Regulation of Myelination: Biosynthesis of the Major Myelin Glycoprotein by Schwann Cells in the Presence and Absence of Myelin Assembly

Schwann cell biosynthesis of the major myelin glycoprotein, P0, was investigated in the crush-injured adult rat sciatic nerve, where there is myelin assembly, and in the permanently transected nerve, where there is no myelin assembly. Endoneurial fractions from desheathed rat sciatic nerves distal to the crush were compared with similar fractions from the permanently transected nerves at 7, 14, 21, 28, and 35 days after injury. The Schwann cell expression of this asparagine-linked glycoprotein was evaluated after sodium dodecyl sulfate-pore gradient electrophoresis by Coomassie Blue and silver stain and by autoradiography after direct overlay of radioiodinated lectins [wheat germ agglutinin, gorse agglutinin, and concanavalin A (Con A)]. As evaluated by these parameters, the concentration of P0 after crush decreased and subsequently increased as a function of time after injury, corresponding to the events of demyelination and remyelination. After permanent transection, the P0 concentration decreased following the same time course found after crush. At subsequent time points, P0 could not be detected with Coomassie Blue stain, silver stain, or wheat germ agglutinin. Both gorse agglutinin and Con A, however, showed binding to P0. Radioactive precursor incorporation studies with [3H]fucose or [3H]-mannose into endoneurial slices at 35 days posttransection revealed active oligosaccharide processing of P0 glycoprotein by Schwann cells in this permanent transection model. Compared with other Schwann cell glycoproteins in the transected nerve, the highest level of incorporation of [3H]mannose was found in P0 which accounted for 42.7% of the incorporated label. In contrast, incorporation of [3H]mannose into endoneurial slices at 35 days after crush accounted for only 13.3% in P0. In addition, higher levels of Con A binding were observed in P0 in the transected nerve compared with the contralateral control or the crushed nerve. Both the [3H]fucose incorporation and gorse agglutinin binding to P0 in the transected nerve suggest posttranslational processing of this glycoprotein in the Golgi apparatus; however, the absence of wheat germ agglutinin binding, the high level of mannose incorporation, and the high level of binding by Con A imply that additional processing steps are required prior to its assembly into myelin.     

External labeling of galactose in surface membrane glycoproteins of the intact myelin sheath.

The molecular organization of surface galactose residues in glycoproteins of the intact myelin sheath was investigated using the enzymatic membrane probe, galactose oxidase. Rat spinal cords treated under physiological conditions with this nonpermanent probe were labeled specifically in galactose residues by reduction with tritiated sodium borohydride. The enzymatically modified proteins from isolated myelin were analyzed electrophoretically and their specific radioactivities determined. Results indicated tritium label associated with a surprising variety of high molecular weight proteins. The most extensively labeled peak corresponded to the major myelin glycoprotein as indicated by the coincidence of tritium label with that of [14C]fucose used as an internal marker for the glycoproteins. The radioactivity associated with this protein was 1.1 to 2.7 times higher after treatment with galactose oxidase when compared to reduction in the absence of the enzyme and 1.4 to 4.8 times higher when oxidized and reduced after prior treatment with neuraminidase. The results suggest a complex heterogeneity of minor glycoproteins associated with isolated myelin. It is concluded that from this complexity of glycoproteins, a major glycoprotein is at least partially localized on the external surface of either the intact myelin sheath or the closely associated oligodendroglial plasma membrane. Such a localization of this glycoprotein and the probable localization of the other glycoproteins enhances their potential role in specific interactions in the process of mpyelination or myelin maintenance.     

EVIDENCE FOR THE CLOSE ASSOCIATION OF A GLYCOPROTEIN WITH MYELIN IN RAT BRAIN

Abstract— Myelin was purified from rats which had been injected intracerebrally with radioactive fucose in order to label specifically the glycoproteins. Myelin contained a small amount of fucose-labelled glycoproteins in comparison to that in other subcellular fractions, but polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulphate revealed a unique pattern of radioactive glycoproteins dominated by a major peak. The same glycoprotein was not prominent in the other subcellular fractions which were examined. This major glycoprotein in the myelin fraction was also labelled after injection with [³H]glucosamine or N -[³H]acetylmannosamine. It was the most intensely staining myelin protein when gels were treated with periodic acid-Schiff reagents, an indication that, in terms of protein-bound carbohydrate, it is the major glycoprotein in the myelin fraction. The glycoprotein was present in myelin purified from rats ranging in age from 14 days to 14 months. Extensive recycling of the myelin through the purification procedures did not significantly reduce the amount of glycoprotein in the myelin. Double label experiments with [³H]fucose and [¹⁴C]fucose were used to compare glycoproteins in myelin purified from white and grey matter, respectively, and from mixed homogenates of myelinated and unmyelinated brain. The results obtained from these experiments suggested that the glycoprotein is closely associated with myelin and that it is not in an unrelated contaminating structure. Possible locations of the glycoprotein are discussed. They include the myelin membrane itself, the oligodendroglial plasma membrane, and the axolemma of myelinated axons.     

Effects of Monensin on Assembly of Po Protein into Peripheral Nerve Myelin

Abstract: The ionophore monensin has been used in a variety of systems to block secretion of glycoproteins or assembly of glycoproteins into membranes. We examined the effects of monensin on assembly of the Po glycoprotein into PNS myelin, and compared this agent with the glycosylation inhibitor tunicamycin in our system. Sciatic nerves from 9-day-old rat pups were sliced and incubated in vitro . Electron microscopy of the Schwann cells in slices incubated with monensin revealed extensive swelling of the Golgi complex. Incubation with 10⁻⁷ M monensin inhibited total protein synthesis by about 20% and fucose incorporation into protein about 35%. Following isolation of myelin, proteins were separated by sodium dodecyl sulfate gel electrophoresis. Monensin inhibited the appearance of Po in myelin, while causing its accumulation in a denser membrane fraction. In addition, a slightly faster-migrating species of P_o labeled with both [³H]fucose and [¹⁴C]glycine was observed in all fractions. Assembly of basic proteins into myelin was not affected. Preincubation with 10 μg/ml tunicamycin for 30 min prior to incubation with [³H]fucose and [¹⁴C]glycine for 2 h resulted in a 65% decrease in [³H]fucose incorporation into P_o, and the appearance of a new [¹⁴C]glycine-labeled peak that migrated in the region of the 23K protein reported by Smith and Sternberger. [³H]Fucose incorporation was inhibited earlier, and to a greater extent, than protein synthesis. Our results show that processing of the P_o glycoprotein is sensitive to both monensin and tunicamycin, and that monensin partially blocks assembly of P_o into myelin.     

A LOW MOLECULAR W eight GLYCOPROTEIN ASSOCIATED WITH ISOLATED MYELIN: DISTINCTION FROM MYELIN PROTEOLIPID PROTEIN

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.     

Incorporation of newly formed lecithin into peripheral nerve myelin

Radioactive choline was used to study the metabolism and movement of choline-containing phospholipids in peripheral nerve myelin of adult mice. Incorporation at various times after intraperitoneal injection was measured in serial segments of sciatic nerve as well as in myelin isolated from those segments. At no time (1 h to 35 days) could a proximal-distal difference in the extent of labeling be demonstrated. This finding suggests that incorporation of precursor choline phospholipids into nerve membranes is a local event, with little contribution from the neuronal perikaryon via axoplasmic transport. Autoradiographic investigations were undertaken to elucidate the pattern of movement of radioactive choline-labeled phospholipids, predominantly lecithin, into the myelin sheaths of the sciatic nerve. A sequence of autoradiographs was prepared from animals sacrificed between 20 min and 35 days after a microinjection of precursor directly into the nerve. Analysis of these autoradiograms revealed that labeling is initially concentrated in the Schwann cell cytoplasm. Later, the label moves first into the outer regions of the myelin sheaths and is eventually distributed evenly throughout the inner and outer layers of the sheath. At no time is there a build-up of label in the axon. The rate of uptake of precursor and subsequent redistribution of lecithin into the myelin were also examined in frog sciatic nerve (18 degrees C). Both uptake and redistribution processes were considerably slower in the cold-blooded animal.     

Localization of Phospholipid Synthesis to Schwann Cells and Axons

Quantitative electron microscopic autoradiography was used to detect and characterize endoneurial sites of lipid synthesis in mouse sciatic nerve. Six tritiated phospholipid precursors (choline, serine, methionine, inositol, glycerol, and ethanolamine) and a protein precursor (proline) were individually injected into exposed nerves and after 2 h the mice were perfused with buffered aldehyde. The labeled segments of nerve were prepared for autoradiography with procedures that selectively remove nonincorporated precursors and other aqueous metabolites, while preserving nerve lipids (and proteins). At both the light and electron microscope levels, the major site of phospholipid and protein synthesis was the crescent-shaped perinuclear cytoplasm of myelinating Schwann cells. Other internodal Schwann cell cytoplasm, including that in surface channels, Schmidt-Lanterman incisures, and paranodal regions, was less well labeled than the perinuclear region. Newly formed proteins were selectively located in the Schwann cell nucleus. Lipid and protein formation was also detected in unmyelinated fiber bundles and in endoneurial and perineurial cells. Tritiated inositol was selectively incorporated into phospholipids in both myelinated axons and unmyelinated fibers. Like inositol, glycerol incorporation appeared particularly active in unmyelinated fibers. Quantitative autoradiographic analyses substantiated the following points: myelinating Schwann cells dominate phospholipid and protein synthesis, myelinated axons selectively incorporate tritiated inositol, phospholipid precursors label myelin sheaths and myelinated axons better than proline.     

Phosphorylation and Fucosylation of Myelin Protein In Vitro by Sciatic Nerve from Developing Rats

Abstract: Proteins of the paniculate fraction of sciatic nerve of rats ranging from 1 to 55 days of age were analyzed by polyacrylamide gel electrophoresis. The major myelin protein, P₀, could not be detected at 1 day of age, but by 10 days it comprised from 15 to 20% of the particulate protein, the same proportion as in adult rats. Growth of nerve continued throughout the period studied. Rat sciatic nerves were incubated with [³²P]orthophosphate or [³H]fucose. Particulate matter proteins from sciatic nerve (and in certain cases proteins of myelin purified from sciatic nerve) were separated by polyacrylamide disc gel electrophoresis and the distribution of protein and of radioactivity along the gels was determined. [³²P]Phosphate appeared to label all myelin proteins. Labeling with fucose was more specific; myelin basic proteins were not fucosylated. A developmental study showed that sciatic nerves from 2-day-old rats could incorporate radioactive fucose and [³²P]-phosphate into several proteins at the P₀ region of polyacrylamide gels. Specific radioactivity of [³H]fucose in P₀ protein was highest in preparations from 5-day-old rats and declined by 80% over the next 5 days as it was diluted by accumulating myelin. The specific radioactivity of incorporated [³²P] phosphate was high at the early age points and declined as a result of the accumulation of compact myelin. The results indicate an association of fucosylation and/or phosphorylation with some step in the formation of myelin.     

Labelling by axonal transport of myelin-associated proteins in the rabbit visual pathway.

After intraocular injections of [3H]leucine, six regions of the visual pathway of adult rabbit were used to study the spatio-temporal pattern of the slow anterograde axonal transport of radioactive proteins associated with the particulate fraction, the water-soluble fraction and the myelin fraction. Unlike other fractions, myelin-associated labelled proteins represented a time-constant (for a given region) percentage of total tissue radioactivity. This percentage increased from the first half to the second half of the optic nerve and remained high in the chiasma and tract. The peak specific radioactivity of myelin decreased in the same direction. Myelin proteins were separated by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis and the labelling patterns obtained in different regions and at different survival times were compared. At the peak of myelin radioactivity of a given region the label was typically associated with four protein bands, L1, L2, L3 and L4, of 40000, 44000, 62000, and 68000 mol.wts. respectively. The basic protein, the proteolipid protein and the W1 component (mol.wt. 51000-53000) of the Wolfgram proteins were not significantly labelled. The radioactivity associated with the W2 component (mol.wt 60000) of the Wolfgram proteins could be derived from the closely migrating L3 component. At shorter survival times no clear labelling pattern could be detected. At longer survival times radioactivity was almost totally localized around band L3. The results presented underline the importance of choosing appropriate experimental conditions to obtain a consistent labelling pattern of myelin-associated proteins and to investigate the possible mechanism responsible for this phenomenon.     

Posttranslational Protein Modification: Biosynthetic Control Mechanisms in the Glycosylation of the Major Myelin Glycoprotein by Schwann Cells

The posttranslational processing of the asparagine-linked oligosaccharide chain of the major myelin glycoprotein (P0) by Schwann cells was evaluated in the permanently transected, adult rat sciatic nerve, where there is no myelin assembly, and in the crush injured nerve, where there is myelin assembly. Pronase digestion of acrylamide gel slices containing the in vitro labeled [3H]mannose and [3H]fucose P0 after electrophoresis permitted analysis of the glycopeptides by lectin affinity and gel filtration chromatography. The concanavalin A-Separose profile of the [3H]mannose P0 glycopeptides from the transected nerve revealed the high-mannose-type oligosaccharide as the predominant species (72.9%), whereas the normally expressed P0 glycoprotein that is assembled into the myelin membrane in the crushed nerve contains 82.9-91.9% of the [3H]mannose radioactivity as the complex-type oligosaccharide chain. Electrophoretic analysis of immune precipitates verified the [3H]mannose as being incorporated into P0 for both the transected and crushed nerve. The high-mannose-type glycopeptides of the transected nerve isolated from the concanavalin A-Sepharose column were hydrolyzed by endo-beta-N-acetylglucosaminidase H, and the oligosaccharides were separated on Biogel P4. Man8GlcNAc and Man7GlcNAc were the predominant species with radioactivity ratios of 12.5/7.2/1.4/1.0 for the Man8, Man7, Man6, and Man5 oligosaccharides, respectively. Jack bean alpha-D-mannosidase gave the expected yields of free Man and ManGlcNAc from these high-mannose-type oligosaccharides. The data support the notion that at least two alpha-1,2-mannosidases are responsible for converting Man9GlcNAc2 to Man5GlcNAc2. The present experiments suggest distinct roles for each mannosidase and that the second mannosidase (I-B) may be an important rate-limiting step in the processing of this glycoprotein with the resulting accumulation of Man8GlcNAc2 and Man7GlcNAc2 intermediates. Pulse chase experiments, however, demonstrated further processing of this high-mannose-type oligosaccharide in the transected nerve. The [3H]mannose P0 glycoprotein with Mr of 27,700 having the predominant high-mannose-type oligosaccharide shifted its Mr to 28,500 with subsequent chase. This band at 28,500 was shown to have the complex-type oligosaccharide chain and to contain fucose attached to the core asparagine-linked GlcNAc residue. The extent of oligosaccharide processing of this down-regulated glycoprotein remains to be determined.     

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.     

Localization and characterization of newly synthesized nuclear RNA in isolated rat hepatocytes

The ultrastructural localization of extranucleolar RNA transcribed during short periods of labeling with [³H]UdR in isolated rat hepatocytes is studied using high resolution autoradiography combined with a preferential staining for ribonucleoproteins. The labeled RNA is characterized in parallel experiments by electrophoresis on exponential polyacrylamide gels under denaturing conditions. It is demonstrated, using ultrathin sections of Epon embedded cells, that after 2 or 5 min of labeling the radioactivity is predominantly associated with perichromatin fibrils localized frequently in proximity to condensed chromatin regions. Autoradiographs of ultrathin frozen sections confirm the perichromatin localization of the rapidly labeled RNA. The great majority of this label is represented by growing chains of pre-mRNA. After 2 or 4 h of non-radioactive chase following the radioactive incubation, the major part of silver grains is still associated with perichromatin fibrils but is found distributed rather homogeneously throughout the nucleoplasm. This would suggest a migration of a part of the labeled perichromatin fibrils towards the interchromatin regions. At this time the label is characterized as pre-mRNA of intermediate size. These findings are discussed in the context of other recent investigations of the localization of newly transcribed nuclear RNA.     

[3 5S]Sulfate incorporation into myelin glycoproteins I. Central nervous system

The in vivo incorporation of [^{3 5}S]sulfate and [³H]fucose into rat brain myelin was investigated. Most of the ^{3 5}S in the myelin was in sulfatide, but about 4% was associated with the residual proteins after chloroform/methanol extraction. Polyacrylamide gel electrophoresis of these proteins indicated that the major ^{3 5}S-labeled component corresponded to the major fucose-labeled glycoprotein. The labeling of this predominant glycoprotein with sulfate was more selective than with fucose, since there was relatively little incorporation of sulfate into some of the minor fucose-labeled glycoproteins. There was little or no ^{3 5}S associated with proteolipid or basic protein on polyacrylamide gels. The fucose-labeled glycoproteins were converted to glycopeptides by pronase digestion and separated into two major classes by gel filtration on Sephadex-G50. Only the higher molecular weight class contained significant amounts of ^{3 5}S. The association of ^{3 5}S with the glycopeptides was not due to binding of sulfatide or free inorganic sulfate. The results indicate that the predominant myelin-associated glycoprotein in rat brain is sulfated.     

[3 5S]Sulfate incorporation into myelin glycoproteins II. Peripheral nervous tissue

The in vivo incorporation of [^{3 5}S]sulfate, [³H]fucose and [³H]leucine into sciatic nerve myelin was investigated. Polyacrylamide gel electrophoresis of the proteins indicated that the ^{3 5}S-labeling of proteins occurred almost exclusively in the major myelin protein. A smaller myelin glycoprotein migrating just ahead of the major one was labeled with [³H]fucose but did not incorporate ^{3 5}S to a detectable extent. There was little or no ^{3 5}S associated with basic proteins on polyacrylamide gels when the proteins were extracted with chloroform/methanol. Fucose-labeled myelin glycoproteins were converted to glycopeptides by pronase digestion. The glycopeptides gave a single peak on Sephadex G-50 in which the ³H and ^{3 5}S coincided. The association of ^{3 5}S with glycopeptides was not caused by binding of sulfatide or free inorganic sulfate. This study shows that the major myelin protein in the sciatic nerve of the rat is glycosylated and sulfated.     

Effects of pronase and neuraminidase treatment on a myelin-associated glycoprotein in developing brain.

Rats (14 days old) were injected with [14c]fucose and young adult rats with [3H]fucose in order to label the myelin-associated glycoproteins. As previously reported, the major [14C]fucose-labelled glycoprotein in the immature myelin had a higher apparent molecular weight on sodium dodecyl sulphate/polyacrylamide gels that the [3H]fucose-labelled glycoprotein in mature myelin. This predominant doubly labelled glycoprotein component was partially purified by preparative gel electrophoresis and converted to glycopeptides by extensive Pronase digestion. Gel filtration on Sephadex G-50 separated the glycopeptides into several clases, which were designted A,B, C AND D, from high to low molecular weight. The 14C-labelled glycopeptides from immature myeline were enriched in the highest-molecular-weight class A relative to the 3H-labelled glycopeptides from mature myelin. Neuraminidase treatment of the glycoprotein before Pronase digestion greatly decreased the proportion of glycopeptides fractionating in the higher-molecular-weight classes and largely eliminated the developmental differences that were apparent by gel filtration. However, neuraminidase treatment did not decrease the magnitude of the developmental difference revealed by electrophoresing the intact glycoprotein on sodium dodecyl sulphate gels, although it did decrease the apparent molecular weight of the glycoprotein from both the 15-day-old and adult rats by an amount comparable in magnitude to that developmental difference. The results from gel filtration of glycopeptides indicate that there is a higher content of large molecular weight, sialic acid-rich oligosaccharide units in the glycoprotein of immature myelin. However, the higher apparent molecular weight for the glycoprotein from 15-day-old rats on sodium dodcyl sulphate gels is not due primarily to its higher sialic acid content.     

Metabolism of Functional Groups Modifying the CNS Myelin-Associated Glycoprotein

We have examined the metabolic turnover of the peptide backbone of the CNS myelin-associated glycoprotein (MAG) and of the fucose and sulfate groups modifying this protein. Rats (20 or 90 days old) were injected intracranially with mixtures of [3H]fucose and [14C]glycine, [3H]glycine and [35S]sulfuric acid, or [3H]fucose and [35S]sulfuric acid. At times ranging from 30 min to 4 weeks later, myelin was isolated, and radioactivity in MAG was determined following electrophoretic separation. Following the peak of incorporation, glycine-derived radioactivity in the MAG peptide backbone declined several-fold during the first week and was then metabolically stable (half-life much greater than 1 month). Declines with time in [3H]fucose- and [35S]sulfate-derived radioactivity in MAG were similar to that of [3H]glycine, an observation indicating that the fucose and sulfate groups modifying MAG are metabolized together with the peptide backbone as a single metabolic entity. These results were confirmed by experiments involving selective immunoprecipitation of MAG. The rates of incorporation of labeled glycine, fucose, and sulfate into MAG all decreased approximately 12-fold between 20 days of age and adulthood, a finding providing further evidence for concerted turnover of the entire molecule. Because of this concerted turnover, we suggest that functional groups modifying MAG serve some permanent structural role in protein configuration.     

An endogenous lectin "CSL" interacts with glycoprotein components in peripheral nervous system myelin

An endogenous mannose binding lectin isolated from the rat cerebellum, CSL, was localized using immunocytochemical techniques in adult and in developing rat sciatic nerve. The lectin is present in Schwann cell cytoplasm and in compact myelin. It is present very early in Schwann cells and persists throughout postnatal sciatic nerve development. Endogenous ligands for the lectin were detected using iodinated-CSL binding to proteins blotted after polyacrylamide gel electrophoresis. Probably PO and MAG glycoproteins are specifically bound by CSL in contrast with numerous other Concanavalin A binding glycoproteins. A 31 kDa glycoprotein identified in purified preparations of axons of young rats also reacts with CSL. Based on the present developmental biochemical and immunochemical studies, an hypothetical scheme is proposed for the molecular basis of axon-Schwann cell interactions and of stabilization of compact myelin.     

Alteration of ethanolamine glycerophospholipid turnover in trembler dysmyelinating mutant: An analysis of the sciatic nerve by biochemistry and radioautography

The turnover of phospholipids was compared in peripheral nerves of Trembler dysmelinating mutant and control mice, after intraperitoneal and local injection of labeled ethanolamine. In the mutant sciatic nerve, neurochemical analysis showed that [¹⁴C]ethanolamine is incorporated into EGP (ethanolamine glycerophospholipids) of the sciatic nerve at a much higher rate in Trembler mutant than in control mice. Furthermore the decay rate of ¹⁴C-labeled EGP is faster in Trembler than in normal animals. The accelerated turnover of EGP in Trembler sciatic nerve affects the diacyl-EGP while the renewal of the alkenylacyl-EGP (plasmalogens) is slower than in controls. Quantitative radioautographic study at the ultrastructural level corroborate that the initial increase of the label in Trembler nerve fibers was different in axons, Schwann cells and myelin sheaths. EM radioautographs reveal indeed that the high label content observed in Trembler axons takes place preferentially in the myelinated portions of axons and drops within 1 week. In both myelinated and unmyelinated segments of the axons, the majority of the radioactivity was contained in axolemma and smooth axoplasmic reticulum. The 10-fold increase of label found in the myelin sheath of Trembler nerve fibers at 1 day raises the question of the origin of the labeled EGP, either by a stimulated synthesis in Schwann cells or by transfer from axonally transported phospholipids. In contrast, the label of axons, Schwann cells and myelin sheaths of control nerve remains stable during the same period.     

Phospholipid Metabolism in Mouse Sciatic Nerve In Vivo

To probe the activities of various pathways of lipid metabolism in peripheral nerve, six phospholipid-directed precursors were individually injected into the exposed sciatic nerves of adult mice, and their incorporation into phospholipids and proteins was studied over a 2-week period. Tritiated choline, inositol, ethanolamine, serine, and glycerol were mainly used in phospholipid synthesis; in contrast, methyl-labeled methionine was primarily incorporated into protein. Phosphatidylcholine was the main lipid formed from tritiated choline, glycerol, and methionine precursors. Phosphatidylserine, phosphatidylethanolamine, and phosphatidylinositol were the main lipids formed from serine, ethanolamine, and inositol, respectively. With time there was a shift in label among phospholipids, with higher proportions of choline appearing in sphingomyelin, glycerol in phosphatidylserine, ethanolamine in phosphatidylethanolamine (plasmalogen), and inositol in polyphosphoinositides, especially phosphatidylinositol 4,5-bisphosphate. We suggest that the delay in formation of these phospholipids, which are concentrated in peripheral nerve myelin, may, at least in part, be due to their formation at a site(s) distant from the sites where the bulk of Schwann cell lipids are made. We propose that separating the synthesis of these myelin-destined lipids to near the Schwann cell's plasma membrane would facilitate their concentration in peripheral nerve myelin sheaths. At earlier labeling times, ethanolamine and glycerol were more actively incorporated into phosphatidylcholine and phosphatidylinositol, respectively, than later. The transient labeling of these phospholipids may reflect some unique role in peripheral nerve function.     

EVIDENCE THAT THE MAJOR PROTEIN IN RAT SCIATIC NERVE MYELIN IS A GLYCOPROTEIN

Evidence is presented that the major protein of rat sciatic nerve myelin is a glycoprotein. When myelin proteins were separated by polyacrylamide gel electrophoresis, the major band which was stained with amido black–Coomassie blue was also stained with periodic acid-Schiff reagents for carbohydrate. Radioactive labelling of myelin in vivo with [³H]leucine and [¹⁴C]fucose, followed by electrophoresis of the proteins, indicated that with both isotopes the major labelled peak corresponded to the major stained band. In addition, a second smaller peak of [¹⁴C]fucose migrated ahead of the major peak. Delipidated myelin contained galactose, mannose, fucose and sialic acid.