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.     

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 (particulary oligodentrocytes); ii) light and heavy myelin are quite similar between them but the former has a higher content of sphingomyelin, a lower hydroxy/nohhydroxy 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.     

Metabolism of three subfractions of myelin in developing rats.

Purified myelin, isolated from rat brain, was subfractionated into light, medium and heavy myelin. The metabolism of [³H] leucine in myelin subfractions was studied at intervals from 1 to 24 hours and from 18 hours to 85 days after the injection of 12-day-old rats. The metabolism of [¹⁴C] glucose in myelin subfractions was also examined during the 85 day interval. In addition, the development of each of these subfractions, as reflected by protein accretion, was determined.Between 13 and 97 days of age, the amount of the three myelin subfractions increased 10- to 44-fold. At 13 days of age the heavy subfraction accounted for the greatest percentage of myelin protein. However, beyond 13 days, light myelin predominated.The total ³H-radioactivity in the light, medium and heavy subfractions increased throughout most of the 85 day interval examined. The ³H specific radioactivity (³H dpm/μgram protein) of light myelin peaked at 12 hours after injection. The specific radioactivity of both ³H and ¹⁴C (¹⁴C dpm/μgram lipid) in light myelin declined beyond the initial time point in the long term (18 hour – 85 day) study. In contrast, the specific radioactivity of both ³H and ¹⁴C peaked in the medium and heavy subfractions at 4 days after injection of radioactive precursor.The possible existence of a membranous precursor to myelin is discussed.     

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.     

The isolation and biochemical characterization of three subfractions of myelin from central nervous tissue of the adult rat

Abstract— By techniques of isosmotic density gradient ultracentrifugation three subfractions of myelin were isolated from homogenates of whole rat brain at densities of 1.054 g/ml (myelin I), 1.060 g/ml (myelin II) and 1.066 g/ml (myelin III). The stability of these fractions was demonstrated by the zonal centrifuge profile analysis of recycled fractions. Examination of the three myelin subfractions by techniques of electron microscopy and thin layer chromatography detected no obvious morphological or chemical differences. However, analysis for protein, cholesterol, phospholipids and cerebrosides did reveal differences among myelin I, myelin II and myelin III. Myelin I contained relatively more cholesterol than II or III. Myelin III contained relatively more phospholipids than I or II. The cerebroside-to-protein ratios were the same in all three fractions. Quantitative differences in fatty acid composition (as detected by gas-liquid chromatography) were also observed.     

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.     

Fatty acid release in incubations of serum with synaptosome and myelin subfractions of brain

To study lipid breakdown in brain membranes following hemorrhage, synaptosome and myelin fractions isolated from rat brain were incubated with rat serum. After 3 h in vitro at 37 degrees C, 0.43 and 0.26 mumol of fatty acid were released in incubations containing synaptosomes (1.37 mumols phospholipid) or myelin (1.23 mumols phospholipid), respectively, in the presence of 0.25 mL serum. Less than 0.05 mumol of fatty acid was liberated in incubations containing only serum, synaptosomes, or myelin. For synaptosomes and serum, docosahexaenoate was the principal fatty acid released (28 mol% of total) after 3 h of incubation. This fatty acid and arachidonate made up 43 mol% of the liberated fatty acid. The presence of free docosahexaenoate was of interest, as this fatty acid is particularly enriched in phosphatidylserine and phosphatidylethanolamine, phospholipids found in the cytoplasmic half of the synaptosomal plasma membrane and in interior synaptosomal membranes. In incubations of serum and myelin, oleate was the major free fatty acid produced in 30 min to 3 h of incubation (29-35 mol% of total). After 3 h, docosahexaenoate contributed 20 mol% to the total. The release of fatty acids from the membranes may be mediated by serum phospholipase(s) or possibly by activated endogenous lipolytic activities.     

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.     

Immunochemical measurement of myelin basic protein in developing rat brain: an index of myelin synthesis.

The initial time and rate of myelin basic protein synthesis in neural tissues of the rat have been measured from birth to 120 days. The protein was quantitated by a radioimmunoassay directly applied to unfractionated cerebrum, cerebellum, olfactory bulb, midbrain, brain stem, optic and trigeminal nerve, and areas of the spinal cord. Because the protein is a specific myelin constituent and its appearance correlates precisely with the synthesis of myelin lipids, the data in this report can be interpreted in terms of myelin synthesis and oligodendrocyte activity. The results show striking heterogeneity in the initial time and rate of myelin synthesis in neural tissue.     

Calcium ion stimulated endogenous protein kinase catalyzed phosphorylation of basic proteins in myelin subfractions and myelin-like membrane fraction from rat brain

Polypeptide composition and endogenous phosphorylation were investigated in the subfractions of rat brain myelin isolated by either discontinuous or continuous sucrose density gradient centrifugation of myelin. Similarly, a myelin-like membrane fraction (SN4) was also studied. Observations were made that strongly indicated the presence of a calcium-stimulated protein kinase in a highly purified myelin preparation and which exclusively phosphorylated myelin basic proteins of the membrane preparation. Adenosine cyclic 3',5'-phosphate (cAMP) stimulated kinase on the other hand was found to be considerably enriched in the myelin-like membrane fraction. Although this latter enzyme is also capable of phosphorylating the basic proteins, its effect was at least 5 times weaker compared to the calcium-stimulated myelin protein kinase. Within the gradient subfractions there appeared a close relation between the amount of basic proteins and their calcium-stimulated phosphorylation; a similar relationship, however, was not obtained in the case of cAMP-dependent phosphorylation of myelin basic proteins. The former (i.e., Ca2+-stimulated phosphorylation) was found to require a protein factor that functionally resembled calmodulin. The results thus raises an interesting possibility of the presence of calmodulin-like proteins and a calcium-stimulated protein kinase in adult myelin membrane from mammalian brain, both of which have been hitherto unrecognized constituents of myelin membranes.     

Protein kinase C in rat brain myelin

It has been suggested that phosphorylation of myelin basic protein (MBP) in CNS is catalyzed by protein kinase C (PKC). In order to demonstrate that PKC in the myelin phosphorylates MBP, PKC was partially purified from rat CNS myelin by solubilization with Triton X-100 followed by a DEAE-cellulose column. MBP and histone III-S were phosphorylated in the presence of Ca²⁺ and phospholipid by rat myelin PKC. High voltage electrophoresis revealed that the phosphoamino acids in MBP by this kinase was serine residue, which is known to be the amino acid phosphorylated by PKC. The activity of PKC extracted from myelin was inhibited by the addition of psychosine to the incubation mixture. To confirm the presence of PKC molecule and to identify the isoform of PKC in the myelin, the solubilized myelin fraction was applied on SDS-PAGE, transferred to a nitrocellulose sheet and stained with anti-PKC monoclonal antibodies. Rat CNS myelin contained the PKC of about 80 kDa (intact PKC), and no proteolytic fragments were observed. PKC isozymes in myelin were type II and III. A developmental study from 14 to 42 postnatal days showed that PKC activity in CNS myelin seemed to parallel the deposition of myelin protein.     

Polyphosphoinositide metabolism in rat brain: effects of neuropeptides, neurotransmitters and cyclic nucleotides

This study describes effects of various peptides, neurotransmitters and cyclic nucleotides on brain polyphosphoinositide metabolism in vitro. The interconversion of the polyanionic inositol phospholipids was studied by incubation of a lysed crude mitochondrial/synaptosomal fraction with [gamma-32P]-ATP. The reference peptide ACTH1-24 stimulated the formation of radiolabelled phosphatidylinositol 4,5-diphosphate (TPI) and inhibited that of phosphatidic acid (PA). Substance P inhibited both TPI and PA labelling, whereas beta-endorphin inhibited that of PA without any effect on TPI. Morphine had no effect at any concentration tested, whereas high concentrations of naloxone inhibited the labelling of both PA and TPI. Naloxone did not counteract the effects of ACTH1-24. The other peptides tested (lysine 8-vasopressin and angiotensin II) were without any effect. Under the conditions used, adrenaline, noradrenaline and acetylcholine did not affect the labelling of the (poly)phosphoinositides. Both dopamine and serotonin, however, dose-dependently inhibited the formation of radiolabelled TPI and PA. Low concentrations of cAMP stimulated TPI, but higher concentrations had an overall inhibitory effect on the labelling of TPI, PA and especially phosphatidylinositol 4-phosphate (DPI). The cyclic nucleotide did not mediate or counteract the effects of ACTH, and cGMP was without any effect. These results are discussed in the light of current ideas on the mechanism of action of neuropeptides.     

Myelination in rat brain: method of myelin isolation

Abstract— A procedure is described for the preparation from rat brain of myelin having the same degree of purity at all ages. Such a procedure is essential for the study of myelin composition during development. Microsomal contamination was successfully eliminated by adjusting the method to maintain a constant amount of brain per unit volume in the initial density gradient step, and by including two osmotic shocks and two low-speed centrifugation steps. Myelin prepared in this way from animals ranging from 15 days to 14months of age had a total ATPase activity of 0.3-2.0 μmol of P_i.h^?1.mg^?1 dry wt of myelin, representing 0.1-1.2 per cent recovery of the total homogenate activity; a Na⁺, K⁺- ATPase activity of 0.1-1.6 μfnol of P_i.h^?1.mg^?1 dry wt, representing 0.04-1.5 per cent recovery; a nucleic acid content of 0.2-0.7 per cent of myelin dry wt, representing 0.2-2.0 per cent recovery; and a ganglioside NANA content of 0.04-0.07 per cent of myelin dry wt. representing 0.2-4.6 per cent recovery. The myelin prepared from 20-day animals had the highest content of the first three constituents; otherwise the values of the four constituents were relatively constant per unit weight of myelin. The amounts of nucleic acid and ganglioside recovered in the myelin fractions increased with increasing age and myelin yield.     

Detection of choline kinase in purified rat brain myelin

Choline kinase, an enzyme involved in the Kennedy pathway conversion of diacylglycerol to phosphatidylcholine, was detected in highly purified rat brain myelin at a level equal to 20% that of whole brain homogenate. This was an order of magnitude higher than the specific activity of lactate dehydrogenase, marker for cytosol. Choline kinase was also detected in the P1, P2, P3, and cytosolic fractions with highest relative specific activity in the latter. Myelin washed with buffered sodium chloride or taurocholate retained most of its kinase, indicating that adsorption of the soluble enzyme was unlikely. The results of mixing experiments and repeated purification further indicated that the enzyme is intrinsic to myelin. This finding in concert with previous studies supports the concept that myelin has all the enzymes needed to convert diacylglycerol to phosphatidylcholine.     

Hypotheses regarding myelination derived from comparisons of myelin subfractions.

Patterns of myelin-associated proteins and glycoproteins in subfractions of central nervous system myelin and changes in these during development have been reviewed. Several hypotheses are put forward regarding classification of these proteins as structural components of myelin, as components of the membranes from which myelin is derived or as molecules present to play a role in myelin formation rather than as true components of compact myelin. 2′, 3′-Cyclic nucleotide 3′-phosphohydrolase is considered to fit into this last category and two different hypothesis are proposed for its role. The major myelin glycoprotein is postulated to serve a function in recognition of axons by oligodendrocytes, a function not needed in the peripheral nervous system where Schwann cells and axons develop in close contact.     

Myelination in rat brain: changes in myelin composition during brain maturation

Abstract— Myelin was isolated from rat brains during development by a procedure giving fractions of constant purity at all ages. The lipid composition of these fractions and of whole brains of littermates was determined. The amount of myelin recovered per brain was a nearly linear function of the logarithm of age from the youngest (15 days) to the oldest (425 days) animals studied. With the exception of the earliest age point, the isolated myelin accounted for approximately 40 per cent of total brain galactolipid, evidence that a constant fraction (calculated to be 60 per cent) of myelin was recovered at all ages. Although the lipid-protein ratio of the myelin was constant with age, marked changes were seen in the amounts of cerebroside, sulphatide, phosphatidylcholine and desmosterol. The total galactolipid increased from 21 per cent of the total lipid at age 15 days to about 31 per cent at maturity. Phosphatidylcholine decreased from 17 to 11 per cent during the same period. Desmosterol decreased from 2.5 per cent of the total sterol to 0.2-0.3 per cent. All of these changes were complete between 2 and 5 months of age; no other ‘lower phase’ lipids showed significant changes with age. Although qualitatively similar to those reported by others, the changes differed in magnitude, with more stability in the levels of cholesterol and phosphatidalethanolamine with development. A sensitive indicator of the maturation of myelin was the mole ratio galactolipid/phosphatidylcholine, which varied from 1.2 at age 15 days to 2.8 at maturity. The maximum rate of myelination occurred at 20 days of postnatal age when myelin was deposited at the rate of 3.5 mg day^?1 brain^?1. However, at this age the rat brain had only 15 per cent of its eventual complement of myelin. The rate of accumulation of cerebroside in the whole brain paralleled that of myelin, and was the only lipid to show this relationship. Myelin deposition appeared to be almost solely responsible for the continued increase in brain weight after about 100 days of age.