Glioblastoma infiltration into central nervous system tissue in vitro: involvement of a metalloprotease

Differentiated oligodendrocytes and central nervous system (CNS) myelin are nonpermissive substrates for neurite growth and for cell attachment and spreading. This property is due to the presence of membrane-bound inhibitory proteins of 35 and 250 kD and is specifically neutralized by monoclonal antibody IN-1 (Caroni, P., and M. E. Schwab. 1988. Neuron. 1:85-96). Using rat optic nerve explants, CNS frozen sections, cultured oligodendrocytes or CNS myelin, we show here that highly invasive CNS tumor line (C6 glioblastoma) was not inhibited by these myelin- associated inhibitory components. Lack of inhibition was due to a specific mechanism as the metalloenzyme blocker 1,10-phenanthroline and two synthetic dipeptides containing metalloprotease-blocking sequences (gly-phe, tyr-tyr) specifically impaired C6 cell spreading on CNS myelin. In the presence of these inhibitors, C6 cells were affected by the IN-1-sensitive inhibitors in the same manner as control cells, e.g., 3T3 fibroblasts or B16 melanomas. Specific blockers of the serine, cysteine, and aspartyl protease classes had no effect. C6 cell spreading on inhibitor-free substrates such as CNS gray matter, peripheral nervous system myelin, glass, or poly-D-lysine was not sensitive to 1,10-phenanthroline. The nonpermissive substrate properties of CNS myelin were strongly reduced by incubation with a plasma membrane fraction prepared from C6 cells. This reduction was sensitive to the same inhibitors of metalloproteases. In our in vitro model for CNS white matter invasion, cell infiltration of optic nerve explants, which occurred with C6 cells but not with 3T3 fibroblasts or B16 melanomas, was impaired by the presence of the metalloprotease blockers. These results suggest that C6 cell infiltrative behavior in CNS white matter in vitro occurs by means of a metalloproteolytic activity, which probably acts on the myelin-associated inhibitory substrates.     

A New Myelin-Deficient Mutant Hamster: Biochemical and Morphological Studies

Biochemical and morphological studies were done on a new trembling mutant hamster CBB. The yield of myelin from the mutant was 30 and 40% of the control at 46 and 140 days of age, respectively, but myelin composition and 2',3'-cyclic nucleotide-3'-phosphohydrolase (CNPase) activity were normal. Morphologically, about 18% of the axons were myelinated in the mutant optic nerve at 46 days of age, in which the myelinated fibers were those with larger diameters (more than 0.6 micron), while the control had a peak at 0.4 micron in diameter. The ultrastructure and thickness of compact myelin lamellae in the mutant were normal. Myelination and the structure of peripheral nerve myelin appeared normal. The results indicate that the essential defect is the delay and arrest of myelination in the CNS, which is probably caused by either a decreased rate of synthesis of myelin components in oligodendrocytes or a defect in the oligodendrocyte-axon recognition in smaller axons.     

Two membrane protein fractions from rat central myelin with inhibitory properties for neurite growth and fibroblast spreading

Lack of neurite growth in optic nerve explants in vitro has been suggested to be due to nonpermissive substrate properties of higher vertebrate central nervous system (CNS) white matter. We have searched for surface components in CNS white matter, which would prevent neurite growth. CNS, but not peripheral nervous system (PNS) myelin fractions from rat and chick were highly nonpermissive substrates in vitro. We have used an in vitro spreading assay with 3T3 cells to quantify substrate qualities of membrane fractions and of isolated membrane proteins reconstituted in artificial lipid vesicles. CNS myelin nonpermissiveness was abolished by treatment with proteases and was not associated with myelin lipid. Nonpermissive proteins were found to be membrane bound and yielded highly nonpermissive substrates upon reconstitution into liposomes. Size fractionation of myelin protein by SDS-PAGE revealed two highly nonpermissive minor protein fractions of Mr 35 and 250-kD. Removal of 35- and of 250-kD protein fractions yielded a CNS myelin protein fraction with permissive substrate properties. Supplementation of permissive membrane protein fractions (PNS, liver) with low amounts of 35- or of 250-kD CNS myelin protein was sufficient to generate highly nonpermissive substrates. Inhibitory 35- and 250-kD proteins were found to be enriched in CNS white matter and were found in optic nerve cell cultures which contained highly nonpermissive, differentiated oligodendrocytes. The data presented demonstrate the existence of membrane proteins with potent nonpermissive substrate properties. Distribution and properties suggest that these proteins might play a crucial inhibitory role during development and regeneration in CNS white matter.     

Neurochemical Characteristics of Myelin-like Structure in the Chick Retina

Abstract: Certain characteristics of myelin-like structures in the chick retina were examined morphologically and biochemically. Developmental changes of 2', 3'-cyclic nucleotide 3'-phosphohydrolase (CNPase) in the chick retina and optic nerve were examined. The measurable activity in the retina was first detected at 16 days of incubation and thereafter, it increased rapidly until 4 weeks post-hatching. By contrast, CNPase activity in the optic nerve reached the maximum level at 4 days post-hatching and maintained a constant level thereafter. The purifed myelin fraction from the chick retina showed higher activity of CNPase, whereas its activity in the retinal homogenate was very low. Hence, it was considered that the myelin fraction from the chick retina is similar to that of CNS myelin with respect to CNPase. Protein profiles of the purified myelin fractions isolated from the chick optic tectum, optic nerve, retina and sciatic nerve were analysed by SDS-polyacrylamide gel elec-trophoresis. Myelin fractions from the chick optic tectum and optic nerve contained basic protein (BP) and Folch-Lees proteolipid protein (PLP). Myelin fraction from the chick sciatic nerve contained BP, P2 and two glycoproteins (PO and 23K). In contrast, retinal myelin fraction contained only BP. PLP, PO, 23K and P2 proteins were definitely undetectable. Electron micrographs revealed that some axons in the optic nerve fiber layer of the chick retina were wrapped by a spiral-structured myelin-like sheath, which showed some differences from those of CNS and PNS myelin sheaths. It was suggested that the origin of the myelin-like structure in the chick retina is other than from oligodendroglia or Schwann cells.     

Effects of Rumpshaker Mutation on CNS Myelin Composition and Structure

Abstract: Myelinated CNS tissues from homozygous/hemizygous and heterozygous jimpy rumpshaker jp ^rsh mutant mice were examined to determine the consequences on myelin structure of this mutation in the proteolipid protein (PLP) gene. Polyacrylamide gel electrophoresis and immunoblotting of brain homogenates confirmed that there was a decrease in PLP levels on the B6C3 genetic background onto which this gene was bred. We also observed an increase in level of a protein band that could correspond to the uncharacterized 10-kDa PLP previously reported in jp ^rsh mice on an Rb(1.3) 1Bnr background. High-performance TLC and densitometry of lipids from brain homogenate and isolated myelin revealed a decrease in content of cerebrosides and sulfatides. Electron microscopy on optic nerves revealed that normal radial component is retained in jp ^rsh myelin, further substantiating that PLP is not a component of this junctional complex. X-raydiffraction measurements on unfixed optic nerves showed that the jp ^rsh period is 5–10 Å larger than normal. Moreover, jp ^rsh optic nerve myelin was unstable, as evidenced by a continual increase in the period postdissection. jp ^rsh myelin that was equilibrated at varying pH and ionic strength typically had a larger than normal period under all conditions (both swelling and compacting). Our findings thus demonstrate that the biochemical abnormalities in the jp ^rsh mutant correlate with a wider periodicity and less stable packing of the myelin.     

Myelin-Associated Glycoprotein: Electron Microscopic Immunocytochemical Localization in Compact Developing and Adult Central Nervous System Myelin

Light microscopic immunocytochemical studies have shown that myelin-associated glycoprotein (MAG) is localized in myelin of the developing CNS; but in the adult, MAG appears to be restricted to periaxonal regions of myelinated fibers. To extend these observations, we embedded optic nerves of 15-day-old rats, adult rats, and an adult human in epon after aldehyde and osmium tetroxide fixation. After 5% H2O2 pretreatment, thin sections were immunostained with 1:250-1:5,000 rabbit antiserum to rat CNS MAG according to the avidin-biotin-peroxidase complex (ABC) method. Dense deposits of reaction product covered compact myelin in both developing and adult optic nerves. When we used 1:500, 1:1,000, and 1:2,000 anti-MAG, less intense immunostaining of myelin was found. We also obtained the same localization in compact myelin with the peroxidase-antiperoxidase (PAP) method. With 1:250 anti-MAG, dense deposits of reaction product were not observed on axolemmal membranes or on oligodendroglial membranes located periaxonally and paranodally. In thin sections of adult human optic nerve, anti-MAG also stained compact myelin intensely. When thin sections of rat and human optic nerves were treated with preimmune or absorbed serum, no immunostaining was observed. Immunoblot tests showed that our MAG antisera did not react with any non-MAG myelin proteins. In contrast with earlier light microscopic data, this study shows that MAG localization does not change during CNS development; both developing and adult compact myelin sheaths contain MAG. As many biochemical studies also show that MAG is present in compact myelin, we suggest that this 100,000 dalton glycoprotein now be called myelin glycoprotein (MGP) instead of MAG.     

Protein and Glycoprotein Composition of Myelin Subfractions from the Developing Rat Optic Nerve and Tract

Abstract: The rat optic nerve and tract (representing a relatively homogeneous part of the CNS) were utilised for a detailed examination of the protein and glycoprotein composition of developing myelin membranes. Animals aged from 5 days through to adulthood were used. Myelin fractions could first be isolated from the nerve 8 days after birth and the yield increased until 60 days of age, before declining slightly to the adult level; a similar (but possibly slightly delayed) pattern was apparent for the optic tract. The homogeneity of optic nerve myelin (compared with that from brain and spinal cord) was demonstrated by zonal centrifugation on continuous sucrose-density gradients; myelin from both 20-day and adult animals exhibited narrow, Gaussian-like distributions, with 19–22% of the total myelin at the population modes. During development, the myelin density profile was shifted to a denser region of the sucrose gradients. Micro-polyacrylamide gel electrophoretic analyses of "light" and "heavy" myelin subfractions from both optic nerve and tract indicated that the gross developmental changes in protein composition were similar to those previously described for myelin prepared from larger CNS areas, particularly the forebrain. The glycoprotein components of the myelin fractions were stained directly on micro-gels using fluorescein isothiocyanate-labelled concanavalin A. The relative proportion of the major high-molecular-weight glycoprotein decreased rapidly during the early phases of myelination. A number of lower-molecular-weight glycoproteins were also apparent; the proportions of these varied during development and in light and heavy myelin subfractions, but definitive data are not available to determine whether they are components of the myelin sheath or of contaminating membranes.     

The Myelin-Deficient Rat Has a Single Base Substitution in the Third Exon of the Myelin Proteolipid Protein Gene

Several genetic disorders that occur in animals and in humans result in an inability to synthesize normal myelin. Some of these disorders are inherited in an X-linked manner. The localization of the myelin proteolipid protein (PLP) gene to the X chromosome has directed the study of X-linked myelination disorders toward PLP. The myelin-deficient rat is one such X-linked dysmyelinating mutant. From a cDNA library constructed from myelin-deficient rat brain mRNA, we have isolated and sequenced cDNAs corresponding to PLP and its alternatively spliced isoform, DM-20. An A to C transition was detected in these cDNAs, which results in a threonine to proline change at amino acid 74 in both PLP and DM-20. No other substitutions were seen in the cDNA sequences. Polymerase chain reaction amplification and sequencing of the corresponding genomic regions were used to confirm the single base change. This substitution occurs in a highly hydrophobic portion of the protein that is thought to be an alpha-helical transmembrane segment. The presence of a helix-breaking amino acid such as proline in this segment is likely to influence the ability of the protein to interact with the membrane.     

Meylin types with different protein components in the same species

Abstract— Myelin was isolated from bovine optic nerve, cerebral white matter, spinal cord white matter and peripheral nerve (intradural spinal roots). The freeze-dried myelin completely dissolved in phenol-formic acid-water (14:3:3, w/v/v), and acrylamide gel electrophoresis of the myelin proteins was performed with this solvent. Qualitative and quantitative differences were observed in the myelin proteins from the various regions of the CNS. Myelin of peripheral nerve contained proteins that are apparently unique to it and which are not found in the myelin of the CNS.     

Immunoglobulins and complement in demyelination induced in mice by Theiler's virus

Intracerebral inoculation of Theiler's murine encephalomyelitis virus (TMEV) produces chronic demyelination and persistent infection in the central nervous system (CNS) of susceptible SJL mice. This series of experiments examined the contribution of humoral immunity and C to myelin destruction. As in multiple sclerosis, mice persistently infected with TMEV had elevated levels of IgG and oligoclonal bands in the cerebrospinal fluid (CSF). Immunoblot studies revealed that even in animals exhibiting profound demyelination, IgG in the serum and CSF was directed primarily at virus antigen rather than at normal myelin components. Inflammatory cells positive for Ig were distributed mainly around blood vessels, but occasionally they infiltrated the spinal cord parenchyma. Rare examples of myelin sheaths positive for IgG were found by immunoelectron microscopy in spinal cord sections from infected mice; the third component of complement (C3) was commonly found in the walls of CNS blood vessels but not on myelin. Neither serum nor CSF IgG from infected mice bound to myelin sheaths or other CNS components in sections of normal syngeneic spinal cord. There were significantly more demyelinating lesions in infected mice depleted of C components with cobra venom factor. These data do not support a humoral autoimmune basis for the CNS demyelination that occurs in association with persistent TMEV infection. However, the humoral immune response directed at TMEV antigens may either limit virus spread or promote virus persistence.     

Myelin Structure and Composition in Zebrafish

To establish a standard for genotype/phenotype studies on the myelin of zebrafish (Danio rerio), an organism increasingly popular as a model system for vertebrates, we have initiated a detailed characterization of the structure and biochemical composition of its myelinated central and peripheral nervous system (CNS; PNS) tissues. Myelin periods, determined by X-ray diffraction from whole, unfixed optic and lateral line nerves, were approximately 153 and approximately 162 Angstrom, respectively. In contrast with the lability of PNS myelin in higher vertebrates, zebrafish lateral line nerve myelin exhibited structural stability when exposed to substantial changes in pH and ionic strength. Neither optic nor lateral line nerves showed swelling at the cytoplasmic apposition in CaCl(2)-containing Ringer's solution, in contrast with nerves from other teleost and elasmobranch fishes. Zebrafish optic nerve showed greater stability against changes in NaCl and CaCl(2) than lateral line nerve. The nerves from zebrafish having mutations in the gene for myelin basic protein (mbpAla2Thr and mbpAsp25Val) showed similar myelin periods as the wildtype (WT), but gave approximately 20% less compact myelin. Analysis of proteins by SDS-PAGE and Western blotting identified in both CNS and PNS of WT zebrafish two orthologues of myelin P0 glycoprotein that have been characterized extensively in trout--intermediate protein 1 (24 kDa) and intermediate protein 2 (28 kDa). Treatment with endoglycosidase-F demonstrated a carbohydrate moiety of approximately 7 kDa, which is nearly threefold larger than for higher vertebrates. Thin-layer chromatography for lipids revealed a similar composition as for other teleosts. Taken together, these data will serve as a baseline for detecting changes in the structure and/or amount of myelin resulting from mutations in myelin-related genes or from exogenous, potentially cytotoxic compounds that could affect myelin formation or stability.     

Does a cytoplasmic bridge connect the CNS axon with the inner loop of myelin?

Sarah Luse (1959) reported over 30 years ago on the presence of a bridge connecting the axon to the myelin sheath in the central nervous system (CNS). This notion has not been accepted in the literature. Wolman (1992) found that the progress of demyelination in some viral diseases affecting the CNS fits the concept of Luse, as the process occurred primarily along the major dense line of myelin, which is in continuity with the cytoplasm of the oligodendroglial cell. Injection of Lucifer yellow (LY) and horseradish peroxidase (HRP) into the vitreous of guinea pigs, with and without iontophoresis, resulted in labeling of the nerve axons and myelin. Labeling of myelin by HRP occurred along the major dense line which indicated that a transient or permanent cytoplasmic bridge connects axons and myelin in the optic nerve.     

Myelin basic protein in the optic nerve of the developing albino rat: An immunoperoxidase study of paraffin embedded tissue

The distribution of myelin basic protein (MBP) was determined by application of the unlabeled peroxidase-anti-peroxidase method to sections of paraffin embedded optic nerve taken from the developing albino rat. MBP was not detected in optic nerves from animals younger than 90 hours postnatum. MBP staining presented first as faint, diffuse deposits of chromagen which were found in approximately one-third of the 90 hour subjects. The number of MBP positive regions and the intensity of staining of these regions increased rapidly with age. There was no obvious radial gradient in the distribution of MBP in cross sections of developing optic nerves, nor were smooth central/peripheral gradients apparent in longitudinal sections.Special Issue dedicated to Dr. Elizabeth Roboz-Einstein.     

Biochemical Analysis of Myelin Proteins in a Novel Neurological Mutant: The Taiep Rat

Abstract: Hemispheres, spinal cords, and sciatic nerves were taken from taiep, carrier, and control rats at ages ranging from 1 day to 16 months. Absolute myelin yields from CNS taiep tissues peaked at ～2 months and then decreased until they reached a low but stable level. Myelin yield from the affected hemispheres expressed as a percentage of age-matched controls decreased continuously from 2 weeks until it reached a stable level of ～10–15%. The same was true for the spinal cords, but here the myelin yield reached a plateau at a slightly higher percentage of 20–25%. In comparison with control rats, isolated CNS myelin fractions from the affected rats had a greater content of high molecular weight proteins. Western blot analyses of CNS homogenates revealed that myelin basic protein (MBP), proteolipid protein, and 2′,3′-cyclic nucleotide 3′-phosphodiesterase were all present but decreased to levels generally consistent with the deficiencies of myelin. However myelin-associated glycoprotein (MAG) levels always were reduced much more than those of the other three myelin proteins, and at younger ages the apparent molecular weight for MAG was increased in the mutants. Western blot analyses of sciatic nerve homogenates showed that the levels of MBP, MAG, and P₀ were not significantly different in control and mutant animals. These results suggested an early hypomyelination of the CNS, with peak levels of myelin at 2 months, followed by a prolonged period of myelin loss, until a very low but stable myelin level was reached. The consistently greater loss of MAG, in comparison with other CNS myelin proteins, is different from most other hypomyelinating mutants in which MAG is relatively preserved in comparison with the proteins of compact myelin. This might be due to microtubular abnormalities in the taiep mutant interfering with transport of myelin proteins and having the greatest effect on MAG because of its most distal location in the periaxonal oligodendroglial membranes.     

Knockout of p75(NTR) impairs re-myelination of injured sciatic nerve in mice

Remyelination is an important aspect of nerve regeneration after nerve injury but the underlying mechanisms are not fully understood. The neurotrophin receptor, p75(NTR), in activated Schwann cells in the Wallerian degenerated nerve is up-regulated and may play a role in the remyelination of regenerating peripheral nerves. In the present study, the role of p75(NTR) in remyelination of the sciatic nerve was investigated in p75(NTR) mutant mice. Histological results showed that the number of myelinated axons and thickness of myelin sheath in the injured sciatic nerves were reduced in mutant mice compared with wild-type mice. The myelin sheath of axons in the intact sciatic nerve of adult mutant mice is also thinner than that of wild-type mice. Real-time RT-PCR showed that mRNA levels for myelin basic protein and P0 in the injured sciatic nerves were significantly reduced in p75(NTR) mutant animals. Western blots also showed a significant reduction of P0 protein in the injured sciatic nerves of mutant animals. These results suggest that p75(NTR) is important for the myelinogenesis during the regeneration of peripheral nerves after injury.     

Morphological and morphometric studies of the dysmyelinating mutant,the Long Evans shaker rat

The Long Evans shaker (les) rat is a recently identified CNS myelin mutant with an autosomal recessive mode of inheritance. Although scattered myelin sheaths are present in some areas of the CNS, most notably the ventral spinal cord in the young neonatal rat, this myelin is gradually lost, and 8-12 weeks little myelin is present throughout the CNS. Despite this severe myelin deficiency, some mutants may live beyond one year of age. Rare, thin myelin sheaths that are present early in development lack myelin basic protein (MBP) and on ultrastructural examination are poorly compacted and lack a major dense line. Many oligodendrocytes develop an accumulation of vesicles and membranous bodies, but no abnormal cell death is observed. In the optic nerve, cell kinetic studies show an increase in proliferation at early time points in les, while total glial cell counts are also increased in les from 2 months of age. In situ hybridization studies demonstrate that the numbers of mature oligodendrocytes are similar to controls early in life and increase with time compared to controls. There is both a progressive astrocyte hypertrophy and microgliosis. While les has a mutation in the myelin basic protein (mbp) gene, it is dissimilar in both genotype and phenotype to the previously described mbp mouse mutants, shiverer (shi) and shiverermld. Unlike shi and its allele, where myelin increases with time and oligodendrocytes become ultrastructurally normal, les oligodendrocytes are permanently disabled, continue to demonstrate cytoplasmic abnormalities, and fail to produce myelin beyond the first weeks of life.     

Schwann cells in the regenerating fish optic nerve: Evidence that CNS axons,not the glia,determine when myelin formation begins

Fish optic nerve fibres quickly regenerate after injury, but the onset of remyelination is delayed until they reach the brain. This recapitulates the timetable of CNS myelinogenesis during development in vertebrate animals generally, and we have used the regenerating fish optic nerve to obtain evidence that it is the axons, not the myelinating glial cells, that determine when myelin formation begins. In fish, the site of an optic nerve injury becomes remyelinated by ectopic Schwann cells of unknown origin. We allowed these cells to become established and then used them as reporters to indicate the time course of pro-myelin signalling during a further round of axonal outgrowth following a second upstream lesion. Unlike in the mammalian PNS, the ectopic Schwann cells failed to respond to axotomy and to the initial outgrowth of new optic axons. They only began to divide after the axons had reached the brain. Shortly afterwards, small numbers of Schwann cells began to leave the dividing pool and form myelin sheaths. More followed gradually, so that by 3 months remyelination was almost completed and few dividing cells were left. Moreover, remyelination occurred synchronously throughout the optic nerve, with the same time course in the pre-existing Schwann cells, the new ones that colonised the second injury, and the CNS oligodendrocytes elsewhere. The optic axons are the only common structures that could synchronise myelin formation in these disparate glial populations. The responses of the ectopic Schwann cells suggest that they are controlled by the regenerating optic axons in two consecutive steps. First, they begin to proliferate when the growing axons reach the brain. Second, they leave the cell cycle to differentiate individually at widely different times during the ensuing 2 months, during the critical period when the initial rough pattern of axon terminals in the optic tectum becomes refined into an accurate map. We suggest that each axon signals individually for myelin ensheathment once it completes this process.     

The Endogenous Lectin Cerebellar Soluble Lectin and Its Ligands in Central Nervous System Myelin of Myelin-Deficient (mld) Mutant Mice

The myelin-deficient (mld) mutation is autosomal recessive mutation in the murine CNS exhibiting severe hypomyelination. The primary defect results in a drastic reduction of myelin basic protein synthesis caused by a duplication of the myelin basic protein gene with partial inversion of the upstream gene copy. The severe deficit of myelin basic protein is responsible for the absence of the major dense line but cannot explain the heterogeneity of myelin compaction found in mld. We have tested the hypothesis that the endogenous cerebellar soluble lectin (CSL) and/or its endogenous glycoprotein ligands could be involved in myelin abnormalities in the dysmyelinating mutant, mld. Immunocytochemical and immunoblotting techniques showed that the CSL level was not reduced significantly in the mld mutant. Furthermore, two ligands of CSL, the myelin-associated glycoprotein and an axonal glycoprotein, with a relative molecular mass of 31 kDa, were not decreased in level in the purified myelin fraction isolated from mld mice. In contrast, three minor glycoprotein ligands of CSL of relative molecular mass of 23, 18, and 16 kDa were greatly reduced in content. The reduced concentration of these low-molecular-mass glycoproteins in mld myelin suggests that they are constituents of compact myelin. Furthermore, the observation that CSL is specifically localized in vivo in regions where mld myelin is more compact and absent from regions devoid of myelin compaction may suggest that the endogenous CSL lectin, as well as its minor glycoprotein ligands, plays a role in the stabilization of the myelin sheath.     

Myelin abnormalities in mice deficient in galactocerebroside and sulfatide

Myelin sheath formation depends on appropriate axo-glial interactions that are mediated by myelin-specific surface molecules. In this study, we have used quantitative morphological analysis to determine the roles of the prominent myelin lipids galactocerebroside (GalC) and sulfatide in both central and peripheral myelin formation, exploiting mutant mice incapable of synthesizing these lipids. Our results demonstrate a significant increase in uncompacted myelin sheaths, the frequency of multiple cytoplasmic loops, redundant myelin profiles, and Schmidt-Lanterman incisures in the CNS of these mutant mice. In contrast, PNS myelin appeared structurally normal in these animals; however, at post-natal day 10, greater than 10% of the axons withered and pulled away from their myelin sheaths. These results indicate that GalC and sulfatide are critical to the formation of CNS myelin. In contrast, PNS myelin formation is not dependent on these lipids; however, GalC and sulfatide appear to be instrumental in maintaining Schwann cell-axon contact during a specific developmental window.