Transcription from the proximal promoter of ELAC1, a gene for tRNA repair, is upregulated by interferons.

tRNase ZS (ELAC1) and TRNT1 function in tRNA recycling. Recently, we have shown that these genes are upregulated in the cells infected with Theiler's mouse encephalitis virus (TMEV), implying that tRNA recycling functions in response to viral infection. To address the molecular mechanism underlying the ELAC1 upregulation in the cells infected with TMEV, we performed luciferase assays using various plasmid constructs harboring the ELAC1 promoter region. The luciferase expression from a construct containing the full-length ELAC1 promoter was augmented by TMEV, poly IC, IFN-ß, or IFN-γ. We identified four IFN-stimulated responsible elements (ISREs) in the proximal promoter region. The luciferase expression from the constructs that lack all the ISREs was strongly reduced compared with that from the constructs with the four ISREs in the presence of IFN-ß or IFN-γ. The observation that the ISREs from the ELAC1 promoter are essential for the gene upregulation by IFN-ß or IFN-γ suggests that the ELAC1 gene is upregulated by IFNs.

Immunoregulation of Theiler's virus-induced demyelinating disease by glatiramer acetate without suppression of antiviral immune responses.

While most disease-modifying drugs (DMDs) regulate multiple sclerosis (MS) by suppressing inflammation, they can potentially suppress antiviral immunity, causing progressive multifocal leukoencephalopathy (PML). The DMD glatiramer acetate (GA) has been used for MS patients who are at high risk of PML. We investigated whether GA is safe for use in viral infections by using a model of MS induced by infection with Theiler's murine encephalomyelitis virus (TMEV). Treatment of TMEV-infected mice with GA neither enhanced viral loads nor suppressed antiviral immune responses, while it resulted in an increase in the Foxp3/Il17a ratio and IL-4/IL-10 production. This is the first study to suggest that GA could be safe for MS patients with a proven viral infection.

Virus expanded regulatory T cells control disease severity in the Theiler's virus mouse model of MS.

Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease (TMEV-IDD) serves as virus-induced model of chronic progressive multiple sclerosis. Infection of susceptible SJL/J mice leads to life-long CNS virus persistence and a progressive autoimmune demyelinating disease mediated by myelin-specific T cells activated via epitope spreading. In contrast, virus is rapidly cleared by a robust CTL response in TMEV-IDD-resistant C57BL/6 mice. We investigated whether differential induction of regulatory T cells (Tregs) controls susceptibility to TMEV-IDD. Infection of disease-susceptible SJL/J, but not B6 mice, leads to rapid activation and expansion of Tregs resulting in an unfavorable CNS ratio of Treg:Teffector cells. In addition, anti-CD25-induced inactivation of Tregs in susceptible SJL/J, but not resistant B6, mice results in significantly decreased clinical disease concomitant with enhanced anti-viral CD4(+), CD8(+) and antibody responses resulting in decreased CNS viral titers. This is the first demonstration that virus-induced Treg activation regulates susceptibility to autoimmune disease differentially in susceptible and resistant strains of mice and provides a new mechanistic explanation for the etiology of infection-induced autoimmunity.

Modulation of viral replication in macrophages persistently infected with the DA strain of Theiler's murine encephalomyelitis virus.

BACKGROUND: Demyelinating strains of Theiler's murine encephalomyelitis virus (TMEV) such as the DA strain are the causative agents of a persistent infection that induce a multiple sclerosis-like disease in the central nervous system of susceptible mice. Viral persistence, mainly associated with macrophages, is considered to be an important disease determinant that leads to chronic inflammation, demyelination and autoimmunity. In a previous study, we described the establishment of a persistent DA infection in RAW macrophages, which were therefore named DRAW. RESULTS: In the present study we explored the potential of diverse compounds to modulate viral persistence in these DRAW cells. Hemin was found to increase viral yields and to induce cell lysis. Enviroxime and neutralizing anti-TMEV monoclonal antibody were shown to decrease viral yields, whereas interferon-alpha and interferon-gamma completely cleared the persistent infection. We also compared the cytokine pattern secreted by uninfected RAW, DRAW and interferon-cured DRAW macrophages using a cytokine protein array. The chemokine RANTES was markedly upregulated in DRAW cells and restored to a normal expression level after abrogation of the persistent infection with interferon-alpha or interferon-gamma. On the other hand, the chemokine MCP-1 was upregulated in the interferon-cured DRAW cells. CONCLUSION: We have identified several compounds that modulate viral replication in an in vitro model system for TMEV persistence. These compounds now await further testing in an in vivo setting to address fundamental questions regarding persistent viral infection and immunopathogenesis.

[Moraprenylphosphates suppress reproduction of Taylor murine encephalomyelitis virus and accumulation of VP3 viral protein in susceptible cell cultures BHK-21 and P388D1].

Influence of moraprenylphosphates (phosphorylated polyprenol of plant origin) upon the accumulation of Taylor murine encephalomyelitis virus VP3 protein in the susceptible cell cultures was studied. It has been shown that moraprenylphosphates inhibited the accumulation of VP3 at early stages of infectious process. Moraprenylphosphates were found to decrease infectivity of the virus as well as virus-induced cellular apoptosis. Mechanisms of immunomodulating and antiviral activity of moraprenylphosphates and prospects of their use as antiviral drugs have been discussed.

High-dose mouse immunoglobulin G administration suppresses Theiler's murine encephalomyelitis virus-induced demyelinating disease.

We studied the effect of high-dose mouse IgG on TMEV-induced demyelinating disease (TMEV-IDD). We injected TMEV intracerebrally into susceptible SJL/J mice and induced TMEV-IDD. Mouse IgG were injected intraperitonealy, and clinical course and various immunological indicators were studied. The results show that TMEV-IDD was significantly suppressed both clinically and histologically (P<0.01) when IgG were administered in the effector phase. The delayed type hypersensitivity and T cell proliferative response specific for TMEV were decreased by this treatment. In an ELISPOT assay, the number of TNF-alpha producing lymphocytes in the spinal cords was low in high-dose IgG treated mice compared with PBS treated control mice. These data suggest that administration of IgG suppresses TMEV-IDD and may be promising treatment to prevent exacerbation of human multiple sclerosis.

Structure of poliovirus type 2 Lansing complexed with antiviral agent SCH48973: comparison of the structural and biological properties of three poliovirus serotypes.

BACKGROUND: Polioviruses are human pathogens and the causative agents of poliomyelitis. Polioviruses are icosahedral single-stranded RNA viruses, which belong to the picornavirus family, and occur as three distinct serotypes. All three serotypes of poliovirus can infect primates, but only type 2 can infect mice. The crystal structures of a type 1 and a type 3 poliovirus are already known. Structural studies of poliovirus type 2 Lansing (PV2L) were initiated to try to enhance our understanding of the differences in host range specificity, antigenicity and receptor binding among the three serotypes of poliovirus. RESULTS: The crystal structure of the mouse neurovirulent PV2L complexed with a potent antiviral agent, SCH48973, was determined at 2.9 A resolution. Structural differences among the three poliovirus serotypes occur primarily in the loop regions of the viral coat proteins (VPs), most notably in the loops of VP1 that cluster near the fivefold axes of the capsid, where the BC loop of PV2L is disordered. Unlike other known structures of enteroviruses, the entire polypeptide chain of PV2L VP4 is visible in the electron density and RNA bases are observed stacking with conserved aromatic residues (Tyr4020 and Phe4046) of VP4. The broad-spectrum antiviral agent SCH48973 is observed binding in a pocket within the beta-barrel of VP1, in approximately the same location that natural 'pocket factors' bind to polioviruses. SCH48973 forms predominantly hydrophobic interactions with the pocket residues. CONCLUSIONS: Some of the conformational changes required for infectivity and involved in the control of capsid stability and neurovirulence in mice may occur in the vicinity of the fivefold axis of the poliovirus, where there are significant structural differences among the three poliovirus serotypes in the surface exposed loops of VP1 (BC, DE, and HI). A surface depression is located at the fivefold axis of PV2L that is not present in the other two poliovirus serotypes. The observed interaction of RNA with VP4 supports the observation that loss of VP4 ultimately leads to the loss of viral RNA. A model is proposed that suggests dual involvement of the virion fivefold and pseudo-threefold axes in receptor-mediated initiation of infection by picornaviruses.

Effect of Theiler's murine encephalomyelitis virus and cytokines on cultured oligodendrocytes and astrocytes.

The pathogenesis of Theiler's murine encephalomyelitis virus (TMEV)-induced demyelinating disease is still controversial. Our hypothesis is that primary infection of oligodendrocytes (OLGs) is not a crucial event in the pathogenesis of demyelination in this model. In fact, it has been proposed that myelin may be destroyed, as an innocent bystander, following an antiviral delayed-type hypersensitivity (DTH) response. This hypothesis would not need widespread oligodendroglial infection, because virus present in other cells would be sufficient to trigger a DTH response. The present study demonstrates that cultured OLGs and astrocytes from susceptible strains of mice (SJL and DBA) and immortalized OLGs can be infected with TMEV in vitro. Infection of OLGs, however, is at very low levels and does not result in overt cytolytic effect. In contrast, infection of immortalized OLGs is very efficient and results in clear cytolysis. Because an important characteristic of DTH responses is the liberation of potentially injurious cytokines into adjacent tissues, we also examined the effects of mouse recombinant tumor necrosis factor-alpha (TNF-alpha), interleukin-1 alpha (IL-1 alpha), and interferon-gamma (IFN-gamma) on cultured OLGs and immortalized OLGs. We found that TNF-alpha caused immortalized OLG cytotoxicity in a time- and dose-dependent manner. In contrast, no cytotoxicity was observed on primary OLGs with any of the above cytokines. To determine whether functional effects could be demonstrated on primary OLGs by either virus or cytokines, we measured mRNA expression of different myelin proteins in primary and immortalized OLGs exposed to virus or TNF-alpha. Neither the BeAn strain or the GDVII strain of TMEV interfered with myelin protein mRNA expression in primary OLGs, whereas GDVII virus dramatically reduced myelin OLG glycoprotein (MOG) mRNA in immortalized OLGs. Interestingly, although even high concentrations of TNF-alpha (10,000 U/ml) did not produce primary OLG cytotoxicity, they resulted in a significant reduction in mRNA for both myelin basic protein (MBP) and MOG in these cells. TNF-alpha (at 500 U/ml) also specifically reduced MOG mRNA in immortalized OLGs. Because immortalized OLGs are considered to be arrested at an early stage of maturation, our results suggest that immature OLGs are susceptible to both virus- and cytokine-dependent cytotoxicity, whereas mature OLGs are resistant to cytolysis by either TMEV or cytokines. TNF-alpha, however, is capable of reducing mRNA expression of myelin proteins in primary OLGs; therefore, it may participate in the induction of demyelination, as suggested by the DTH-mediated hypothesis.

Characteristics of cloned cerebrovascular endothelial cells following infection with Theiler's virus. I. Acute infection.

The present study describes the replication of Theiler's virus in cloned cerebrovascular endothelial cells (CVE) isolated from strains of mice that are either susceptible or resistant to Theiler's virus-induced demyelination (TVID). CVE isolated from all strains of mice were equally permissive to Theiler's virus infection. Interferon-gamma and tumor necrosis factor-alpha were found to inhibit the replication of Theiler's virus in CVE. A correlation between susceptibility to demyelination and the ability of Theiler's virus to induce MHC Class I on CVE was demonstrated.