Toll-like receptor 2-mediated alternative activation of microglia is protective after spinal cord injury

Improving neurological outcome after spinal cord injury is a major clinical challenge because axons, once severed, do not regenerate but 'dieback' from the lesion site. Although microglia, the immunocompetent cells of the brain and spinal cord respond rapidly to spinal cord injury, their r...

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Bibliographic Details
Published in:Brain (London, England : 1878) England : 1878), 2014-03, Vol.137 (Pt 3), p.707-723
Main Authors: STIRLING, David P, CUMMINS, Karen, MISHRA, Manoj, WULIN TEO, WEE YONG, V, STYS, Peter
Format: Article
Language:English
Subjects:
Animals
Axons - drug effects
Axons - pathology
Axons - ultrastructure
Bacterial Proteins
Biological and medical sciences
Brain injury
Cerebrospinal fluid. Meninges. Spinal cord
Disease Models, Animal
Green Fluorescent Proteins
Injuries of the nervous system and the skull. Diseases due to physical agents
Lasers - utilization
Lipopeptides - pharmacology
Luminescent Proteins
Medical sciences
Mice
Mice, Inbred C57BL
Mice, Knockout
Microglia - drug effects
Microglia - pathology
Microglia - ultrastructure
Microscopy, Confocal
Myelin Sheath - drug effects
Myelin Sheath - pathology
Myelin Sheath - ultrastructure
Nervous system (semeiology, syndromes)
Neurology
Neuroprotective Agents - pharmacology
Spinal Cord Injuries - etiology
Spinal Cord Injuries - metabolism
Spinal Cord Injuries - pathology
Toll-Like Receptor 2 - agonists
Toll-Like Receptor 2 - metabolism
Traumas. Diseases due to physical agents
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Summary:Improving neurological outcome after spinal cord injury is a major clinical challenge because axons, once severed, do not regenerate but 'dieback' from the lesion site. Although microglia, the immunocompetent cells of the brain and spinal cord respond rapidly to spinal cord injury, their role in subsequent injury or repair remains unclear. To assess the role of microglia in spinal cord white matter injury we used time-lapse two-photon and spectral confocal imaging of green fluorescent protein-labelled microglia, yellow fluorescent protein-labelled axons, and Nile Red-labelled myelin of living murine spinal cord and revealed dynamic changes in white matter elements after laser-induced spinal cord injury in real time. Importantly, our model of acute axonal injury closely mimics the axonopathy described in well-characterized clinically relevant models of spinal cord injury including contusive-, compressive- and transection-based models. Time-lapse recordings revealed that microglia were associated with some acute pathophysiological changes in axons and myelin acutely after laser-induced spinal cord injury. These pathophysiological changes included myelin and axonal spheroid formation, spectral shifts in Nile Red emission spectra in axonal endbulbs detected with spectral microscopy, and 'bystander' degeneration of axons that survived the initial injury, but then succumbed to secondary degeneration. Surprisingly, modulation of microglial-mediated release of neurotoxic molecules failed to protect axons and myelin. In contrast, sterile stimulation of microglia with the specific toll-like receptor 2 agonist Pam2CSK4 robustly increased the microglial response to ablation, reduced secondary degeneration of central myelinated fibres, and induced an alternative (mixed M1:M2) microglial activation profile. Conversely, Tlr2 knock out: Thy1 yellow fluorescent protein double transgenic mice experienced greater axonal dieback than littermate controls. Thus, promoting an alternative microglial response through Pam2CSK4 treatment is neuroprotective acutely following laser-induced spinal cord injury. Therefore, anti-inflammatory treatments that target microglial activation may be counterintuitive after spinal cord injury.
ISSN:0006-8950
1460-2156
DOI:10.1093/brain/awt341