Presence of Marchi-positive myelinoid bodies in the spinal cord white matter of some vertebrate species

Is There Evidence for Myelin Modeling by Astrocytes in the Normal Adult Brain?

A set of astrocytic process associated with altered myelinated axons is described in the forebrain of normal adult rodents with confocal, electron microscopy, and 3D reconstructions. Each process consists of a protuberance that contains secretory organelles including numerous lysosomes which polarize and open next to disrupted myelinated axons. Because of the distinctive asymmetric organelle distribution and ubiquity throughout the forebrain neuropil, this enlargement is named paraxial process (PAP). The myelin envelope contiguous to the PAP displays focal disruption or disintegration. In routine electron microscopy clusters of large, confluent, lysosomes proved to be an effective landmark for PAP identification. In 3D assemblies lysosomes organize a series of interconnected saccules that open up to the plasmalemma next to the disrupted myelin envelope(s). Activity for acid hydrolases was visualized in lysosomes, and extracellularly at the PAP-myelin interface and/or between the glial and neuronal outer aspects. Organelles in astrocytic processes involved in digesting pyknotic cells and debris resemble those encountered in PAPs supporting a likewise lytic function of the later. Conversely, processes entangling tripartite synapses and glomeruli were devoid of lysosomes. Both oligodendrocytic and microglial processes were not associated with altered myelin envelopes. The possible roles of the PAP in myelin remodeling in the context of the oligodendrocyte-astrocyte interactions and in the astrocyte's secretory pathways are discussed.

Lymphocytes and macrophages outnumber oligodendroglia in normal fish spinal cord

As shown by staining with a monoclonal antibody against fish CD45, leukocytes are present in very large numbers in the fish central nervous system. Their subtypes were distinguished by electron microscopy and found to include all major hematogenous forms except thrombocytes, the most numerous being tissue macrophages and lymphocytes. As a population, they differ fundamentally from ramified microglia, the restricted form of myeloid cells present in the central nervous system in mammals. They are rare in most grey matter regions but are concentrated in myelinated fiber tracts as well as in certain strata of the radial glial network. The macrophages engulf discarded myelin and outnumber the oligodendrocytes in normal spinal cord white matter, where the density of lymphocytes is > 5000-fold greater than reported in rat.

Metabolic relationships between proteins of myelin and paranodally shedded, partially degraded myelin fragments in the rabbit CNS

The "close-to-node" regions of myelinated nerve fibres, i.e., the paranodal end segments, are generally thought to be sites of high metabolic activity and myelin sheath turnover. Data on turnover rates of individual myelin constituents are conflicting but there exists a common belief that myelin is metabolized as independent molecules rather than as a unit. The occurrence of paranodal Marchi-positive bodies, with morphological and biochemical properties consistent with partially degraded myelin, prompted us to examine the temporal dynamics of the incorporation of radioactive precursor label in the major proteins of myelin and the Marchi-positive bodies. 3H-leucine was administered intrathecally in adult rabbits. After various survival times, the spinal cord was subfractionated by ultracentrifugation in a discontinuous two-step 0.32 M/0.85 M sucrose gradient. Myelin was collected from the interface and a floating fraction, heavily enriched in Marchi-positive bodies, was recovered on top of the 0.32 M sucrose. By scintillation counting and by gel fluorography combined with immunoblotting, a gradual appearance with time of partially degraded peptides of myelin-associated protein and 2',3'-cyclic nucleotide 3'-phosphodiesterase was seen in the floating fraction but not in myelin. The temporal dynamics of the specific activities of these two proteins and myelin-basic protein and proteolipid protein were consistent with a typical source-product relationship between myelin and the material in the floating fraction. In conjunction with earlier morphological and biochemical findings, these data may suggest that Marchi-positive bodies appear as a consequence of myelin catabolism.

Degradation products of myelin-oligodendrocyte-associated proteins in a light CNS subcellular fraction

The presence of degradation products of the myelin/oligodendrocyte glycoprotein (MOG) and a new myelin/oligodendrocyte associated protein, FD1, defined by a monoclonal antibody was established in a subfraction (the floating fraction, or FF) of adult rabbit CNS. The histochemical distribution of FD1 was determined by indirect immunofluorescence using conventional and confocal microscopy. FD1 was found to be present in oligodendrocytes, and at the outer rim of CNS myelin sheaths. Strong antibody reactivity was noted at nodes of Ranvier, as well as in regions with a high nodal density. No staining of compact myelin was seen. In the PNS, inner and outer cytoplasmic compartments of the Schwann cells as well as their cell bodies were stained, with no staining of compact myelin. The FF has previously been shown to be highly enriched in Marchi-positive bodies. These structures are situated paranodally in the CNS of myelinated nerve fibers, and their presence has been interpreted as reflections of myelin breakdown and turnover occurring in association with myelin sheath segments situated close to nodes at Ranvier in adult, normal vertebrate CNS. The present findings extend previous observations of partially degraded myelin-associated proteins in the FF, and give further results indicating that Marchi-positive bodies are aspects of intermediate stages in myelin catabolism.

Calpain activity in a subcellular fraction enriched in partially degraded CNS myelin fragments compared with myelin

Marchi-positive bodies are structures present paranodally in large myelinated nerve fibers. They have morphological and biochemical characteristics closely resembling the partially degraded myelin fragments formed during the early phases of Wallerian degeneration. Levels of calcium-activated neutral proteases (calpains) and their endogenous specific inhibitor calpastatin were measured in highly purified rabbit myelin and a spinal cord subcellular light ('floating') fraction heavily enriched in Marchi-positive bodies. Calpain levels were found to be significantly higher in the floating fraction as compared to myelin. No calpastatin was detectable in either fraction.

Cellular relationships of paranodal Marchi-positive bodies studied with monoclonal antibodies against partially degraded CNS myelin fragments

Histochemical and electron microscopical studies have shown that Marchi-positive bodies in the normal mammalian CNS are associated with paranodal regions and it has been proposed that the formation of Marchi-positive bodies represents a step in the catabolic events of normal myelin turnover. After a two-step density gradient ultracentrifugation a light 'floating fraction' highly enriched in these structures can be collected and in the present study two monoclonal antibodies, FC4 and 3B5, were produced against proteins present in the floating fraction but absent from the myelin fraction. Immunohistochemical studies showed that these antibodies bound preferentially to the PNS-CNS transitional region and the glia limitans. Double-staining experiments demonstrated an extensive overlap in these regions with cells stained by antibodies against the astrocyte marker glial fibrillary acidic protein. Centrally in the white matter, FC4 and 3B5 mainly stained cells which also stained with the microglia lectin marker Bandeiraea simplicifolia isolectin B4. Three-dimensional reconstructions made from confocal microscopic scans showed that FC4/3B5-positive cells in the white matter extend processes enveloping paranodal Marchi-positive bodies and nodes of Ranvier. It is suggested that astrocyte-like and microglia-like cells both are participants in paranodal myelin turnover and that a division of labour with respect to, for example, protein degradation and immunological functions, may be present between the two cell types.

Two-dimensional electrophoresis of membrane proteins: separation of myelin proteins

A method for two-dimensional electrophoretic separation of myelin proteins is presented. The first dimension consists of isoelectric focusing of lyophilized and delipidated membrane proteins, solubilized in a mixture of the nonionic detergent Triton X-100, the zwitterionic detergent CHAPS, 9 M urea and carrier ampholytes, and incorporated into a slab gel before separation. Subsequent discontinuous sodium dodecyl sulfate-polyacrylamide gel electrophoresis was performed by moulding the isoelectric focusing slab gel with its supporting glass plate into the stacking gel. This method proved to give highly reproducible results since mechanical forces and thus the risk of stretching, folding or rupture of the isoelectric focusing slab gel is minimized. Furthermore, by immunoblotting, the positions of myelin-associated glycoprotein and 2',3'-cyclic nucleotide 3'-phosphodiesterase were established with specific antibodies.

Relation between axons and oligodendroglial cells during initial myelination. I. The glial unit

The morphology of oligodendroglial-axon units was examined by electron microscopy during ensheathment and initial myelination in developing feline spinal cord and corpus callosum white matter. In addition to a qualitative examination of single sections from many stages of development, a morphological analysis of spinal cord and corpus callosum units was made on the basis of serial sections from a few stages. The results show that myelination commences around embryonic/fetal day 40 and the 20th postnatal day in the spinal cord and corpus callosum areas, respectively. In both areas immature glial cells, lacking the cytological features of typical oligodendrocytes, initially associate with several axons and provide them with cytoplasmic sheaths. Serial section analysis of units, which have begun formation of compact myelin, indicates that individual cells are associated with single myelin sheaths in the spinal cord area, in a way principally similar to the Schwann cell-myelin units in developing peripheral nerves. This suggests the possibility that early spinal cord oligodendrocytes might shift from a polyaxonal to a monoaxonal association after initial ensheathment and before formation of compact myelin. In the corpus callosum area the examined serially-sectioned cells were found to be connected to several myelin sheaths through long thin processes. The myelin sheaths related to one cell are relatively uniform in terms of number of myelin lamellae and axon diameter, but the clockwise/counter-clockwise course of the myelin spiral varies randomly. Units containing both homogeneously uncompacted (cytoplasmic) and fully compacted (myelin) sheaths have not been found. In both areas the ensheathing cells achieve an oligodendrocyte-like cytology during formation of the first layers of compact myelin. These observations support the view that oligodendrocytes are structurally heterogeneous: those myelinating prospective large axons seems to differ from those myelinating axons destined to remain small. The possible functional and pathophysiological implications of this heterogeneity remain to be elucidated.

Isoelectric focusing of membrane proteins: high resolution separation of myelin proteins

A mixture of the nonionic detergent Triton X-100, the zwitterionic detergent 3-[(cholamidopropyl)dimethylammonio]-1-propanesulphonate (CHAPS), 9M urea and carrier ampholytes was found comparable to media containing sodium dodecyl sulfate in the capacity for solubilization of myelin proteins, including the highly hydrophobic proteolipid protein. The solubilized sample was incorporated into the polymerization mixture before moulding an ultrathin gel, with heat convection characteristics allowing a high wattage to be applied, thus allowing fast separation with high resolving power. Since the most basic protein in myelin focuses at a pH greater than 10, fast separation is essential in order to minimize decay of the cathodic end of the pH gradient.

Myelin breakdown in the posterior funiculus of the kitten after dorsal rhizotomy. A qualitative and quantitative light and electron microscopic study

Morphological aspects of myelin breakdown in the posterior funiculus during Wallerian degeneration were studied in kittens subjected to lumbosacral dorsal rhizotomies 6-8 days after birth. The first sign of myelin breakdown was characterized by swollen or shrunken nerve fibers. Shortly thereafter there was an increased occurrence of collapsed myelin sheaths and later of rounded myelin bodies. Myelin was clearly seen in microglial cells. Correlative observations on Marchi-stained material indicted the simultaneous and frequent appearance of Marchi-positive bodies (MPB:s) and myelin bodies. Due to the rapidity of the degeneration process in the kitten, the increase in the occurrence of Marchi-positive granules (MPG:s) seemed to start concomitantly with increased occurrence of MPB:s. However, the frequent occurrence of MPG:s outlasted that for MPB:s. The findings indicate that the MPB:s may be the counterpart to myelin bodies and the MPG:s to lipid droplets. Microglial cells may be responsible for the primary uptake of degenerating myelin and the subsequent transformation of myelin bodies to lipid droplets. The much faster breakdown of myelin and elimination of lipid material in the degenerating posterior funiculus of the kitten, as compared to the adult, seemed to be due not only to the lower myelin content in the kitten, but also to a higher density of microglial and a greater efficiency in the myelin breakdown process in the degenerating posterior funiculus of the kitten.

Aspects of the protein and the lipid composition of myelinoid Marchi-positive bodies from mammalian spinal cord

The fraction floating on 0.32 M sucrose was isolated from normal mammalian spinal cord and analyzed with regard to protein and lipid composition. Comparisons were made with the myelin fraction isolated from the same spinal cord. A close relationship between the two fractions was indicated by a similar protein banding on SDS-polyacrylamide gel electrophoresis. The relative amounts of various proteins however were different and some high molecular weight proteins appeared unique to the floating fraction. The phospho- and galactolipid patterns, as revealed by thin-layer chromatography, were similar in the floating and the myelin fractions. The proportion of hydrophobic lipids, such as sterols and isoprenyl derivatives, was higher in the floating fraction. Bands co-migrating with cholesterol esters were detected only in the floating fraction from guinea pigs. Marchi-positive material of possible paranodal origin is enriched in the floating fraction. The present findings of a biochemical composition of the floating fraction closely resembling that of myelin is in line with the view that myelin turnover includes a step of degradation localized to the paranodal regions.

Isolation of myelinoid Marchi-positive bodies from normal rabbit spinal cord

Normal rabbit spinal cord was homogenized in sucrose and fractionated by centrifugation in a sucrose density gradient system slightly modified after the Norton-Poduslo method for the isolation of myelin. The following fractions were recovered: the fraction floating on 0.32 M sucrose, the myelin fraction at the 0.32 M/0.85 M interface and the pellet. After fixation in glutaraldehyde the fractions were subjected to Marchi staining, a histochemical method used for the demonstration of degenerating myelin. The floating fraction was enriched in Marchi-positive bodies as compared to the homogenate while the myelin fraction and the pellet contained low amounts. No esterified cholesterol was found in the floating fraction. Since histochemical and electron microscopical studies have shown that Marchi-positive myelinoid bodies in the normal CNS are associated with node-paranode regions our results indicate a possibility to isolate and biochemically characterize a presumably closely myelin-related fraction of known anatomical origin. The absence of esterified cholesterol in the floating fraction shows that biochemical or biophysical properties other than a content of esterified cholesterol may give rise to a positive Marchi reaction.

Transganglionic degeneration in vibrissae innervating primary sensory neurons of the rat: a light and electron microscopic study

Previous studies have shown that transection of peripheral branches of primary sensory neurons leads to light microscopical degeneration argyrophilia and ultrastructural changes in the central termination areas of these neurons. This type of degeneration has been termed transganglionic degeneration (TGD). In the present experiments TGD has been studied specifically in neurons innervating the rat vibrissae at the light and electron microscopic levels. Light microscopically, small amounts of degeneration argyrophilia are observed in the magnocellular zone of the trigeminal subnucleus caudalis at 8-14 days survival. At longer survival times there are substantial amounts of degeneration in this area. At the ultrastructural level the first signs of TGD are observed at 6 days survival, when some terminals show a small increase in electron density, loss of synaptic vesicles, and mitochondrial disintegration. Terminals showing a more advanced increase in electron density become common at 8 days survival, but few of them are still left at 14 days survival. Neurofilamentous terminals appear in small numbers 8-14 days postoperatively. Various forms of degeneration in myelinated axons are observed from 8 days survival and are common also at 80 days survival. Electron-dense axons are rather unfrequent, but more or less disrupted myelin sheaths containing disintegrated axoplasmic remnants and empty areas are common as well as extremely expanded myelin sheaths. Glial cells containing axonal and myelin debris are seen from 8 days survival and become a more common finding at longer survivals. A most striking finding 8-10 days postoperatively is a complex relationship between glial cells and less darkened terminals, indicating phagocytosis before reaching an entirely darkened state. The findings clearly show that peripheral nerve transection leads to severe central alterations in a population of mechanoreceptor neurons innervating the vibrissae of the adult rat.

Electron-microscopic identification of Gomori-positive rings in normal spinal cord white matter

Longitudinal vibratome slices from glutaraldehyde-fixed adult guinea pig lateral funiculus white matter were incubated in a Gomori medium, stained with ammonium sulfide, osmicated and section-embedded in vestopal. Following light-microscopic localization of ring-shaped deposits of reaction product series of thin sections were cut from these areas. In the electron microscope ring-shaped deposits of reaction product were consistently found to surround lamellated myelinoid bodies within glial cells. By following the series some of these cells could be identified as microglia. Sparse aggregates of reaction product were occasionally seen outside myelinoid bodies in typical astrocytes. Precipitates were not related to myelinoid bodies associated with typical oligodendrocytes. The findings suggest that microglia and possibly astroglia participate in the breakdown of spontaneously formed myelin fragments in normal adult white matter.

Remodelling of optic nerve myelin sheaths and axons during metamorphosis in Xenopus laevis

Whole mounts and transverse sections of Xenopus optic nerves were examined with the light and electron microscopes before, during, and after metamorphosis. In stage 52--58 tadpoles, almost all myelin sheaths were circular in transverse sections. Early in metamorphosis (stages 60--61) large redundant myelin loops surrounded many large axons in central regions of the nerve. The loops subsequently were broken down into ovoids and lamellar segments that remained mostly within oligodendrocytes. These myelin changes were not observed in the chiasm or next to the eye. They were not associated with significant axonal degeneration and were no longer apparent in optic nerves of young frogs. Xenopus optic nerves also became shorter during metamorphosis. We therefore suggest that myelin sheaths with redundant loops which degenerate and disappear are being remodelled as the nerve decreases in length.

An ultrastructural study of transganglionic degeneration in the main sensory trigeminal nucleus of the rat

In adult rats subjected to unilateral transection of the infraorbital nerve, the main sensory trigeminal nucleus was studied by electron microscopy. Post-operative survival times varied between 2 and 60 days. A variety of ultrastructural alterations was observed from the sixth post-operative day onwards. These changes were in many respects similar to those seen in the course of Wallerian degeneration. Neurofilamentous boutons and axons were found 6-30 days post-operatively. Various types of dark boutons were observed between 7 and 30 days and axonal changes indicative of degeneration between 7 and 60 days post-operatively. Astrocytes and microglial cells contained degenerating structures 7-60 days post-operatively. The alterations observed in the present study are interpreted as related, at least in part, to the nerve cell degeneration and the nerve cell death previously shown to occur in the trigeminal ganglion after infraorbital nerve transection.

Relation between myelin sheath thickness and axon size in spinal cord white matter of some vertebrate species

The relation between number of myelin lamellae and axon size in the CNS was examined by electron microscopy of spinal cord white matter fibres in different vertebrate species (cat, rabbit, guinea pig, rat, mouse, frog and perch). The results show that the number of myelin lamellae increases with increasing axon size in a non-linear fashion. Below an axon size of 4--5 micron the relation follows a fairly straight line but above this size rectilinearity is lost. The mouse and the frog differ from the pattern shared by the other animals. In the mouse the lamellar number increases more slowly with axon size and the relation is close to linear. In the frog the number of lamellae increases very slowly with axon size and the relation is markedly curvilinear. Measurements of the myelin repeating period show that in the mammals and the frog the average period of thick sheaths is about 85% of that in thin sheaths, in accordance with previous findings in the cat. In the perch a clearcut difference in this respect between thick and thin sheaths is not found. Calculations of the g-ratio on the basis of the findings indicate that it increases with increasing fibre size. This is most pronounced in the perch and the frog in which the g-ratio for the largest fibres far exceeds the functionally optimal value defined in theoretical analyses on impulse propagation.

Age-related changes in occurrence of Marchi-positive granules and Marchi-positive myelinoid bodies in postnatally developing feline white matter

The occurrence of clusters of Marchi-positive granules and of Marchi-positive myelinoid bodies at different postnatal developmental stages was examined lightmicroscopically in Vibratome sections from the cervical lateral funiculus of the cat, after perfusion-fixation with glutaraldehyde. The findings show that clusters of Marchi-positive granules are most common at birth and rapidly decrease in number with development, being largely absent in animals older than 1 month. The pattern of change resembles the postnatal changes in content of esterified cholesterol in the cervical lateral funiculus and is compatible with the view that the clusters of Marchi-positive granules may result from spontaneous myelin sheath disintegration occurring early postnatally. The incidence of Marchi-positive myelinoid bodies increases 7 times during the first 4 months after birth to a peak and declines about 40% during late maturation. The size spectrum of the Marchi-positve bodies shifts markedly towards larger sizes with development and presents a close to mature picture from 120 days on. Comparisons between the Marchi-positive myelinoid bodies and the myelin sheaths in the same region, with respect to postnatal change in occurrence and size spectrum, suggest that the Marchi-positive bodies are related to myelin sheaths of large fibres or fibres destined to become large.