Experimental allergic encephalomyelitis mediated by murine encephalitogenic T cell lines specific for myelin proteolipid apoprotein

T cell lines specific for bovine myelin proteolipid apoprotein (PLP) were established from SJL/J mice. The line cells bore surface phenotypes of T helper/inducer cells (Lyt-1+, Lyt-2-, L3T4+) and responded well to bovine, rat, and guinea pig PLP but not to myelin basic protein. One line responded to major PLP, and another responded to both major PLP and DM-20, which are the two major intrinsic membrane proteins of the central nervous system (CNS) myelin. Intraperitoneal inoculation of 4 to 30 X 10(6) PLP-activated line cells followed by injection of pertussis vaccine induced acute inflammatory disease of the CNS, with typical clinical signs of EAE mostly in a week in recipient mice that had been treated with low-dose irradiation. Almost all animals recovered completely, and two of the 12 animals relapsed 42 or 75 days after inoculation. The lesions were restricted to the CNS and were characterized by perivascular and parenchymal infiltration of inflammatory cells, fibrin deposit, and demyelination. In the severe lesions, axons were also damaged. These observations suggest that PLP is a definite encephalitogen, and PLP-sensitized effector T cells induce inflammatory demyelination in the CNS.     

Over-Expression of the DM-20 Myelin Proteolipid Causes Central Nervous System Demyelination in Transgenic Mice

Abstract: We have created transgenic mice bearing varying copy numbers of a transgene coding for normal DM-20, the alternatively spliced quantitatively minor isoform of myelin proteolipid protein. Demyelination of the CNS occurs as a consequence of 70 copies of this transgene. Overt symptoms begin at ∼3 months with a wobbling gait. Occasional seizures lasting a few seconds begin at 3–4 months. These symptoms progress in severity with age. Death occurs by 8–10 months. Myelination in 2-month-old animals, before the onset of any overt symptoms, appears morphologically normal at the electron microscopic level. However, the myelin in these 2-month-old animals has a reduced amount of the major myelin proteolipid protein and about three times as much DM-20 as normal animals. In 7-month-old animals that appear to be undergoing demyelination in the CNS, both the major myelin proteolipid protein and DM-20 are greatly reduced relative to the 2-month-old animal. Mice with 17 copies of the transgene also have a reduced amount of the major myelin proteolipid protein but appear to be otherwise normal and have normal life spans (>2 yr). Mice with low copy numbers of the transgene (2–4 copies) appear to be unaffected and have normal life spans.     

Epigenetic factors up-regulate expression of myelin proteins in the dysmyelinating jimpy mutant mouse

Proteolipid protein (PLP) is a major structural component of central nervous system (CNS) myelin. Evidence exists that PLP or the related splice variant DM-20 protein may also play a role in early development of oligodendrocytes (OLs), the cells that form CNS myelin. There are several naturally occurring mutations of the PLP gene that have been used to study the roles of PLP both in myelination and in OL differentiation. The PLP mutation in the jimpy (jp) mouse has been extensively characterized. These mutants produce no detectable PLP and exhibit an almost total lack of CNS myelin. Additionally, most OLs in affected animals die prematurely, before producing myelin sheaths. We have studied cultures of jp CNS in order to understand whether OL survival and myelin formation require production of normal PLP. When grown in primary cultures, jp OLs mimic the relatively undifferentiated phenotype of jp OLs in vivo. They produce little myelin basic protein (MBP), never immunostain for PLP, and rarely elaborate myelin-like membranes. We report here that jp OLs grown in medium conditioned by normal astrocytes synthesize MBP and incorporate it into membrane expansions. Some jp OLs grown in this way stain with PLP antibodies, including an antibody to a peptide sequence specific for the mutant jp PLP. This study shows that: (1) an absence of PLP does not necessarily lead to dysmyelination or OL death; (2) OLs are capable of translating at least a portion of the predicted jp PLP; (3) the abnormal PLP made in the cultured jp cells is not toxic to OLs. These results also highlight the importance of environmental factors in controlling OL phenotype. © 1996 John Wiley & Sons, Inc.     

Proteolipid/DM-20 proteins bearing the paralytic tremor mutation in peripheral nerves and transfected Cos-7 cells

Paralytic tremor (Plp-pt) is a missense mutation of the myelin proteolipid gene (Plp) in rabbits. The myelin yield in the Plp-pt brain is reduced and the protein and lipid composition of central nervous system (CNS) myelin is abnormal. We studied the intracellular transport of the normal and Plp-pt mutant PLP and DM-20 in transiently transfected Cos-7 cells. While the mutant PLP accumulates in the rough endoplasmic reticulum and does not reach the plasma membrane, the spliced isoform of PLP, mutant DM-20, is normally transported to the cell surface and integrated into the membrane. Analysis of rabbit sciatic nerves revealed that concentration of peripheral nervous system (PNS) myelin proteins is normal in Plp-pt myelin. In the PNS like in the CNS, the level of Plp gene products is subnormal. But this does not affect myelination, in the PNS where PLP, present in low concentration, is not a structural component of compact myelin. The normal level of Plp gene expression in Schwann cells is low and these results suggest that, in the Plp-pt PNS, Schwann cell function is not affected by the deficiency in PLP and/or the impairment of intracellular PLP transport. Special issue dedicated to Dr Marion E. Smith.     

Morphometric Analysis of Normal, Mutant, and Transgenic CNS: Correlation of Myelin Basic Protein Expression to Myelinogenesis

The neurological mutant mice shiverer (shi) and myelin deficient (shimld) lack a functional gene for the myelin basic proteins (MBP), have virtually no myelin in their CNS, shiver, seize, and die early. Mutant mice homozygous for an MBP transgene have MBP mRNA and MBP in net amounts approximately 25% of normal, have compact myelin, do not shiver or seize, and live normal life spans. We bred mice with various combinations of the normal, transgenic, shi, and shimld genes to produce mice that expressed MBP mRNA at levels of 0, 5, 12.5, 17.5, 50, 62.5, and 100% of normal. The CNS of these mice were analyzed for MBP content, tissue localization of MBP, degree of myelination, axon size, and myelin thickness. MBP protein content correlated with predicted MBP gene expression. Immunocytochemical staining localized MBP to white matter in normal and transgenic shi mice with an intensity of staining comparable to the degree of MBP gene expression. An increase in the percentage of myelinated axons and the thickness of myelin correlated with increased gene expression up to 50% of normal. The percentage of myelinated axons and myelin thickness remained constant at expression levels greater than 50%. The presence of axons loosely wrapped with oligodendrocytic membrane in mice expressing lower amounts of MBP mRNA and protein suggested that the oligodendroglia produced sufficient MBP to elicit axon wrapping but not enough to form compact myelin. Mean axon circumference of myelinated axons was greater than axon circumference of unmyelinated axons at each level of gene expression, further evidence that oligodendroglial cells preferentially myelinate axons of larger caliber.(ABSTRACT TRUNCATED AT 250 WORDS)     

Truncated Tau with the Fyn-binding domain and without the microtubule-binding domain hinders the myelinating capacity of an oligodendrocyte cell line

The mechanisms underlying developmental myelination have therapeutic potential following CNS injury and degeneration. We report that transplanted central glial (CG)-4 cells had a diminished myelinating capacity in myelin-deficient (md) rats when cells express a mutated form of Tau (Tau [688]), which binds Fyn but not the microtubules. In the brain of the md rats, Tau [688]-transfected CG-4 cells displayed a decrease in cellular process outgrowth and myelination; in the spinal cord the extent of myelination rostral and caudal to the injection site was decreased. In contrast, control Tau [605]-transfected CG-4 cells formed long cellular processes and substantial areas of myelin both in the brain and spinal cord. In culture, Tau [688]-transfected CG-4 cells displayed a decrease in cellular process outgrowth, and Fyn localized largely in the cell body, not the processes. Thus, Tau in oligodendrocytes plays a key role in myelination, and a functional Tau-Fyn interaction might have therapeutic potential during demyelination and myelin repair following CNS injury and degeneration.     

Specific T regulatory cells display broad suppressive functions against experimental allergic encephalomyelitis upon activation with cognate antigen

To date, very few Ag-based regimens have been defined that could expand T regulatory (Treg) cells to reverse autoimmunity. Additional understanding of Treg function with respect to specificity and broad suppression should help overcome these limitations. Ig-proteolipid protein (PLP)1, an Ig carrying a PLP1 peptide corresponding to amino acid residues 139-151 of PLP, displayed potent tolerogenic functions and proved effective against experimental allergic encephalomyelitis (EAE). In this study, we took advantage of the Ig-PLP1 system and the PLP1-specific TCR transgenic 5B6 mouse to define a regimen that could expand Ag-specific Treg cells in vivo and tested for effectiveness against autoimmunity involving diverse T cell specificities. The findings indicate that in vivo exposure to aggregated Ig-PLP1 drives PLP1-specific 5B6 TCR transgenic cells to evolve as Treg cells expressing CD25, CTLA-4, and Foxp3 and producing IL-10. These Treg cells were able to suppress PLP1 peptide-induced EAE in both SJL/J and F(1) (SJL/J x C57BL/6) mice. However, despite being effective against disease induced with a CNS homogenate, the Treg cells were unable to counter EAE induced by a myelin basic protein or a myelin oligodendrocyte glycoprotein peptide. Nevertheless, activation with Ag before transfer into the host mice supports suppression of both myelin oligodendrocyte glycoprotein- and myelin basic protein peptide-induced EAE. Thus, it is suggested that activation of Treg cells by the cognate autoantigen is necessary for operation of broad suppressive functions.     

A myelin proteolipid protein-LacZ fusion protein is developmentally regulated and targeted to the myelin membrane in transgenic mice

Transgenic mice were generated with a fusion gene carrying a portion of the murine myelin proteolipid protein (PLP) gene, including the first intron, fused to the E. coli LacZ gene. Three transgenic lines were derived and all lines expressed the transgene in central nervous system white matter as measured by a histochemical assay for the detection of beta-galactosidase activity. PLP-LacZ transgene expression was regulated in both a spatial and temporal manner, consistent with endogenous PLP expression. Moreover, the transgene was expressed specifically in oligodendrocytes from primary mixed glial cultures prepared from transgenic mouse brains and appeared to be developmentally regulated in vitro as well. Transgene expression occurred in embryos, presumably in pre- or nonmyelinating cells, rather extensively throughout the peripheral nervous system and within very discrete regions of the central nervous system. Surprisingly, beta- galactosidase activity was localized predominantly in the myelin in these transgenic animals, suggesting that the NH2-terminal 13 amino acids of PLP, which were present in the PLP-LacZ gene product, were sufficient to target the protein to the myelin membrane. Thus, the first half of the PLP gene contains sequences sufficient to direct both spatial and temporal gene regulation and to encode amino acids important in targeting the protein to the myelin membrane.     

Generation of demyelination models by targeted ablation of oligodendrocytes in the zebrafish CNS

Demyelination is the pathological process by which myelin sheaths are lost from around axons, and is usually caused by a direct insult targeted at the oligodendrocytes in the vertebrate central nervous system (CNS). A demyelinated CNS is usually remyelinated by a population of oligodendrocyte progenitor cells, which are widely distributed throughout the adult CNS. However, myelin disruption and remyelination failure affect the normal function of the nervous system, causing human diseases such as multiple sclerosis. In spite of numerous studies aimed at understanding the remyelination process, many questions still remain unanswered. Therefore, to study remyelination mechanisms in vivo, a demyelination animal model was generated using a transgenic zebrafish system in which oligodendrocytes are conditionally ablated in the larval and adult CNS. In this transgenic system, bacterial nitroreductase enzyme (NTR), which converts the prodrug metronidazole (Mtz) into a cytotoxic DNA cross-linking agent, is expressed in oligodendrocyte lineage cells under the control of the mbp and sox10 promoter. Exposure of transgenic zebrafish to Mtz-containing media resulted in rapid ablation of oligodendrocytes and CNS demyelination within 48 h, but removal of Mtz medium led to efficient remyelination of the demyelinated CNS within 7 days. In addition, the demyelination and remyelination processes could be easily observed in living transgenic zebrafish by detecting the fluorescent protein, mCherry, indicating that this transgenic system can be used as a valuable animal model to study the remyelination process in vivo, and to conduct high-throughput primary screens for new drugs that facilitate remyelination.     

Peptide determinants of myelin proteolipid protein (PLP) in autoimmune demyelinating disease: A review

This article reviews recent advances in understanding the role of myelin proteolipid protein (PLP) in autoimmune demyelination. It is drawn largely from work published within the last years and discusses the immunology of PLP in the historical context of what has been learned from extensive studies on the immune response to myelin basic protein (MBP). Despite the, fact that PLP is the major protein constituent of mammalian myelin, its role in autoimmune demyelination has not been widely recognized. The lack of understanding about the immunology of PLP is a direct result of the biochemical characteristics of the protein. PLP is a highly hydrophobic membrane protein with limited aqueous solubility. The hydrophobicity of PLP has thwarted, immunologic studies of the intact protein. Recent work has circumvented the technical obstacles of studying the intact protein by using soluble synthetic PLP peptides. This approach has rapidly resulted in a more definitive understanding of the immune response to PLP. Presently, the data indicate that:i) PLP is a major central nervous system (CNS) specific encephalitogen;ii) CD4+T cell reactivity to discrete PLP peptide determinants can mediate the development of acute chronic relapsing, and chronic progressive experimental autoimmune encephalomyelitis (EAE); andiii) T cell reactivity to multiple PLP determinants occurs in patients with multiple sclerosis (MS), the major human CNS demyleinating disease.Special Issue dedicated to Dr. Majorie B. Lees.     

Immunoglobulins and complement in demyelination induced in mice by Theiler's virus

Intracerebral inoculation of Theiler's murine encephalomyelitis virus (TMEV) produces chronic demyelination and persistent infection in the central nervous system (CNS) of susceptible SJL mice. This series of experiments examined the contribution of humoral immunity and C to myelin destruction. As in multiple sclerosis, mice persistently infected with TMEV had elevated levels of IgG and oligoclonal bands in the cerebrospinal fluid (CSF). Immunoblot studies revealed that even in animals exhibiting profound demyelination, IgG in the serum and CSF was directed primarily at virus antigen rather than at normal myelin components. Inflammatory cells positive for Ig were distributed mainly around blood vessels, but occasionally they infiltrated the spinal cord parenchyma. Rare examples of myelin sheaths positive for IgG were found by immunoelectron microscopy in spinal cord sections from infected mice; the third component of complement (C3) was commonly found in the walls of CNS blood vessels but not on myelin. Neither serum nor CSF IgG from infected mice bound to myelin sheaths or other CNS components in sections of normal syngeneic spinal cord. There were significantly more demyelinating lesions in infected mice depleted of C components with cobra venom factor. These data do not support a humoral autoimmune basis for the CNS demyelination that occurs in association with persistent TMEV infection. However, the humoral immune response directed at TMEV antigens may either limit virus spread or promote virus persistence.     

The immunopathology of chronic experimental allergic encephalomyelitis induced in rabbits with bovine proteolipid protein

The role of myelin proteolipid apoprotein (PLP) in the central nervous system (CNS) immune response of rabbits has been investigated by analyzing the immunopathology of chronic experimental allergic encephalomyelitis (EAE) induced by sensitization with PLP. Clinical disease occurred in seven out of nine rabbits sensitized with bovine PLP and monitored for up to 6 mo. Positive delayed hypersensitivity skin test reactions to PLP occurred in all but one of the PLP-sensitized animals. All PLP-sensitized animals had meningeal and CNS parenchymal inflammation that correlated with disease severity. Serial blood samples were stained with a panel of antibodies to rabbit T and B cells, as well as Ia, and large and small mononuclear cell populations were analyzed by flow cytometry. Peripheral leukocyte population staining did not correlate with clinical signs or sensitization to PLP. Cryostat CNS tissue sections were stained with the same set of antibodies by using an immunoperoxidase technique, and positive cells and vessels were counted. T cells and macrophages were numerous and in equal numbers in perivascular parenchymal inflammatory infiltrates, whereas B cells were less numerous (p less than 0.001). T cells also diffusely infiltrated the parenchyma. Most perivascular inflammatory cells and many scattered parenchymal cells were Ia+; Ia vascular expression was increased over controls (p less than 0.001), and also correlated with disease severity. The immunopathology of this chronic EAE model is the same as that of whole CNS tissue- and myelin basic protein-induced EAE in other species, and is similar to that of multiple sclerosis. Cellular immune responses to PLP may therefore contribute to systemic and in situ responses in CNS tissue demyelinating diseases.     

Effects of Rumpshaker Mutation on CNS Myelin Composition and Structure

Abstract: Myelinated CNS tissues from homozygous/hemizygous and heterozygous jimpy rumpshaker jp ^rsh mutant mice were examined to determine the consequences on myelin structure of this mutation in the proteolipid protein (PLP) gene. Polyacrylamide gel electrophoresis and immunoblotting of brain homogenates confirmed that there was a decrease in PLP levels on the B6C3 genetic background onto which this gene was bred. We also observed an increase in level of a protein band that could correspond to the uncharacterized 10-kDa PLP previously reported in jp ^rsh mice on an Rb(1.3) 1Bnr background. High-performance TLC and densitometry of lipids from brain homogenate and isolated myelin revealed a decrease in content of cerebrosides and sulfatides. Electron microscopy on optic nerves revealed that normal radial component is retained in jp ^rsh myelin, further substantiating that PLP is not a component of this junctional complex. X-raydiffraction measurements on unfixed optic nerves showed that the jp ^rsh period is 5–10 Å larger than normal. Moreover, jp ^rsh optic nerve myelin was unstable, as evidenced by a continual increase in the period postdissection. jp ^rsh myelin that was equilibrated at varying pH and ionic strength typically had a larger than normal period under all conditions (both swelling and compacting). Our findings thus demonstrate that the biochemical abnormalities in the jp ^rsh mutant correlate with a wider periodicity and less stable packing of the myelin.     

Evolution of a neuroprotective function of central nervous system myelin

The central nervous system (CNS) of terrestrial vertebrates underwent a prominent molecular change when a tetraspan membrane protein, myelin proteolipid protein (PLP), replaced the type I integral membrane protein, P0, as the major protein of myelin. To investigate possible reasons for this molecular switch, we genetically engineered mice to express P0 instead of PLP in CNS myelin. In the absence of PLP, the ancestral P0 provided a periodicity to mouse compact CNS myelin that was identical to mouse PNS myelin, where P0 is the major structural protein today. The PLP-P0 shift resulted in reduced myelin internode length, degeneration of myelinated axons, severe neurological disability, and a 50% reduction in lifespan. Mice with equal amounts of P0 and PLP in CNS myelin had a normal lifespan and no axonal degeneration. These data support the hypothesis that the P0-PLP shift during vertebrate evolution provided a vital neuroprotective function to myelin-forming CNS glia.     

IL-17A Promotes Granulocyte Infiltration,Myelin Loss,Microglia Activation,and Behavioral Deficits During Cuprizone-Induced Demyelination

Recent evidence suggests a pivotal role of the proinflammatory cytokine interleukin - 17A (IL-17) in demyelinating autoimmune diseases of the central nervous system (CNS) such as multiple sclerosis (MS). Nevertheless, it remains unclear if this cytokine exerts direct effects on CNS resident cells during MS or modulates the function of infiltrating immune cells towards a more detrimental phenotype. Here, we investigated the effects of locally produced IL-17 during experimental demyelination of the CNS using the cuprizone (CPZ) model in mice with (GF/IL17) or without transgenic production of IL-17 by astrocytes in the CNS. During early demyelination, GF/IL17 mice demonstrated enhanced activity and decreased anxiety-related behavior in the elevated plus maze suggesting a more severe disease course. Furthermore, in GF/IL17 mice, toxic demyelination was accelerated and synthesis of myelin proteins was reduced. Early demyelination was accompanied by an increased ratio of infiltrating granulocytes in GF/ILl17 mice. The presence of IL-17 during CPZ treatment increased the accumulation of activated microglia and sustained microglial proliferation during myelin loss. Taken together, our results argue for a detrimental role of IL-17 during demyelinating diseases.