Transgenic expression of viral capsid proteins predisposes to axonal injury in a murine model of multiple sclerosis

We used transgenic expression of capsid antigens to Theiler's murine encephalomyelitis virus (TMEV) to study the influence of VP1, VP2 or VP2(121-130) to either protection or pathogenesis to chronic spinal cord demyelination, axonal loss and functional deficits during the acute and chronic phases of infection. We used both mice that are normally susceptible (FVB) and mice normally resistant (FVB.D(b) ) to demyelination. Transgenic expression of VP2(121-130) epitope in resistant FVB.D(b) mice caused spinal cord pathology and virus persistence because the VP2(121-130) epitope is the dominant peptide recognized by D(b) , which is critical for virus clearance. In contrast, all three FVB TMEV transgenic mice showed more demyelination, inflammation and axonal loss as compared with wild-type FVB mice, even though virus load was not increased. Motor function measured by rotarod showed weak correlation with total number of midthoracic axons, but a strong correlation with large-caliber axons (>10μm(2) ). This study supports the hypothesis that expression of viral capsid proteins as self influences the extent of axonal pathology following Theiler's virus-induced demyelination. The findings provide insight into the role of axonal injury in the development of functional deficits that may have relevance to human demyelinating disease.     

Inhibition of Theiler's virus-induced demyelination in vivo by tumor necrosis factor alpha

Employing a murine model of multiple sclerosis which utilizes intracranial injection of Theiler's virus murine encephalomyelitis (TMEV) into SJL/J mice, we tested the potential role of tumor necrosis factor alpha (TNF-alpha) in ameliorating CNS demyelination. Infection with TMEV caused early grey matter inflammation (7 days post-infection) in the brain and spinal cord followed by chronic demyelination (35 days post-infection) in the spinal cord. Administration of recombinant human or mouse TNF-alpha starting 12 h prior to infection and then three times weekly had minimal effect on development of grey matter inflammation in the spinal cord. In contrast, TNF-alpha dramatically reduced demyelination present in spinal cord on days 14 and 35 after TMEV infection (P less than 0.01) when compared to controls. CNS virus titers of TMEV were not modified by TNF-alpha administration as measured on days 7, 14, and 35 following infection. In vivo administration of TNF-alpha inhibits TMEV-induced demyelination in susceptible SJL/J mice without affecting virus replication in the CNS.     

Direct comparison of demyelinating disease induced by the Daniel's strain and BeAn strain of Theiler's murine encephalomyelitis virus

We compared CNS disease following intracerebral injection of SJL mice with Daniel's (DA) and BeAn 8386 (BeAn) strains of Theiler's murine encephalomyelitis virus (TMEV). In tissue culture, DA was more virulent then BeAn. There was a higher incidence of demyelination in the spinal cords of SJL/J mice infected with DA as compared to BeAn. However, the extent of demyelination was similar between virus strains when comparing those mice that developed demyelination. Even though BeAn infection resulted in lower incidence of demyelination in the spinal cord, these mice showed significant brain disease similar to that observed with DA. There was approximately 100 times more virus specific RNA in the CNS of DA infected mice as compared to BeAn infected mice. This was reflected by more virus antigen positive cells (macrophages/microglia and oligodendrocytes) in the spinal cord white matter of DA infected mice as compared to BeAn. There was no difference in the brain infiltrating immune cells of DA or BeAn infected mice. However, BeAn infected mice showed higher titers of TMEV specific antibody. Functional deficits as measured by Rotarod were more severe in DA infected versus BeAn infected mice. These findings indicate that the diseases induced by DA or BeAn are distinct.     

Mechanism of Theiler's virus-induced demyelination in nude mice

In its natural murine host, infection with Theiler's murine encephalomyelitis virus (TMEV) produces a chronic, progressive demyelinating disease. To help elucidate the role of host immune mechanisms involved in demyelination, we studied TMEV infection in Nude mice. These animals demonstrated rising titers of infectious virus within the central nervous system and failed to produce anti-TMEV antibody. Neurologic signs including the development of severe hind limb paralysis were evident approximately 2 weeks postinfection with most animals succumbing within the first month. Immunoperoxidase studies demonstrated viral antigen in the cytoplasm of neurons and glial cells for the entire period of observation. Plaques of demyelination associated with scanty inflammatory infiltrates were present in the spinal cord by 14 days postinfection. Electron microscopic studies of the involved white matter revealed numerous degenerating glial cells, many of which contained paracrystalline arrays of picornavirus within their cytoplasm. Some of the infected glial cells were identified as oligodendrocytes by demonstrating their myelin-plasma membrane connections. The studies indicate that in Nude mice TMEV causes a lytic infection of oligodendrocytes producing demyelination independent of the T lymphocyte immune system.     

The relationship between viral RNA, myelin-specific mRNAs, and demyelination in central nervous system disease during Theiler's virus infection.

The DA strain of Theiler's murine encephalomyelitis virus (DAV) causes a chronic demyelinating disease in susceptible mouse strains. To elucidate the pathogenesis of DAV-induced demyelination, the authors investigated the spatial and chronologic relationship between virus (antigen and RNA), myelin-specific mRNAs, and demyelination in DAV-infected mice using immunohistochemistry, in situ hybridization, and slot blot hybridization analyses. In spinal cord white matter, viral RNA was detected easily in ventral root entry zones 1 to 2 weeks after infection. Viral RNA increased to maximum levels by 4 weeks after infection, which was associated with inflammation and mild demyelination. At 8 to 12 weeks after infection, when demyelination became most extensive, viral RNA was significantly decreased. Demyelination did not chronologically or spatially parallel the presence of viral RNA within the spinal cord. Decrease of myelin-specific mRNAs, including myelin-basic protein and proteolipid protein mRNAs, was observed within the demyelinating lesions with or without detectable viral RNA. These results indicate that a viral infection of white matter in the early phase of the infection initiates spinal cord disease leading to demyelination, but later an ongoing immunopathologic process contributes to the presence of extensive demyelination.     

Clearance of Theiler's virus infection depends on the ability to generate a CD8+ T cell response against a single immunodominant viral peptide

Theiler's murine encephalomyelitis virus (TMEV) induces a chronic demyelinating disease in the central nervous system of susceptible mice. Resistance to persistent TMEV infection maps to he D locus of the major histocompatibility complex suggesting a prominent role of antiviral CTL in the protective immune response. Introduction of the D(b) gene into the FVB strain confers resistance to this otherwise susceptible mouse line. Infection of the FVB/D(b) mouse with TMEV provides a model where antiviral resistance is determined by a response elicited by a single class I molecule. Resistant mice of the H-2(b) haplotype mount a vigorous H-2D(b)-restricted immunodominant response to the VP2 capsid protein. To investigate the extent of the contribution of the immunodominant T cell population in resistance to TMEV, FVB/D(b) mice were depleted of VP2-specific CD8(+) T cells by peptide treatment prior to virus infection. Peptide-treated mice were not able to clear the virus and developed extensive demyelination. These findings demonstrate that the D(b)-restricted CD8(+) T cells specific for a single viral peptide can confer resistance to TMEV infection. Our ability to manipulate this cellular response provides a model for investigating the mechanisms mediating protection against virus infection by CD8(+) T cells.     

CD40L is critical for protection from demyelinating disease and development of spontaneous remyelination in a mouse model of multiple sclerosis

Theiler's murine encephalomyelitis virus (TMEV) induces acute neuronal disease followed by chronic demyelination in susceptible strains of mice. In this study we examined the role of a limited immune defect (deletion or blocking of CD40 ligand [CD40L]) on the extent of brain disease, susceptibility to demyelination, and the ability of demyelinated mice to spontaneously remyelinate following TMEV infection. We demonstrated that CD40L-dependent immune responses participate in pathogenesis in the cerebellum and the spinal cord white matter but protect the striatum of susceptible SJL/J mice. In mice on a background resistant to TMEV-induced demyelination (C57BL/6), the lack of CD40L resulted in increased striatal disease and meningeal inflammation. In addition, CD40L was required to maintain resistance to demyelination and clinical deficits in H-2 ^b mice. CD40L-mediated interactions were also necessary for development of protective H-2^b-restricted cytotoxic T cell responses directed against the VP2 region of TMEV as well as for spontaneous remyelination of the spinal cord white matter. The data presented here demonstrated the critical role of this molecule in both antibody- and cell-mediated protective immune responses in distinct phases of TMEV-mediated pathology.     

Experience with examination of the spinal cord and peripheral nervous system (PNS) in mice: A brief overview

The representative areas for examination of the mouse peripheral nervous system are the spinal cord, containing central components of the peripheral nervous system that needs to be examined at least at cervical and lumbar level, the sciatic and the tibial nerve. Skeletal muscle samples should include the soleus muscle and the quadriceps femoris or long digital extensor, as well as the medial gastrocnemius. Examination can be extended to the thoracic spinal cord, lumbar dorsal root ganglia and spinal nerve roots, as well as the plantar nerve, and other areas of interest. Perfusion fixation is considered optimal for the nervous system; however, immersion fixation allows producing microscopic sections of excellent quality as well. Paraffin-embedded, hematoxylin and eosin-stained sections can be made from all areas, save for small nerves such as the tibial or plantar nerve, which are examined with advantage in hard plastic sections. It is possible to produce hard plastic sections also of the vertebral column, including the spinal cord, dorsal root ganglia and nerve roots. For special investigations, mice can be fixed in toto, decalcified, embedded and sectioned to reveal the areas of interest. In the mouse peripheral nerves, myelination progresses until the adult age. In aging peripheral nerves there is axonal atrophy, degeneration, nerve fiber loss, increase of collagen and sporadic demyelination, especially radiculoneuropathy. The dorsal root ganglia of untreated control animals show frequent cytoplasmic vacuolation. Axonal degeneration is distally, primary demyelination proximally accentuated. Mouse is not very sensitive to peripheral neurotoxicity: to induce toxic peripheral neuropathy mostly parenteral administration and/or newborn animals are used. Naturally occurring infection affecting the spinal cord and peripheral nerves is Theiler's encephalomyelitis virus inducing acute poliomyelitis or chronic demyelination. Any experimental results are to be assessed taking into account spontaneous, age-related, background changes.     

Ultrastructural immunohistochemical localization of virus in acute and chronic demyelinating Theiler's virus infection.

Mice experimentally infected with Theiler's murine encephalomyelitis virus (TMEV) develop a persistent infection of the central nervous system (CNS). The most striking feature of this infection is the occurrence of inflammatory primary demyelination in the spinal cord white matter. The pathogenesis of myelin degeneration in this model has not been clarified, but morphologic and immunologic data suggest that the host immune response plays a major role in the production of myelin injury. Because of low virus titers in infected adult mice and of the small size of TMEV, virus particles have never been observed in this demyelinating model. Yet elucidation of the types of cells in the CNS supporting virus replication would be important for a better understanding of both virus persistence and virus-induced demyelinating pathology. The present paper is a sequential study of the localization of TMEV in the spinal cord in infected mice by ultrastructural immunohistochemical techniques. Results indicate that virus replication is mainly in neurons during the acute phase of the disease, while in the chronic phase viral inclusions are mainly found in macrophages in and around demyelinating lesions. Other cells are also infected, but to a lesser degree. In the neuronal system both axoplasmic and dendritic flow appear to facilitate the spread of virus in the CNS. In macrophages, the presence of virus particles and the association of virus with altered components of the cytoskeleton support active virus production rather than simple internalization. The macrophage appears to play an important role in both the establishment of virus persistence and in the process of demyelination in this animal model.     

Demyelination and axonal dystrophy in alpha A-crystallin transgenic mice

Homozygous mice transgenic for alphaA-crystallin, one of the structural eye lens proteins, developed hindlimb paralysis after 8 weeks of age. To unravel the pathogenesis of this unexpected finding and the possible role of alphaA-crystallin in this pathological process, mice were subjected to a histopathological and immunohistochemical investigation. Immunohistochemistry showed large deposits of alphaA-crystallin in the astrocytes of the spinal cord, and in the Schwann cells of dorsal roots and sciatic nerves. Additionally, microscopy showed dystrophic axons in the spinal cord and digestion chambers as a sign of ongoing demyelination in dorsal roots and sciatic nerves. Apart from a few areas with slight alphaA-crystallin-immunopositive structures, the brain was normal. Because the alphaA-crystallin protein expression appeared in specific cells of the nervous system (astrocytes and Schwann cells), the most plausible explanation for the paralysis is a disturbance of cell function caused by the excessive intracytoplasmic accumulation of the alphaA-crystallin protein. This is followed by a sequence of secondary changes (demyelination, axonal dystrophy) and finally arthrosis. In conclusion, alphaA-crystallin transgenic mice develop a peripheral and central neuropathy primarily affecting spinal cord areas at the dorsal side, dorsal root and sciatic nerve.     

Type 3 reovirus neuroinvasion after intramuscular inoculation: direct invasion of nerve terminals and age-dependent pathogenesis

Neonatal but not adult mice are vulnerable to reovirus invasion of the central nervous system after peripheral inoculation. After hindlimb injection, type 3 reovirus travels via the sciatic nerve to replicate in spinal cord motor neurons before spread to the brain and development of lethal encephalitis. Here we provide ultrastructural evidence for direct reovirus invasion of unmyelinated neonatal motor nerve terminals within 2 h and replication in spinal cord motor neurons within 14 h after hindlimb injection of 1-day-old mice. In adult mice, resistance to reovirus lethality after intracranial (IC) injection correlates with the restriction of virus growth in cortical neurons. We found that neuroinvasion also is age dependent after intramuscular injection. Virus lethality and CNS infection decreased sharply during the first postnatal week, while lethality after IC injection continued for 2 additional weeks. Mice inoculated at 7 days of age with high virus doses suffered paralysis of the injected limb, but significant brain infection was not lethal. These results suggest that reovirus invasion of the neonatal CNS is restricted by several progressive age-dependent mechanisms.     

Demyelination and axonal degeneration in Lewis rat experimental allergic neuritis depend on the myelin dosage

We describe the clinical and pathologic features of experimental allergic neuritis in Lewis rats inoculated with varying doses of myelin, ranging from 0.5 to 20 mg. The clinical scores were assessed daily. On days 18 and 19 or 28 postimmunization, the rats were perfused with fixative and samples of cervical and lumbar roots and sciatic nerves were processed and embedded in Epon. Tissues were examined by light and electron microscopy and the degree of edema, inflammation, demyelination, and axonal degeneration was assessed quantitatively. We found that the severity of clinical and pathologic experimental allergic neuritis correlated positively with the dose of myelin used for immunization. High dose tolerance was not observed. Demyelination prevailed in nerve roots and increased with higher doses of antigen. Accompanying axonal degeneration was seen only with high doses of myelin. The pathology of sciatic nerves differed. Sciatic nerves of rats immunized with 0.5 and 1 mg of myelin were either normal or showed perivenular lymphocytic infiltrates and demyelination, but nerves from rats with higher immunizing doses of myelin showed increasingly severe axonal degeneration. The axonal degeneration in nerve roots paralleled the degree of inflammation and demyelination and may have been a nonspecific product of the inflammatory reaction. However, the much more severe axonal destruction seen in sciatic nerves with high myelin doses was probably due to other pathogenetic mechanisms.     

Contrasting effects of immunosuppression on Theiler''s virus infection in mice.

In the present study, cyclophosphamide and rabbit anti-mouse thymocyte serum were used to immunosuppress SJL/J mice infected with Theiler's mouse encephalomyelitis virus (TMEV) in order to delineate the potential mechanism(s) of virus-induced cellular injury in this infection. Whereas both immunosuppressive agents produced a significant increase in mortality, this treatment had differing effects on the pathological involvement of gray and white-matter structures in the central nervous system. The central nervous system of immunosuppressed TMEV-infected mice had increased microglial cell proliferation and neuronal necrosis, longer maintenance of high virus levels and spread of virus antigen to involve the neocortex and hippocampal complex. These observations indicate that TMEV causes a cytolotic infection of neurons and possibly other cells in gray matter. In contrast, immunosuppression produced a dramatic reduction in mononuclear inflammatory cells in the leptomeninges and spinal cord white matter of infected mice and prevented demyelination. Further, virus antigen was not detected in the leptomeninges and white matter of immunosuppressed and infected mice. These findings suggest that demyelination of TMEV infection is immune mediated.     

Marek's disease as a model for the Landry--Guillain--Barré syndrome: latent viral infection in nonneuronal cells accompanied by specific immune responses to peripheral nerve and myelin.

In the chicken, Marek's disease virus (MDV) induces a demyelinating peripheral neuropathy that, early in the course of the disease, is histopathologically indistinguishable from that seen in the Landry--Guillain--Barré syndrome in man. A continuing role for a productive infection in the pathogenesis of this disease is unlikely, since neither MDV nor MDV antigens can be characteristically detected in nerves or spinal ganglia examined at necropsy. The authors investigated the possible role of a latent viral infection by explanting and maintaining in vitro the sciatic nerves and spinal ganglia from diseased birds. In these tissues, viral specific products were induced and detected by immunofluorescence and ultrastructural methods early after explanation in well-isolated Schwann cells, satellite cells, and lymphocytes. Later, virus was detected in fibroblasts, macrophages, and neoplastic lymphoblastoid cells. Neurons and myelinating Schwann cells, in contrast, did not replicate the agent. Specific cell-mediated and humoral immune responses to chicken peripheral nerve and peripheral nerve myelin were demonstrated early in the course of the disease. When considered relative to potential pathogenetic mechanisms, these results suggest that Marek's disease neuropathy is initiated by the establishment of a latent viral infection in neuronal supporting cells. A specific immune response to viral-induced antigens on these cells could, in turn, result in subsequent demyelination.     

Targeting inflammatory demyelinating lesions to sites of Wallerian degeneration

In Theiler's murine encephalomyelitis virus (TMEV) infection, an animal model for multiple sclerosis (MS), axonal injury precedes inflammatory demyelinating lesions, and the distribution of axonal damage present during the early phase of infection corresponds to regions where subsequent demyelination occurs during the chronic phase. We hypothesized that axonal damage recruits inflammatory cells to sites of Wallerian degeneration, leading to demyelination. Three weeks after TMEV infection, axonal degeneration was induced in the posterior funiculus of mice by injecting the toxic lectin Ricinus communis agglutinin (RCA) I into the sciatic nerve. Neuropathology was examined 1 week after lectin injection. Control mice, infected with TMEV but receiving no RCA I, had inflammatory demyelinating lesions in the anterior/lateral funiculi. Other control mice that received RCA I alone did not develop inflammatory lesions. In contrast, RCA I injection into TMEV-infected mice induced lesions in the posterior funiculus in addition to the anterior/lateral funiculi. We found no differences in lymphoproliferative responses or antibody titers against TMEV among the groups. This suggests that axonal degeneration contributes to the recruitment of inflammatory cells into the central nervous system by altering the local microenvironment. In this scenario, lesions develop from the axon (inside) to the myelin (outside) (Inside-Out model).     

CD4 T cells mediate axonal damage and spinal cord motor neuron apoptosis in murine p0106-125-induced experimental autoimmune neuritis

The pathogenesis of inflammatory autoimmune diseases of the peripheral nervous system, leading to demyelination and/or axonal damage, remains incompletely understood. In particular, it is controversial regarding the extent to which (i) autoimmune-mediated destruction of peripheral nerves results in secondary damage of the central nervous system, and (ii) CD4 and CD8 T cells contribute to disease. To address these issues, we applied the murine model of P0(106-125)-induced experimental autoimmune neuritis. Immunization of C57BL/6 mice with P0(106-125) resulted in severe axonal damage and mild demyelination. Importantly, these mice developed a "dying-back" axonopathy with apoptosis of a large fraction of neurons in the anterior horn of the lumbar and thoracic spinal cord and a progressive neurogenic muscular atrophy. T cell-depletion experiments identified CD4, but not CD8, T cells as important mediators of experimental autoimmune neuritis. CD4 T cells represented the major cellular source of antigen-specific interferon-gamma and interleukin-17 production, regulated the number of tumor necrosis factor-positive and inducible nitric oxide synthase-positive macrophages in the diseased sciatic nerve, and mediated axonal damage and subsequent neuronal apoptosis and neurogenic muscular atrophy. In contrast, the demyelination of peripheral nerves was only slightly ameliorated in CD4 T cell-depleted mice. In conclusion, P0(106-125)-induced experimental autoimmune neuritis is a CD4 T cell-mediated autoimmune disease that affects both the peripheral and central nervous systems.     

The response of the (myelinating) Schwann cell population to multiple episodes of demyelination

The effects of multiple intraneural injections of the known demyelinating agent lysophosphatidyl choline, LPC, have been studied in the sciatic nerves of adult mice. Up to six separate episodes of demyelination were induced at the same site within the tibial fascicle. Demyelination and subsequent remyelination occurred after each injection. The number of Schwann cells produced during each repair programme exceeded the number required for remyelination and some of the surplus cells temporarily remained associated with the remyelinating axon/Schwann cell units as supernumerary Schwann cells. There was a progressive decline in the proportion of promyelinated axons as the number of injections of LPC increased. The proposition that this could have reflected a more rapid repair following demyelination of thinly (re)myelinated axons was investigated in double LPC-injected nerves. No structures resembling onion bulbs characteristic of hypertrophic neuropathies in man were seen during the course of this study.     

Cytotoxic CD8+ T cell ablation enhances the capacity of regulatory T cells to delay viral elimination in Theiler's murine encephalomyelitis

Theiler's murine encephalomyelitis (TME) of susceptible mouse strains is a commonly used infectious animal model for multiple sclerosis. The study aim was to test the hypothesis whether cytotoxic T cell responses account for the limited impact of regulatory T cells on antiviral immunity in TME virus‐induced demyelinating disease (TMEV‐IDD) resistant C57BL/6 mice. TME virus‐infected C57BL/6 mice were treated with (i) interleukin‐2/‐anti‐interleukin‐2‐antibody‐complexes to expand regulatory T cells (“Treg‐expansion”), (ii) anti‐CD8‐antibodies to deplete cytotoxic T cells (“CD8‐depletion”) or (iii) with a combination of Treg‐expansion and CD8‐depletion (“combined treatment”) prior to infection. Results showed that “combined treatment”, but neither sole “Treg‐expansion” nor “CD8‐depletion,” leads to sustained hippocampal infection and virus spread to the spinal cord in C57BL/6 mice. Prolonged infection reduces myelin basic protein expression in the spinal cord together with increased accumulation of β‐amyloid precursor protein in axons, characteristic of myelin loss and axonal damage, respectively. Chronic spinal cord infection upon “combined treatment” was also associated with increased T and B cell recruitment, accumulation of CD107b⁺ microglia/macrophages and enhanced mRNA expression of interleukin (IL)‐1α, IL‐10 and tumor necrosis factor α. In conclusion, data revealed that the suppressive capacity of Treg on viral elimination is efficiently boosted by CD8‐depletion, which renders C57BL/6 mice susceptible to develop chronic neuroinfection and TMEV‐IDD.     

Kallikrein 6 regulates early CNS demyelination in a viral model of multiple sclerosis

Kallikrein 6 (Klk6) is a secreted serine protease that is elevated in active multiple sclerosis lesions and patient sera. To further evaluate the involvement of Klk6 in chronic progressive demyelinating disease, we determined its expression in the brain and spinal cord of SJL mice infected with Theiler's murine encephalomyelitis virus (TMEV) and assessed the effects of Klk6-neutralizing antibodies on disease progression. Klk6 RNA expression was elevated in the brain and spinal cord by 7 days postinfection (dpi). Thereafter, Klk6 expression persisted primarily in the spinal cord reaching a peak of fivefold over controls at mid-chronic stages (60?dpi-120?dpi). Significant elevations in Klk6 RNA were also induced in splenocytes stimulated with viral capsid proteins in vitro and in activated human acute monocytic leukemia cells. Klk6-neutralizing antibodies reduced TMEV-driven brain and spinal cord pathology and delayed-type hypersensitivity (DTH) responses when examined at early chronic time points (40?dpi). Reductions in spinal cord pathology included a decrease in activated monocytes/microglia and reductions in the loss of myelin basic protein (MBP). By 180?dpi, pathology scores no longer differed between groups. These findings point to regulatory activities for Klk6 in the development and progression of central nervous system (CNS) inflammation and demyelination that can be effectively targeted through the early chronic stages with neutralizing antibody.