H, F, and M antigens. Immune fluorescent intensity was variably reduced in cells infected with the Biken, IP-3, and DR strains labelled with anti M, H, and F antibodies. The Biken strain produced moderate titers of extracellular virus and moderate amounts of M, H, and F antigens whereas the DR strain produced no extracellular virus and contained no detectable M or F and only trace amounts of H antigen. The IP-3 strain was intermediate both in antigen expression and in production of extracellular virus.