key: cord-0036462-bf2r2f4c authors: Lavi, Ehud title: Histopathology in Coronavirus-Induced Demyelination date: 2005 journal: Experimental Models of Multiple Sclerosis DOI: 10.1007/0-387-25518-4_37 sha: b2a35f2f5651210034a473c45d1a7480845e6644 doc_id: 36462 cord_uid: bf2r2f4c The experimental model system of coronavirus mouse hepatitis virus (MHV) induced demyelination in 4–6 week old C57Bl/6 or Balb/c mice exhibits a biphasic disease and two distinct forms of virus-induced demyelination. During the acute phase of the disease MHV infection causes acute encephalitis, and some strains of virus cause also hepatitis. Infection with the JHM strain of MHV causes severe panencephalitis, whereas MHV-A59 causes mild to moderate encephalitis involving specific limbic and limbic related areas of the brain and brain stem. The target cells are neurons and glia including oligodendrocytes. Demyelination during the acute stage is due to cytolytic infection of oligodendrocytes. After two weeks, the disease process enters a chronic stage of immune-mediated demyelination, in the presence of high levels of anti-viral antibodies and persistent low levels viral RNA in glial cells, without detectable levels of infectious virus or viral antigens. The mechanism of demyelination in the model system of MHV-induced demyelination has been the subject of intense controversy. In the early years following its original description, the MHV model has been considered a perfect example of virus-induced demyelination due to direct cytolytic effect on oligodendrocytes, as opposed to EAE and the Theiler's virus induced encephalomyelitis model, which were considered the prototypes of autoimmune demyelination. In recent years, evidence was presented in favor of an immune-mediated mechanism in MHV-induced demyelination. However, examining the strong evidence that supports each mechanism it appears that the only explanation for to this discrepancy is that the two mechanisms co-exist in the same model. While the early descriptions referred to the cytolytic mechanism of acute infection, the later evidence described the mechanism that dominates the chronic disease. In the following chapter the histopathological features of MHV disease of the brain will be described for the two stages of the disease. Some strains of MHV are purely hepatotropic (e.g. MHV-2) (Hirano et al. 1981) , some are primarily neurotropic (e.g. JHM ) (Robb et al. 1979) , while others (MHV-A59, MHV-S and MHV-3) are both hepatotropic and neurotropic (Virelizier et al. 1975; Barthold and Smith 1983; Lavi et al. 1986 ). MHV infection has been extensively used as a model system for viral persistence and for acute and chronic neurologic diseases (Weiner 1973; Knobler et al. 1981; Stohlman and Weiner 1981; Sorensen et al. 1982; Wege et al. 1982 ; Barthold and Smith 1983; Buchmeier et al. 1984; Perlman et al. 1990 ). The experimental models of neurotropic MHVs exhibit a bi-phasic disease. Acute meningoencephalitis (with or without hepatitis) is the major pathologic process in the first two weeks following inoculation. Subsequently, subacute and chronic diseases develop, which can be either an inflammatory demyelinating disease (in JHM and A59) or vasculitis (in MHV-3). MHV enters and spreads into the brain primarily by hematogenous spread. This conclusion is based on the fact that injection of virus into one hemisphere produces a simultaneous appearance of viral antigen in both hemispheres at the same time. When the route of infection is by intracerebral injection virus quickly enters the blood circulation and re-enters the brain, and other target organs such as liver, by hematogenous spread. However, following intranasal inoculation of mice, virus can be traced propagating from the olfactory system into limbic system structures and their connections in the brain stem. Thus interneuronal transport has been suggested as an additional mode of spread within neuronal cells during acute encephalitis (Barthold 1988; Lavi et al. 1988 ; Barnett et al. 1993 ). In addition, the fact that the virus travels from cerebral hemispheres to brainstem and then to spinal cord (Perlman et al. 1990 ) suggests an interneuronal transport. During the acute phase of the disease the JHM strain of MHV causes severe panencephalitis, involving the telencephalon, diencephalon, brain stem, cerebellum and spinal cord. In contrast to the pantropic property of wt JHM, MHV-A59 and certain mutants of JHM produce a limited CNS disease restricted to specific locations of predilection. These include the olfactory and limbic systems, and certain basal nuclei, which are physiologically connected with the limbic system. Acute MHV encephalitis cuases a lytic infection of cells including neurons, astrocytes and oligodendrocytes (Lampert et al. 1973) . This finding raised the speculation that demyelination is caused only by direct cytolytic effect of the virus on oligodendrocytes. The first description of the ability of MHV to cause demyelination was in 1949. Cheever and co-workers isolated JHM, a strain of MHV, from the brains of mice with hind leg paralysis (Cheever et al. 1949) . A detailed histological analysis by Bailey et al revealed disseminated encephalomyelitis and areas of demyelination with sparing of axons in the brain and spinal cord (Bailey et al. 1949 ). Twenty-four years later, Leslie Weiner studied in more details the pathogenesis of demyelination induced by JHM (Weiner 1973) . He found that the development of demyelination was a function of the age of mice, the dose of virus and the route of inoculation. The study was focused on demyelination during the 7-15 days post infection. There was evidence of viral antigen but no evidence of immunopathology. Immunosuppressive treatment did not abolish demyelination and taking all this information together the study concluded that JHM-induced demyelination was due to a cytopathic effect of the virus on oligodendrocytes. In the same year Lampert and co-workers came to the same conclusion. They studied by electronmicroscopy the ultrastructural pathology of JHM-induced acute demyelination, 3-6 days after infection. They found acute encephalomyelitis with patchy demyelination in the brainstem and spinal cord. They also found viral particles consistent with the appearance of coronaviruses in the cytoplasm of oligodendrocytes. The obvious conclusion from that study was that JHM replicated in oligodendrocytes and killed some of them causing demyelination. Both JHM and A59 then cause subacute and chronic inflammatory demyelination in the brain, but mainly in the spinal cord (Stohiman and Weiner 1981; ). Propagation of virus from the initial site of infection in the brain to the spinal cord occurs by transport of the virus in neurons and astrocytes (Sun and Perlman 1995) . Astrocytes in particular may play an important role in this process by secreting cytokines and producing iNOS . Perivascular mononuclear (lymphocytic/macrophage) inflammatory infiltration of meninges and Virchow-Robin spaces is seen adjacent to areas of destruction of myelin, denuded, but otherwise intact axons, and macrophages containing myelin debris are seen in various areas of white matter, especially in the spinal cords of infected animals (Lampert et al. 1973; Weiner 1973; Fleury et al. 1980; . Recurrent demyelination, remyelination, regeneration of oligodendrocytes and increased myelin basic protein gene expression have been demonstrated in various MHV model systems (Herndon et al. 1975; Herndon et al. 1977; Kristensson et al. 1986 ). These features parallel many of the pathologic findings seen in multiple sclerosis in contrast to the monophasic viral or post viral human demyelinating diseases such as acute disseminated encephalomyelitis (ADEM), and progressive multifocal leukoencephalopathy (PML). Several laboratories including our own showed evidence of persistent coronavirus infection in both glial cell cultures and in animals. Persistent virions were demonstrated in chronic infection with ts mutant of JHM (Knobler et al. 1982) , and persistence of viral genome was found following infection with MHV-A59 . Persistent infection of glial cultures with MHV-A59 was used to demonstrate induction of MHC class I expression on astrocytes and oligodendrocytes, mediated by a soluble factor (Suzumura et al. 1986; Suzumura et al. 1988; Lavi et al. 1989) . MHC class II induction mediated by viral particles has been demonstrated in glial cell infection with JHM (Massa et al. 1986 ). In the last decade the role of an immune mediated pathogenesis as the major mechanism of chronic MHVinduced demyelinating disease has been suggested based on indirect evidence. Adoptive transfer of demyelination with T cells from JHMinfected rats and in-vitro sensitivity to myelin basic protein suggested the possibility that MHV induced demyelination can be at least in part an immune-mediated, EAE-like disease (Watanabe et al. 1984 ). Immunosuppression of mice infected with JHM decreased the incidence of demyelination suggesting that the chronic demyelinating disease is immunemediated (Wang et al. 1990 ). A murine virus (JHM) causing disseminated encephalomyelitis with extensive destruction of myelin. II Pathology Two neurotropic viruses, herpes simplex virus type 1 and mouse hepatitis virus, spread along different neural pathways from the main olfactory bulb Olfactory neural pathway in mouse hepatitis virus nasoencephalitis Mouse hepatitis virus S in weanling Swiss mice following intranasal inoculation Murine hepatitis virus-4 (strain JHM) -induced neurologic disease is modulated in vivo by monoclonal antibody A murine virus (JHM) causing disseminated encephalomyelitis with extensive destruction of myelin Further ultrastractrual observations of morphogenesis and myelin pathology in JHM virus encephalomyelitis Mouse hepatitis virus induced recurrent demyelination Regeneration of oligodendroglia during recovery from demyelinating disease Comparison of mouse hepatitis virus strains for pathogenicity in weanling mice infected by various routes Mouse hepatitis virus type 4 (JHM strain)-induced fatal central nervous system disease, part 1 (genetic control and the murine neurone as the susceptible site for disease) Virus persistence and recurring demyelination produced by a temperature sensitive mutant of MHV-4 Increased levels of myelin basic protein transcript gene in virus-induced demyelination Mechanism of demyelination in JHM virus induced encephalomyelitis, electron microscopic studies Limbic encephalitis following inhalation of murine coronavirus MHV-A59 Persistence of MHV-A59 RNA in a slow virus demyelinating infection in mice as detected by in situ hybridization The organ tropism of mouse hepatitis virus A59 is dependent on dose and route of inoculation Experimental demyelination produced by the A59 strain of mouse hepatitis virus Induction of MHC class I antigens on glial cells is dependent on persistent mouse hepatitis virus infection Viral particles induce la antigen expression on astrocytes Identification of the spinal cord as a major site of persistence during chronic infection with a murine coronavirus Pathogenic murine coronaviruses. III. Biological and biochemical characterization of temperature sensitive mutants of JHMV In vivo and in vitro models of demyelinating disease: endogenous factors influencing demyelinating disease caused by mouse hepatitis virus in rats and mice Chronic central nervous system demyelination in mice after JHM virus infection Activation of astrocytes in the spinal cord of mice chronically infected with a neurotropic coronavirus Spread of a neurotropic coronavirus to spinal cord white matter via neurons and astrocytes Induction of glial cell MHC antigen expression in neurotropic coronavirus infection: characterization of the H-2 inducing soluble factor elaborated by infected brain cells Coronavirus infection induces H-2 antigen expression on oligodendrocytes and astrocytes Neuropathological effects of persistent infection of mice by mouse hepatitis virus Demyelination induced by murine hepatitis virus JHM strain (MHV-4) is immunologically mediated Adoptive transfer of EAE-like lesion from rats with coronavirus-induced demyelinating encephalomyelitis The biology and pathogenesis of coronaviruses Pathogenesis of demyelination induced by a mouse hepatitis virus (JHM virus) This work was supported in part by grants from the NIH and the National Multiple Sclerosis Society. The intellectual and technical contributions of Li Fu, Yun Li, Jayasri Das Sarma, Talya Schwartz, Donna M. Gonzales and Elsa Aglow are greatly appreciated.