Morphological and biochemical characterization of light and heavy myelin isolated from developing rat brain

Phospholipid and cholesterol alterations accompany structural disarray in myelin membrane of rats with hepatic encephalopathy induced by thioacetamide

Fulminant hepatic failure is often associated with a wide range of neurological symptoms which are collectively referred to as hepatic encephalopathy. Fulminant hepatic failure with associated hepatic encephalopathy has a poor prognosis with the currently available sure treatment being only liver transplantation. This is largely owing to the lack of understanding of critical factors involved in the etiology of the condition. Lipid changes have been implicated in cerebral derangements characteristic of hepatic encephalopathy. About 79% of the brain lipid is concentrated in the myelin fraction where they play an important role in ion balance and conduction of nerve impulses. Hence, in the present study we aimed to investigate changes in myelin lipid composition and structure. Myelin was isolated by sucrose density gradient centrifugation from cerebral cortex of male Wistar rats (250-300 g body weight) treated with 300 mg/kg body weight thioacetamide administered twice at 24h interval to induce hepatic encephalopathy. Significant decrease was observed in the cholesterol and phospholipids content of myelin from treated rats. Sphingomyelin, phosphatidylserine and phosphatidylethanolamine content also decreased significantly following 18 h of thioacetamide administration. However, phosphatidylcholine levels remained unaltered. Transmission electron microscopic observation of myelin membrane from cerebral cortex sections showed considerable disorganization in myelin structure. Increase in malondialdehyde levels precede lipid changes leading to the speculation that oxidative damage may be the critical factor leading to decrease in the anionic phospholipids. Changes in myelin were evident only in later stages of hepatic encephalopathy indicating that myelin alteration may not play a role in early stages of hepatic encephalopathy. Nevertheless, myelin alteration may have a crucial role to play in various psycho-motor alterations during later stages of hepatic encephalopathy.

The myelin-axolemmal complex: biochemical dissection and the role of galactosphingolipids

Myelin-axolemmal interactions regulate many cellular and molecular events, including gene expression, oligodendrocyte survival and ion channel clustering. Here we report the biochemical fractionation and enrichment of distinct subcellular domains from myelinated nerve fibers. Using antibodies against proteins found in compact myelin, non-compact myelin and axolemma, we show that a rigorous procedure designed to purify myelin also results in the isolation of the myelin-axolemmal complex, a high-affinity protein complex consisting of axonal and oligodendroglial components. Further, the isolation of distinct subcellular domains from galactolipid-deficient mice with disrupted axoglial junctions is altered in a manner consistent with the delocalization of axolemmal proteins observed in these animals. These results suggest a paradigm for identification of proteins involved in neuroglial signaling.

Highly basic myelin and oligodendrocyte proteins analyzed by NEPHGE-two-dimensional gel electrophoresis: recognition of novel developmentally regulated proteins

Two-dimensional polyacrylamide gel electrophoresis (2D-PAGE) provides high resolution separation of proteins and offers a powerful method for their identification and characterization. Since many myelin-specific proteins are highly basic, they cannot readily be analyzed by standard isoelectric focusing (IEF)-2D-PAGE that affords separation primarily in the isoelectric points (pI) range of 4-8. An alternative method, nonequilibrium pH gradient electrophoresis (NEPHGE)-2D-PAGE, can provide excellent resolution of highly basic proteins. In the present study, we have optimized the NEPHGE-2D-PAGE protocol for the analysis of myelin proteins with basic pIs, and provide a NEPHGE-2D-PAGE map based on size, pI, and immunoreactivity (Western blot) of myelin basic protein (MBP), 2', 3'-cyclic-nucleotide 3'-phosphodiesterase (CNP), myelin proteolipid protein (PLP), and its smaller spliced variant DM20, myelin/oligodendrocyte glycoprotein (MOG) and oligodendrocyte-specific protein (OSP). We have also demonstrated, by analyzing metabolically radiolabeled oligodendrocytes in culture at specific stages of the developmental lineage, the developmentally up-regulated expressions of several undefined, oligodendrocyte, basic membrane proteins during oligodendrocyte differentiation. We suggest that this approach offers an important tool for identifying and characterizing the plethora of uncharacterized myelin proteins.

Metabolic turnover of myelin glycerophospholipids

The apparent half life for metabolic turnover of glycerophospholipids in the myelin sheath, as determined by measuring the rate of loss of label in a myelin glycerophospholipid following radioactive precursor injection, varies with the radioactive precursor used, age of animal, and time after injection during which metabolic turnover is studied. Experimental strategies for resolving apparent inconsistencies consequent to these variables are discussed. Illustrative data concerning turnover of phosphatidylcholine (PC) in myelin of rat brain are presented. PC of the myelin membrane exhibits heterogeneity with respect to metabolic turnover rates. There are at least two metabolic pools of PC in myelin, one with a half life of the order of days, and another with a half life of the order of weeks. To a significant extent biphasic turnover is due to differential turnover of individual molecular species (which differ in acyl chain composition). The two predominant molecular species of myelin PC turnover at very different rates (16:0, 18:1 PC turning over several times more rapidly than 18:0, 18:1 PC). Therefore, within the same membrane, individual molecular species of a phospholipid class are metabolized at different rates. Possible mechanisms for differential turnover of molecular species are discussed, as are other factors that may contribute to a multiphasic turnover of glycerophospholipids.

Myelin membrane biogenesis by oligodendrocytes. Developmental regulation of low molecular weight GTP-binding proteins

Oligodendrocytes synthesize dramatic amounts of myelin membrane. We hypothesized that this requires unique aspects of vesicular trafficking. Specific stages of the oligodendrocyte lineage were assayed for low molecular weight GTP-binding proteins implicated in the regulation of vesicular transport pathway (two dimensional gel electrophoresis, [alpha-32P]GTP overlay). Consistent with the hypothesis, as oligodendrocytes differentiate from early progenitors to mature myelin-producing cells, > or = 12 small GTP-binding proteins become up-regulated. Myelin membrane also has a complex pattern of GTP-binding proteins. Several of these proteins may be specific to oligodendrocytes, suggesting that oligodendrocytes may utilize cell-type specific GTP-binding proteins for biogenesis and maintenance of the myelin membrane.

Myelin isolation: comparison of sedimentation and flotation techniques

Brains from young (20 day old) and adult rats were used to compare myelin yields obtained by sedimentation and flotation techniques. The flotation method consistently gave approx 70% higher yields of myelin than the sedimentation method. Both myelin preparations have virtually identical protein composition as assessed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Electrophoretic analysis revealed substantial concentrations of myelin proteins in the non-myelin particulate fraction obtained by the sedimentation but not by the flotation method. The study indicates that the paradigm of the sedimentation method results in a significant loss of myelin during isolation, and that this loss can be avoided or minimized by employing the flotation method.

In vitro changes in the fine structure and protein composition of light myelin fractions isolated from guinea pig brain

To find out if in vitro maintenance produces changes in the electron microscopic appearance, protein composition and phosphorylation properties of guinea pig CNS myelin fractions, we incubated them for 10 min, 4 hr, 24 hr, and 48 hr in phosphate-buffered saline (pH 7.4) or in 20 mM Hepes, 2 mM EDTA, 0.5 mM EGTA, 0.5 mM dithiothreitol, and 20 mM NaCl at 4 and 30 degree C. Aliquots were processed for electron microscopic study, were analyzed for protein content by gel electrophoresis, and were assayed for endogenous protein phosphorylation. Before incubation, electron micrographs of fractions contained two types of multilamellar whorls with the periodicity of CNS myelin sheaths. The first type of whorl was separated from nearby whorls; the other type had surface lamellae that were connected to other multilayered membrane fragments. After incubation at 4 degree C for 24 hr, the number of both types of multilamellar whorls in micrographs had increased approximately 3- to 4- fold. Counts per unit area showed that the observed increase was both time- and temperature-dependent. In aliquots studied by gel electrophoresis, only minor degradation of myelin proteins was observed. The endogenous protein phosphorylation properties of the myelin fragments also remained functional, suggesting that the activities of protein phosphotransferases were not altered. We conclude that the incubation conditions described here favor interactions of proteins and lipids that lead to the formation of multilayered aggregates of CNS myelin membranes.

Lipid profile of rat myelin subfractions

Myelin from adult rat brains was separated on a discontinuous sucrose gradient into three subfractions. Analysis of "light", "heavy" and "membrane fraction" lipid classes was performed by HPTLC and densitometry while fatty acid composition was determinated by GLC. The more interesting results observed are: i) the "membrane fraction" resembles in its lipid and fatty acid composition other cell membranes (particularly oligodentrocytes); ii) "light" and "heavy" myelin are quite similar between them but the former has a higher content of sphingomyelin, a lower hydroxy/nonhydroxy cerebrosides ratio and a lower content of monoenoic fatty acids than the "heavy" subfraction. The results obtained could explain the different structures observed in each myelin subfraction since fatty acid composition, hydroxy fatty acids, sphingomyelin and cholesterol play a key role in the stability and structure of membranes.

Isolation and characterization of bovine brain myelin distribution of 5'-nucleotidase

Myelin was isolated from bovine brain by several published procedures and modifications of these procedures. High activity of the myelin marker (2',3'-cyclic nucleotide 3'-phosphohydrolase) and low activity of contaminants markers in white matter homogenates in respect to cerebral cortex showed the white matter to be better than the cerebral cortex or the whole brain for myelin isolation. A procedure is described for the preparation of purified myelin from bovine white matter which yielded a content of protein (40%), myelin marker (51%), and 5'-nucleotidase (25%) in purified myelin higher than by any used method. Acetylcholinesterase or succinate dehydrogenase was lower than 7% of its activity in the white matter homogenate, and monoamine oxidase and NADPH:cytochrome c reductase were not recovered in myelin fraction. Morphologically, myelin fraction was shown to mainly consist of multilamellar membranes of different sizes. Sodium dodecyl sulphate polyacrylamide gel electrophoresis of myelin fraction showed a characteristic protein pattern of myelin. When our procedure was applied to frozen white matter, lower protein (32%) and myelin marker (34%) and similar 5'-nucleotidase activity (24%) were recovered in myelin, increasing its recovery in denser fractions of white matter.

Characterization of myelin fractions from human brain white matter

Myelin and myelin-containing (P3) fractions were prepared from human white matter by discontinuous sucrose gradient centrifugation. The myelin isolated from each of the fractions of different densities was morphologically and biochemically distinct. Light myelin fractions consisted of compact, multilamellar myelin, whereas the denser fractions consisted predominantly of loose myelin with fewer lamellae. The amounts of both basic protein and lipophilin (proteolipid protein) were reduced in the denser fractions. In contrast, the high-molecular-weight components were elevated in the dense fractions. The lipid composition was similar in all the fractions studied. Analysis of basic protein by gel electrophoresis at pH 10.6 revealed differences in basic protein microheterogeneity among the fractions. The light myelin fraction was enriched in the more positively charged basic protein components (components 1, 2, and 3), whereas these components were reduced in the denser fractions. Myelin in the dense fractions was enriched in the more modified forms of basic protein (components 6, 7, and 8). The pattern of microheterogeneity was different for basic protein isolated from myelins of a 2-year-old and an adult brain; the former showed fewer components and mainly the most cationic species. On the other hand, the pattern of microheterogeneity of basic protein isolated from the different density gradient fractions was similar for both ages.

Regional studies of myelin proteins in human brain and spinal cord

The myelin specific proteins, myelin basic protein (MBP) and myelin proteolipid protein (PLP) were quantitated by radioimmunoassay (RIA) and the activity of the enzyme 2',3'-cyclic 3' phosphohydrolase (CNP) measured, in 27 regions of normal brain and spinal cord. Varying regional concentrations for each protein and regional variations for protein ratios were noted, supporting the concept of a varying chemical composition for myelin throughout the central nervous system (CNS). Variation was also noted among myelin subfractions from a single region. Regions with special sensitivity to the multiple sclerosis process had relatively lower proportions of CNP in several, but not all cases.

In vivo acylation of proteolipid protein and DM-20 in myelin and myelin subfractions of developing rat brain: immunoblot identification of acylated PLP and DM-20

The acylation of proteolipid protein (PLP) was examined in myelin and myelin subfractions from rat brain during the active period of myelination. Proteolipid protein and DM-20 in myelin and myelin subfractions were readily acylated in developing rat brain 22 hours after intracerebral injection of [3H]palmitic acid. No differences in the relative specific activity of PLP in myelin from 9-, 15-, and 30-day-old rat brains was observed; however, the relative specific activity of PLP in the heavy myelin subfraction tended to be higher than that in the light myelin subfraction. The acylation of PLP was confirmed by fluorography of immuno-stained cellulose nitrate sheets, clearly establishing that the acylated protein is in fact the oligodendroglial cell- and myelin-specific protein, PLP. Since PLP is acylated in the 9-day-old animal, when little compact myelin is present, it is possible that the acylation of PLP is a prerequisite for the incorporation of this protein into the myelin membrane.

Development and maturation of central nervous system myelin: comparison of immunohistochemical localization of proteolipid protein and basic protein in myelin and oligodendrocytes

The immunohistochemical localization of two myelin specific proteins-basic protein (BP) and proteolipid protein (PLP)-was compared during the process of myelination. Although both proteins were present in oligodendrocytes, (i) neither protein was observed in oligodendrocytes not already closely associated with nerve fibers exhibiting a fluorescent coating; (ii) in any discrete anatomical area oligodendrocytes were positive for BP before PLP was visible; and (iii) as myelination progressed, immunoreactivity for BP in oligodendrocytes appeared to decrease and simultaneously PLP immunofluorescence became visible in this cell type. During the period of active myelination, fibers exhibited a distinct varicose appearance. As myelination progressed, the myelin sheath increased in thickness and these varicosities became less prominent, eventually completely disappearing. Therefore, the nature and the appearance of varicosities can be used as an index of the relative stage of maturation of myelin in an individual fiber. In general, PLP appeared in fibers at a later stage of maturation than did BP based on the above criteria. However, in a relatively small number of fine fibers PLP was observed at a very early stage. In fully mature myelin, very large fibers were frequently more intensely fluorescent for BP than PLP, whereas fine myelinated fibers were more intensely stained for PLP. These observations are consistent with the following interpretations. (i) Substantial differentiation of oligodendrocytes occurs prior to appearance of either of these proteins by immunofluorescence. (ii) BP is added to the myelin sheath prior to PLP and there appears to be a shift in priority of synthesis from BP to PLP in individual oligodendrocytes during the process of myelination. (iii) Very small fibers often contain low concentrations of BP relative to PLP, and conversely, very large fibers may contain a high concentration of BP relative to PLP. Thus, the relative concentration of these proteins in myelin appears not to be constant but may vary as a function of the size of the myelinated fiber.

Myelin subfractions isolated from mouse brain: analysis of the lipid composition at three developmental stages

Lipids were examined in whole myelin and 8 myelin subfractions isolated from mouse brain at 18-24, 44-48 and 80-90 days of age. Relative to protein, total lipid was lowest in whole myelin isolated from the oldest animals as well as from subfractions isolated at greater sucrose densities, thus partially accounting for the observed myelin subfraction distribution pattern which shifted during development and an average peak density between 0.55 and 0.65 M sucrose to one banding between 0.60 and 0.70 M sucrose. Whole myelin and each myelin subfraction isolated at one age contained nearly the same ratio of sterol and phospholipid to galactolipid; these ratios decreased uniformly during development suggesting enrichment with galactolipid in all myelin subfractions. Sulfatide, as percentage of total galactolipid, was relatively constant during development and appeared to be slightly enriched in the denser myelin subfractions. The findings suggest that regardless of the origin(s) of the subfractions, an age-related mechanism exists in the central nervous system which modified myelin lipid composition relatively uniformly.

Developmental regulation of the carbohydrate composition of glycoproteins associated with central nervous system myelin

Glycoproteins from central nervous system myelin were evaluated for developmental alterations in their carbohydrate composition by autoradiographic analysis of radioiodinated lectin binding after separation by high-resolution sodium dodecyl sulfate-pore gradient slab gel electrophoresis (SDS-PGE). Sixteen lectin-binding components were assessed in highly purified myelin preparations from 15-day, 18-day, and adult rat brains, using the lectins Triticum vulgaris (wheat germ agglutinin) and Ulex europeus (gorse agglutinin I). Developmental changes in lectin binding for individual glycoproteins were evaluated semiquantitatively by comparing densitometric scans of the autoradiographs. Both increases and decreases in lectin binding for individual components were observed as a consequence of development, as well as the appearance and disappearance of lectin binding to three low-molecular-weight components. No changes in electrophoretic mobility and hence glycoprotein molecular weight were observed in any components when using these lectins. These developmental changes in lectin binding suggest that increases in glycoprotein (receptor) density occur, as well as an elaboration of oligosaccharide branching for individual glycoproteins. In addition, the appearance of a new glycoprotein in the adult myelin membrane could imply a new functional role not present in the immature membrane. These observations suggest that dynamic alterations of myelin-associated glycoproteins occur during development. Such developmental regulation of membrane glycoproteins increases the significance of their potential role in myelination and myelin maintenance.

Demonstration of five major glycoproteins in myelin and myelin subfractions

Myelin was found to contain five major glycoproteins with molecular weights of 120000, 95000, 88000, 43000 and 38000. Light myelin contained only 5-7% of the amount of these glycoproteins in whole myelin, whereas heavy myelin and the membrane fraction contained amounts nearly identical with whole myelin. Since all the major and minor glycoproteins, with the exception of 120000-mol-wt. glycoprotein, were detected only after treating the myelin membrane with neuraminidase, N-acetylneuraminic acid is a terminal sugar residue in these glycoproteins.

UDP-galactose-ceramide galactosyltransferase in rat brain myelin subfractions during development

The localization and activity of the enzyme UDP-galactose-hydroxy fatty acid-containing ceramide galactosyltransferase is described in rat brain myelin subfractions during development. Other lipid-synthesizing enzymes, such as cerebroside sulphotransferase, UDP-glucose-ceramide glucosyltransferase and CDP-choline-1,2-diacylglycerol cholinephosphotransferase, were also studied for comparison in myelin subfractions and microsomal membranes. The purified myelin was subfractionated by isopycnic sucrose-density-gradient centrifugation. Four myelin subfractions, three floating respectively on 0.55 M- (light-myelin fraction), 0.75 M- (heavy-myelin fraction) and 0.85 M-sucrose (membrane fraction), and a pellet, were isolated and purified. At all ages, 70--75% of the total myelin proteins was found in the heavy-myelin fraction, whereas 2--5% of the protein was recovered in the light-myelin fraction, and about 7--12% in the membrane fraction. Most of the galactosyltransferase was associated with the heavy-myelin and membrane fractions. Other lipid-synthesizing enzymes studied appeared not to associate with purified myelin or myelin subfractions, but were enriched in the microsomal-membrane fraction. During development, the specific activity of the microsomal galactosyltransferase reached a maximum when the animals were about 20 days old and then declined. By contrast the specific activity of the galactosyltransferase in the heavy-myelin and membrane fractions was 3--4 times higher than that of the microsomal membranes in 16-day-old animals. The specific activity of the enzyme in the heavy-myelin fraction sharply declined with age. Chemical and enzymic analyses of the heavy-myelin and membrane myelin subfractions at various ages showed that the membrane fraction contained more proteins in relation to lipids than the heavy-myelin fraction. The membrane fraction was also enriched in phospholipids compared with cholesterol and contrined equivalent amounts of 2':3'-cyclic nucleotide 3'-phosphohydrolase compared with heavy- and light-myelin fractions. The membrane fraction was deficient in myelin basic protein and proteolipid protein and enriched in high-molecular-weight proteins. The specific localization of galactosyltransferase in heavy-myelin and membrane fractions at an early age when myelination is just beginning suggests that it may have some role in the myelination process.

Preparation of membrane vesicles from isolated myelin: studies on functional and structural properties

Myelin membranes purified from bovine brain are shown to form membrane vesicles when incubated in hypotonic buffer. Following restoration of isotonicity a resealing of the membrane occurs as judged by a significant decrease in 22Na+ permeability. Electron spin resonance measurements using stearic acid spin label I indicate a small decrease in membrane fluidity with increasing ionic strength between 50 and 80 mM NaCl. Iodination of myelin membrane vesicles by lactoperoxidase shows a four-fold increase in the amount of iodine incorporation into the myeline basic protein from 0--150 mM NaCl, while the iodination of the proteolipid protein remains essentially unaffected by the change in ionic strength. This dependence of the iodination of the myelin basic protein on the ionic strength can be explained by the electrostatic interactions of this protein with membrane lipids. In view of striking analogies with studies on model membranes correlating protein binding with membrane permeability changes, we suggest a similar structure-function relationship for the myelin basic protein.

Density and protein profiles of myelin from two regions of young and adult rat CNS

Myelin, isolated from forebrain and spinal cord of young and adult rats, was distributed by zonal centrifugation on linear (0.32--1.00 M) sucrose gradients in a bell-shaped mode. The peak position of forebrain myelin shifted from the density of 0.58 M sucrose in young animals to that of 0.67 M sucrose in adult rats, while in spinal cord no such pronounced shift was noticed (approximately 0.58 M sucrose). Morphologically, the preparations appeared very similar across the density ranges. Specific activities of acetylcholinesterase were substantially below the total homogenates, while those of 2', 3'-cyclic nucleotide 3'-phosphohydrolase were higher in all fractions, except in the light myelin subfractions from adult spinal cord. Basic proteins decreased from the light to the heavier fractions; higher molecular weight proteins increased, together with proteolipid protein, which in spinal cord reached a plateau and in forebrain decreased towards the heavy side. The ratio of the small basic protein/large basic protein showed higher values in the light myelin subfractions in the regions and ages examined, pointing to a higher degree of maturation.

Protein heterogeneity in rat CNS myelin subfractions

Microsomal fraction-free myelin from forebrain and spinal cord of young and mature rats, when subjected to hypo-osmotic shock and slow speed centrifugation, yielded a myelin pellet and a supernatant fraction (SN 4). Fraction SN 4 consisted of small vesicular profiles in which the major myelin proteins were reduced whereas high molecular weight material such as Wolfgram protein, myelin-associated glycoprotein and CNP were substantially increased over myelin. A close correlation of the SN 4 fraction to the myelin-like fraction of Davison and coworkers was suggested. The myelin pellets were subfractioned on zonal sucrose gradients to yield bell-shaped particle distributions. Besides shifts in densities of the maxima between myelin of young and mature forebrain and spinal cord, a decrease was observed from the light to the heavy gradient end in basic proteins, and an increase in Wolfgram protein and other high molecular weight proteins. Proteolipid protein took an intermediate position. Light fractions from adult spinal cord displayed CNP activities below those of the total homogenate. This result, together with the very high CNP activities in fraction SN 4 casts some doubt on CNP being a marker for compact myelin; rather it appears that CNP is a marker for the process of myelin formation.

Quantitation of myelin carbonic anhydrase-development and subfractionation of rat brain myelin and comparison with myelin from other species

A number of related studies have been performed to characterize further the carbonic anhydrase activity of myelin. Recent assertions that carbonic anhydrase activity is intrinsic to the myelin sheath were subjected to the additional test of isolation of rat brain myelin in the presence of purified carbonic anhydrase. This procedure did not increase the carbonic anhydrase activity in myelin above the endogenous level, indicating that this enzyme does not stick to myelin membranes. A developmental study of rat brain carbonic anhydrase showed that the enzyme activity increased in whole brain homogenates and in myelin, with the greatest increments in enzyme activity occurring before the animals were 60 days old. When myelin from adult rat brains was fractionated on a density gradient, carbonic anhydrase activity was relatively enriched in the heavy subfraction but was present in all three layers. This finding suggested that the activity in myelin preparations was not due to contamination with a carbonic anhydrase-rich membrane fragment. Carbonic anhydrase in myelin was not confined to the rat. Beef brain homogenates and myelin had low activities of the enzyme, but myelin from rabbit, cat, monkey and mouse had carbonic anhydrase activities comparable to that of the rat, accounting for 6.3--13.6% of the respective homogenate activities.

Myelin subfractions isolated from mouse brain. Studies of normal mice during development, quaking mutants, and three brain regions

Myelin isolated from three areas of mouse brain, from whole brain at several ages in normal mice, and from whole brain of adult quaking mutant mice was separated into seven bands and a pellet on discontinuous density gradients using 0.32, 0.45, 0.55, 0.60, 0.70, 0.75 and 0.85 M sucrose. The distribution of myelin in the subfractions was independent of homogenization and shocking conditions employed to isolate the myelin preparations, but was related to the type of myelin applied to the gradient. Compared to myelin isolated from older animals, myelin isolated from 18-24 day old mice displayed a distribution pattern with greater proportions of material banding at lesser sucrose densities. Similarly, myelin obtained from hindbrain contained proportionately more material layering at lesser sucrose densities compared to myelin isolated from cerebral cortex. Myelin subfraction patterns observed for 8-12 day old control mice and quaking mutants were unlike each other or any other myelin preparation examined. In the 18-90 days old animals, the markers studied were not uniformly distributed among the myelin subfractions. The pellet and the layer banding at the 0.75/0.85 M sucrose interface contained the highest specific concentrations of sialic acid, nucleic acid, and total adenosine triphosphatase activity. In contrast, the specific activity of 2',3'-cyclicnucleotide-3'-phosphohydrolase was lowest in the pellet as well as the three bands obtained above 0.60 M sucrose and was highest in the fraction banding at the 0.65/0.70 M sucrose interface. The results obtained were not consistent with an artifactual origin of the myelin subfractions, but instead suggested that the subfraction have physiological significance. One explanation for the different banding patterns observed between young and mature myelin may be the different amount of myelin in various brain regions during development.