STUDIES OF THE MECHANISM OF DEMYELINATION REGIONAL DIFFERENCES IN MYELIN STABILITY IN VITRO1

—Incubation of slices of rat central nervous system in Krebs-Ringer bicarbonate buffer produced a lipoprotein fraction which floated on 10·5% sucrose after homogenization of the slices and centrifugation. This fraction was not found after homogenization and centrifugation of fresh tissue and appeared to depend upon incubation. The amount of the light fraction increased in the following order per 100-mg slice: cerebrum < thalamic area < cerebellum < brain stem < spinal cord. The lipid composition of this fraction was similar to that of myelin, but contained a lower protein content compared to myelin of the corresponding area. This fraction was termed ‘dissociated myelin’. Upon incubation of slices a portion of the basic protein was lost from myelin subsequently isolated, and the dissociated fraction was slightly enriched in basic protein. The distribution of myelin protein among the characteristic three groups (basic, proteolipid and high mol. wt.) was quite different in myelin from spinal cord compared to that from other CNS area. Spinal cord myelin contained about 17% protein compared to about 23% in cerebrum, with brain stem myelin intermediate (19%), and the difference appeared to be due to lesser amounts of proteolipid in the caudal areas. The amount of dissociation after incubation was about 3–5 per cent of the total myelin in the cerebral cortex, 10 per cent in the thalamic area, 20 per cent in cerebellum, 35 per cent in the brain stem, and around 45 per cent in spinal cord. The smaller amount of proteolipid protein in spinal cord myelin may result in a deficiency of cohesive forces holding lipids and proteins together, thus causing greater instability and dissociation. Myelin dissociation increased with time of incubation up to 3 h, was augmented by Ca²⁺, and was substantial at pH 11, reaching a peak at pH 7, then decreased in the acid range. A similar fraction has been isolated previously from fresh CNS tissue made edematous by chronic treatment of rats with triethyl tin. The possible relationship of swelling in the disease process and myelin dissociation are discussed.     

STUDIES ON THE MECHANISM OF DEMYELINATION: TRIETHYL TIN-INDUCED DEMYELINATION

The metabolism of myelin undergoing breakdown as a result of edema induced by chronic administration of triethyl tin (TET) dissolved in the drinking water (10 mg/l.) was examined. The spinal cord showed more edema and loss of myelin than the brain. Uptake in vitro of [1-¹⁴C]acetate into myelin lipids of slices of brain or spinal cord from TET-treated rats was depressed until 4–5 weeks after the beginning of the regime, then rose to above normal levels. The uptake of [l-¹⁴C]leucine into myelin protein rose within several weeks of TET treatment to levels averaging over 300 per cent of normal and remained high even after the TET was removed. The high levels of [l-¹⁴C]leucine incorporation were inhibited by cycloheximide and were not explained by an increase in the size of the free amino acid pool. The three classes of myelin proteins, basic, proteolipid protein, and Wolfgram protein shared in the increased incorporation. Spinal cord myelin showed the greatest metabolic response, brain stem myelin less, and myelin from the forebrain was minimally affected by the TET treatment. Myelin prelabelled by intracisternal injection of [l-¹⁴C]acetate and [l-¹⁴C]leucine before the onset of TET administration showed faster turnover in myelin proteins in relation to the myelin lipids than the control in the most severely affected animals, but not in others less affected. A ‘floating fraction’ was observed floating on 10.5% (w/v) sucrose during the myelin purification. This fraction showed metabolic characteristics typical of myelin, and myelin-labelling studies at various stages of the animal's development showed it to be derived from recently synthesized myelin. The floating fraction from the brain contained less cerebroside and more lecithin than myelin, while the spinal cord floating fraction composition was much like that of myelin. The floating fractions contained less protein typical of myelin (basic and proteolipid protein) and more highmolecular-weight protein which may have been derived from contaminating microsomes. The floating fraction was presumed to be partially deproteinated myelin. The use of TET-treatment as model for demyelination as a result of edema and proceeding in the absence of macrophages is discussed.     

SIMULTANEOUS ISOLATION OF PURIFIED MICROSOMAL and MYELIN FRACTIONS FROM RAT SPINAL CORD

Abstract— The fraction that sediments between 2 × 10⁵ g -min and 6 × 10⁶ g -min from dilute dispersions of rat brain in 0.32 m -sucrose is a microsomal fraction with very little contamination by myelin. A crude microsomal fraction prepared in the same way from rat spinal cord contains more myelin than microsomes. Centrifugation of the crude microsomal fraction in 0.85 m -sucrose gave a floating fraction, an infranatant fraction (purified microsomes) and a small pellet. The purified microsomes contained very little myelin as judged by electron microscopy and polyacrylamide gel electrophoresis. The lipid composition resembled that of spinal cord myelin except that the purified microsomes contained relatively less cholesterol and ethanolamine plasmalogens. The content of galactolipids was much greater in spinal cord microsomes than in brain microsomes. The spinal cord CDP-ethanol-amine:diglyceride ethanolaminephosphotransferase activity (EC 2.7.8.1) was concentrated in the purified microsomes.
A spinal cord myelin fraction isolated from the 2 × 10⁵ g -min pellet was quite pure as judged by electron microscopy, enzyme activities and polyacrylamide gel electrophoresis. No NADPH-cyto-chrome c reductase activity (EC 1.6.2.3) could be detected in the purified myelin. The ethanolaminephosphotransferase specific activity was about 5% of that found in the purified microsomal fraction. The protein content was 25% by weight for spinal cord myelin and 31% for brain myelin. Of the total spinal cord 2',3'-cyclic nucleotide-3'-phosphohydrolase activity, 16% was lost from the crude myelin during purification, 21% was recovered in the purified myelin, and 11% was found in the floating fraction from the crude microsomes. The purified myelin and microsomal fractions from spinal cord were relatively pure. Additional myelin was recovered in the floating fraction from the crude microsomes.     

DISTRIBUTION AND OPTICAL ACTIVITY OF THE BASIC PROTEIN IN BOVINE PERIPHERAL NERVE MYELIN

Abstract— Antiserum to BF protein isolated from bovine spinal roots has been used to study the distribution of the protein in other species and tissues.
Significant amounts of protein could be demonstrated in bovine, pig and rabbit peripheral nerve myelin. It was, however, scarcely detectable in guinea pig peripheral nerve myelin. There was BF protein in rabbit spinal cord as well as in peripheral nerve, but little or no BF protein in the liver, kidney, muscle or brain. BF protein in bovine spinal cord was localized in the myelin. The ratio of the BF protein to the encephalitogenic protein in the spinal cord myelin was around 0.15:1.0. BF protein was extractable from peripheral nerve myelin by saline as well as by acid solutions.
The circular dichroism spectrum of the BF protein in aqueous solution suggested that this protein contained a very large amount of β-structure. This structure was not considered to be the result of acid denaturation because the protein purified from the saline extract of peripheral nerve also showed a similar spectrum.     

Specificity of oligoclonal IgG bands against myelin proteins in chronic relapsing EAE in guinea pigs

We showed previously by using imprint electroimmunofixation that the oligoclonal IgG in sera and CSF from chronic relapsing EAE in guinea pigs were specific to spinal cord and Mycobacterium tuberculosis. We now show that most oligoclonal IgG bands are directed predominantly against isolated myelin basic protein (MBP). Activity to the latter could be removed from sera or CSF by absorption with MBP but not with histone or lysozyme. The oligoclonal IgG reacted weakly with isolated proteolipid apoprotein, and lacked reactivity to myelin-associated glycoprotein. When the oligoclonal IgG activity to myelin proteins was removed from the sera by absorption with a preparation of delipidated myelin before imprint electroimmunofixation, a few bands in some sera still reacted with whole spinal cord homogenate. These results indicate that, in some sera, a part of the oligoclonal IgG was directed against non-myelin proteins or lipids. In contrast to chronic relapsing EAE, CSF oligoclonal IgG from patients with multiple sclerosis showed no reactivity against human brain homogenate, whole myelin, delipidated myelin, and MBP in imprint electroimmunofixation.     

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 23-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.     

COMPARATIVE STUDIES ON THE MYELIN PROTEINS OF BOVINE PERIPHERAL NERVE AND SPINAL CORD

Abstract— (1) Two myelin fractions of bovine peripheral nerve and spinal cord have been studied comparatively. Cholesterol as well as cerebroside content per mg of protein in the peripheral nerve myelin was less than that in the spinal cord myelin, while no significant difference in the total phospholipid content was noted.
(2) The basic proteins in myelin fractions were quantitatively estimated by disc gel electrophoresis. Around one-fourth of the total myelin protein in the bovine peripheral nerve was a basic protein with a mobility of 1.07 relative to lysozyme by Reisfeld's disc gel electrophoresis.
(3) The myelin proteins in the peripheral nerve were less completely solubilized than those of the spinal cord by treatment with deoxycholate as well as by Triton-salt solution. The protein fractions obtained from the peripheral nerve myelin by techniques similar to that for obtaining the proteolipids from the spinal cord myelin, contained different types of protein.
(4) 2',3'-Cyclic nucleotide 3'-phosphohydrolase activity in the peripheral nerve myelin was only one tenth of that in the spinal cord myelin. The Triton-salt insoluble fraction showed remarkable high activity among subfractions of the spinal cord myelin.
(5) By immunological studies, it may be concluded that an antigenic substance for experimental allergic neuritis was localized in the peripheral nerve myelin, but not in its basic protein.     

A regional survey of myelin development: some compositional and metabolic aspects

A survey of differences in composition and metabolism of myelin from five areas of the central nervous system was made in brain and spinal cord slices of the rat from 20 days to 20 months postnatal age. Purified myelin from the forebrain areas showed a composition characteristic of immaturity longer than did myelin from the hindbrain and spinal cord. The trend of chemical maturity is in agreement with the anatomical observations that myelination begins in the hindbrain and proceeds rostrally. Myelin recovery per 100-mg slice increased continually from 20 days to 20 months of age, while the uptake of [1-(14)C]acetate into myelin lipid and of [1-(14)C]leucine into myelin protein decreased precipitously with age. Taking into account the continuous increase in myelin during maturation, a calculation was made of the total amount of incorporation of labeled material into lipids or proteins per 100-mg slice for each region at each age. The metabolic characteristics of myelin from the cerebral cortex (including the corpus callosum), the thalamic area, and the cerebellum were very similar, while myelin from brainstem and spinal cord was metabolically more active, especially at the early ages. Synthesis of lipid in the myelin sheath represents about 50% of the lipid synthesis of the whole brain and about 75% of that of the spinal cord. The proportion of myelin-related protein synthesis is much less, probably less than 10% of the protein synthesis occurring in whole brain and about 15% of that in the spinal cord except at early ages.     

ACTIVITY OF 2'',3''-CYCLIC-NUCLEOTIDE 3''-PHOSPHODIESTERASE IN REGIONS OF RAT BRAIN DURING DEVELOPMENT: QUANTITATIVE RELATIONSHIP TO MYELIN BASIC PROTEIN

2′,3′-Cyclic-nucleotide-3′-phosphodiesterase activity was examined in several regions of rat brain during development, namely optic nerve, olfactory bulb, cerebrum, cerebellum, midbrain, brain stem, and spinal cord. From 4 to 120 days the total activity increased in all regions, although the specific activity approached a constant value in adults. The developmental profile of the enzyme appeared to correlate with the onset of myelination and with the levels of myelin basic protein as well as the appearance of galactocerebroside sulfotransferase. A correlation coefficient of 0.91 was found between total basic protein, expressed as the per cent of the adult (120 day) value, and total enzyme activity over 12–42 days of age (P < 0.001) from six different brain regions as well as for whole brain. By increasing the sensitivity of the assay with the use of [³H-8]adenosine 2′,3′-cyclic monophosphate, we were able to detect activity at birth in both whole brain and spinal cord.     

Effects of Altered Thyroid States on Myelinogenesis

Abstract: Myelinogenesis was studied in controls and in rats treated since birth with Methimazole (hypothyroid) or thyroxine (hyperthyroid). The amount of myelin in forebrain and its protein composition were determined between 13 and 40 days of age, the period of most rapid myelin accumulation. Hypothyroid rats had reduced body and brain weights relative to controls and the yield of myelin was reduced on both a per brain and a per milligram brain protein basis. Developmental changes in the protein composition of isolated myelin followed the pattern of control animals (the percentage of total myelin protein present as proteolipid protein, large basic protein, and small basic protein increased, as did the ratio of proteolipid/large basic protein) but were delayed temporally by 1–2 days. Hyperthyroid rats also had reduced body and brain weights. At 13 days myelin accumulation was greater than that of controls, corresponding to an earlier initiation of myelination. At later ages myelin yield was reduced on a per brain basis but not on a per milligram brain protein basis. The developmental pattern of myelin protein composition was accelerated temporally by 1–2 days. Myelination in optic nerve, assayed by proteolipid protein content, also was slightly delayed in hypothyroid animals and somewhat accelerated in hyperthyroid animals. The relative synthesis of myelin proteins (determined as incorporation of intracranially injected [³H]glycine into myelin protein relative to incorporation into whole brain protein), as well as distribution of radioactivity among individual myelin proteins, was determined. The results supported the conclusion of the myelin protein accumulation study; hypothyroidism retards the developmental program for myelinogenesis, whereas in the hyperthyroid state myelin synthesis is initiated earlier but is also terminated earlier.     

ISOLATION AND CHARACTERIZATION OF MYELIN-RELATED MEMBRANES

Abstract— Myelin related membrane fractions from rat brain and spinal cord were isolated from material normally discarded during standard myelin isolation procedures. A fraction which floated on 0.32 M-sucrose (F) and the material released after subjecting the myelin fraction to osmotic shock at two stages in the purification (W₁ and W₂) were characterized. These fractions were subjected to subfractionation on three step discontinuous sucrose gradients. Morphologically, the heavier subfrac-tions of W₁ and W₂ were shown to consist mainly of single membranes and vesicles. Sodium dodecyl sulphate (SDS) polyacrylamide gel electrophoresis showed that, relative to myelin, proteolipid and basic protein were reduced in all subfractions, while the high molecular weight proteins were increased. The specific activity of 2′,3′-cyclic nucleotide 3′-phosphohydrolase (CNP) was up to 2-fold higher than that of myelin in the heavier subfractions of W₁ and W₂. The major myelin-associated glycoprotein was also increased in these subfractions as determined by periodic acid-Schiff staining. Differential centrifugation of the initial tissue homogenate to remove microsomes prior to myelin isolation gave rise to W₁ and W₂ subfractions with a CNP specific activity 3–4 times that of myelin. The high molecular weight proteins and glycoproteins were enriched in these microsome-depleted subfractions, but were qualitatively similar to those of myelin. Some of the membranes in these fractions may be derived from the continuum between the plasma membrane of the oligodendrocyte and compact myelin. Fraction F consisted of small membrane fragments and many vesicles, and was particularly deficient in proteolipid. The specific activity of CNP in fraction F was about the same as myelin, while the major myelin associated glycoprotein could not be detected. Fraction F from normal CNS tissue appears to be similar to the floating fractions previously isolated in larger amounts from pathological brain undergoing edematous demyelination.     

Immunoblot Identification of 13.5 Kilodalton Myelin Basic Protein in Goldfish Brain Myelin

Myelin isolated from goldfish brain shows a multilamellar structure with a major dense line and two intraperiod lines. Sodium dodecyl sulfate gel electrophoresis revealed that the protein profile of goldfish brain myelin is distinctly different from that of rat brain myelin. No protein migrating to the position of proteolipid protein or DM-20 was seen in goldfish myelin. Goldfish acclimated to 5 degrees, 15 degrees, and 30 degrees C showed no qualitative differences in myelin proteins. The 13.5 kD protein in goldfish brain myelin and brain homogenate was intensely immunostained with the antiserum to human basic protein by the immunoblot technique. In contrast, none of the proteins of goldfish myelin were immunostained with antiproteolipid protein serum; however, both proteolipid protein and DM-20 of rat brain myelin were immunostained. The significance of the synthesis of myelin proteins by astrocytes in the goldfish brain is discussed.     

Biosynthesis of myelin proteins in vitro

Abstract— The rates of uptake of DL-[1-¹⁴C]leucine into the three classes of protein in myelin isolated from slices of rat brain and spinal cord were determined. Basic protein exhibited the slowest rate of uptake; chloroform-methanol-soluble proteolipid protein exhibited intermediate rates and the insoluble protein had the most active uptake. All myelin proteins were less active than the mixture of proteins derived from the non-myelin fraction. Cyclohexi-mide (10^?3 M) and choramphenicol (5 × 10^?3 M) inhibited the incorporation of [1-¹⁴C]leucine into brain proteins by as much as 95 per cent. γ-Aminobutyric acid had no effect on the system. Chloramphenicol also inhibited the uptake of [1-¹⁴C]acetate into myelin lipids, but cycloheximide did not affect lipid synthesis. These effects were observed on both 35-day-oldand 18-month-old rats, but the biosynthetic activity was far less in myelin from the older rats. The results are discussed in relation to the structure of myelin. It is suggested that the data best fit models in which lipid and protein are in separate phases in the membrane.     

Major Central Nervous System Myelin Glycoprotein of the African Lungfish (Protopterus dolloi) Cross-Reacts with Myelin Proteolipid Protein Antibodies, Indicating a Close Phylogenetic Relationship with Amphibians

CNS myelin was isolated from the spinal cord of the African lungfish Protopterus dolloi. Its proteins consisted of (1) two basic proteins (16,000 and 18,500 apparent Mr) that reacted with anti-human CNS myelin basic protein antibodies and (2) a major protein (29,000 apparent Mr) that stained with concanavalin A-horseradish peroxidase and bound to anti-rat CNS myelin proteolipid protein (PLP) antibodies. This dominant 29,000 Mr protein showed no reaction with antibodies against the major bovine PNS myelin glycoprotein P0. Following treatment with endoglycosidase F the 29,000 Mr protein was reduced in size to a 26,000 apparent Mr component that no longer bound concanavalin A but retained the anti-PLP reactivity. These results agree with a concanavalin A-binding oligosaccharide linked through asparagine to a protein backbone of PLP homology. The major 29,000 Mr lungfish CNS myelin protein was therefore termed g-PLP (glycosylated proteolipid protein). This is the first report demonstrating the occurrence of a PLP-cross-reactive protein in CNS myelin of a fish. It attests to the close phylogenetic relationship of lungfishes to amphibians. Amphibians were previously recognized as the oldest class bearing PLP in its CNS myelin.     

Chemical compositions of brain and myelin in two patients with multiple sulphatase deficiency (a variant form of metachromatic leukodystrophy)

The lipid composition of the brain, including myelin, was studied in detail in two cases with a variant form of metachromatic leukodystrophy (multiple sulphatase deficiency type). In the white matter, the sulphatide concentration was 3-4 times higher than the normal level in both cases. There was a significant accumulation of cholesterol sulphate in the brain, liver and kidney of both cases. The ganglioside pattern in the grey and white matter was abnormal, with a higher proportion of GM3, GM2 and GD3-gangliosides. Non-lipid hexosamine contents were increased 1.5-2 times in brain, 8-10 times in liver and 2-3 times in kidney. Increased amounts of glucocerobroside, ceramide lactoside and ceramide trihexoside were present in grey and white matter of both cases. Recovery of purified myelin from two patients' brains was much less than from control (1-2% in case 1 and 20-30% in case 2). The lipid composition of myelin was almost normal except for a higher proportion of sulphatide, with a decreased amount of cerebroside. The fatty acid compositions of myelin sulphatide and sphingomyelin were almost normal, while non-hydroxy fatty acids of cerebroside contained less long-chain fatty acids, as characterized by a significant increase of C16:0 and C18:0 fatty acids. The myelin polypeptide pattern by SDS-disc gel electrophoresis showed a relative decrease of basic protein and of proteolipid protein. A possible mechanism of myelin loss in MSD is discussed.     

Cytotoxicity of sera against brain and spinal cord antigens in relation to lymphocytes of varying origin]

Rabbit sera against antigens prepared from the brain and the spinal cord antigens were investigated in a cytotoxic test with mouse and guinea pig lymphocytes. None of the sera exerted a cytotoxic effect on the bone marrow lymphocytes. The sera against mouse brain and spinal cord and guinea pig brain and myelin isolated from it exerted the greatest cytotoxic activity; the cytotoxicity was maximum against the thymocytes, less pronounced against the lymph node lymphocytes, and least--against the spleen cells. The cytotoxicity of the sera against the bovine spinal cord homogenate, myelin and the basic protein isolated from it was the minimal and equal with lymphocytes from any of the three mentioned sources. The serum against the encephalitogenic polypeptide 2c was practically devoid of the cytotoxic activity. The encephalitogenic activity of the 2c fraction was greater than that of the myelin and basic protein from the bovine spinal cord. Experiment of antibrain serum absorption suggested that the brain cortex contained a cross-reacting antigen. The subcutaneous injection of a relatively high dose (224 x 10(6)) of thymocytes in the complete Freund's adjuvant failed to induce the development of allergic encephalomyelitis in guinea pigs.     

Composition of myelin from peripheral and central nervous systems of the squirrel monkey

Myelin was prepared from the brachial plexus and cervical spinal cord of adult squirrel monkeys (Saimiri sciureus). Brachial plexus myelin contained a larger amount of sphingomyelin and smaller amounts of cholesterol, lipid galactose, ethanolamine phosphoglyceride, choline phosphoglyceride, and alk-1-enyl ether than spinal cord myelin when compared as ratios to total lipid phosphorus. The peripheral nervous system myelin had a higher proportion of protein. All of these differences were statistically significant. Thus peripheral nervous system myelin and central nervous system myelin differ in protein content and lipid composition in this subhuman primate.     

BIOCHEMICAL CHARACTERIZATION OF A MYELIN FRACTION ISOLATED FROM RAT BRAIN AGGREGATING CELL CULTURES

Abstract— Subcellular fractions isolated from rat brain aggregating cell cultures were studied by electron microscopy and showed the presence of typical myelin membranes. The chemical composition of purified culture myelin was similar to the fraction isolated from rat brain in terms of CNP specific activity, protein and lipid composition. The ratio of small to large components of myelin basic protein was comparable in culture and in vivo. These two proteins incorporated radioactive phosphorus. The major myelin glycoprotein was present and during development in culture its apparent molecular weight decreased although it never reached the position observed in myelin isolated from adult rats. In culture, the yield of myelin did not increase substantially between 33 and 50 days and was comparable to that of 15-day-old rat brain. The ratio basic protein to proteolipid protein resembled immature myelin and the cerebroside content was very low. A 'floating fraction' was isolated from the cultures and contained some myelin but mostly single membranes. Although these results indicate that myelin maturation is delayed in vitro this culture system provides substantial amounts of purified myelin to allow a complete biochemical analysis and metabolic studies during development.     

An electrophoretic analysis of proteolipids from different rat brain subcellular fractions

Proteolipid proteins were extracted from adult rat brain subcellular fractions and purified by chromatography on Sephadex LH-60. Polyacrylamide gel electrophoresis of the delipidized proteins, in the presence or absence of 8 M urea, was carried out with all fractions. The distribution of the various types of proteolipid proteins was studied and their molecular weight calculated by the Ferguson relationship. Several bands of proteolipid proteins were found in the five membrane fractions analyzed. Some of them, such as the 17.5 K and 37 K components were very prominent in mitochondria and synaptosomes. The 30 K component was found in myelin-derived membranes and in microsomes, while the 20 K and 25 K proteolipid proteins were present in all subcellular fractions. The 30 K component (proteolipid protein (PLP)), typical of the purified myelin membranes, showed a similar distribution to that of 2′,3′-cyclic-nucleotide 3′-phosphohydrolase (EC 3.1.4.37) activity, while the other major proteolipid protein present in all subcellular fractions (25 K) did not show such parallelism, indicating that it might not be an exclusive component of myelin. The electrophoretic pattern of microsomal proteolipid proteins did not show the high molecular weight components (aggregates of PLP) which are found in myelin. Furthermore, the 30 K component showed a smaller $\text{Y}{}_0$ value than that of the 30 K found in myelin. Thus the presence of 30 K proteolipid protein in microsomes should not be considered as being due to myelin contamination.     

CHARACTERIZATION AND PROTEIN ANALYSIS OF MYELIN SUBFRACTIONS IN RAT BRAIN: DEVELOPMENTAL AND REGIONAL COMPARISONS

—Myelin preparations from the whole brains of 16-day-old rats and from cortical regions and brainstem, respectively, of 40-day-old rats were separated into light, medium and heavy subfractions on a discontinuous sucrose gradient by a procedure previously used for whole adult rat brain (Matthieu, et al., 1973). The total dry weight of myelin recovered from the 16-day-old rats was only 2·4mg/g fresh brain in comparison to 20 mg from adult brains. In 16-day-old rat brains, the percentage of the total myelin protein in the light fraction was higher than that found in adult brains; the percentage in the medium fraction was only one-third that in adults; while the percentage in the heavy fraction was about the same at both ages. The heavy fraction from the 16-day-old rats contained less basic protein and proteolipid than the light fraction, and the levels of the 2′3′-cyclic nucleotide 3′-phosphohydrolase (CNP) and glycoprotein were less than half those in the light and medium fractions. Double labelling experiments with radioactive fucose indicated that the major labelled glycoprotein in the heavy and medium fractions had a slightly higher apparent mol. wt than that in the light fraction. Electron microscopy showed much readily identifiable, compact myelin in the light and medium fractions from the 16-day-old rats, whereas the heavy fraction contained more single membranous structures and much less multilamellar myelin. The yield of myelin/g fresh wt from brainstem of 40-day-old rats was 4-fold higher than from cortical regions, and the percentage recovered in the light fraction was greater in the brainstem. In both regions basic proteins decreased from the light to the heavy fraction, whereas high mol. wt proteins, the glycoprotein and CNP increased. The biochemical and morphological results suggest that in both 16-day-old and young adult rats the light fraction is enriched multilamellar, compact myelin. In contrast, the heavy fraction at both ages is enriched in loose, uncompacted myelin and myelin-related membranes, although the heavy fraction from 16-day-old rats also may be substantially contaminated with membranes which are unrelated to myelin.