The role of complement in immunological demyelination of the mammalian spinal cord.

STUDY DESIGN: Specificity of serum complement component to elicit immunological demyelination. OBJECTIVES: To assess the role of complement components and pathways in experimental immunological demyelination of the adult rat spinal cord. SETTING: ICORD, University of British Columbia, Vancouver, Canada. SUBJECTS: We used 32 adult male Sprague-Dawley rats, of approximately 220 g weight. METHODS: Rats received intraspinal infusions of demyelinating reagents, delivered by osmotic minipump, for a 7-day infusion at 0.5 microl/h. Reagents consisted of a polyclonal antibody to galactocerebroside and human serum complement. Complement sera deficient for a single component were used to assess the role of the alternative pathway, the classical pathway, and the membrane attack complex. Demyelination was assessed, at 7 days, ultrastructurally. RESULTS: Removal of C3 protein, common to classical and alternative complement pathways, or C4 protein, a classical pathway protein, resulted in no demyelination. However, complement deficient in Factor B, an alternative pathway protein, produced effective demyelination. Upon removal of C5 or C6, membrane attack complex proteins, demyelination was also observed. CONCLUSION: This suggests that the classical pathway is sufficient for the protocol to demyelinate the adult rat spinal cord, and that the membrane attack complex is also not required.

Model for focal demyelination of the spinal dorsal columns of transgenic MBP-LacZ mice by phototargeted ablation of oligodendrocytes.

Focal demyelination models provide powerful tools to study demyelination and remyelination in the central nervous system. In this report, we present a novel technique, which selectively targets oligodendrocytes within the spinal cord of transgenic mice to produce focal demyelination. Transgenic mice expressing the E. coli LacZ (beta-galactosidase) gene from the myelin basic protein promotor allowed for oligodendrocyte-specific cleavage of topically applied fluorescein-di-beta-galactopyranoside liberating photoactivatable fluorescein. Subsequent fluorescence illumination generated oxygen radicals that oxidized a second exogenous substrate, 3-amino-9-ethyl carbazole, to form a toxic precipitate within oligodendrocytes. Histochemical staining of the spinal cord dorsal columns 8 days following phototargeting revealed that the treated region no longer contained beta-galactosidase-positive cells. Focal demyelination of the dorsal columns was observed to a depth of 150 microm in transverse semithin plastic sections. Numerous bundles of naked axons interspersed with myelin, debris-laden macrophages, and reactive astrocytes were evident by electron microscopy. Remyelination of axons by both oligodendrocytes and invading Schwann cells was observed within the treated region 14 days after phototargeting. Newly generated oligodendrocytes were identified within the demyelinated region by their incorporation of bromodeoxyuridine. Thus, this novel focal demyelination protocol provides: (1) a method for selective targeted ablation of oligodendrocytes in vivo, (2) control over the extent of the demyelinated region, with (3) an environment that maintains its remyelination capacity. Phototargeted ablation of oligodendrocytes may therefore be a useful model for studying axon-glia interactions, axon regeneration within a demyelinated zone, and remyelination of axons.

Regeneration of brainstem-spinal axons after lesion and immunological disruption of myelin in adult rat.

We previously observed that the transient developmental suppression of myelination or disruption of mature myelin, by local intraspinal infusion of serum complement proteins along with a complement-fixing, myelin-specific antibody (e.g., anti-Galactocerebroside), facilitated avian brainstem-spinal axonal regeneration after spinal transection. We now report the effects of similar immunological protocols on axonal regeneration in the injured adult rat spinal cord. After a lateral hemisection injury of the T10 spinal cord, infusion of the above reagents, over 14 days at T11, facilitated the regeneration of some brainstem-spinal axons. The hemisection lesion enabled comparisons between the retrograde labeling within an injured brainstem-spinal nucleus and the uninjured contralateral homologue. The brainstem-spinal nucleus examined in detail was the red nucleus (RN), chosen for its relatively compact descending pathway within the dorsolateral cord. Comparing the number of labeled neurons within each RN, of an experimentally myelin suppressed animal, indicated that approximately 32% of injured rubrospinal projections had regenerated into the caudal lumbar cord. In contrast, control-treated animals (e.g., PBS vehicle alone, GalC antibody alone, or serum complement alone) showed little or no axonal regeneration. We also examined the ultrastructural appearance of the treated cords. We noted demyelination over 1-2 segments surrounding the infusion site (T11) and a further two segments of myelin disruption (delamination) on either side of the demyelinated zone. The demyelination is an active process (< 3 days) with microglia and/or macrophages engulfing myelin. Thus, the facilitation of axonal regeneration through the transient suppression of CNS myelin may be fundamental to all higher vertebrates.