Variation of proteins, enzyme markers and gangliosides in myelin subfractions

A discontinuous sucrose gradient was used to separate adult rat brain myelin into light, medium and heavy subfractions. Basic proteins decreased sharply, proteolipid potein changed very little, and high molecular weight proteins increased from the light to the heavy fraction. The concentration of monosialoganglioside G_M1 was the highest in the middle fraction. The amount of carbohydrate in the major myelin-associated glycoprotein per mg total myelin protein increased 3.5-fold from the light to the heavy fraction. 2′,3′-Cyclic nucleotide 3′-phosphohydrolase, which is related to myelin or the oligodendroglial membrane, and acetylcholinesterase, which is in neural membranes such as the axolemma, both increased between the light and the heavy fraction, although their relative distributions among the three fractions were different. The glycoprotein and 2′,3′-cyclic nucleotide 3′-phosphohydrolase had similar distributions suggesting that they were concentrated in similar locations, possibly in the loose myelin and oligodendroglial plasma membrane. Electron microscopic examination of the subfractions was consistent with this interpretation.     

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.     

QUAKING MOUSE MYELIN: BIOCHEMICAL CHARACTERIZATION OF ZONAL GRADIENT SUBFRACTIONS

The brains of Quaking and littermate control mice were fractionated by differential and density gradient centrifugation into soluble, microsomal, myelin and related (SN 4) fractions. There were no apparent differences in protein composition between any Quaking and control fraction with the exception of myelin and SN 4. Analysis of CNP activity indicated that in Quaking animals a high proportion of the total activity was localized in microsomal fractions, while in controls a large percentage of activity was found in myelin and SN4; in contrast, there were no marhcd differences in the distribution of AChE activity between Quaking and control fractions. The yield of myelin isolated from Quaking animals was 3.6%, of that from controls by electron microscopy myelin fractions from both Quaking and controls consisted of compact myelin whorls. Zonal centrifugation on continuous sucrose gradients demonstrated that both control and Quaking myelin was distributed in a bell-shaped mode with peak densities at 0.66 0.68 and 0.71-0.75 M-sucrose, respectively. The specific activity of CNP was generally lower in mutant subfractions than in controls. Protein analysis revealed that there were similar qualitative trends between light and heay myelin subfractions from both mutant and control animals, although the levels of proteolipid and small basic proteins were substantially lower in all Quaking fractions. These results indicate that. although all mutant myelin subfractions are compositionally abnormal, the type of particle heterogeneity in Quaking myelin is similar to that observed in controls.     

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.     

METABOLIC RELATIONSHIPS BETWEEN MYELIN SUBFRACTIONS: ENTRY OF PROTEINS 1

Abstract— Partially purified myelin from brains of 17-day-old rats was separated into 4 subfractions on a discontinuous sucrose gradient by virtue of heterogeneity in density and particle size. The protein composition of each subfraction was determined by densitometry following separation of proteins on polyacrylamide gels in buffers containing sodium dodecyl sulphate. The major proteins studied included two basic proteins, proteolipid protein, the major high molecular weight protein (W) and a group of high molecular weight proteins. The percentage of high molecular weight proteins decreased sequentially from fraction D to A, that of the W protein remained constant, while relative amounts of the two basic proteins increased. Proteolipid protein concentration also increased as a percentage of the total protein from fraction D to B, but the uppermost fraction. A, had a markedly lower amount than fraction B. At 1 h after intracranial injection of [³H]leucine, the specific radioactivity of the basic and proteolipid proteins decreased from fraction D to B, with proteolipid protein in fraction A again anomalous (specific radioactivity higher than expected). These results are consistent with (but do not prove) a precursor-product relationship for individual proteins from denser to lighter subfractions, with the exception of myelin subfraction A. Experiments involving time staggered injections of a [¹⁴C] and later a [³H] labelled amino acid gave data which demonstrated that the W and basic proteins were added simultaneously (or with delays of much less than 20 min) to all of the subfractions, while proteolipid protein was added sequentially, from lower to upper fractions on the gradient. This double isotope technique also confirmed our previous observations that proteolipid protein shows a lag in entry into myelin compared to basic protein.     

Localization of 2',3'-cyclic nucleotide-3'-phosphohydrolase of rabbit brain by sedimentation in a continuous sucrose gradient.

Abstract— The enzyme 2′,3′-cyclic nucleotide-3′-phosphohydrolase (CNP) has been assayed in fractions from a continuous sucrose density gradient zonal centrifugation of rabbit brain homogenates. Basic protein (BP) was also assayed by a radioimmunomethod. Fractions were examined by SDS-polyacrylamide gel electrophoresis and by electron microscopy. These studies show that the major membrane fractions in the gradient differ greatly in the content of CNP and BP, and of high molecular weight proteins (HMW). The lightest membrane fractions contained numerous multilamellae, the highest content of BP and the lowest content of CNP and HMW, while the heaviest membrane fractions contained single membrane fragments and vesicles of unknown origin, the lowest content of BP and the highest content of CNP and HMW. The fraction containing the largest amount of membrane measured by turbidity, protein content, and water-washed dry weight contained only half the CNP specific activity of a denser fraction in the gradient. CNP specific activity in the lightest fractions was insignificant compared to that of denser fractions. Thus, we conclude that this enzyme may be absent from the typical multilamellar myelin structures but present in the single-membrane structures associated with myelin, such as the glial membrane and the paranodal segments of myelin adjacent to the axon. BP appears to occupy the opposite positions, highest in the multilamellae and lowest in the single-membrane structures of myelin. These studies do not exclude the possibility that CNP may not be bound to myelin membranes, but rather to a membrane of different origin. Evidence that this enzyme is a myelin-marker enzyme is circumstantial. Our evidence indicates the enzyme could be present either in a unique portion of myelin membranes or in another membrane structure.     

Myelin glycosphingolipid/cholesterol-enriched microdomains selectively sequester the non-compact myelin proteins CNP and MOG

Plasma membranes are complex arrays of protein and lipid subdomains. Detergent-insoluble, glycosphingolipid/cholesterol-enriched micro-domains (DIGCEMs) have been implicated in protein sorting and/or as sites for signaling cascades in the plasma membrane. We previously identified the presence of DIGCEMs in oligodendrocytes in culture and purified myelin and characterized a novel DIGCEM-associated tetraspan protein, MVP17/rMAL (Kim et al. (1995) Journal of Neuroscience Research 42, 413–422). We have now analyzed the association of known myelin proteins with DIGCEMs in order to provide a better understanding of their roles during myelin biogenesis. We used four well-established criteria to identify myelin DIGCEM-associated proteins: insolubility in a non-ionic detergent Triton X-100 at low temperature (4°C), flotation of the insoluble complexes to low density fractions in sucrose gradients, and TX-100 solubilization at 37°C, or at 4°C following treatment with the cholesterol-binding detergent saponin. We demonstrate that these proteins fall into four distinct groups. Although all tested proteins could be floated to a low-density fraction, proteolipid protein (PLP), myelin basic protein (MBP) and myelin associated glycoprotein (MAG) were solubilized by the detergent extraction, and connexin32 (Cx32) and oligodendrocyte-specific protein (OSP) met only some of the criteria for DIGCEMs. Only the non-compact myelin proteins 2′,3′-cyclic nucleotide 3′-phosphodiesterase (CNP) and myelin/oligodendrocyte glycoprotein (MOG) satisfied all four criteria for DIGCEM-associated proteins. Significantly, only ～40% of CNP and MOG were selectively associated with DIGCEMs. This suggests that they may have both non-active “soluble”, and functionally active DIGCEM-associated, forms in the membrane, consistent with current views that DIGCEMs provide platforms for bringing together and activating components of the signal transduction apparatus. We therefore propose that CNP and MOG may have unique roles among the major myelin proteins in signaling pathways mediated by lipid-protein microdomains formed in myelin.     

Simultaneously entry of palmitic acid into proteolipid protein in different myelin subfractions of rat brain

Rats of 20-days of age were injected intracranially with radioactive palmitic acid to study its incorporation into proteolipid protein (PLP) of myelin and myelin subfractions. At short times (120 min), the radioactivity present in PLP was shown to be due to palmitic acid bound to the protein by ester linkages. The specific radioactivity of palmitic acid labeled PLP was identical in all the myelin subfractions except the myelin-like fraction, in which it was lower, suggesting that the entry of the fatty acid into PLP of the different subfractions occurs simultaneously.Experiments using time staggered injections of ¹⁴C- and ³H-labeled palmitic acid also showed that entry of the fatty acid into PLP of the various subfractions was simultaneous. These results seem to indicate that the acylation of PLP occurs in the myelin membrane and that synthesis and transport of this protein are events unrelated to the acylation process.     

Differential effect of colchicine upon the entry of proteins into myelin and myelin related membranes

Brain slices from 20 day old rats were incubated with radioactive aminoacids in the presence and absence of 500 M colchicine and the appearance of labeled proteins in myelin and in a myelin-like fraction (SN₄ fraction) was measured. In the presence of the inhibitor, the entry of proteolipid proteins was decreased to 55% in myelin and to 45% in SN₄ fraction with reference to control values while the entry of basic proteins and other minor protein components was unaffected in both fractions. The synthesis of proteolipid proteins was not affected by the presence of colchicine; moreover, a slight accumulation of these proteins was observed in microsomes. The results suggest that the microtubular system is involved in the transport of proteolipid proteins from their site of synthesis to their site of deposition and that the various types of myelin proteins follow different transport routes to enter into this special type of membrane.     

FRACTIONATION OF OLFACTORY TISSUE HOMOGENATES. ISOLATION OF A CONCENTRATED PLASMA MEMBRANE FRACTION

Abstract— Differential and sucrose-density-gradient centrifugation techniques were used for studies on the separation of subcellular particles from rabbit brain and olfactory tissue. Comparisons were made among various fractions from the two types of tissue. These comparisons included protein concentration and enzyme activities of the individual fractions as well as their distribution in subfractions from density gradient separations. In tissue whole homogenates, the percentage of total ATPase activity as ouabain sensitive Na⁺-K⁺ ATPase activity was about 4 times greater in brain cortex (63 per cent) than in olfactory tissue (17 per cent). Cytochrome oxidase and Na⁺-K⁺ ATPase activities were used to indicate the presence and the concentration of mitochondria and of the plasma membranes. A fraction with properties similar to the mitochondria plus nerve ending fraction from brain homogenates (fraction B) was obtained from olfactory tissue. Nerve ending concentration subfractions (B₂) were prepared from the B primary fractions. Plasma membrane subfractions were obtained by osmotic shock treatment of B₂, In the fraction of plasma membrane from olfactory tissue (E₂), 56 per cent of the total ATPase activity was Na⁺-K⁺ ATPase activity. In E₂ from brain 71 per cent was Na⁺-K⁺ ATPase activity. Deoxycholate (DOC)-treated fractions containing nerve endings from brain preparations showed much greater increase in cytochrome oxidase activity than did similar fractions from olfactory tissue. DOC treatment increased the NADH cytochrome c reductase activity of all fractions and subfractions from brain, while it decreased activity in all but one fraction from olfactory tissue. DOC treatment decreased both the Mg²⁺ and Na⁺-K⁺ ATPase activities in both types of tissue. Electron photomicrographs of olfactory B₂, B₃, E₂ and E₃ show clear morphological differences among these subfractions. The presence of possible cilia and basal bodies on vesicles in B₂ gives morphological evidence for the presence of terminal swellings in this subtraction in agreement with enzyme marker activity results.     

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

Myelin from developing rat brains was separated on a discontinuous sucrose gradient into subfractions of two different densities, i.e. light and heavy myelin. Electron photomicrographs showed that heavy myelin consisted primarily of large compacted multilamellar structures with a distinct intraperiod line characteristic of myelin in situ. Light myelin, on the other hand, was composed of small vesicles having a unilamellar structure. Similar to whole myelin, both membrane subfractions were highly enriched in 2',3'-cyclic nucleotide-3'-phosphohydrolase. The specific activity of the enzyme, however, showed no developmental trend. Both subfractions contained all the four major proteins characteristic of the whole myelin membrane. There were, however, quantitative differences in the relative distribution of these proteins between light and heavy myelin. Basic protein accounted for 55% and proteolipid protein for 46% of the total myelin proteins of light and heavy myelin, respectively. DM-20 (Agrawal, H.C., Burton, R. M., Fishman, M.A., Mitchell, R.F. and Prensky, A.L. (1972) J. Neurochem. 19, 2083-2089) exhibited a developmental "switch" between light and heavy myelin. Light myelin appeared to contain more DM-20 in 15- to 20-day-old rat brain, whereas the concentration of this protein was higher in heavy myelin at subsequent ages studied.     

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

Myelin from developing rat brains was separated on a discontinuous sucrose gradient into subfractions of two different densities, i.e. light and heavy myelin. Electron photomicrographs showed that heavy myelin consisted primarily of large compacted multilamellar structures with a distinct intraperiod line characteristic of myelin in situ. Light myelin, on the other hand, was composed of small vesicles having a unilamellar structure. Similar to whole myelin, both membrane subfractions were highly enriched in 2′,3′-cyclic nucleotide-3′-phosphohydrolase. The specific activity of the enzyme, however, showed no developmental trend. Both subfractions contained all of the four major proteins characteristic of the whole myelin membrane. There were, however, quantitative differences in the relative distribution of these proteins between light and heavy myelin. Basic protein accounted for 55 % and proteolipid protein for 46 % of the total myelin proteins of light and heavy myelin, respectively. DM-20 (Agrawal, H. C., Burton, R. M., Fishman, M. A., Mitchell, R. F. and Prensky, A. L. (1972) J. Neurochem. 19, 2083–2089) exhibited a developmental “switch” between light and heavy myelin. Light myelin appeared to contain more DM-20 in 15- to 20-day-old rat brain, whereas the concentration of this protein was higher in heavy myelin at subsequent ages studied.     

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.     

Sodium channel activity in brain membrane fractions isolated from rats of different ages

The Na⁺ channel activity (tetrodotoxin sensitive ²²Na⁺ flux induced by veratridine and/or anemone toxin II) was studied in two fractions of brain cell plasma membranes, named A and B, isolated by the method of Gray and Whittaker ((1962) J. Anat. 96, 79–87) from rats 5, 10, 30 and 60 days old. The ²²Na⁺ flux was measured in membrane vesicles formed by the isolated membranes, in the absence of drugs (control), in the presence of veratridine, and in the presence of veratridine plus tetrodotoxin. Fraction A consists primarily of neuronal and glial membranes in rats of 5 and 10 days of age, while in the older rats this fraction becomes enriched in myelin. In Fraction A of 5-day-old and 10-day-old rats, veratridine (25 μM) increases the ²²Na⁺ flux 2.4- and 1.6-fold, respectively, and the increment continues to diminish with age, until it becomes negligible in the 60-day-old rats. Fraction B consists of synaptosomes and membrane vesicles, and at the four ages studied veratridine (25 μM) causes an increment of the ²²Na⁺ flux of about 2.5-fold. Fractions A and B from 10-day-old rats, and Fraction B from 60-day-old rats, which are sensitive to veratridine, also respond to anemone toxin II. When veratridine is used in presence of anemone toxin II (0.5 μM), the $\text{K}{}_{0.5}$ for veratridine is diminished and the maximum ²²Na⁺ flux is increased. The increments of ²²Na⁺ flux caused by veratridine and/or anemone toxin II in Fractions A and B are blocked by tetrodotoxin ($\text{K}{}_{0.5}$ approx. 5 nM). Fraction A from 60-day-old rats could be subfractionated by osmotic shock and sucrose gradient centrifugation to obtain three subfractions, two of which are enriched in axolemma and display Na⁺ chennel activity. The other subfraction is enriched in myelin and shows no Na⁺ channel actiivty. The plasma membrane preparations from young rats (up to 10 days) are devoid of myelin and are useful for studies of Na⁺ channel activity.     

The histones of rat testis

Polyacrylamide gel electrophoresis of the histones of the nuclei of seminiferous epithelial cells of rat testis revealed the five principal histone fractions which are found in liver and other somatic tissues, but, in addition, three unusual bands (desginated X₁, X₂, and X₃) were observed. Fraction X₁ had a mobility slightly less than that of F1 and was isolated with F1 in the fractionation procedure of Johns. F1 and X₁ were separated by chromatography on carboxymethylcellulose, and they were shown by amino acid analyses to be closely related lysine-rich histones. However, X₁ had lower content of lysine and alanine and higher content of arginine, aspartic acid, serine, proline, valine and leucine than F1. Both of these fractions had blocked amino-terminal residues, and both had a lysine residue at the carboxyl terminus. These fractions had similar molecular weights by electrophoresis on sodium dodecyl sulfate gels.Fraction X₂ migrated between histone fractions F1 and F3 on electrophoresis while X₃ migrated between fractions F2b and F3. Fraction X₃ was isolated with F2b during fractionation by the Johns procedure. Fraction X₂ has received minimal study, and this fraction may not be unique to the testis inasmuch as a faint band in approximately the position of X₂ can be seen in electrophoretic patterns of rat liver histones.The results of the treatment of the histone fractions with alkaline phosphatase indicated that the electrophoretic differences between X₁ and F1, or X₃ and F2b are not attributable to phosphorylation.     

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.     

DENSITY GRADIENT SEPARATION OF SARCOTUBULAR VESICLES AND OTHER PARTICULATE CONSTITUENTS OF RABBIT MUSCLE

Separation of particulate matter in rabbit muscle extracts by differential centrifugation leads, in first approximation, to the isolation of fraction I (15,000 to 41,000 g) and fraction II (41,000 to 150,000 g). The former consists mainly of sarcotubular material, actively transporting calcium ions, and displaying relaxation factor activity. The latter is heterogeneous, shows little calcium accumulation, and contains factors both inhibiting and activating myofibrillar ATPase. Fraction I is resolved by density gradient centrifugation into 2 main subfractions. The lighter one represents sarcotubular material in the best state of preservation, with biochemical activities stable for weeks in the cold. The heavier one may consist of the same material in a less well preserved form. Upon aging, it develops an activating activity toward myofibrillar ATPase, when the relaxing effect has declined. Fraction II is resolved by density gradient centrifugation into 3 or more fractions, with some variability. Relaxing activity in terms of inhibition of myofibrillar ATPase predominates among the lighter subfractions, increase of ATPase among the heavier. The intrinsic ATPase of fraction II is activated by calcium ions, but there is little or no bulk accumulation of calcium oxalate. Nevertheless, its limited calcium uptake seems to suffice to explain its relaxing activity. The particulate material contains mucopolysaccharide and lipid. Most of the lipid in fraction I is phospholipid; in fraction II this is less than half, if calculated as lecithin. The unfractionated material contains an adenylcyclase. There is no acetylcholine esterase.     

Biochemical Changes in Central Nervous System Membranes in Experimental Allergic Encephalomyelitis

Biochemical and morphological studies of myelin subfractions were undertaken on Lewis rats during the early stage of the development of experimental allergic encephalomyelitis (EAE). Myelin subfractions, obtained by sucrose density gradient centrifugation at 10 days post-induction, were subjected to sodium dodecyl sulfate-polyacrylamide gel electrophoresis and assayed for 2':3'-cyclic nucleotide 3'-phosphodiesterase (CNPase) activity. Aliquots were processed for electron microscopic analysis. When comparing the myelin subfractions of EAE-affected animals with those of controls, differences were observed only in the light fractions, i.e., a decrease in the specific activity of CNPase and in the percentage of basic proteins relative to the total proteins of the fraction. This decrease was also evident in the basic protein/proteolipid protein ratio which is frequently used in the literature. In addition, electron microscopic observations demonstrated strong differences in the morphology of the same fraction. These findings suggest that the light fraction is the most sensitive in the early stages of the disease and must play a key role in demyelinating processes.     

MYELIN SUBFRACTIONS IN DEVELOPING RAT BRAIN: CHARACTERIZATION AND SULPHATIDE METABOLISM

Centrifugation of isolated myelin on discontinuous sucrose gradients resulted in a separation into three bands and a pellet. The three bands were morphologically identical to myelin, whereas the pellet consisted primarily of vesicular membranes. These four fractions differed from one another in their lipid-to-protein ratios and in molar ratios of cholesterol:phospholipid:galactolipid. All of the fractions contained proteins typical of myelin, although the proportions of the proteins varied, with the pellet being the lowest in basic protein and proteolipid protein. High activity of 2′,3′-cyclic nucleotidase and low activity of cerebroside sulphotransferase further distinguished these fractions from the microsomal fraction. Distribution of radioactive sulphatide in the subfractions at 15 min after intracranial injection of radioactive sulphate indicated that newly-labelled sulphatide first appeared in the lipid-poor fractions, followed by the lipid-rich fractions; results of pulse-chase experiments also suggested this relationship. Several days or weeks after the injection of radioactive sulphate, most of the radioactive sulphatide was in the lipid-rich fractions.     

Biochemical and immunohistochemical studies with specific polyclonal antibodies directed against bovine myelin/oligodendrocyte glycoprotein

Bovine myelin/oligodendrocyte glycoprotein (MOG) was purified from a Wolfgram protein fraction of brain myelin by molecular sieving and preparative gel electrophoresis. The N-terminal sequence of this wheat germ agglutinin reacting glycoprotein was determined. Antibodies against purified MOG and synthetic N-terminal octapeptide of MOG were produced in rabbits. Respective affinity purified antibody preparations gave identical results on Western blots. Treatment with specific glycosidases indicated that the oligosaccharide chains of MOG are only of N-chain type. This glycoprotein seems to be restricted to mammalian species since it was not detected in other animal species, ranging from fish up to reptiles. Immunohistochemical investigations on rat brain sections revealed that MOG is restricted to myelin sheaths and oligodendrocytes, thus corroborating previous results obtained with the MOG 8-18C5 monoclonal antibody. Decreased staining pattern in Jimpy brain further attested its specific localization in myelin-related structures. The octapeptide site-specific antibodies were not reactive on brain sections which may be attributed to the burying of this N-terminal sequence in the membrane. These MOG polyclonal antibodies appear to be valuable tools for further studies concerning this minor glycoprotein.Abbreviations BSA bovine serum albumin - CNS central nervous system - DM-20 minor myelin proteolipid protein - MAG Myelin-associated glycoprotein - MBP myelin basic proteins - MOG Myelin/oligodendrocyte glycoprotein - OMgp Oligodendrocyte/Myelin glycoprotein - PAGE polyacrylamide gel electrophoresis - PBS phosphate buffered saline - PeptMOG n-terminal octapeptide of MOG - PLP major myelin proteolipid protein - PMSF phenylmethylsulfonylfluoride - SDS sodium dodecylsulphate - TBS Tris buffered saline - WPF Wolfgram protein fraction - WGA Wheat germ agglutinin