Abbreviated exposure to cuprizone is sufficient to induce demyelination and oligodendrocyte loss

Cuprizone intoxication is one of several animal models used to study demyelination and remyelination. Early treatment protocols exposed mice to cuprizone for 6 weeks to induce demyelination; however, more recent reports have varied exposure times from 4 to 5 weeks. The goal of this study was to determine the minimal exposure of cuprizone in C57BL/6 mice that would induce a pathology of robust demyelination and gliosis similar to that described for a 5‐ or 6‐week treatment. We found that an abbreviated insult of only 2 weeks of exposure to cuprizone induced significant demyelination 3 weeks later (5‐week time point) but was somewhat variable. Three weeks of exposure to cuprizone produced extensive demyelination by week 5, equivalent to that observed with 5 weeks of exposure. The depletion of mature oligodendrocytes, as well as microglia and astrocyte accumulation, showed trends similar to those with 5‐week exposure to cuprizone. Once mature oligodendrocytes are perturbed after a 3‐week treatment, the progression to demyelination occurs without requiring further exposure. Furthermore, the early removal of cuprizone did not accelerate remyelination, suggesting that other sequences of events must follow before repair can occur. Thus, a short, “hit and run” CNS insult triggers a cascade of events leading to demyelination 2–3 weeks later. © 2012 Wiley Periodicals, Inc.     

Investigation of Cuprizone Inactivation by Temperature

Animal models, such as cuprizone (bis-cyclohexanone oxaldihydrazone) feeding, are helpful to study experimental demyelination and remyelination in the context of diseases like multiple sclerosis. Cuprizone is a copper chelator, which when supplemented to the normal food of C57BL/6J mice in a concentration of 0.2% leads to oligodendroglial loss, subsequent microglia and astrocyte activation, resulting in demyelination. Termination of the cuprizone diet results in remyelination, promoted by newly formed mature oligodendrocytes. The exact mode of cuprizone’s action is not well understood, and information about its inactivation and cleavage are still not available. The knowledge of these processes could lead to a better understanding of cuprizone’s mode of action, as well as a safer handling of this toxin. We therefore performed experiments with the aim to inactivate cuprizone by thermal heating, since it was suggested in the past that cuprizone is heat sensitive. C57BL/6J mice were fed for 4 weeks with 0.2% cuprizone, either thermally pretreated (60, 80, 105, 121 °C) or not heated. In addition, primary rat oligodendrocytes, as a known selective toxic target of cuprizone, were incubated with 350 μM cuprizone solutions, which were either thermally pretreated or not. Our results demonstrate that none of the tested thermal pretreatment conditions could abrogate or restrict the toxic and demyelinating effects of cuprizone, neither in vitro nor in vivo. In conclusion, the current study rebuts the hypothesis of cuprizone as a heat-sensitive compound, as well as the assumption that heat exposure is a reason for an insufficient demyelination of cuprizone-containing pellets.     

The cuprizone model for demyelination

Background –  Important advances in multiple sclerosis (MS) research have been made as a direct or indirect result of experiments in animal models for the disease, although MS is a disease only affecting humans. The cuprizone model is a model for toxic demyelination. In this model, young mice are fed with the copper chelator cuprizone, leading to oligodendrocyte death and a subsequent reversible demyelination. Spontaneous remyelination can be seen as early as 4 days after withdrawal of cuprizone.
Materials and methods –  This article reviews previous research on this model and discusses the potential of the model for future application in MS research.
Discussion –  The cuprizone model correlates with newer histopathological data in MS and is a valuable tool for studies on de- and remyelination. The use of the C57BL/6 strain offers the potential for future studies on transgene and knockout mice.     

Effects of acute and repeated exposure to lipopolysaccharide on cytokine and corticosterone production during remyelination

Chronic exposure to the copper-chelating agent, cuprizone (CPZ), is an increasingly popular model for producing demyelination. More importantly, cessation of cuprizone exposure allows for full remyelination, which represents a window of opportunity for determining the influence of environmental factors on regenerative processes. In the present study, CPZ-treated animals were assessed for functional status of systemic and central cytokine responsiveness to LPS, as well as assessment for signs of body weight changes. Exposure of male C57BL/6J mice to 5 weeks of 0.2% CPZ in the diet was optimal in producing demyelination and microglial activation, as measured by myelin basic protein, CD11b, and CD45 immunohistochemistry. Acute challenge with LPS at the end of 5 weeks CPZ treatment did not alter IL-1beta, IL-6, nor TNFalpha responses in the spleen and corpus callosum. Similarly, repeated exposure to LPS during the remyelination phase (CPZ removal) did not influence these measures to LPS. Plasma corticosterone was unaffected following acute challenge of CPZ-pretreated animals, but after repeated LPS treatment, there was a significant augmentation of the corticosterone response in CPZ-pretreated mice. Interestingly, the basal concentration of IL-1beta in the corpus callosum of CPZ treated animals was significantly increased, which was in keeping with the increase in activated microglial cells. In conclusion, the cuprizone model of demyelination and remyelination does not appear to influence the systemic nor central IL-1, IL-6, and TNF responses to acute nor repeated LPS. This opens up the possibility for studying the contribution of systemic inflammatory processes on remyelination after cessation of CPZ treatment.     

Episodic demyelination and subsequent remyelination within the murine central nervous system: changes in axonal calibre

Exposure of young adult C57BL/6 mice to cuprizone in the diet initiated profound and synchronous demyelination of the corpus callosum, which was virtually complete by 4 weeks of exposure. Interestingly, even in the face of a continued exposure to cuprizone, there was spontaneous remyelination 2 weeks later. This remyelination preferentially involved smaller calibre axons. There was a suggestion of yet another cycle of demyelination (at 10 weeks) and remyelination (at 12 weeks), but by 16 weeks of exposure, the regenerative capacity was exhausted and the animals were near death. The relapsing-remitting pattern suggests this may be a useful model for certain human demyelinating disorders. In contrast to the above chronic model, the corpus callosum from mice exposed to cuprizone for only 6 weeks continued to remyelinate, with 67% of the axons being myelinated or remyelinated at 10 weeks. Interestingly, a significant reduction in the mean value for axonal diameter was observed during acute demyelination. Upon remyelination, however, the axonal calibre distribution returned to near-normal. In contrast, when mice were maintained on a cuprizone diet for 16 weeks, the mean value for axonal diameter was reduced to 60% of normal. These results provide further evidence that the interactions between oligodendrocytes and axons alter axonal calibre.     

Astrocyte-specific expression of a soluble form of the murine complement control protein Crry confers demyelination protection in the cuprizone model

Complement has been implicated as a potential effector mechanism in neurodegeneration; yet the precise role of complement in this process remains elusive. In this report, we have utilized the cuprizone model of demyelination-remyelination to examine the contribution of complement to disease. C1q deposition was observed in the corpus callosum of C57BL/6 mice during demyelination, suggesting complement activation by apoptotic oligodendrocyte debris. Simultaneously, these mice lost expression of the rodent complement regulatory protein, Crry. A soluble CNS-specific form of the Crry protein (sCrry) expressed in a transgenic mouse under the control of an astrocyte-specific promoter was induced in the corpus callosum during cuprizone treatment. Expression of this protein completely protected the mice from demyelination. Interestingly, sCrry mice had low levels of demyelination at later times when control mice were remyelinating. Although the sCrry transgenic mice had lower levels of demyelination, there was no decrease in overall cellularity, however there were decreased numbers of microglia in the sCrry mice relative to controls. Strikingly, sCrry mice had early recovery of mature oligodendrocytes, although they later disappeared. TUNEL staining suggested that production of the sCrry protein in the transgenic mice protected from a late apoptosis event at 3 weeks of cuprizone treatment. Our data suggest complement provides some protection of mature oligodendrocytes during cuprizone treatment but may be critical for subsequent remyelination events. These data suggest that temporal restriction of complement inhibition may be required in some disease settings.     

Age increases axon loss associated with primary demyelination in cuprizone-induced demyelination in C57BL/6 mice

Axon loss is recognised as a significant contributor to the progression of the disability associated with multiple sclerosis. Although evidence of axon damage is found in areas of chronic demyelination it is more frequently seen in association with acute demyelination. This study compares the incidence of axon degeneration associated with the areas undergoing demyelination in young adult (8-10 weeks) and aged (6-7 months) C57BL/6 mice in cuprizone intoxication; a widely used model of demyelination. The incidence of axon transection, as indicated by the presence of SMI 32 positive axonal spheroids, and evidence of axon loss in the medial corpus callosum, were significantly greater in aged mice, as was the magnitude of the macrophage and astrocyte response to demyelination. Aged C57BL/6 mice are thus more prone to axon degeneration in association with demyelination than young adult mice. A retrospective study indicated that the incidence of axon degeneration was much higher in C57BL/6 mice than in the Swiss albino mice used in the early cuprizone intoxication studies which were fed much higher doses of cuprizone. These results indicate both a genetic and age susceptibility to demyelination-associated axon transection.     

Demyelination in the juvenile period, but not in adulthood, leads to long-lasting cognitive impairment and deficient social interaction in mice

Background

Dysmyelination is hypothesized to be one of the causes of schizophrenic symptoms. Supporting this hypothesis, demyelination induced by cuprizone was recently shown to cause schizophrenia-like symptoms in adult rodents [Xiao L, Xu H, Zhang Y, Wei Z, He J, Jiang W, et al. Quetiapine facilitates oligodendrocyte development and prevents mice from myelin breakdown and behavioral changes. Mol Psychiatry 2008;13:697–708]. The present study asked if the timing of demyelination (i.e., juvenile period or adulthood) influenced abnormal behavior.

Methods

B57BL/6 mice were fed with 0.2% cuprizone either from postnatal day 29 (P29) to P56 (early demyelination group) or from P57 to P84 (late demyelination group), and then returned to normal mouse chow until P126, when the behavioral analysis was initiated.

Results

In both groups, the intake of cuprizone for 28 days produced massive demyelination in the corpus callosum by the end of the treatment period, and subsequent normal feeding restored myelination by P126. In a Y-maze test, the spatial working memory was impaired in both groups right after the cuprizone feeding ceased, consistent with previous studies, whereas only the early demyelination group exhibited impaired working memory after remyelination took place. In an open field test, social interactions were decreased in the early demyelination group, but not in the late group. Novel cognition and anxiety-related behaviors were comparable between the two groups.

Conclusions

Our findings suggest that the timing of demyelination has substantial impacts on behaviors of adult mice.     

Peripheral macrophage recruitment in cuprizone-induced CNS demyelination despite an intact blood-brain barrier

The contribution of peripheral macrophage was assessed in cuprizone intoxication, a model of demyelination and remyelination in which the blood-brain barrier remains intact. Flow cytometry of brain cells isolated from cuprizone-treated mice revealed an increase in the percentage of Mac-1(+)/CD45(hi) peripheral macrophage. To confirm these results in situ, C57BL/6 mice were lethally irradiated, transplanted with bone marrow from GFP-transgenic mice, and exposed to cuprizone. GFP(+) peripheral macrophages were seen in the CNS after 2 weeks of treatment, and infiltration continued through 6 weeks. While the peripheral macrophages were far outnumbered by the resident microglia, their recruitment across the blood-brain barrier alludes to a potentially important role.     

Effect of CSF1R inhibitor on glial cells population and remyelination in the cuprizone model

Multiple sclerosis is a kind of autoimmune and demyelinating disease with pathological symptoms such as inflammation, myelin loss, astrocytosis, and microgliosis. The colony stimulating factor 1 receptor (CSF1R) is an essential factor for the microglial function, and PLX3397 (PLX) is its specific inhibitor. In this wstudy, we assessed the effect of different doses of PLX for microglial ablation on glial cell population and remyelination process. Sixty male C57BL/6 mice (8 weeks old) were divided into 6 groups. The animals were fed with 0.2% cuprizone diet for 12 weeks. For microglial ablation, PLX (290 mg/kg) was added to the animal food for 3, 7, 14 and 21 days. Glial cell population was measured using immunohistochemistry. The rate of remyelination was evaluated using electron microscopy and Luxol Fast Blue staining. The expression levels of all genes were assessed by qRT-PCR method. Data were analysed using GraphPad Prism and SPSS software. The results showed that the administration of different doses of PLX significantly reduced microglial cells (p ≤ .001). PLX administration also significantly increased oligodendrocytes population (p ≤ .001) and remyelination compared to the cuprizone mice, which was aligned with the results of LFB and TEM. Gene results showed that PLX treatment reduced CSF1R expression. According to the results, the administration of PLX for 21 days enhanced remyelination by increasing oligodendrocytes in the chronic demyelination model. These positive effects could be related to the reduction of microglia.     

Intravenous administration of human embryonic stem cell-derived neural precursor cells attenuates cuprizone-induced central nervous system (CNS) demyelination

S. J. Crocker, R. Bajpai, C. S. Moore, R. F. Frausto, G. D. Brown, R. R. Pagarigan, J. L. Whitton and A. V. Terskikh (2011) Neuropathology and Applied Neurobiology 37, 643–653 Intravenous administration of human embryonic stem cell‐derived neural precursor cells attenuates cuprizone‐induced central nervous system (CNS) demyelination Aims: Previous studies have demonstrated the therapeutic potential for human embryonic stem cell‐derived neural precursor cells (hES‐NPCs) in autoimmune and genetic animal models of demyelinating diseases. Herein, we tested whether intravenous (i.v.) administration of hES‐NPCs would impact central nervous system (CNS) demyelination in a cuprizone model of demyelination. Methods: C57Bl/6 mice were fed cuprizone (0.2%) for 2 weeks and then separated into two groups that either received an i.v. injection of hES‐NPCs or i.v. administration of media without these cells. After an additional 2 weeks of dietary cuprizone treatment, CNS tissues were analysed for detection of transplanted cells and differences in myelination in the region of the corpus callosum (CC). Results: Cuprizone‐induced demyelination in the CC was significantly reduced in mice treated with hES‐NPCs compared with cuprizone‐treated controls that did not receive stem cells. hES‐NPCs were identified within the brain tissues of treated mice and revealed migration of transplanted cells into the CNS. A limited number of human cells were found to express the mature oligodendrocyte marker, O1, or the astrocyte marker, glial fibrillary acidic protein. Reduced apoptosis and attenuated microglial and astrocytic responses were also observed in the CC of hES‐NPC‐treated mice. Conclusions: These findings indicated that systemically administered hES‐NPCs migrated from circulation into a demyelinated lesion within the CNS and effectively reduced demyelination. Observed reductions in astrocyte and microglial responses, and the benefit of hES‐NPC treatment in this model of myelin injury was not obviously accountable to tissue replacement by exogenously administered cells.     

Mouse strain differences in locomotor,sensitisation and rewarding effect of heroin; association with alterations in MOP‐r activation and dopamine transporter binding

There is growing agreement that genetic factors play an important role in the risk to develop heroin addiction, and comparisons of heroin addiction vulnerability in inbred strains of mice could provide useful information on the question of individual vulnerability to heroin addiction. This study examined the rewarding and locomotor‐stimulating effects of heroin in male C57BL/6J and DBA/2J mice. Heroin induced locomotion and sensitisation in C57BL/6J but not in DBA/2J mice. C57BL/6J mice developed conditioned place preference (CPP) to the highest doses of heroin, while DBA/2J showed CPP to only the lowest heroin doses, indicating a higher sensitivity of DBA/2J mice to the rewarding properties of heroin vs C57BL/6J mice. In order to investigate the neurobiological substrate underlying some of these differences, the effect of chronic ‘intermittent’ escalating dose heroin administration on the opioid, dopaminergic and stress systems was explored. Twofold higher μ‐opioid receptor (MOP‐r)‐stimulated [³⁵S]GTPγS binding was observed in the nucleus accumbens and caudate of saline‐treated C57BL/6J mice compared with DBA/2J. Heroin decreased MOP‐r density in brain regions of C57BL/6J mice, but not in DBA/2J. A higher density of dopamine transporters (DAT) was observed in nucleus accumbens shell and caudate of heroin‐treated DBA/2J mice compared with heroin‐treated C57BL/6J. There were no effects on D₁ and D₂ binding. Chronic heroin administration decreased corticosterone levels in both strains with no effect of strain. These results suggest that genetic differences in MOP‐r activation and DAT expression may be responsible for individual differences in vulnerability to heroin addiction.     

Platelet-derived growth factor promotes repair of chronically demyelinated white matter

In multiple sclerosis, remyelination becomes limited after repeated or prolonged episodes of demyelination. To test the effect of platelet-derived growth factor-A (PDGF-A) in recovery from chronic demyelination we induced corpus callosum demyelination using cuprizone treatment in hPDGF-A transgenic (tg) mice with the human PDGF-A gene under control of an astrocyte-specific promoter. After chronic demyelination and removal of cuprizone from the diet, remyelination and oligodendrocyte density improved significantly in hPDGF-A tg mice compared with wild-type mice. In hPDGF-A tg mice, oligodendrocyte progenitor density and proliferation values were increased in the corpus callosum during acute demyelination but not during chronic demyelination or the subsequent recovery period, compared with hPDGF-A tg mice without cuprizone or to treatment-matched wild-type mice. Proliferation within the subventricular zone and subcallosal zone was elevated throughout cuprizone treatment but was not different between hPDGF-A tg and wild-type mice. Importantly, hPDGF-A tg mice had reduced apoptosis in the corpus callosum during the recovery period after chronic demyelination. Therefore, PDGF-A may support oligodendrocyte generation and survival to promote remyelination of chronic lesions. Furthermore, preventing oligodendrocyte apoptosis may be important not only during active demyelination but also for supporting the generation of new oligodendrocytes to remyelinate chronic lesions.     

Sexual differences and estrous cycle in methamphetamine-induced dopamine and serotonin depletions in the striatum of mice

Summary. Four consecutive doses (10 mg/kg) of methamphetamine, s.c., produced a substantial striatal dopamine depletion in both sexes of BALB/c and C57BL/6J mice. Male C57BL/6J mice exhibited greater dopamine depletions in the striatum compared to female C57BL/6J mice. In contrast, male and female BALB/c mice demonstrated an equivalent magnitude of striatal dopamine depletion. Regardless of sex, C57BL/6J mice demonstrated approximately 1.4 to 2.2 times greater dopamine depletions in the striatum compared to BALB/c mice. Moreover, methamphetamine caused 4 times greater serotonin depletions in male as opposed to female BALB/c mice while sparing either sex of the C57BL/6J mice. Furthermore, female mice of both strains appeared to have the greatest basal dopamine levels during proestrus and the lowest basal dopamine levels during diestrus. Likewise, female mice of both strains exhibited the lowest dopamine depletions in the striatum when the dosing regimen of methamphetamine started at proestrus whereas the greatest dopamine depletions in the striatum occurred when the regimen started during diestrus. These results suggest that sex hormones and other modulating factors may play a role in methamphetamine-induced dopamine and serotonin neurotoxicity. Received August 3, 1999; accepted September 13, 1999     

Abrogation of resistance to Theiler's virus-induced demyelination in C57BL mice by total body irradiation

Theiler's murine encephalitis virus (TMEV) produces an unusual biphasic disease in susceptible mice characterized by poliomyelitis with early viral replication in neurons, followed by chronic demyelination with viral antigen expression in spinal cord white matter. In addition, infectious virus persists in the central nervous system (CNS) throughout the chronic phase of disease. Previous studies have indicated an important role for major histocompatibility complex (MHC)-gene products in determining resistance/susceptibility to disease. In particular, certain class I gene products of the D region of the H-2 gene complex render mice of the C57BL lineage resistant to induction of demyelination. Intracerebral infection of B10.S(DS) mice results in demyelination in the spinal cord while infection of C57BL/10(Db) or B10.S(9R)(Dd) fails to produce white matter destruction. In this study we showed that immunosuppression with gamma irradiation renders normally resistant B10.S(9R) and C57BL/10 mice susceptible to TMEV-induced demyelination and allowed for increased viral replication. In addition, the majority of irradiated C57BL/10 mice infected with virus showed extensive areas of CNS remyelination by oligodendrocytes beginning at 63 days post-infection. In contrast, immunosuppression of normally susceptible B10.S mice resulted in acute disease and high mortality accompanied by overwhelming destruction of neurons. The study supports the hypothesis that MHC-conferred resistance in C57BL mice is associated with MHC D region products and indicate an important active role for the immune system early in infection in limiting vital infection during disease induction in nonimmunosuppressed mice.     

Effects of commissural de- and remyelination on motor skill behaviour in the cuprizone mouse model of multiple sclerosis

Feeding of copper chelator cuprizone induces reversible demyelination, predominantly of the corpus callosum in C57/Bl6 mice. With the availability of knockout and transgenic mice, this animal model of multiple sclerosis has increasingly attracted scientists to study the roles of various factors involved in de- and remyelination. However, central motor deficits have not been reported in this model so far. In the present study, we introduce a novel murine motor test, the motor skill sequence (MOSS). This test is designed to detect latent deficits in motor performance. In a first step, we habituated mice to training wheels composed of regularly spaced crossbars till maximal wheel-running performance was achieved. Subsequently, the animals were exposed to wheels with irregularly spaced crossbars demanding high-level motor coordination. This two-step approach minimized a contribution of cardiopulmonary and musculoskeletal training to any improvement of motor performance on the complex wheels. We applied the MOSS test under acute cuprizone-induced demyelination as well as in remyelinated mice after cuprizone withdrawal. Demyelinated animals on a cuprizone diet already showed reduced running performance on the training wheels as compared to control animals. This was even more pronounced when these mice were subsequently exposed to the complex wheels. In contrast, remyelinated animals after cuprizone withdrawal did not exhibit any functional impairment on the training wheels. Latent motor skill deficits were however revealed on the complex wheels, although clearly ameliorated as compared to acutely demyelinated mice. Our results show that latent motor deficits of cuprizone-induced demyelination and after remyelination can be quantified by MOSS. This motor test thus expands the usability of the cuprizone model to a functional level and might also be applicable to other animal models of human CNS diseases associated with subtle motor deficits of central origin.     

Astrocyte‐targeted production of interleukin‐6 reduces astroglial and microglial activation in the cuprizone demyelination model: Implications for myelin clearance and oligodendrocyte maturation

Multiple sclerosis (MS) is a chronic demyelinating disease of the central nervous system. Interleukin (IL)−6 is a pleiotropic cytokine with a potential role in MS. Here we used transgenic mice with astrocyte‐targeted production of IL‐6 (GFAP‐IL6Tg) to study the effect of IL‐6 in the cuprizone‐induced demyelination paradigm, which is an experimental model of de‐ and re‐myelination, both hallmarks of MS. Our results demonstrated that cuprizone‐treated GFAP‐IL6Tg mice showed a significant reduction in astroglial and especially microglial activation/accumulation in the corpus callosum in comparison with the corresponding cuprizone‐treated wild type (WT). Production of a key microglial attracting chemokine CXCL10, as well as CXCL1 and CCL4 was lower in cuprizone‐treated GFAP‐IL6Tg mice compared with cuprizone‐treated WT. Reduced microglial cell accumulation was associated with inefficient removal of degraded myelin and axonal protection in cuprizone‐treated GFAP‐IL6Tg mice, compared with WT mice at the peak of demyelination. In addition, transgenic production of IL‐6 did not alter initial oligodendrocyte (OL) apoptosis and oligodendrocyte precursor cell recruitment to the lesion site, but it impaired early OL differentiation, possibly due to impaired removal of degraded myelin. Indeed, a microglial receptor involved in myelin phagocytosis, TREM2, as well as the phagolysosomal protein CD68 were lower in cuprizone‐treated GFAP‐IL6Tg compared with WT mice. Our results show for the first time that astrocyte‐targeted production of IL‐6 may play a role in modulating experimental demyelination induced by cuprizone. Further understanding of the IL‐6‐mediated molecular mechanisms involved in the regulation of demyelination is needed, and may have implications for the development of future therapeutic strategies for the treatment of MS. GLIA 2016;64:2104–2119     

p75NTR independent oligodendrocyte death in cuprizone-induced demyelination in C57BL/6 mice

Feeding C57Bl/6 J mice the copper chelator cuprizone leads to selective apoptosis of mature oligodendrocytes and concomitant demyelination predominantly in the corpus callosum. The process of oligodendrocyte apoptosis in this animal model for multiple sclerosis (MS) involves early microglial activation, but no infiltration of T-lymphocytes. Therefore, this model could mimic early stages of oligodendrocyte degeneration Affected oligodendrocytes express the common neurotrophin receptor, p75(NTR), a 'stress-receptor' which under certain circumstances can induce apoptosis. Only affected oligodendrocytes in MS lesions and MS animal models express this receptor. In order to study the significance of p75(NTR) in the fate of oligodendrocytes, we have exposed wild-type as well as p75(NTR)-knockout mice to a 0.2% (w/w) cuprizone diet and performed a comparative immunohistochemical analysis of the corpus callosum at various time points. Surprisingly, our results show that the absence of p75(NTR) did not alter cuprizone-induced oligodendrocyte death (and subsequent de- or remyelination). Apparently, intracellular apoptosis pathways in adult oligodendrocytes do not require p75(NTR) activated signal transduction in the absence of T-lymphocytes and T-lymphocyte derived cytokines.     

Endogenous cell repair of chronic demyelination

In multiple sclerosis lesions, remyelination typically fails with repeated or chronic demyelinating episodes and results in neurologic disability. Acute demyelination models in rodents typically exhibit robust spontaneous remyelination that prevents appropriate evaluation of strategies for improving conditions of insufficient remyelination. In the current study, we used a mouse model of chronic demyelination induced by continuous ingestion of 0.2% cuprizone for 12 weeks. This chronic process depleted the oligodendrocyte progenitor population and impaired oligodendrocyte regeneration. Remyelination remained limited after removal of cuprizone from the diet. Fibroblast growth factor 2 (FGF2) expression was persistently increased in the corpus callosum of chronically demyelinated mice as compared with nonlesioned mice. We used FGF2 mice to determine whether removal of endogenous FGF2 promoted remyelination of chronically demyelinated areas. Wild-type and FGF2 mice exhibited similar demyelination during chronic cuprizone treatment. Importantly, in contrast to wild-type mice, the FGF2 mice spontaneously remyelinated completely during the recovery period after chronic demyelination. Increased remyelination in FGF2 mice correlated with enhanced oligodendroglial regeneration. FGF2 genotype did not alter the density of oligodendrocyte progenitor cells or proliferating cells after chronic demyelination. These findings indicate that attenuating FGF2 created a sufficiently permissive lesion environment for endogenous cells to effectively remyelinate viable axons even after chronic demyelination.