Binding of delta-aminolevulinic acid by myelin proteins

Delta-[14C]aminolevulinic acid (ALA) was injected intracranially into experimental animals; the gray and white matter was obtained from the brain 24 hours thereafter. The radioactive label content in the ALA, protoporphyrin, microsomes, mitochondria, cell membranes and myelin was determined; no radioactivity was detected in ALA and protoporphyrin. The radioactive label was localized in the subcellular fractions and myelin, in particular, in the white matter. Analysis of protein myelin fractions demonstrated that ALA was incorporated into practically all basic proteins. The highest capacity to bind ALA was observed in case of Wolfgram proteins; however, almost half of the bound ALA in the myelin fraction was found within the composition of basic proteins. It was assumed that the binding of ALA to proteins occurs via the amide, carboxylic and keto groups of ALA.     

KINETICS OF ENTRY OF PROTEINS INTO THE MYELIN MEMBRANE1

Brain slices were prepared from 17-day old rats, and incubated with [³H]glycine or [³H]-leucine to label proteins. Myelin was isolated from the slices, and the proteins were separated by discontinuous gel electrophoresis in buffers containing sodium dodecyl sulfate. Radioactive basic and Wolfgram proteins appeared in myelin at similar initial rates, and their entry was nearly linear between 15 and 120 min with no detectable lag. Radioactive proteolipid protein appeared in myelin at one-fourth the rate of the basic and Wolfgram proteins between 0 and 30 min, then entered at a rate comparable to the other proteins between 45 and 120 min. When cycloheximide (0.2 mM) or puromycin (1.0 mM) was added, appearance of newly labeled basic and Wolfgram proteins in myelin stopped while proteolipid protein continued to appear in myelin at a normal rate for at least 30 min. Chase experiments with unlabeled glycine had similar effects. These results indicate the existence of a previously synthesized precursor pool of proteolipid protein with a 30-min interval between synthesis of proteolipid protein and its appearance in myelin. Incorporation of [³H]fucose into glycoprotein of the myelin sheath was studied, as was inhibition of incorporation of radioactivity by the use of either cycloheximide, or dilution with unlabeled fucose. The results indicated fucosylation of a sizable pool of presynthesized protein and a delay of 30 min between fucosylation of these polypeptides and their subsequent appearance in myelin as glycoproteins.     

Studies on the Wolfgram High Molecular Weight CNS Myelin Proteins: Relationship to 2'',3''-Cyclic Nucleotide 3''-Phosphodiesterase

Evidence is presented that the major protein components of the high molecular weight CNS myelin proteins designated as the Wolfgram protein doublet (W1 and W2) contain the enzyme 2',3'-cyclic nucleotide 3'-phosphodiesterase (EC 3.1.4.37, CNP). CNP is a basic hydrophobic protein containing about 830 to 840 amino acid residues. When electrophoresed on SDS polyacrylamide gels, CNP appears as a protein doublet, separated by a molecular weight difference of about 2500-3000 in bovine, human, rat, guinea pig, and rabbit. A similar protein doublet has been identified as the Wolfgram proteins W2 and W1 in myelin and in the chloroform-methanol-insoluble pellet obtained from myelin. Moreover, the relative Coomassie blue staining intensity of the CNP2 plus CNP1 protein doublet among the species examined was remarkably similar to that observed for electrophoresed myelin and chloroform-methanol-insoluble pellet derived from myelin. Antisera raised against purified bovine CNP recognized the W1 and W2 proteins isolated from bovine and human brain. The amino acid composition of pure bovine CNP is presented and compared with the compositions of several rat and bovine Wolfgram proteins obtained by other investigators. Our electrophoretic, compositional, and immunological data support the contention that the enzyme CNP is a major component of the Wolfgram protein doublet.     

The Immunological Identification of Brain Proteins on Cellulose Nitrate in Human Demyelinating Disease

Abstract: An immunological technique has been employed to identify proteins, separated in polyacrylamide gels, which show changes in brain samples from cases of multiple sclerosis and subacute sclerosing panencephalitis. Sodium dodecylsulphate-treated proteins in particulate and soluble fractions were separated in polyacrylamide slab gels, transferred electrophoretically onto cellulose nitrate sheets, incubated with specific antisera and visualized by an immunoperoxidase method. Protein bands showing changes were identified using antisera raised against the myelin basic and Wolfgram proteins, the neurofilament triplet proteins, tubulin and glial fibrillary acidic protein. In addition to the loss of myelin proteins, decreases in the neurofilament proteins and in tubulin were seen in both multiple sclerosis and subacute sclerosing panencephalitis samples. The distribution of glial fibrillary acidic protein polypeptides in the particulate and soluble fractions of plaque samples appeared to vary according to the degree of fibrosis. Changes in the levels of the myelin-associated glycoprotein, the lower molecular weight component of the Wolfgram protein, albumin and immunoglobulin G, none of which were visualized by protein staining, were also seen. This immunological technique has allowed a closer examination of changes occurring in brain protein spectra in multiple sclerosis and subacute sclerosing panencephalitis.     

The Presence of Aldehyde-Reacted Proteins in Normal and Multiple Sclerosis White Matter

The incorporation of tritium from NaB3H4 into the major protein components of myelin and the presence of weak fluorescence emission bands at wavelengths of approximately 440 and 500 nm from sodium dodecyl sulfate-solubilized, delipidated white matter are indicative of the presence of the products of aldehyde reactions with proteins. The incorporation of tritium from NaB3H4 into myelin proteins was confirmed by reaction with purified components of myelin basic protein or with lipophilin, a purified fraction of proteolipid protein. From the extent of tritium incorporation into the purified proteins, it is estimated that approximately 0.2 mol of tritium is incorporated/mol of myelin basic protein and approximately 0.4 mol of tritium/mol of proteolipid protein. There is approximately 50% greater incorporation of tritium into a more degraded, less positively charged form of the basic protein. The incorporation of tritium into normal and multiple sclerosis white matter was compared. There is a small but statistically significant difference in the percentage of the total counts incorporated into the major protein fractions for the two groups, with the multiple sclerosis samples showing a higher percentage of the counts in the Wolfgram protein and a lower percentage in the myelin basic protein compared with the normal samples.     

EFFECT OF PROTEOLYTIC ATTACK ON THE STRUCTURE OF CNS MYELIN MEMBRANE

Rat CNS myelin particles have been incubated with trypin and acetyltrypsin under conditions which ensured a selective and substantial removal of the basic proteins leaving acidic Wolfgram and proteolipid proteins. Some trypsin became associated with the basic protein denuded pellet while no attachment of acetyltrypsin was observed. The removal of basic proteins ‘solubilized’ some myelin and produced a lighter ‘fluff’ layer on top of the myelin pellet, but this amounted to no more than 10 per cent of the total myelin lamellae. Electron microscopy indicated a more dense-straining interperiod line in a small percentage of lamellae which otherwise remained normal. Selective extraction of complex lipids with solvents of increasing polarity, nuclear magnetic resonance spectra and X-ray diffraction patterns showed no significant changes on removing basic proteins from myelin. The results are interpreted as suggesting that the basic proteins are not uniformly distributed in myelin but preferentially located in the outside layers of the myelin sheath and that they play little part in stabilizing the bulk of the myelin membrane structure.     

Diphtheria toxin inhibits the synthesis of myelin proteolipid and basic proteins by peripheral nerve in vitro

Abstract— Diphtheria toxin (DT) did not produce measurable degradation of myelin proteins or sulphatide in sciatic nerves of chick embryos after incubation in vitro for 4 h. In contrast, DT inhibited the in vitro incorporation of L-[U-¹⁴C]leucine into myelin proteins by the nerves after a delay of 1 h. Separation of the myelin proteins by SDS-polyacrylamide gel electrophoresis indicated that the synthesis of Wolfgram proteins and proteins not entering the gel was inhibited by 21–22 per cent, whereas synthesis of myelin proteolipid and basic proteins was inhibited by 79–88 per cent. Incorporation of ³⁵SO₄ into myelin [³⁵S]sulphatide was also inhibited by DT after a delay of 2 h. The inhibition of [³⁵S]sulpha-tide incorporation into myelin caused by DT differed from that observed with puromycin in that it did not depend on depletion of an intracellular transport lipoprotein. Instead, the inhibition seemed to be secondary to the decreased synthesis of myelin proteolipid and basic proteins.     

Density distribution of 2′,3′-cyclic nucleotide 3′-phosphodiesterase and myelin proteins in particulate material from myelin deficient (mld) mutant and control brains

Total particulate material from control and myelin deficient (mld) brains was subjected to density centrifugation on a continuous sucrose gradient. Particles from control brains distributed in a bell-shaped mode with a peak density near 0.64 M-sucrose. In mld material only a slight elevation of optical density was observed near 0.8 M-sucrose. The highest specific activities of 2′,3′-cyclic nucleotide 3′-phosphodiesterase were observed at densities of 0.63 and 0.71 M-sucrose for mld and control brains, respectively. The peak of myelin basic protein in control fractions was near 0.60 M-sucrose. In mld fractions no peak was observed. Proteolipid and Wolfgram proteins had a maximum near 0.65 and 0.73 M-sucrose in control and mld fractions, respectively. The absence of myelin basic proteins in all the fractions makes it unlikely that, in mld mice, myelin basic proteins are synthesized but not incorporated into myelin.     

ARE MYELIN PROTEINS SYNTHESIZED IN RETINAL GANGLION CELLS?1

—We studied the incorporation of radioactivity into individual proteins of myelin by sodium dodecyl sulfate polyacrylamide gel electrophoresis after the injection of [³H]tryptophan into the right eye of developing rabbits. We found that the specific activity of basic protein (c.p.m./mg of basic protein) and the specific activity of DM-20 and proteolipid protein (c.p.m./mg total myelin protein applied to the gel) did not approach the ratio predicted by decussation of the fibres of the rabbit optic nerve. The specific activity of Wolfgram protein, however, approached an expected ratio of 15:1. We therefore concluded that myelin basic protein, DM-20 and proteolipid protein were probably not synthesized in retinal ganglion cells.     

Endogenous cyclic AMP-stimulated phosphorylation of a Wolfgram protein component in rabbit central-nervous-system myelin.

Cyclic AMP-stimulated phosphorylation of membrane proteins in central-nervous-system myelin was investigated, with rabbit brain myelin. Subfractionation of a myelin membrane preparation by sucrose-density-gradient centrifugation produced a rapidly sedimenting population of membrane vesicles containing 5'-nucleotidase and acetylcholinesterase, a light membrane fraction containing myelin basic protein and 2',3'-cyclic nucleotide 3'-phosphodiesterase, and an intermediate membrane fraction containing the highest specific activity of 2',3'-cyclic nucleotide 3'-phosphodiesterase and a small proportion of myelin basic protein. Cyclic AMP stimulation of protein phosphorylation was confined to a protein of Mr 49 700, which co-electrophoresed with the upper component of the Wolfgram protein doublet. Cyclic AMP did not affect the phosphorylation of myelin basic protein. Cyclic AMP-stimulated phosphorylation of this protein followed 2',3'-cyclic nucleotide 3'-phosphodiesterase activity on subcellular fractionation and was correspondingly high in the intermediate or 'myelin-like' fraction on sucrose-density-gradient centrifugation.     

Degradation of myelin proteins by cathepsin B and inhibition by E-64 analogue

Purified human brain myelin was isolated, heat-treated to inactivate the endogenous proteolytic activity and incubated with cathepsin B purified from rat liver, at pH 6.0. Incubation resulted in a marked reduction of myelin basic protein (BP) and partial breakdown of proteolipid protein or Wolfgram protein. Degradation of myelin proteins was inhibited by E-64 analogue (E-64-a). E-64 is a specific thiol protease inhibitor isolated from a solid culture of Aspergillus japonicus. The present study suggests that cathepsin B may play some role in demyelination.     

Protein analysis of myelin isolated from the CNS of fish: Developmental and species comparisons

The protein composition of myelin isolated from the CNS of four different fish species (trout, goldfish, eel, Tilapia) was analysed by SDS-polyacrylamide gel electrophoresis and compared with that of pig and rat brain. Thereby the following features were found typical to the myelin of fish: (1) a basic protein of particular low molecular weight, (2) the entire absence of Wolfgram protein, (3) the appearance of an additional major component of medium molecular weight (around 36,000) and (4) a strong Con A-affinity exhibited by the intermediate proteins, being most clearly discernible in trout and eel myelin. During development of the trout brain, in particular, a myelin fraction could first be isolated from the brainstem at 14 days after hatching and the myelin yield steadily increased during the first year of life. In tectum and cerebellum main myelin accumulation was stated during the third and seventh month. Concomittantly marked changes in the relative distribution of major myelin proteins were observed: especially the IP1-protein showed a marked increase during the first half year, whilst the relative amount of the 36-K protein was gradually declining during the same time.     

Comparative localization of Wolfgram W1 and myelin basic proteins in the rat brain during ontogenesis

Summary Antisera raised in rabbits against myelin basic proteins (MBP) and Wolfgram W1 protein isolated from rat myelin were used to study the maturation of oligodendrocytes in the developing rat nervous system. Both proteins were localized immunohistochemically at the light and electron microscopical levels in rat brain from the time of their first appearance to the adult stage. Oligodendrocytes were first detected by their positive staining with W1 antiserum two days after birth and at 1–3 days later with MBP antiserum. At 8–10 days, the number of oligodendrocytes labelled with both sera increases and the myelinated fibre pathways were clearly visible. Labelling with W1 antiserum was observed in oligodendrocytes at all stages from 2 days after birth to adulthood and in myelin fibres when they were present. In contrast, staining of oligodendroglial cells with MBP declined during the period of rapid myelination (20–25 days after birth) and finally disappeared, whereas myelin staining was still apparent. The electron microscopical study revealed that the synthesis of Wolfgram proteins occurred mostly at the peripheral cytoplasmic ribosomes of the cells, from where they were probably transported to processes engaged in myelination. The electron micrographs also showed that the sites of MBP synthesis seemed to be more uniformly distributed over the entire cytoplasm.     

Turnover of myelin and other structural proteins in the developing rat brain

1. Protein metabolism of myelin and other subcellular components from developing rat brain was studied for periods from 5h to 210 days after intraperitoneal injection of [(3)H]lysine and [(14)C]glucose. 2. Half-lives for total brain proteins (t(0.5)) were 27 days after [(3)H]lysine and 4 days after [(14)C]glucose injection. 3. Factors accounting for the difference in the turnover rates obtained with different precursors, and the problem of reutilization of the label were investigated. 4. The catabolism of purified myelin proteins was studied and the half-lives of individual myelin proteins were calculated. 5. Myelin basic proteins turned over at two different rates. Half-life of the fast component of myelin basic proteins was 19-22 days and the slow component exhibited a high degree of metabolic stability. 6. Proteolipid protein underwent slow turnover. High-molecular-weight Wolfgram (1966) proteins underwent (relatively) fast metabolism (t(0.5) of 17-22 days).     

Suppressive Effect of Triethyllead on Entry of Proteins into the CNS Myelin Sheath In Vitro

Incorporation of [¹⁴C]leucine into the myelin sheath was studied in brain stem slices prepared from 22-day-old rats. Individual major myelin proteins were separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate. There was a time lag before incorporation of the label into proteolipid protein (PLP) and intermediate protein (IP) reached maximal rates. Labelling of basic proteins (BP) and Wolfgram proteins (WP) revealed a much shorter lag in entry. Appearance of radioactive proteins in the myelin sheath was significantly hampered by triethyllead (PbEt₃) added to the incubation medium at micromolar concentrations. Inhibition values were highest in the case of PLP and were closely followed by the values for IP. BP and WP were less inhibited, although incorporation of these proteins into myelin was still suppressed more than was synthesis of total homogenate protein. Thus, myelin-forming cells seem to be unduly vulnerable to the toxin relative to the rest of the tissue. Furthermore, the results indicate an interference of PbEt₃ with certain posttranslational processes involved in furnishing of integral myelin proteins.     

Susceptibility of the Myelin-Associated Glycoprotein and Basic Protein to a Neutral Protease in Highly Purified Myelin from Human and Rat Brain

Abstract: Incubation of highly purified human myelin at 25° and pH 8 in ammonium bicarbonate buffer resulted in the conversion of the myelin-associated glycoprotein (MAG) to a smaller derivative (dMAG) with an apparent molecular weight about 10,000 less. dMAG was stable and was not degraded to lower-molecular-weight breakdown products. Incubation of myelin under these conditions also resulted in the degradation of basic protein, but at a much slower rate. Half of the MAG was converted to dMAG in about 30 min, whereas degradation of half of the basic protein required 18 h of incubation. There was no significant loss of proteolipid, the Wolfgram doublet, or other myelin proteins during incubation for up to 18 h under these conditions. The formation of dMAG and the degradation of basic protein appear to be mediated by similar enzymatic activities; both processes exhibited broad pH optima in the neutral range, were prevented by briefly heating the myelin to 70° before incubation, and were stimulated by ammonium bicarbonate and other salts. Incubation of purified rat myelin also resulted in the formation of dMAG and the degradation of basic protein, but the conversion to dMAG occurred much more slowly than in human myelin preparations. In the rat, the percentage decreases in intact MAG and in basic protein were similar to each other and proceeded at rates comparable to the loss of basic protein in human myelin. These studies confirm and extend earlier demonstrations of neutral protease activity in purified myelin, and show that cleavage of MAG is one of the effects of this activity. The proteolytic activity affecting MAG and basic protein was not significantly reduced by further purification of the myelin on sucrose or CsCl gradients, suggesting that the neutral protease may be a myelin-related enzyme. The very high susceptibility of human MAG to this enzyme indicates that the effect of neutral protease on this glycoprotein should be considered in connection with demyelinating diseases.     

The breakdown of myelin-bound proteins by intra- and extracellular proteases

Changes in protein components of purified myelin were measured following incubation in vitro with purified intra- and extracellular enzymes. Incubation with calf brain cathepsin D did not result in a significant relese of acid-soluble peptides as measured by ninhydrin analysis but was accompanied by a large loss of myelin proteins as determined on SDS-acrylamide gels. After 5 hr at 37°C there was a loss of about 25% for fast and slow basic proteins and the Agrawal proteolipid, but only a 5–10% loss for the Folch-Lees and Wolfgram components. Rat brain cathepsin D prepared by affinity chromatography gave a 30–60% breakdown of basic proteins and proteolipids. In general, breakdown using lyophilized myelin was increased over two-fold as compared to experiments with fresh myelin. Breakdown induced by cathepsin D was completely inhibited by the pentapeptide pepstatin. Incubation of myelin at physiological pH resulted in an endogenous breakdown of about 12% for basic proteins in freshly prepared, and 50% for lyophilized material. Addition of a soluble neutral proteinase that splits hemoglobin did not induce additional breakdown except for a small change in the Folch-Lees component. The extracellular enzymes pepsin and TPCK-treated trypsin resulted in a larger breakdown of all components as compared to brain enzymes. Present results demonstrate that all protein components of myelin are accessible to hydrolases and vulnerable to breakdown to varying extents by brain enzymes. These facts are consistent with the known rates for myelin protein turnover and may have a bearing on changes associated with demyelinating diseases     

Lipid and basic protein interaction in myelin

1. Purified myelin labelled with [(3)H]myo-inositol or [1-(14)C]acetate was incubated with trypsin or acetylated trypsin at 37 degrees C, pH8.0 for 30min. 2. After incubation and centrifugation analysis of the myelin pellet showed marked digestion of basic protein on polyacrylamide-gel electrophoresis. Proteolipid and Wolfgram proteins remained unchanged. 3. A loss of 15% of total protein and loss of all classes of lipids was also found. Most significant lipid losses were phosphoinositides, phosphatidylserine and sulphatide. 4. A low-density material containing more phospholipid than cholesterol and galactolipid was isolated from the supernatant obtained after centrifugation of trypsin-treated myelin. 5. Interaction of sulphatide and myelin basic protein was shown to take place in a biphasic system. Basic protein does not form any complex either with cerebroside or cholesterol in the same solvent system. 6. The release of acidic lipids from myelin suggests that they may be linked to basic protein by ionic forces and the neutral lipids may be by lipid-lipid interactions. 7. The relevance of these studies as a model of brain degeneration is discussed.     

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