In this article we first discuss the factors that regulate macrophage recruitment, activation, and myelin phagocytosis during Wallerian degeneration and some of the factors involved in the termination of inflammation at the end of the period of Wallerian degeneration after peripheral nerve injuries. In particular, we deal with the early events that trigger chemokine and cytokine expression; the role of phospholipase A 2 in initiating the breakdown of compact myelin, and chemokine, cytokine expression; and the role of MCP-1, MIP-1a, and IL-1b in macrophage recruitment and myelin phagocytosis. We also discuss how inflammation may be switched off and the recently identified role of the Nogo receptor on activated macrophages in the clearance of these cells from the injured nerve. In the second half of the article we focus on the role of certain Schwann cell borne cytokines and chemokines, such as M-CSF and MCP-1 as well as intracellular signaling that regulate their expression in animal models of inherited demyelinating disease. Additionally, we present the preservation of sensory nerves fibers from macrophage attack in these animal models as a challenging paradigm for the development of putative treatment approaches. Finally, we also discuss the similarities and differences in these Schwann cell-macrophage responses in injury-induced Wallerian degeneration and inherited demyelinating diseases. Knowledge of the molecular mechanisms underlying Schwann cell-macrophage interaction under pathological conditions is an important prerequisite to develop effective treatment strategies for various peripheral nerve disorders. V V C
Overexpression of the major myelin protein of the CNS, proteolipid protein (PLP), leads to late-onset degeneration of myelin and pathological changes in axons. Based on the observation that in white matter tracts of these mutants both CD8ϩ T-lymphocytes and CD11bϩ macrophage-like cells are numerically elevated, we tested the hypothesis that these cells are pathologically involved in the primarily genetically caused neuropathy. Using flow cytometry of mutant brains, CD8ϩ cells could be identified as activated effector cells, and confocal microscopy revealed a close association of the T-cells with MHC-Iϩ (major histocompatibility complex class I positive) oligodendrocytes. Crossbreeding the myelin mutants with mice deficient in the recombination activating gene-1 (RAG-1) lacking mature T-and B-lymphocytes led to a reduction of the number of CD11bϩ cells and to a substantial alleviation of pathological changes. In accordance with these findings, magnetic resonance imaging revealed less ventricular enlargement in the double mutants, partially because of more preserved corpora callosa. To investigate the role of CD8ϩ versus CD4ϩ T-lymphocytes, we reconstituted the myelin-RAG-1 double mutants with bone marrow from either CD8-negative (CD4ϩ) or CD4-negative (CD8ϩ) mice. The severe ventricular enlargement was only found when the double mutants were reconstituted with bone marrow from CD8ϩ mice, suggesting that the CD8ϩ lymphocytes play a critical role in the immune-related component of myelin degeneration in the mutants. These findings provide strong evidence that a primary glial damage can cause secondary immune reactions of pathological significance as it has been suggested for some forms of multiple sclerosis and other leukodystrophies.
Progressive forms of multiple sclerosis lead to chronic disability, substantial decline in quality of life and reduced longevity. It is often suggested that they occur independently of inflammation. Here we investigated the disease progression in mouse models carrying PLP1 point mutations previously found in patients displaying clinical features of multiple sclerosis. These mouse models show loss-of-function of PLP1 associated with neuroinflammation; the latter leading to clinically relevant axonal degeneration, neuronal loss and brain atrophy as demonstrated by inactivation of the recombination activating gene 1. Moreover, these pathological hallmarks were substantially amplified when we attenuated immune regulation by inactivation of the programmed cell death-1 gene. Our observations support the view that primary oligodendroglial abnormalities can evoke pathogenically relevant neuroinflammation that drives neurodegeneration, as observed in some forms of multiple sclerosis but also in other, genetically-mediated neurodegenerative disorders of the human nervous system. As many potent immunomodulatory drugs have emerged during the last years, it is tempting to consider immunomodulation as a treatment option not only for multiple sclerosis, but also for so far non-treatable, genetically-mediated disorders of the nervous system accompanied by pathogenic neuroinflammation.
a b s t r a c t NAD + plays central roles in energy metabolism as redox carrier. Recent research has identified important signalling functions of NAD + that involve its consumption. Although NAD + is synthesized mainly in the cytosol, nucleus and mitochondria, it has been detected also in vesicular and extracellular compartments. Three protein families that consume NAD + in signalling reactions have been characterized on a molecular level: ADP-ribosyltransferases (ARTs), Sirtuins (SIRTs), and NAD + glycohydrolases (NADases). Members of these families serve important regulatory functions in various cellular compartments, e.g., by linking the cellular energy state to gene expression in the nucleus, by regulating nitrogen metabolism in mitochondria, and by sensing tissue damage in the extracellular compartment. Distinct NAD + pools may be crucial for these processes. Here, we review the current knowledge about the compartmentation and biochemistry of NAD + -converting enzymes that control NAD + signalling.
The chemokine monocyte chemoattractant protein-1 (MCP-1/CCL2) has been previously shown to be an important mediator of macrophage-related neural damage in models of two distinct inherited neuropathies, Charcot-Marie-Tooth (CMT) 1A and 1B. In mice deficient in the gap junction protein connexin 32 (Cx32def), an established model for the X-chromosome-linked dominant form of CMT (CMT1X), we investigated the role of the chemokine in macrophage immigration and neural damage by crossbreeding the Cx32def mice with MCP-1 knockout mutants. In Cx32def mutants typically expressing increased levels of MCP-1, macrophage numbers were strongly elevated, caused by an MCP-1-mediated influx of haematogenous macrophages. Curiously, the complete genetic deletion of MCP-1 did not cause reduced macrophage numbers in the nerves due to compensatory proliferation of resident macrophages. In contrast, and as already seen in other CMT models, heterozygous deletion of MCP-1 led to reduced numbers of phagocytosing macrophages and an alleviation of demyelination. Whereas alleviated demyelination was transient, axonal damage was persistently improved and even robust axonal sprouting was detectable at 12 months. Other axon-related features were alleviated electrophysiological parameters, reduced muscle denervation and atrophy, and increased muscle strength. Similar to models for CMT1A and CMT1B, we identified MEK-ERK signalling as mediating MCP-1 expression in Cx32-deficient Schwann cells. Blocking this pathway by the inhibitor CI-1040 caused reduced MCP-1 expression, attenuation of macrophage increase and amelioration of myelin- and axon-related alterations. Thus, attenuation of MCP-1 upregulation by inhibiting ERK phosphorylation might be a promising approach to treat CMT1X and other so far untreatable inherited peripheral neuropathies in humans.
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