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Notes: Abstract— Border disease (BD) of sheep is caused by a virus in the genus Pestivirus that results in decreased myelination throughout the CMS when acquired congenitally. Pregnant ewes were inoculated with BD virus at 50 days of gestation, and myelin proteins were quantified in several regions of the CNS during prenatal and postnatal development of infected lambs for comparison with age-matched controls. Newborn field-infected lambs were also examined. Myelin basic protein (MBP), proteolipid protein (PLP), myelin-associated glycoprotein (MAG), and 2′,3′-cyclic nucleotide 3′-phosphodiesterase (CNP) were measured by densitometric scanning of western blots. Deficiencies in the myelin proteins were detected as early as 116 days of gestation, and the deficiencies of myelin proteins were most pronounced in the cerebellum at all ages examined. PLP and MBP increased from 10–30% of normal in cerebellar white matter at birth to 40–60% of normal at 6 months, suggesting some catch-up in the amount of compact myelin with development. MAG and CNP were between 70 and 80% of control levels in the cerebellum at birth and at 6 months. Similar results were obtained for the corpus callosum and spinal cord of infected lambs, but the deficiencies of myelin proteins were not as great. A common finding in all regions examined was that MBP and PLP were reduced more than MAG and CNP. This is probably explained by a greater deficit of compact myelin, in which MBP and PLP are localized, than of associated oli-godendroglial membranes, in which MAG and CNP are concentrated. Similar results have been obtained in several dysmyelinating mutants, pointing to common factors in virally and genetically caused hypomyelination. Key Words: Border disease—Myelin—Hypomyelination—Development—Sheeo.

Notes: Abstract: Hemispheres, spinal cords, and sciatic nerves were taken from taiep, carrier, and control rats at ages ranging from 1 day to 16 months. Absolute myelin yields from CNS taiep tissues peaked at ∼2 months and then decreased until they reached a low but stable level. Myelin yield from the affected hemispheres expressed as a percentage of age-matched controls decreased continuously from 2 weeks until it reached a stable level of ∼10–15%. The same was true for the spinal cords, but here the myelin yield reached a plateau at a slightly higher percentage of 20–25%. In comparison with control rats, isolated CNS myelin fractions from the affected rats had a greater content of high molecular weight proteins. Western blot analyses of CNS homogenates revealed that myelin basic protein (MBP), proteolipid protein, and 2′,3′-cyclic nucleotide 3′-phosphodiesterase were all present but decreased to levels generally consistent with the deficiencies of myelin. However myelin-associated glycoprotein (MAG) levels always were reduced much more than those of the other three myelin proteins, and at younger ages the apparent molecular weight for MAG was increased in the mutants. Western blot analyses of sciatic nerve homogenates showed that the levels of MBP, MAG, and P0 were not significantly different in control and mutant animals. These results suggested an early hypomyelination of the CNS, with peak levels of myelin at 2 months, followed by a prolonged period of myelin loss, until a very low but stable myelin level was reached. The consistently greater loss of MAG, in comparison with other CNS myelin proteins, is different from most other hypomyelinating mutants in which MAG is relatively preserved in comparison with the proteins of compact myelin. This might be due to microtubular abnormalities in the taiep mutant interfering with transport of myelin proteins and having the greatest effect on MAG because of its most distal location in the periaxonal oligodendroglial membranes.

Notes: Abstract: The glycoprotein component in rat brain reacting most strongly with Galanthus nivalis agglutinin (GNA) on western blots migrates as an 85-kDa band. GNA identifies mannose-rich oligosaccharides because it is highly specific for terminal α-mannose residues. After purification of this 85-kDa glycoprotein band by chromatography on GNA-agarose and preparative gel electrophoresis, binding of other lectins demonstrated the presence of fucose and a trace of galactose, but no sialic acid. Treatment with N-Glycanase or endoglycosidase H produced a 65-kDa band, indicating that it consisted of about one-fourth N-linked oligomannosidic carbohydrate moieties. High-performance anion-exchange chromatography and fluorescence-assisted carbohydrate electrophoresis indicated that the major carbohydrate moiety is a heptasaccharide with the structure Manα1-6(Manα1-3)Manα1-6(Manα1-3)Manβ1-4Glc-NAcβ1-4GlcNAc (Man5GlcNAc2). Determination of amino acid sequences of peptides produced by endoproteinase digestion demonstrated that this 85-kDa mannose-rich glycoprotein component contained the SHP substrate-1 for phosphotyrosine phosphatases and at least one other member of the signal-regulatory protein (SIRP) family. The unusually high content of oligomannosidic carbohydrate moieties on these receptor-like members of the immunoglobulin superfamily in neural tissue could be of functional significance for intercellular adhesion or signaling.

Notes: Abstract— A low molecular weight glycoprotein has been demonstrated in myelin isolated from immature rat brains. Both short term and long term fucose incorporation studies have identified this protein in the proteolipid protein region of a sodium dodecyl sulfate, polyacrylamide gel. A 1.7-2.1 fold increase in radioactive fucose in this glycoprotein relative to the major myelin glycoprotein was seen after long term fucose incorporation (21 days) compared to short term incorporation (18–22 h). The demonstration that this fucose-labelled protein is distinguishable from that of proteolipid protein was achieved by a variety of independent techniques. One technique involved a comparison of ether-ethanol extracted, freshly isolated, myelin with myelin extracted with chloroform-methanol. Treatment of isolated myelin with chloroform-methanol results in the solubilization of the proteolopid protein and its subsequent absence on gel electrophoresis while, in contrast, an enhancement of fucose label was observed in the same region of the polyacrylamide gel. Another procedure involved the electrophoretic separation of the radioactive fucose peak from that of proteolipid protein by employing a continuous, phosphate buffered, gel system. Finally carbohydrate analysis by gas-liquid chromatography of a partially purified proteolipid protein fraction did not reveal significant amounts of carbohydrates which are characteristic of glycoproteins. The identification of this minor glycoprotein comigrating with proteolipid protein indicates, therefore, a greater complexity associated with the purified myelin membrane than has been previously demonstrated.

Notes: Myclin was purified from bovine and human midbrain at various stages of prenatal and postnatal development. Basic protein and proteolipid proteins were the major individual proteins at all stages. The specific activity of 2′3′-cyclic nucleotide 3′-phosphohydrolase remained constant in the bovine myclin during development but decreased slightly in human myelin. A high molecular weight glycoprotein with electrophoretic mobility similar to that previously reported in rodent myelin (QUARLES et al., 1973) was present in both bovine and human myelin at all stages of development. The intensity of staining of this glycoprotein with periodic acid-Schiff reagents per mg total myelin protein was less in mature bovine and human myelin than in rat myelin.

Notes: Abstract— Proteins and glycoproteins in a myelin fraction isolated from Quaking mutant mice were separated by polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate and stained with Fast Green or with periodic acid-Schiff reagents. Double labelling experiments with [3H]fucose and [14C]fucose were also used to compare glycoproteins in myelin from the mutant mice with those from control mice. In the myelin fraction from the Quaking mice the basic proteins and proteolipid protein were decreased relative to the high molecular weight proteins. Some glycoproteins which are present in small amounts in myelin from normal mice were increased relative to the major glycoprotein in the myelin fraction of the Quaking mice. Furthermore, the major myelin-associated glycoprotein was shifted toward higher apparent molecular weight in comparison with controls of the same age or even with 9-day-old controls. The abnormal glycoproteins in the mutant myelin fraction could be a factor in the impairment of myelination.

Notes: Abstract— Intracerebral injections of radioactive fucose into developing rats resulted in specific labelling of the brain glycoproteins in their fucose moieties. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate revealed that the radioactive glycoproteins were very heterogeneous with regard to molecular weight. A procedure utilizing [3H]fucose and [14C]fucose together with double-label counting techniques was developed for comparing the electrophoretic patterns of newly synthesized glycoproteins from different samples of tissue. By the use of this procedure we showed that the incorporation of radioactive fucose into the glycoproteins of high mol. wt. was relatively greater in the brains of 5-day-old rats than in those of 25-day-old rats. Intracerebral injection of N-[Ac-3H]acetyl-d-mannosamine resulted in a high degree of specificity for the labelling of sialic acid moieties in glycoproteins and gangliosides. The ratio of the d.p.m. of N-[3H]acetylmannosamine incorporated into glycoproteins to the d.p.m. incorporated into gangliosides was higher in 5-day-old rats than in 15- or 25-day-old rats. Experiments in which 15-day-old rats were injected with a mixture of [14C]fucose and N-[3H]acetylmannosamine showed that there were differences in the relative degrees of incorporation of the two radioactive precursors into the various glycoproteins. The greatest incorporation of [14C]fucose relative to that of N-[3H]acetylmannosamine occurred in some of the glycoproteins of smaller mol. wt.

Notes: 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.

Notes: —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.

Notes: Abstract— A subcellular fraction (called the 0·85-fraction) was isolated from the brains of Jimpy mice by a procedure for obtaining myelin of high purity from immature normal brains. The yield of this fraction obtained from 17-day-old Jimpy mice was only 5 per cent of that from age matched controls. In the electron microscope, the O·85-fractions obtained from 9- and 17-day-old control mice showed many multilayered whorls of myelin, whereas the corresponding fraction from the Jimpy mice was free of multilayered structures which could be recognized as myelin. Basic proteins, proteolipid protein and galactocerebrosides could not be detected in the 0·85-fraction from Jimpy mice although they were major components of the 0·85-fractions from both 9- and 17-day-old control mice. The specific activity of 2′,3′-cyclic nucleotide 3′- phosphohydrolase in the Jimpy 0·85-fraction was only 15 per cent of the value for controls. These results can be explained either by the 0·85-fraction from Jimpy brain being a very abnormal ‘myelin’ or by its being primarily non-myelin contaminants. Little or none of the major glycoprotein found in normal myelin fractions was found in the 0·85-fraction from Jimpy brains. This finding is strong evidence indicating that the glycoprotein is closely associated with normal myelin in situ.