Oligodendroglial ensheathment of axons during myelination in the developing rat central nervous system. A serial section electron microscopical sttudy

CNS myelin sheath is stochastically built by homotypic fusion of myelin membranes within the bounds of an oligodendrocyte process

Myelin - the multilayer membrane that envelops axons - is a facilitator of rapid nerve conduction. Oligodendrocytes form CNS myelin; the prevailing hypothesis being that they do it by extending a process that circumnavigates the axon. It is pertinent to ask how myelin is built because oligodendrocyte plasma membrane and myelin are compositionally different. To this end, we examined oligodendrocyte cultures and embryonic avian optic nerves by electron microscopy, immuno-electron microscopy and three-dimensional electron tomography. The results support three novel concepts. Myelin membranes are synthesized as tubules and packaged into "myelinophore organelles" in the oligodendrocyte perikaryon. Myelin membranes are matured in and transported by myelinophore organelles within an oligodendrocyte process. The myelin sheath is generated by myelin membrane fusion inside an oligodendrocyte process. These findings abrogate the dogma of myelin resulting from a wrapping motion of an oligodendrocyte process and open up new avenues in the quest for understanding myelination in health and disease.

Age-related and cuprizone-induced changes in myelin and transcription factor gene expression and in oligodendrocyte cell densities in the rostral corpus callosum of mice

During aging, there is a decrease both in the stability of central nervous system (CNS) myelin once formed and in the efficiency of its repair by oligodendrocytes (OLs). To study CNS remyelination during aging, we used the cuprizone (a copper chelator) mouse model. Inclusion of cuprizone in the diet kills mature OLs and demyelinates axons in the rostral corpus callosum (CC) of mice, which enabled us to characterize age-related changes (i.e., 2-16 months of age) in glial cell response during the recruitment (i.e., demyelination) and differentiation (i.e., remyelination) phases of myelin repair. We have found that the time between 12 and 16 months of age is a critical period during which there is an age-related decrease in the number of OL lineage cells (Olig2(Nuc)+ve/GFAP-ve cells) in the rostral CC of both control mice and mice recovering from cuprizone-induced demyelination. Our results also show there was an age-related impaired recruitment of progenitor cells to replace lost OLs in spite of there being no major age-related decrease in the size of the progenitor cell pool (PDGFalphaR+ve/GFAP-ve, and Olig2(Nuc) +ve/PDGFalphaR+ve cells). However, there were cuprizone-induced increased numbers of astrocyte progenitor cells (Olig2(Cyto)+ve/PDGFalphaR+ve) in these same mice; thus PDGFalphaR+ve progenitor cells in mice as old as 16 months of age retain the ability to differentiate into astrocytes, with this fate choice occurring following cytoplasmic translocation of Olig2. These data reveal for the first time age-related differences in the differentiation of PDGFalphaR+ve progenitor cells into OLs and astrocytes and lead us to suggest that during aging there must be a transcriptional switch mechanism in the progenitor cell fate choice in favor of astrocytes. This may at least partially explain the age-related decrease in efficiency of OL myelination and remyelination.

Spinal cord dysmyelination caused by an antiproteolipid protein IgM antibody: implications for the mechanism of central nervous system myelin formation

Antiglycolipid IgM antibodies are known to induce formation of "wide spaced" or "expanded" myelin, a distinctive form of dysmyelination characterized by a repeat period approximately two or three times normal, which is seen also in diseases, including multiple sclerosis. To determine whether an antibody directed against a myelin protein would cause equivalent pathology, we implanted O10 hybridoma cells into the spinal cord of adult or juvenile rats. O10 produces an IgM directed against PLP, the major protein of CNS myelin. Subsequent examination of the cords showed focal demyelination and remyelination. In addition, however, some juvenile cords, but none of the adult cords, displayed wide-spaced myelin with lamellae separated by an extracellular material comprising elements consistent with IgM molecules in appearance. Wide spacing tended to involve the outer layers of the sheath and in some cases alternated with normally spaced lamellae. A feature not seen previously consists of multiple expanded myelin lamellae in one sector of a sheath continuous with normally spaced lamellae in another, resulting in variation in sheath thickness around the axonal circumference. This uneven distribution of wide-spaced lamellae is most simply explained based on incorporation of IgM molecules into immature sheaths during myelin formation and implies a model of CNS myelinogenesis more complex than simple spiraling. The periaxonal space never displays widening of this kind, but the interface with adjacent myelin sheaths or oligodendrocytes may. Thus, wide spacing appears to require that IgM molecules bridge between two PLP-containing membranes and does not reflect the mere presence of immunoglobulin within the extracellular space.

Microtubule deacetylases, SirT2 and HDAC6, in the nervous system

Examination of the cytoskeleton has demonstrated the pivotal role of regulatory proteins governing cytoskeletal dynamics. Most work has focused on cell cycle and cell migration regarding cancer. However, these studies have yielded tremendous insight for development, particularly in the nervous system where all major cell types remodel their shape, generate unsurpassed quantities of membranes and extend cellular processes to communicate, and regulate the activities of other cells. Herein, we analyze two microtubule regulatory alpha-tubulin deacetylases, histone deacetylase-6 (HDAC6) and SirT2. HDAC6 is expressed by most neurons but is abundant in cerebellar Purkinje cells. In contrast, SirT2 is targeted to myelin sheaths. Expression of these proteins by post-mitotic cells indicates novel functions, such as process outgrowth and membrane remodeling. In oligodendrocytes, targeting of SirT2 to paranodes coincides with the presence of the microtubule-destabilizing protein stathmin-1 during early myelinogenesis and suggests the existence of a microtubule regulatory network that modulates cytoskeletal dynamics.

CNS myelin paranodes require Nkx6-2 homeoprotein transcriptional activity for normal structure

Homeodomain proteins play critical roles during development in cell fate determination and proliferation, but few studies have defined gene regulatory networks for this class of transcription factors in differentiated cells. Using a lacZ-knock-in strategy to ablate Nkx6-2, we find that the Nkx6-2 promoter is active embryonically in neuroblasts and postnatally in oligodendrocytes. In addition to neurological deficits, we find widespread ultrastructural abnormalities in CNS white matter and aberrant expression of three genes encoding a paranodal microtubule destabilizing protein, stathmin 1, and the paranodal cell adhesion molecules neurofascin and contactin. The involvement of these downstream proteins in cytoskeletal function and cell adhesion reveals mechanisms whereby Nkx6-2 directly or indirectly regulates axon- glial interactions at myelin paranodes. Nkx6-2 does not appear to be the central regulator of axoglial junction assembly; nonetheless, our data constitute the first evidence of such a regulatory network and provide novel insights into the mechanism and effector molecules that are involved.

Three-dimensional electron microscopic studies of the transitional oligodendrocyte associated with the initial stage of myelination in developing rat hippocampal fimbria

We identified the transitional oligodendrocyte and their processes of rat hippocampal fimbria associated with the initial stage of myelination in both the morphological and functional classifications by means of three-dimensional ultrastructural analysis. Transitional oligodendrocytes appeared around P7, and their cell bodies were morphologically an intermediate form between the light and medium oligodendrocytes described by Mori and Leblond [J. Comp. Neurol. 139 (1970) 1]. Three phenotypes of the transitional oligodendrocytic processes were recognized. Spiral wrapping processes were ensheathing processes, club-like processes were nonensheathing processes, and sheet-like processes were possibly the transmuting form between the nonensheathing and ensheathing processes. Club-like processes were the major part of the nonensheathing processes, and most likely function as sensors to perceive axon maturation and find target axons. Multivesicular bodies that appeared to be associated with the initial ensheathment were observed in the transitional oligodendrocytic processes, suggesting that their roles are crucial in myelinogenesis.

Infection of human oligodendroglioma cells by a recombinant measles virus expressing enhanced green fluorescent protein

One of the hallmarks of the human CNS disease subacute sclerosing panencephalitis (SSPE) is a high level of measles virus (MV) infection of oligodendrocytes. It is therefore surprising that there is only one previous report of MV infection of rat oligodendrocytes in culture and no reports of human oligodendrocyte infection in culture. In an attempt to develop a model system to study MV infection of oligodendrocytes, time-lapse confocal microscopy, immunocytochemistry, and electron microscopy (EM) were used to study infection of the human oligodendroglioma cell line, MO3.13. A rat oligodendrocyte cell line, OLN-93, was also studied as a control. MO3.13 cells were shown to be highly susceptible to MV infection and virus budding was observed from the surface of infected MO3.13 cells by EM. Analysis of the infection in real time and by immunocytochemistry revealed that virus spread occurred by cell-to-cell fusion and was also facilitated by virus transport in cell processes. MO3.13 cells were shown to express CD46, a MV receptor, but were negative for the recently discovered MV receptor, signaling leucocyte activation molecule (SLAM). Immunohistochemical studies on SSPE tissue sections demonstrated that CD46 was also expressed on populations of human oligodendrocytes. SLAM expression was not detected on oligodendrocytes. These studies, which are the first to show MV infection of human oligodendrocytes in culture, show that the cells are highly susceptible to MV infection and this model cell line has been used to further our understanding of MV spread in the CNS.

Expression of four immunoglobulin superfamily adhesion molecules (L1, Nr-CAM/Bravo, neurofascin/ABGP, and N-CAM) in the developing mouse spinal cord

To identify cell adhesion molecules (CAMs) expressed by mammalian motoneurons, we applied the polymerase chain reaction to a murine motor neuron-like cell line, NSC-34. Using primers derived from a group of L1-related CAMs, we cloned two alternatively spliced forms of mouse L1, which differ by a 12-base-pair insert, plus putative murine orthologs of the chicken cell adhesion molecules Nr-CAM/Bravo and neurofascin. All four mRNAs are expressed in NSC-34 cells, but only neurofascin and the insert-minus form of L1 are expressed in its neuroblastoma parent, N18TG2. Analysis of RNA in neonatal tissues reveals expression largely restricted to the brain and spinal cord. In situ hybridization histochemistry of spinal cord shows that motoneurons express L1, Nr-CAM, and neurofascin as well as N-CAM. L1 and N-CAM RNAs are detected throughout the period studied (from embryonic day [E]11 to postnatal day [P]28), whereas Nr-CAM is expressed only at early ages (< E15) and neurofascin is predominantly expressed postnatally. Moreover, each CAM is expressed by distinct subsets of neighboring cells and at distinct times. For example, Nr-CAM mRNA is present in floor plate cells of embryonic spinal cord, whereas neurofascin is expressed by a subset of glia postnatally. Finally, we show that each CAM has a distinct spatiotemporal pattern of expression in dorsal root ganglia.

Fish optic nerve oligodendrocytes support axonal regeneration of fish and mammalian retinal ganglion cells

Segments from adult fish and rat retinae were explanted on myelin-marker expressing oligodendrocytes derived from the regenerating goldfish optic nerve. Fish axons grew in high density and even rat retinal axons regenerated to considerable length on the surface of the fish oligodendrocytes, suggesting that this type of fish glia has axon-growth promoting surface components that exert their influence across species boundaries. One interesting surface component of the fish oligodendrocytes as demonstrated here is the E 587 antigen, which is related to the L1 family of cell adhesion molecules. In long term cocultures of oligodendrocytes and retinal axons, the fish glial cells were found to enwrap rat axons. This suggests that the oligodendrocytes of the regenerating goldfish optic nerve/tract may, despite striking differences, represent the equivalent to mammalian optic nerve oligodendrocytes.

Oligodendrocyte proteoglycans: modulation by cell-substratum adhesion

The signals that trigger the cytodifferentiation of oligodendrocytes (OLGs) are largely unknown. Using as a model system cultures of pure OLGs, we have shown that adhesion to a substratum initiates myelinogenesis (Yim SH, Szuchet S, Polak PE, J Biol Chem 261:11808-11815, 1986). It was of interest to investigate whether components such as proteoglycans (PGs) play any role in the biology of OLGs as it pertains to myelinogenesis. We set out to determine first, whether OLGs carry PGs; second, the nature of the association of these components with OLG plasma membrane; and third, if and how these PGs are modulated by OLG-substratum interaction. We compared the expression and characteristics of PGs extracted with different solvents from nonattached (B3.f) and attached (B3.fA) OLGs. B3.f and B3.fA OLG cultures were labeled with carrier-free 35SO4(2-) in serum-free medium. After removing excess label, OLGs were treated with heparin to extract susceptible components. Pellets were then exposed to 1% Triton X-100 plus 0.1 M NaCl and subsequently to 4 M guanidine-HCl plus 0.5 M NaCl. Solutions containing extracted material were characterized by size-exclusion chromatography, SDS-PAGE, and enzymatic degradation. Herein we report that (1) OLGs display [35S]PGs on their surface within 24 hr of substratum adhesion, and (2) these PGs can be operationally classified as peripheral and integral. We further show that the peripheral PGs are of high and intermediate size as assessed by size-exclusion chromatography and are segregated within the plasma membrane in such a way that the species with intermediate mass are extracted while OLGs remain adhered, whereas the high-molecular-weight species are only extracted after OLGs have been detached. Heparin also dislodges a number of sulfated proteins/Gps. Only a single class--high molecular weight--of integral PGs was identified; this PG requires guanidine-HCl for extraction. All PGs belong to the heparan sulfate class as evidenced by their degradation with heparitinase and their lack of susceptibility to chondroitinase ABC. The common theme of our findings is that these macromolecules have basal levels of expression in the nonadhered OLGs but undergo an adhesion-induced enhancement in their syntheses. We postulate that these PGs (1) play a role in OLG-substratum adhesion and hence myelinogenesis, and (2) may be determinants in establishing OLG polarity. Such polarization is the first overt sign of OLG functional differentiation and occurs prior to any morphological differentiation, e.g., extension of processes does not occur until 48 hr later when the plasma membrane is already polarized.

Relations between axons and oligodendroglial cells during initial myelination. II. The individual axon

Axo-glial relations in the ventral funiculus of the spinal cord (SC) and in the corpus callosum (CC) of the cat were examined by electron microscopy during initial myelination. In addition to random transverse and longitudinal sections from several stages, two series of sections were studied. As a first step in myelination the axons become ensheathed by one to three uncompacted glial lamellae (E-sheaths). E-sheaths present a length range from less than 5 microns to 149 microns (SC) or to 93 microns (CC). E-sheaths are more frequent along SC-axons than CC-axons, and the mean E-sheath is 3.3-fold longer in the former compared to the latter. In both areas naked axon portions occur between successive E-sheaths, but these gaps are insufficient to allow elongation of all short E-sheaths into long ones. Sheaths composed of mixed compacted (M-sheaths) and uncompacted segments have a length range of 66-212 microns in the SC and 66-171 microns in the CC. In relation to the undifferentiated terminations of E-sheaths or mixed E/M-sheaths, undercoated axolemmal domains are always lacking. Fully compacted sheaths were not found in the series from the SC. In the CC, 141-212 microns long compact sheaths were found, with tight axoglial junctions at their terminations. Axolemmal domains with a 'nodal' undercoating occur in relation to some of these terminations. In both areas, individual developing axons present a chaotic mixture of naked, ensheathed and myelinated portions; bulges with clusters of vesiculotubular profiles are frequent along naked and ensheathed axonal portions, particularly in the SC. The axon diameter is clearly larger in myelinated than in naked portions of the same axon. On the basis of these results, we propose that the early glial sheaths of developing CNS axons actively elongate and undergo extensive remodelling before compaction. The maximal length of uncompacted E-sheaths, and the sheath length at which axoglial junctions and nodes of Ranvier form, are markedly different in the two areas.

Specificity in central myelination: evidence for local regulation of myelin thickness

The ventral funiculi of normal and X-irradiated 13-day-old rats were studied by electron microscopy. In both tissues, oligodendrocytes form myelin sheaths around multiple axons, with a single oligodendrocyte associated with several axons of different sizes. Despite their origin from the same glial cell, the myelin sheaths are thicker for larger axons. Polyribosomes and rough endoplasmic reticulum are observed in distal oligodendrocyte processes, in proximity to the forming myelin sheaths. These results indicate that myelin sheath thickness is matched to axon size via local mechanisms, and suggest a role of polyribosomes and/or rough endoplasmic reticulum in myelin formation.

Early myelin formation and glial cell development in the human spinal cord

In order to identify the onset of myelination as well as to clarify the development of glial cells in human cervical spinal cord 21 embryos and fetuses ranging from 5 weeks of ovulation age (16 mm in crown-rump length) to 13 weeks (110 mm) were examined with the light the electron microscope. The first appearance of definite myelinated fibers occurred in the lateral portion of the ventral marginal layer of 66-mm (10-weeks) fetus. These nascent myelinated axons were always of larger diameter than unmyelinated axons. Although they occurred infrequently, there were, nevertheless, degenerative changes observed in some of these first myelinated axons in the 66-mm fetus. by this time glial cells in the marginal layer rapidly increased in number and substantial differentiation had occurred. Young oligodendrocytes are considered as the only myelin-forming cells in the human spinal cord.

Dysmyelination in Chow Chow dogs: further studies in older dogs

The ultrastructure of myelin deficiency in Chow Chow dogs was studied in the spinal cord of a 15-month-old and a 3-year-old animal. It was found that myelination progresses with age in these dogs but is still deficient at the age of 3 years. The findings included axons with thin or uncompacted myelin sheaths, separated from each other by massive astrocytosis, and bizarre myelin formations. Normal numbers of morphologically normal oligodendrocytes were present in the myelin-deficient areas. The disease in these Chow Chow dogs consists of a strongly retarded myelination which is possibly due to a dysfunction or delay in glial maturation.

Interlamellar tight junctions of central myelin. I. Developmental mechanisms during myelogenesis

The process of myelination in the central nervous system (CNS) of the rat (optic nerve) was studied with the freeze-fracturing technique and ultrathin sectioning to obtain information on the developmental mechanisms of interlamellar tight junctions. Using a tilting cartridge for analysis of thin sections, it could be demonstrated that during the initial phase of wrapping a tight junction formation develops between the joining tips of the oligodendrocytic process. In tannic acid-stained samples these junctions appear as typical quintuple-layered membrane fusions, while in potassium permanganate-stained material membrane thickenings between the apposing glial tips are prevalent. The latter configuration represents the characteristic feature of the so-called radial component of central myelin. Using the freeze-fracturing technique, a biphasic mode of the myelinic tight junction assembly was detected. It is suggested that tight junctions represent a prerequisite of the myelination process.

Ultrastructural study of myelinating cells and sub-pial astrocytes in developing rat spinal cord

The anterior funiculus of the spinal cervical cord of post-natal rats was examined ultrastructurally. The myelinating cells found one day after brith contained a large amount of evenly distributed ribosomes up to the outer tongue of mesaxons, representing the cytoplasmic density. These cells were separated by astrocytic processes from the pial basement membrane, even when they were located on the pial surface. Astrocytes contained glial fibrils from one day onwards and often attached their processes to the pial basement membrane. Although the cytoplasmic processes of astrocytes occasionally wrapped axons, they were never shown to form the initial layer of myelin sheaths. However, the tenuous processes of the sub-pial astrocytes were occasionally rolled in myelin lamellae, as if a part of the myelin sheaths was constructed by astrocytic processes. The interpretation for this finding is discussed in relation to function and potency of the astrocytes, and variations and anomalies of nervous ontogeny.

A comparative study of the immunohistochemical localization of basic protein to myelin and oligodendrocytes in rat and chicken brain

Antisera to highly purified basic protein (BP) from rat and chicken brain were prepared and their purity and specificity demonstrated by double immunodiffusion and cross-immunoadsorption. These antisera were used for immunohistochemical localization of BP in the brains of adult and developing rat and chick. Myelin basic protein was exclusively localized to myelin or the myelin forming elements of the CNS. It was present in high concentrations in white matter and absent in areas free of myelin. Neuronal parikarya and dendrites were negative as were axons cut in cross section and at Nodes of Ranvier. The latter was best observed in cross sections of human spinal cord demonstrating also the immunoreactivity of the antibodies with human BP. The internodal distance in a fine (1.5 micrometer) rat cortical fiber was determined to be approximately 45 micrometers. Myelin basic protein was shown to extend into cranial roots, in contrast to myelin proteolipid protein which abruptly lose fluorescence as the nerves emerged from the brain. During development, BP was first observed on the fourteenth day of incubation in chick and at birth in the rat. The protein appeared in oligodendrocytes and in association with fibers near these cells. Fluorescent processes were frequently observed connecting the oligodendrocytes with the fibers. As myelination progressed, the intensity of the immunohistochemical reaction decreased in the oligodendrocytes while the brightness in fibers increase. Eventually, the oligodendrocytes became undetectable. Fibers with immature myelin exhibited a beaded or varicosed appearance with the highest concentration of immunofluorescence in the outer portion of the varicosities. The varicosities were postulated to represent dilations in the newly forming sheath between intervals of compaction along the axon undergoin myelination. These dilations might represent areas of increased cytoplasmic volume which could serve as channels for transport and/or storage sites for myelin proteins prior to incorporation into the membrane. The varicosities became less prominent with the thickening of the myelin sheath and mature myelinated fibers became smooth. The process of synthesis of BP, transport of the protein to the varicosed fibers, and maturation of the myelin sheath was seen to progress in a more or less caudal to rostral direction as myelination of the CNS takes place. In the rat, this was accomplished over approximately a 30-day period starting near the time of birth. In the chick, most of the myelination was accomplished in the three or four days immediately before hatching. At this time, innumerable oligodendrocytes were observed producing BP simultaneously in the major white fiber tracts. It is postulated that in chick some degree of oligodendrocytic cell death occurs normally during myelination.

The growth and myelination of central and peripheral segments of ventral motoneurone axons. A quantitative ultrastructural study

This study compares the growth and myelination of those parts of cervical ventral motoneurone axons in the spinal cord (the intramedullary segments) and in the ventral roots of fetal and young rats (up to 21 days postnatal). The same fibre bundles are examined centrally and peripherally. Myelination begins centrally and peripherally at about birth. However, the peripheral segments of some fibres may begin to become myelinated before the central. Over the first 3 weeks after birth the minimum circumference of peripheral segments of myelinated axons remains relatively constant at 3 mum but that of central segments falls from 2.5 mum to just over 1 mum. Axons within the same fibre bundles tend to be thinner and less heavily myelinated centrally than peripherally. With ageing, axon circumference becomes more strongly correlated with sheath thickness. The thickness of the sheath surrounding an axon of a given circumference does not differ statistically from one age to another or between central and peripheral segments. Studies of myelin sheath growth rate show that in the early stages glial and Schwann cells vary independently of one another in the rates at which they add new turns to sheaths around central and peripheral segments of axons in the same bundles.