Therapeutic inhibition of soluble brain TNF promotes remyelination by increasing myelin phagocytosis by microglia
Maria Karamita, Christopher Barnum, Wiebke Möbius, Malú G. Tansey, David E. Szymkowski, Hans Lassmann, Lesley Probert
Maria Karamita, Christopher Barnum, Wiebke Möbius, Malú G. Tansey, David E. Szymkowski, Hans Lassmann, Lesley Probert
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Research Article Therapeutics

Therapeutic inhibition of soluble brain TNF promotes remyelination by increasing myelin phagocytosis by microglia

Abstract

Multiple sclerosis (MS) is an inflammatory CNS demyelinating disease in which remyelination largely fails. Transmembrane TNF (tmTNF) and TNF receptor 2 are important for remyelination in experimental MS models, but it is unknown whether soluble TNF (solTNF), a major proinflammatory factor, is involved in regeneration processes. Here, we investigated the specific contribution of solTNF to demyelination and remyelination in the cuprizone model. Treatment with XPro1595, a selective inhibitor of solTNF that crosses the intact blood-brain barrier (BBB), in cuprizone-fed mice did not prevent toxin-induced oligodendrocyte loss and demyelination, but it permitted profound early remyelination due to improved phagocytosis of myelin debris by CNS macrophages and prevented disease-associated decline in motor performance. The beneficial effects of XPro1595 were absent in TNF-deficient mice and replicated in tmTNF-knockin mice, showing that tmTNF is sufficient for the maintenance of myelin and neuroprotection. These findings demonstrate that solTNF inhibits remyelination and repair in a cuprizone demyelination model and suggest that local production of solTNF in the CNS might be one reason why remyelination fails in MS. These findings also suggest that disinhibition of remyelination by selective inhibitors of solTNF that cross the BBB might represent a promising approach for treatment in progressive MS.

Authors

Maria Karamita, Christopher Barnum, Wiebke Möbius, Malú G. Tansey, David E. Szymkowski, Hans Lassmann, Lesley Probert

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Figure 2

Therapeutic inhibition of soluble TNF in brain does not alter acute cuprizone-induced axon damage but prevents its progression in the corpus callosum in a TNF-dependent manner.

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Therapeutic inhibition of soluble TNF in brain does not alter acute cupr...
(A) Bielschowsky’s silver staining (Biel) and neurofilament H nonphosphorylated (SMI 32) immunostaining of axons in brain coronal sections from representative vehicle- (left column), XPro1595- (middle column), and etanercept-treated (right column) naive mice (CPZ0) or cuprizone-fed (CPZ-fed) CPZ3, CPZ5, CPZ6+1, and CPZ6+4 mice (n = 8 for vehicle-treated CPZ0, n = 4 for XPro1595-treated CPZ0, and n = 6–12 for other time points). The area used for quantitating axon damage is shown in the vehicle-treated Bielschowsky-stained CPZ0 sample. Scale bars: 500 μM for Bielschowsky, 50 μM for SMI 32. (B) Quantitative representation of SMI 32 immunoreactivity in the corpus callosum of groups of mice represented in A. (C) Levels of Snap25 mRNA transcripts relative to Gusb in whole brain samples from CPZ0, CPZ3, CPZ5, CPZ6+1, and CPZ6+4 mice by quantitative PCR (n = 4 per group). (D) Quantitative representation of SMI 32 immunoreactivity in the corpus callosum of vehicle- and XPro1595-treated CPZ0 and CPZ5 Tnf–/– or WT mice (n = 6–8 per group). The results shown are from one representative ([D] Tnf–/–) of two (C) or three ([A, B, and D] WT) independent experiments. Statistical significance after comparisons between measurements of immunoreactivity in the different mouse strains (B, D) and mRNA levels (C) by two-way ANOVA with Bonferroni’s test and ordinary one-way ANOVA with Tukey’s test, respectively, is shown. *P < 0.05, **P < 0.01, ***P < 0.001. (A) Asterisks show maintenance of axon integrity. (B–D) Circles show values for individual mice.