Jessica Jopek Ashbaugh scite author profile

Tumour necrosis factor is linked to the pathophysiology of various neurodegenerative disorders including multiple sclerosis. Tumour necrosis factor exists in two biologically active forms, soluble and transmembrane. Here we show that selective inhibition of soluble tumour necrosis factor is therapeutic in experimental autoimmune encephalomyelitis. Treatment with XPro1595, a selective soluble tumour necrosis factor blocker, improves the clinical outcome, whereas non-selective inhibition of both forms of tumour necrosis factor with etanercept does not result in protection. The therapeutic effect of XPro1595 is associated with axon preservation and improved myelin compaction, paralleled by increased expression of axon-specific molecules (e.g. neurofilament-H) and reduced expression of non-phosphorylated neurofilament-H which is associated with axon damage. XPro1595-treated mice show significant remyelination accompanied by elevated expression of myelin-specific genes and increased numbers of oligodendrocyte precursors. Immunohistochemical characterization of tumour necrosis factor receptors in the spinal cord following experimental autoimmune encephalomyelitis shows tumour necrosis factor receptor 1 expression in neurons, oligodendrocytes and astrocytes, while tumour necrosis factor receptor 2 is localized in oligodendrocytes, oligodendrocyte precursors, astrocytes and macrophages/microglia. Importantly, a similar pattern of expression is found in post-mortem spinal cord of patients affected by progressive multiple sclerosis, suggesting that pharmacological modulation of tumour necrosis factor receptor signalling may represent an important target in affecting not only the course of mouse experimental autoimmune encephalomyelitis but human multiple sclerosis as well. Collectively, our data demonstrate that selective inhibition of soluble tumour necrosis factor improves recovery following experimental autoimmune encephalomyelitis, and that signalling mediated by transmembrane tumour necrosis factor is essential for axon and myelin preservation as well as remyelination, opening the possibility of a new avenue of treatment for multiple sclerosis.

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Hematogenous macrophage depletion reduces the fibrotic scar and increases axonal growth after spinal cord injury

Zhu

Soderblom

Krishnan

et al. 2015

Neurobiology of Disease

168

171

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Spinal cord injury (SCI) leads to formation of a fibrotic scar that is inhibitory to axon regeneration. Recent evidence indicates that the fibrotic scar is formed by perivascular fibroblasts, but the mechanism by which they are recruited to the injury site is unknown. Using bone marrow transplantation in mouse model of spinal cord injury, we show that fibroblasts in the fibrotic scar are associated with hematogenous macrophages rather than microglia, which are limited to the surrounding astroglial scar. Depletion of hematogenous macrophages results in reduced fibroblast density and basal lamina formation that is associated with increased axonal growth in the fibrotic scar. Cytokine gene expression analysis after macrophage depletion indicates that decreased Tnfsf8, Tnfsf13 (Tumor necrosis factor superfamily members) and increased BMP1-7 (Bone Morphogenetic Proteins) expression may serve as anti-fibrotic mechanisms. Our study demonstrates that hematogenous macrophages are necessary for fibrotic scar formation and macrophage depletion results in changes in multiple cytokines that make the injury site less fibrotic and more conducive to axonal growth.

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Astrocytes play a key role in EAE pathophysiology by orchestrating in the CNS the inflammatory response of resident and peripheral immune cells and by suppressing remyelination

Brambilla

Morton

Ashbaugh

et al. 2013

Glia

139

117

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Astrocytes respond to insult with a process of cellular activation known as reactive astrogliosis. One of the key signals regulating this phenomenon is the transcription factor nuclear factor-kappa B (NF-κB), which is responsible for modulating inflammation, cell survival, and cell death. In astrocytes, following trauma or disease, the expression of NF-κB-dependent genes is highly activated. We previously demonstrated that inactivation of astroglial NF-κB in vivo (GFAP-IκBα-dn mice) leads to improved functional outcome in experimental autoimmune encephalomyelitis (EAE), and this is accompanied by reduction of pro-inflammatory gene expression in the CNS. Here we extend our studies to show that recovery from EAE in GFAP-IκBα-dn mice is associated with reduction of peripheral immune cell infiltration into the CNS at the chronic phase of EAE. This is not dependent on a less permeable blood-brain barrier, but rather on a reduced immune cell mobilization from the periphery. Furthermore, once inside the CNS, the ability of T cells to produce pro-inflammatory cytokines is diminished during acute disease. In parallel, we found that the number of total and activated microglial cells is reduced, suggesting that functional improvement in GFAP-IκBα-dn mice is dependent upon reduction of the overall inflammatory response within the CNS sustained by both resident and infiltrating cells. This results in preservation of myelin compaction and enhanced remyelination, as shown by electron microscopy analysis of the spinal cord. Collectively our data indicate that astrocytes are key players in driving CNS inflammation and are directly implicated in the pathophysiology of EAE, since blocking their pro-inflammatory capability results in protection from the disease.

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