A biochemical comparison of Xenopus laevis and mammalian myelin from the central and peripheral nervous systems.

Myelin purified from the central nervous system of Xenopus laevis contained the same major lipid and protein components as human myelin. However, some minor differences in the myelin proteins were noted. The Xenopus basic protein had a higher apparent mol wt. on sodium dodecyl sulfate gels than the corresponding mammalian protein. The absolute specific activity of 2',3'-cyclic nucleotide 3'-phosphohydrolase in the Xenopus myelin was considerably higher than in mammals. There were differences in the high mol wt. proteins, and the glycoproteins in Xenopus myelin were more heterogeneous than those in mammals. Peripheral myelin from Xenopus sciatic nerve was compared with that from the rat. The lipids in the two types of myelin were similar. There was a major glycoprotein in the Xenopus myelin corresponding to the P0 protein and a basic protein of slightly larger mol wt. than the P1 protein of rat myelin.     

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.     

The P2 protein of bovine root myelin: isolation and some clinical and immunological properties

Abstract— A small basic protein (mol.wt. 12,000), referred to as the P₂ protein, was extracted with dilute acid from delipidated bovine root myelin and purified by ion exchange chromatography on cellulose phosphate. It appeared homogeneous on polyacrylamide gel electrophoresis. The P₂ protein had a distinctly different amino acid composition than the larger basic protein (mol.wt. 18,000), referred to as the P₁ protein, that is also present in peripheral nerve myelin. It contained relatively more hydrophobic residues and much less histidine and proline. The P₂ protein conjugated with peroxidase was bound by lymph node cells and infiltrates in rabbits sensitized with whole bovine root myelin. No binding was evident with the bovine central nervous system myelin basic protein. Chemically and immunologically, the P₂ protein appears to be specific to peripheral nervous system myelin. The isolated P₂ protein produced mild clinical symptoms of experimental allergic neuritis, but no histological evidence of disease. It was suggested that the P₂ protein is an important antigen for experimental allergic neuritis, and that its antigenic determinants are likely to be conformation-dependent.     

Peripheral nervous system myelin assembly in vitro: perturbation by the ionophore monensin

Abstract: Sciatic nerves from 13-day-old rats were incubated in vitro with [³⁵S]methionine in the presence or absence of 0.22 μM monensin and total paniculate and myelin fractions prepared. The total particulate was further subfractionated by continuous density gradient centrifugation, after which the maximal specific activities of three marker enzymes, 2′,3′-cyclic nucleotide phospho-diesterase (myelin), 5′-nucleotidase (plasma membrane), and cerebroside sulphotransferase were recovered at 0.72, 0.82, and 0.92 M sucrose, respectively. The radiolabelled proteins present in the gradient subtractions were analysed by sodium dodecyl sulphate polyacrylamide gel electrophoresis (SDS-PAGE) and fluorography, and bands corresponding to the P₀ and myelin basic proteins were identified by co-migration with unlabelled myelin marker proteins on both one-dimensional SDS-PAGE and two-dimensional nonequilibrium isoelectric focussing/SDS-PAGE systems. Following a 90-min incubation with [³⁵S]methionine, newly synthesized myelin basic proteins were recovered in fractions between 0.5 and 0.7 M sucrose; this distribution was unaltered by monensin. In contrast, the distribution of newly synthesized P₀ protein across the gradients was influenced by monensin: a bimodal distribution across the control gradients with peaks of recovery of 0.60 and 0.82 M sucrose was altered to give a single peak at an intermediate density of 0.72 M sucrose. The total proportions of newly synthesized P₀ and myelin basic proteins (MBP) present across the entire gradients were calculated from the fluorograms, and the ratio was found to be 2.8 P₀: (LBP + SBP), in both the presence and absence of the ionophore. However, only 70% and 50% of the control levels of MBP and P₀ were recovered with a purified myelin fraction after incubation with monensin. The results are discussed with reference to different intracellular transport processes for the P₀ glycoprotein and the MBP within the Schwann cell, and also to the differential compartmentation of the sites of synthesis and membrane export within the Golgi body.     

Purification and partial characterization of two glycoproteins in bovine peripheral nerve myelin membrane

Two major glycoproteins of bovine peripheral nerve myelin were isolated from the acid-insoluble residue of the myelin by a procedure involving delipidation with chloroform/methanol (2:1, v/v) and chromatography on Sephadex G-200 column with a buffer containing sodium dodecyl sulfate. The separation patterns of the proteins on the gel were affected considerably by the dodecyl sulfate concentration in the elution buffer. At above 2% dodecyl sulfate concentration in the elution buffer, the glycoproteins could be separated clearly on the gel and were purified. The purified proteins, the BR protein (mol. wt. 28 000) and the PAS-II protein (mol. wt. 13 000), were homogeneous on dodecyl sulfate-polyacrylamide gel electrophoresis. The NH₂-terminal amino acids of the BR and the PAS-II proteins were isoleucine and methionine, respectively. The BR protein contained glucosamine, mannose, galactose, fucose and sialic acids and the PAS-II protein contained glucosamine, mannose, galactose, fucose and glucose. Neither the BR protein nor the PAS-II were a glycosylated derivative of a basic protein of bovine peripheral nerve myelin, a deduction based on the results of amino acid analysis. The two major glycoproteins were observed commonly in the peripheral nerve myelin of cows, pigs, rabbits and guinea pigs, using dodecyl sulfate-polyacrylamide gel electrophoresis.     

PHOSPHORYLATION OF ENDOGENOUS PROTEINS IN MYELIN OF RAT BRAIN

Abstract— The phosphorylation of endogenous proteins occurring in the myelin of rat brain was examined using the method of sodium dodecyl sulphate-polyacrylamide gel electrophoresis. Two myelin basic proteins and at least five more proteins were phosphorylated after incubation of myelin fraction in the presence of ATP + Mg²⁺. The apparent molecular weights of the proteins other than the myelin basic proteins were 120,000, 76,000, 60,000, 41,000 and 38,000, respectively. The proteins of mol wt 60,000. 41,000 and 38,000 were extracted by treatment with hydrochloric acid, whereas those of mol wt 120,000 and 76,000 were insoluble in hydrochloric acid and chloroform-methanol. Folch-Lees proteolipid protein was not found to be phosphorylated under the conditions studied. The endogenous phosphorylation of the proteins was not stimulated by adenosine 3',5'-monophosphate.     

Phosphorylation in vivo of four basic proteins of rat brain myelin

When rat brain myelin was examined by sodium dodecyl sulphate/polyacrylamideslab-gel electrophoresis followed by fluorography of the stained gel, it was found that a host of proteins of rat brain myelin were labelled 2, 4 and 24h after the intracerebral injection of H₃³²PO₄. Among those labelled were proteins migrating to the positions of myelin-associated glycoprotein, Wolfgram proteins, proteolipid protein, DM-20 and basic proteins. The four basic proteins with mol.wts. 21000, 18000 (large basic protein), 17000 and 14000 (small basic protein) were shown to be phosphorylated after electrophoresis in both acid-urea- and sodium dodecyl sulphate-containing gel systems followed by fluorography. The four basic proteins imparted bluish-green colour, after staining with Amido Black, which is characteristic of myelin basic proteins. The four basic proteins were purified to homogeneity. Fluorography of the purified basic proteins after re-electrophoresis revealed the presence of phosphorylated high-molecular-weight `polymers' associated with each basic protein. The amino acid compositions of the phosphorylated large basic protein and small basic proteins are compatible with the amino acid sequences. Proteins with mol.wts. 21000 and 17000 gave the expected amino acid composition of myelin basic proteins. Radiolabelled phosphoserine and phosphothreonine were identified after partial acid hydrolysis of the four purified basic proteins. The [³²P]phosphate–protein bond in the basic protein was stable at an acidic pH but was readily hydrolysed at alkaline pH, as would be expected of phosphoester bonds involving both serine and threonine residues. Double-immunodiffusion analysis demonstrated that the four phosphorylated proteins showed complete homology when diffused against antiserum to a mixture of small and large basic proteins. Since the four basic proteins of rat brain myelin were phosphorylated both in vivo and in vitro it is postulated that the same protein kinase is responsible for their phosphorylation in both conditions.     

Myelin protein changes with digestion of whole sciatic nerve in trypsin.

Whole mouse sciatic nerves were split and incubated in phosphate buffered saline (PBS) and in PBS containing various amounts of trypsin. After 24 hours of exposure to PBS alone there were no changes in the gel electrophoresis pattern of myelin proteins. During the same period of time, trypsin digested major amounts ofboth the main myelin protein (P_O) and the two basic proteins of myelin (P₁, P₂). The basic proteins were undetectable after 24 hours of 1% trypsin digestion while the main myelin protein was not completely digested. The amount of digestion of the myelin proteins was related to the concentration of trypsin and the time of digestion. Myelin proteins were demonstrated by staining with Coomassie blue, periodic acid Schiff (PAS) and by special indirect lighting techniques.     

The polyadenylated RNA directing the synthesis of the rat myelin basic proteins is present in both free and membrane-bound forebrain polyribosomes.

Free and membrane-bound polyribosomes were isolated from the forebrain of actively myelinating 24-day-old rats. The poly(A)+ RNA (polyadenylated RNA) extracted from both fractions was translated in vitro in reticulocyte lysates [Hall & Lim (1981) Biochem. J. 196. 327-336] in the presence or absence of a heterologous microsomal membrane fraction from dog pancreas. The rat myelin basic proteins synthesized in vitro were isolated by CM-cellulose chromatography and by immunoprecipitation with purified anti-(myelin basic protein) antibody. The large (mol.wt. 18 500) and small (mol.wt. 16 000) myelin basic proteins were translational products of poly(A)+ RNA from both free and membrane-bound polyribosomes. The identity of the myelin basic proteins was verified by analysis of peptides generated by the cathepsin D digestion of the immunoprecipitated proteins synthesized in vitro, in comparison with authentic rat myelin basic proteins. Although several other translational products of membrane-bound polyribosomal poly(A)+ RNA were modified when microsomal membranes were present during translation, molecular weights of the myelin basic proteins themselves were unchanged. The myelin basic proteins synthesized in vitro also did not differ significantly in size from the authentic myelin basic proteins, indicating that these membrane proteins are unlikely to be synthesized as substantially larger precursor molecules. The presence of the specific mRNA species on both free and membrane-bound polyribosomes is compatible with the extrinsic location of the myelin basic proteins on the cytoplasmic surface of the myelin membrane.     

Immunoblot identification of phosphorylated basic proteins of rat and rabbit CNS and PNS myelin: Evidence for four phosphorylated basic proteins and P2 in rat PNS myelin

The immunoblot technique permits the visualization of proteins following their separation on acrylamide gels, transfer to cellulose nitrate sheets and subsequent staining with antiserum. We have utilized this technique to demonstrate the presence of four basic proteins in rat PNS myelin with molecular weights of 21K, 18K, 17K, and 14K. Similarly, we demonstrated the presence of two basic proteins in rabbit PNS myelin (molecular weights of 21K and 18K). Exposure of the immunostained cellulose nitrate strips to X-ray film revealed the phosphorylation of four and two basic proteins in rat and rabbit PNS myelin, respectively. These basic proteins were present in the CNS myelin of the two species and were also phosphorylated. Because of the sensitivity of the immunoblot technique, it was also possible for us to visualize the P₂ protein in both rat and rabbit PNS myelin.     

THE ISOLATION AND LIPID COMPOSITION OF MYELIN-FREE AXONS FROM RAT CNS1

—Myelin-free axons were isolated from rat CNS using a modification of the method of De Vries et al. (1972). On a dry weight basis, the axons contained 15·2% lipid composed of 19·4% cholesterol, 56·9% phospholipid and 23·7% galactolipid with a weight ratio of cerebroside to sulfatide of 3·6-1. The phospholipid was composed of 11·0% ethanolamine phosphatides (44·4% in the plasmalogen form), 21·0% choline phosphatides (9·3% in the plasmalogen form), 4·5% sphingomyelin, 4·5% phosphatidyl serine, 4·3% phosphatidyl inositol, 3·0% diphosphatidyl glycerol and 8·5% unidentified phospholipid. The rat axons contained 0·18 μg ganglioside NeuNAc/mg dry wt. In addition to the 4 major brain gangliosides, the rat axons contained gangliosides G_D2 and G_D3. The axonal galactolipid could not be accounted for by myelin contamination as revealed by electron microscopy, absence of the characteristic ratio of myelin specific proteins in the axonal protein profile as shown by polyacrylamide gel electrophoresis, and the axonal level of the myelin marker enzyme 2′,3′-cyclic nucleotide-3′-phosphohydrolase. The relationship between lipids of axons isolated from rat and bovine CNS, and rat whole brain and CNS myelin is discussed.     

THE OCCURRENCE OF TWO MYELIN BASIC PROTEINS IN THE CENTRAL NERVOUS SYSTEM OF RODENTS IN THE SUBORDERS MYOMORPHA AND SCIUROMORPHA

Extracts containing myelin basic proteins have been prepared from CNS tissue of representatives of the three suborders of Rodentia—Myomorpha, Hystricomorpha and Sciuro-morpha. Analyses of the extracts by electrophoresis at low pH showed that one type (L) of myelin basic protein is present in the CNS of all of the rodents examined (rat, mouse, hamster, guinea pig, chinchilla, prairie dog, woodchuck and squirrel). This protein is comparable in molecular size and charge to the CNS myelin basic proteins found in several other mammalian orders. In the CNS of the myomorphs (rat, mouse, hamster) and sciuro-morphs (prairie dog, woodchuck, squirrel) there is an additional type (S) of myelin basic protein of higher cathodic mobility and smaller molecular size. This additional protein is absent from the CNS of the hystricomorphs (guinea pig, chinchilla). These findings indicate that the presence of two myelin basic proteins originally reported in the CNS of the inbred rat is not an anomaly of inbreeding. These data further suggest that the presence of a single L-type CNS myelin basic protein might be a general characteristic of hystricomorphs, while the presence of both L- and S-type CNS myelin basic proteins might be a general characteristic of the myomorphs and sciuromorphs. Analyses by electrophoresis at low pH failed to reveal differences in mobility among either the L-type or the S-type CNS myelin basic proteins of the different species. In contrast, when electrophoresis was carried out cathodically at high pH, species-related differences in mobility were observed among the L- and S-type CNS myelin basic proteins.     

Identification of the major sites of enzymic glycosylation of myelin basic protein

In the presence of porcine submaxillary N-acetylgalactosaminyltransferase and uridine diphospho-N-acetyl-D-galactosamine, approx. 1.2–1.5 mol of N-acetylgalactosamine were transfered per mol of myelin basic protein. Tritium-labelled N-acetylgalactosamine-labelled basic protein was digested with trypsin and the peptides were separated by HPLC and the radioactivity measured. Most of the radioactivity was associated with three peptide peaks (I, II and III) containing 17, 69 and 6% of the total radioactivity, respectively. The remaining radioactivity was distributed amongst several peptides, each containing less than 2.5% of the total radioactivity. Glycosylation of the basic proteins isolated from human, bovine and guine pig myelins showed that they were all equally good acceptors. In spite of differences in the peptide profiles of the basic proteins from different species, the distribution of radioactivity between the three peptide peaks was similar for all the species studies. The transfer of N-acetylgalactosamine to peptide II was much faster than to peptides I and III. The apparent K_m values of the three peptides were within a narrow range of 0.52–0.63 mM, whereas the V_max values were considerably different. The glycosylated peptide peaks (I, II and III) were separated by electrophoresis, the radioactivity measured, and amino acid compositions determined after hydrolysis. The major radioactive peptides of the human basic protein were identified with tryptic peptides containing the following sequences:

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Tissue and species conservation of the vertebrate and arthropod forms of the low molecular weight (16–18000) proteins of gap junctions

Summary Gap junctions have been isolated from four murine tissues, from rat and Xenopus laevis liver, and from Nephrops norvegicus (Norway lobster) hepatopancreas. The preparations of gap junctions from each vertebrate tissue contain a single major protein, M_r 16000, and those from Nephrops hepatopancreas a protein, M_r 18000. Immunocytochemical studies using affinity-purified antibodies raised against gap junctions from Nephrops show the junctional origin of the 18k protein. Immunological studies using Western blotting and biochemical studies using tryptic peptide mapping show no significant differences between the 16k junctional proteins of mouse and hence provide no evidence of tissue variation. These studies also suggest that the mouse, rat, and Xenopus 16 k proteins and the Nephrops 18 k protein share some common structural features.     

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.     

Myelin lipids: A phylogenetic study

The lipid composition of CNS and PNS myelin was studied in rat,Xenopus, trout andTorpedo. The main difference lay in the proportion of cerebrosides, which decreased in the sequence rat > Xenopus > Torpedo > trout. In additionTorpedo CNS and PNS myelins were extremely rich in sulfatides. In some respects,Torpedo appeared closer to tetrapods than trout. Otherwise the proportion of the different lipid classes did not reveal any clear evolutionary trends.The presence of hydroxylated galactolipids in CNS myelin was investigated in several additional species. Considerable amounts were found inTorpedo, Polypterus, Protopterus, lizard, and chicken, with the highest values in rat and anurans. Only very small amounts of hydroxylated cerebrosides were detected in trout and in axolotl, while newt had none. This parameter appears therefore of doubtful usefulness for phylogenetic studies. In contrast to myelin proteins, myelin lipids are of limited value for establishing phylogenetic relationship among vertebrates.Abbreviations CH cholesterol - CNS central nervous system - FA fatty acids - GC cerebrosides - HPTLC high-performance thin-layer chromatography - PC phosphatidylcholine - PE phosphatidylethanolamine and ethanolamine plasmalogens - PI phosphatidylinositol - PLP proteolipid protein - PNS peripheral nervous system - PS phosphatidylserine - SM sphingomyelin - SU sulfatides     

Lipid and Protein Alterations of Spinal Cord and Cord Myelin of Multiple Sclerosis

Abstract: A comprehensive study was carried out to clarify the chemical compositions of spinal cord, cord myelin, and myelin subfractions of multiple sclerosis (MS). The protein compositions of normal-appearing cerebral white matter and cerebral plaque and periplaque tissues were also analyzed for comparison. MS whole cord samples were found to contain higher amounts of water compared with normal samples. The total lipid contents were below normal. Among the individual lipids, cholesterol content remained unchanged, whereas cholesteryl esters appeared increased in MS cords. The acidic phospholipid concentrations were found to be lower than normal. Glycolipids, such as cerebrosides G_M4, G_M1, and G_D1b, which are abundant in myelin, were all decreased. However, the concentrations of G_M3 and G_D3, which are more characteristic of reactive astrocytes, were highly elevated. The total protein content of MS cord samples was decreased, and the decrease was attributable to the loss of myelin proteins as evidenced by the low recovery of myelin. The concentrations of myelin-specific proteins, such as proteolipid protein and myelin basic protein, were significantly reduced. Other changes in the protein compositions included the accretion of two low molecular weight proteins of approximately 11,000 and 12,000, and the appearance of a periodic acid-Schiff-positive protein with the same electrophoretic mobility as the P₀ protein. Analysis of the isolated myelin indicated that it had a grossly normal protein composition. However, the two low molecular weight proteins and the P₀ protein appeared to be enriched in an upper-phase cord subtraction. We attribute the appearance of the two low molecular weight proteins to the breakdown of proteolipid protein and/or myelin basic protein as a result of demyelination, and the appearance of P₀ to the involvement of PNS myelin. The latter finding provides the first biochemical evidence that in MS cord, remyelination can be achieved in part by invading Schwann cells and/or by the small number of Schwann cells that may be present in the cord.     

Partial deficiencies in the myelin proteins of developing mice heterozygous for the shiverer mutation

The central nervous system of the shiverer mouse is known to be severely deficient in myelin. Animals heterozygous for this autosomal-recessive mutation were crossed, and the myelin proteins were examined in the brains and spinal cords of shiverers and unaffected littermates among the offspring. In the brains and spinal cords of nine of the 14 unaffected littermates examined, the quantities of the myelin basic and proteolipid proteins were lower than normal. Furthermore, in the brains of heterozygotes 33 to ～ 150 days old, the myelin basic and proteolipid proteins were reduced in amount, compared to wild-type controls; the myelin basic protein was also present in subnormal amounts in the spinal cords from heterozygous animals at the ages of 17 to 150 days. More severe reductions in the quantities of the myelin proteins were observed in central nervous system tissue from homozygous shiverer mice, and the quantity of the myelin proteolipid protein in the central nervous system of the shiverer mouse, expressed as a ratio to the control value at each age, underwent a developmental decline. In heterozygotes, as well as shiverers, the peripheral nerves were also deficient in the P₁ and P_r proteins, which are the same as the basic proteins in rodent central nervous system myelin. The findings regarding heterozygotes suggest that the defective primary gene product in the shiverer mouse could be the myelin basic protein itself or a protein required for a rate-limiting step in the processing of the myelin basic protein.     

ASSOCIATION OF AXONALLY TRANSPORTED PROTEINS WITH GOLDFISH BRAIN MYELIN FRACTIONS

—The presence of rapidly transported axonal proteins in purified preparations of myelin has been investigated in the goldfish visual system. Fish were injected intraocularly with ³H proline and contralateral optic tecta were pooled 8–12 h later for purification of myelin. Three purification procedures were employed using continuous and discontinuous gradients of sucrose and continuous gradients of CsCl. All of the myelin preparations were found to have physical, chemical and enzymatic properties attributable to relatively pure preparations of myelin. The goldfish myelin differed from mammalian preparations in having a slightly lower density and in containing an additional major protein of approx. 45,000 mol. wt. All of the myelin preparations retained relatively high levels of axonally transported radioactivity with specific radioactivities which ranged from 70 to 80 per cent of that of the whole tectal homogenate. Acrylamide gel analysis showed the myelin-associated radioactivity to be confined to the higher molecular weight proteins with very little radioactivity associated with basic protein or proteolipid protein. Both the axonally transported radioactivity and the group of higher molecular weight proteins were found to be more concentrated in a myelin subfraction of relatively high density than in a subfraction of low density. The possible significance of the association of axonally transported proteins with myelin is discussed.     

Antigenic sites common to major fish myelin glycoproteins (IP) and to major tetrapod PNS myelin glycoprotein (Po) reside in the amino acid chains

The major myelin glycoproteins in the CNS and PNS of trout (IP) were enzymatically deglycosylated with endoglycosidase F (Endo F) and examined by electro-immunoblotting. Following carbohydrate removal and loss of concanavalin A affinity each of the four IP components underwent a similar reduction in molecular size, corresponding to approximately 3,000 daltons. Immunological cross-reactivities with anti-bovine P_o or anti-trout IP2 antibodies, were however fully retained by the Endo F cleavage products. This strongly implies that the antigenic sites shared by the mammalian P_o protein and the various intermediate glycoproteins of trout CNS and PNS are located in the protein portion. Immunoblot analysis of the PNS myelin proteins from various species of the major vertebrate classes with anti-trout IP2 antiserum revealed striking differences in the immunological properties of the individual P_o components which were not detected when anti-bovine P_o antiserum was used as a probe.