Mechanisms of immune-mediated demyelinating disease of the central nervous system

Special issue dedicated to Dr. Louis Sokoloff.     

Myelin lipophilin-induced demyelinating disease of the central nervous system

Purified lipophilin, a hydrophobic lipoprotein of myelin, induces a cell-mediated demyelinating disease of the central nervous system similar to experimental allergic encephalomyelitis (EAE) induced by the myelin basic protein (MBP). Guinea pigs challenged with lipophilin (emulsified with CFA) developed clinical and histological signs of disease indistinguishable from those developed by animals similarly challenged with MBP. Both lipophilin and MBP induced and elicited delayed-type hypersensitivity in animals challenged with respective antigens. Tryptophan, an essential component of the MBP-determinant for disease in guinea pigs, is required for the encephalitogenicity of lipophilin.     

Kinesin family in murine central nervous system

In neuronal axons, various kinds of membranous components are transported along microtubules bidirectionally. However, only two kinds of mechanochemical motor proteins, kinesin and brain dynein, had been identified as transporters of membranous organelles in mammalian neurons. Recently, a series of genes that encode proteins closely related to kinesin heavy chain were identified in several organisms including Schizosaccharomyces pombe, Aspergillus niddulans, Saccharomyces cerevisiae, Caenorhabditus elegans, and Drosophila. Most of these members of the kinesin family are implicated in mechanisms of mitosis or meiosis. To address the mechanism of intracellular organelle transport at a molecular level, we have cloned and characterized five different members (KIF1-5), that encode the microtubule-associated motor domain homologous to kinesin heavy chain, in murine brain tissue. Homology analysis of amino acid sequence indicated that KIF1 and KIF5 are murine counterparts of unc104 and kinesin heavy chain, respectively, while KIF2, KIF3, and KIF4 are as yet unidentified new species. Complete amino acid sequence of KIF3 revealed that KIF3 consists of NH2-terminal motor domain, central alpha-helical rod domain, and COOH-terminal globular domain. Complete amino acid sequence of KIF2 revealed that KIF2 consists of NH2-terminal globular domain, central motor domain, and COOH-terminal alpha-helical rod domain. This is the first identification of the kinesin-related protein which has its motor domain at the central part in its primary structure. Northern blot analysis revealed that KIF1, KIF3, and KIF5 are expressed almost exclusively in murine brain, whereas KIF2 and KIF4 are expressed in brain as well as in other tissues. All these members of the kinesin family are expressed in the same type of neurons, and thus each one of them may transport its specific organelle in the murine central nervous system.     

Expression and potential role of inducible nitric oxide synthase in the central nervous system of Theiler's murine encephalomyelitis virus-induced demyelinating disease.

Intracerebral inoculation of susceptible strains of mice with Theiler's murine encephalomyelitis virus (TMEV) results in immune-mediated demyelinating disease. We examined the pathogenic roles of nitric oxide (NO) and inducible NO synthase (iNOS) in TMEV-induced demyelinating disease (TMEV-IDD). The presence of iNOS was confirmed in the spinal cords of TMEV-infected mice using immunohistochemical staining with anti-iNOS antibody on day 0 (control) and days 15, 30, 60, and 120. Aminoguanidine (AG), a specific inhibitor of iNOS, was injected intraperitoneally (ip) on 1, 3, 5, 8, 10, and 12 days post-TMEV inoculation as induction phase or 15, 17, 19, 22, 24, and 26 days as effector phase. Control animals in each experiment received phosphate-buffered saline (PBS) ip at similar time intervals. Few iNOS-positive cells were observed in the spinal cords of naive SJL/J mice. In the early phase (day 15) of TMEV-IDD, an increase of iNOS-positive cells was detected in the leptomeninges and perivascular space of the spinal cords. The number of iNOS-positive cells was increased and reached its peak on day 60, when histology of the animals showed peak infiltration with inflammatory cells. The clinical course of TMEV-IDD on each day postintracerebral infection was significantly reduced in mice treated with AG in the effector phase, and there was no significant difference between mice treated with AG in induction phase versus those administered PBS. Thus, NO production via iNOS appears to be a pathogenic factor in the effector phase of TMEV-IDD.     

Animal models for autoimmune demyelinating disorders of the nervous system

Multiple sclerosis (MS) is an inflammatory demyelinating disease of the central nervous system (CNS) that takes a relapsing-remitting or a progressive course (reviewed in Refs 1,2). Its counterpart in the peripheral nervous system (PNS) is chronic inflammatory demyelinating polyradiculoneuropathy (CIDP) (reviewed in Ref. 3). In addition, there are acute, monophasic disorders, such as the inflammatory demyelinating polyradiculoneuropathy termed Guillain-Barré syndrome (GBS) in the PNS, and acute disseminated encephalomyelitis (ADEM) in the CNS. Both MS and GBS are heterogeneous syndromes. In MS different exogenous assaults together with genetic factors can result in a disease course that finally fulfils the diagnostic criteria. In both diseases, axonal damage can add to a primarily demyelinating lesion and cause permanent neurological deficits. No single animal model exists that mimics all the features of human demyelinating diseases; rather, the available models reflect specific facets. Here, we focus on experimental autoimmune encephalomyelitis (EAE) and neuritis (EAN) as models in rat and mouse strains, and discuss their distinct histopathology and the roles played by different autoantigens.     

Plasmalogenase activity in normal and demyelinating tissue of the central nervous system

1. The plasmalogenase activity of brain was found to be associated with the white matter but was absent from myelin fractions. 2. Increased enzyme activity was found in demyelinating spinal cords from vitamin B₁₂-deficient monkeys and in white matter from a patient with multiple sclerosis.     

Mechanisms of magnetic stimulation of central nervous system neurons

Transcranial magnetic stimulation (TMS) is a stimulation method in which a magnetic coil generates a magnetic field in an area of interest in the brain. This magnetic field induces an electric field that modulates neuronal activity. The spatial distribution of the induced electric field is determined by the geometry and location of the coil relative to the brain. Although TMS has been used for several decades, the biophysical basis underlying the stimulation of neurons in the central nervous system (CNS) is still unknown. To address this problem we developed a numerical scheme enabling us to combine realistic magnetic stimulation (MS) with compartmental modeling of neurons with arbitrary morphology. The induced electric field for each location in space was combined with standard compartmental modeling software to calculate the membrane current generated by the electromagnetic field for each segment of the neuron. In agreement with previous studies, the simulations suggested that peripheral axons were excited by the spatial gradients of the induced electric field. In both peripheral and central neurons, MS amplitude required for action potential generation was inversely proportional to the square of the diameter of the stimulated compartment. Due to the importance of the fiber's diameter, magnetic stimulation of CNS neurons depolarized the soma followed by initiation of an action potential in the initial segment of the axon. Passive dendrites affect this process primarily as current sinks, not sources. The simulations predict that neurons with low current threshold are more susceptible to magnetic stimulation. Moreover, they suggest that MS does not directly trigger dendritic regenerative mechanisms. These insights into the mechanism of MS may be relevant for the design of multi-intensity TMS protocols, may facilitate the construction of magnetic stimulators, and may aid the interpretation of results of TMS of the CNS.     

Degeneration and repair in central nervous system disease

Divergent disease triggers in neurodegeneration may induce convergent endogenous pathways in neuronal, glial and vascular elements as the central nervous system (CNS) attempts to compensate, remodel and recover. Dissecting these multicellular mechanisms and the integrative responses in cerebral blood flow and metabolism may allow us to understand the balance between injury and repair, validate new targets and define therapeutic time windows for neurodegeneration.     

中枢神经系统隐球菌感染动物模型的研究

目的 构建中枢神经系统隐球菌感染的动物模型。方法 给予小鼠脑内接种隐球菌构建中枢神经系统隐球菌感染的动物模型。小鼠被随机地分为实验组和对照组,给予实验组小鼠脑内接种隐球菌菌悬液,对照组小鼠脑内接种生理盐水。结果 从组织病理方面观察到,实验组小鼠脑组织中的蛛网膜下腔、软脑膜表面、脑实质内、侧脑室脉络丛组织内均可见隐球菌菌体,脑膜轻度增生,侧脑室轻度扩大,脉络丛血管轻度扩张充血。对照组小鼠脑组织可见侧脑室轻度扩大,蛛网膜下腔血管、脑实质内血管、脉络丛血管均有轻度扩张充血,而蛛网膜下腔、软脑膜表面、脑实质内及侧脑室和室旁均未见隐球菌浸润。从组织病理观察结果两组具有一定的对比性。结论 小鼠脑内接种隐球菌构建其中枢神经系统隐球菌感染的模型,为研究人中枢神经系统隐球菌病提供了一个工具。     

In vivo and in vitro models of demyelinating disease: JHM virus in the rat central nervous system localized by in situ cDNA hybridization and immunofluorescent microscopy.

In situ probing of central nervous system (CNS) tissues has made it possible to associate the presence of JHM virus (JHMV) RNA with individual cells in the rat CNS. The presence of viral RNA was not always associated with antigen expression. The in situ hybridization revealed that cerebellar Purkinje cells and hippocampal neurons were highly susceptible to JHMV infection during either acute or paralytic disease. In the paralytic disease, Purkinje cell neurons frequently contained viral RNA. This observation suggests that these neurons, and perhaps others, may be repositories for JHMV in rats that undergo prolonged infections.     

B-lymphocyte requirement for vaccine-mediated protection from Theiler's murine encephalomyelitis virus-induced central nervous system disease.

The role of humoral immunity in the protection of vaccinated SJL/J mice from central nervous system disease induced by the DA strain (DAV) of Theiler's murine encephalomyelitis virus was investigated in B-cell-deficient mice. Mice were depleted of B cells by treatment with a mouse monoclonal antibody specific for immunoglobulin M. DAV-vaccinated, B-cell-deficient mice failed to clear viral infection and were no longer protected from Theiler's murine encephalomyelitis virus-mediated central nervous system disease. CD4+ T cells are required in this model of protection to provide help for the development of an antiviral antibody response in the central nervous system.     

Immunolocalization of iron regulatory protein expression in the murine central nervous system

We examined the expression of the iron regulatory proteins 1 and 2 (IRP1 and IRP2) in the brains of adult (4-6 months) CBA/J mice. Anti-IRP1 immunoreactivity was localized to cell bodies, including putative neurons and oligodendrocytes. In contrast, anti-IRP2 staining was prevalent throughout the neuropil of regions of the brain consistent with the central autonomic network (CAN) and mossy fibers emanating from hippocampal dentate granule cells. Essentially no staining for IRP2 was observed in the cerebellum in contrast to strong IRP1 immunoreactivity in Purkinje cells. Notably, cells within one vestibular nucleus exhibited staining by both IRP1 and IRP2. Our results suggest distinct roles for IRP1 and IRP2 in the regulation of iron homeostasis in the mammalian nervous system where IRP1 may provide a maintenance function in contrast to IRP2 that could participate in modulating proper CAN functions, including cardiopulmonary, gustatory as well as fine motor control.     

Progressive chronic inflammatory demyelinating polyneuropathy in a child with central nervous system involvement and myopathy

Chronic inflammatory demyelinating polyneuropathy (CIDP) is a chronic disorder, manifesting with monophasic or relapsing course. Progressive course is rare in children. The article presents a boy with progressive generalized muscle weakness and areflexia since the age of two, developed after viral infection. Electromyoneurography showed severe neurogenic lesion, with myopathic pattern in proximal muscles. Increased serum ganglioside antibody titers (anti-GM1 and anti-GD1b) were registered. Sural nerve biopsy revealed demyelination and onion bulbs. Inflammatory perivascular CD3 positive infiltrates were present in muscle and nerve biopsies. Brain magnetic resonance imaging showed cortical atrophy, hyperintensities of the white matter and gray matter hypointensities. Improvement occurred on intravenous immune globulins and methylprednisolone treatment. Demyelination might develop in central and peripheral nervous system associated with inflammatory myopathy in patients with progressive course of CIDP.     

The blood cerebrospinal fluid barrier orchestrates immunosurveillance,immunoprotection, and immunopathology in the central nervous system

Once characterized as an immune privileged area, recent scientific advances have demonstrated that the central nervous system (CNS) is both immunologically active and a specialized site. The anatomical and cellular features of the brain barriers, the glia limitans, and other superficial coverings of the CNS endow the brain with specificity for immune cell entry and other macro- and micro-elements to the brain. Cellular trafficking via barriers comprised of tightly junctioned non-fenestrated endothelium or tightly regulated fenestrated epithelium results in different phenotypic and cellular changes in the brain, that is, inflammatory versus regulatory changes. Based on emerging evidence, we described the unique ability of the blood cerebrospinal fluid barrier (BCSFB) to recruit, skew, and suppress immune cells. Additionally, we sum up the current knowledge on both cellular and molecular mechanisms governed by the choroid plexus and the cerebrospinal fluid at the BCSFB for immunosurveillance, immunoprotection, and immunopathology.     

Age-dependent pathogenesis of murine gammaherpesvirus 68 infection of the central nervous system

Gammaherpesvirus infection of the central nervous system (CNS) has been linked to various neurological diseases, including meningitis, encephalitis, and multiple sclerosis. However, little is known about the interactions between the virus and the CNS in vitro or in vivo. Murine gammaherpesvirus 68 (MHV-68 or _γHV-68) is genetically related and biologically similar to human gammaherpesviruses, thereby providing a tractable animal model system in which to study both viral pathogenesis and replication. In the present study, we show the successful infection of cultured neuronal cells, microglia, and astrocytes with MHV-68 to various extents. Upon intracerebroventricular injection of a recombinant virus (MHV-68/LacZ) into 4–5-week-old and 9–10-week-old mice, the 4–5-week-old mice displayed high mortality within 5–7 days, while the majority of the 9–10-week-old mice survived until the end of the experimental period. Until a peak at 3–4 days post-infection, viral DNA replication and gene expression were similar in the brains of both mouse groups, but only the 9–10-week-old mice were able to subdue viral DNA replication and gene expression after 5 days post-infection. Pro-inflammatory cytokine mRNAs of tumor necrosis factor-α, interleukin 1β, and interleukin 6 were highly induced in the brains of the 4–5-week-old mice, suggesting their possible contributions as neurotoxic factors in the agedependent control of MHV-68 replication of the CNS. These authors contributed equally to this work.     

Association of Chlamydia pneumoniae with central nervous system disease

Chlamydia pneumoniae is a common respiratory pathogen that is now being incriminated in a number of chronic diseases. The ability of C. pneumoniae to infect and persist in macrophages makes it a likely candidate to disseminate in a number of different tissues, including those of the central nervous system. This review addresses the potential and the underlying mechanisms by which C. pneumoniae infections can play a role in such diverse neurological diseases as multiple sclerosis and Alzheimer's disease.     

Mechanisms involved in activity-dependent synapse formation in mammalian central nervous system cell cultures

Differences in neuronal activity produced by electrical stimulation lead to competition between synapses from sensory afferents converging on a common spinal cord neuron. Studies were performed on neurons dissociated from the mouse spinal cord and grown in culture dishes with three compartments. Synaptic efficacy from stimulated afferents was increased compared with unstimulated convergents, and the number of functional connections was increased by stimulation compared with control cultures. Blocking NMDA channel activation with 100 microM APV in medium containing 1.8 mM calcium inhibited this synaptic plasticity, but plasticity was not blocked by APV in medium in which the calcium concentration was elevated to 3 mM. These experiments support the view that electrical activity differentially influences processes that cause a persistent decrease in synaptic efficacy or lead to synapse elimination and those that increase synaptic strength or lead to synapse augmentation. We interpret our results in terms of a model in which these antagonistic mechanisms are both regulated via changes in calcium levels and second messengers that are modulated by electrical activity. A significant portion of the activity-related calcium influx relevant to synaptic plasticity passes through the NMDA channel, but other sources of calcium are involved. In particular, competitive elimination of synapses appears to occur during blockade of NMDA channels if the extracellular concentration of calcium is elevated moderately. The outcome of competition between the two calcium-dependent but antagonistic processes may depend either on their differential sensitivity to intracellular calcium concentration or separate specificities to NMDA and non-NMDA receptor-linked mechanisms.