Cold Blockade of Axonal Transport Activates Premitotic Activity of Schwann Cells and Wallerian Degeneration

Between 3 and 4 days after transection of cat sciatic nerve, Schwann cell-associated premitotic activity spreads anterogradely along degenerating distal nerve stumps at a rate of approximately 200 mm/day. We investigated whether fast anterograde axonal transport contributes to the initiation of this component of Wallerian degeneration. Axonal transport was blocked in intact and transected cat sciatic nerves by focally chilling a proximal segment to temperatures below 11 degrees C for 24 hr. Incorporation of [3H]thymidine (a marker of premitotic DNA synthesis) was then measured 3 and 4 days posttransection in cold blocked- and control-degenerating nerves. Effects of cold block prior to and concomitant with nerve transection were studied. Results failed to support the hypothesis that Schwann-cell premitotic activity after axotomy is associated with entry into the axon of mitogenic substances and their anterograde fast transport along the distal stump. Instead, data suggested that progressive anterograde failure of fast anterograde transport distal to transection serves to effect the Schwann-cell premitotic response to axotomy.     

Biosynthesis of Neutral Glucocerebroside Homologues in the Absence of Myelin Assembly After Nerve Transection

The biosynthesis of myelin-associated glycolipids during various stages of myelination was studied by in vitro incorporation of [3H]Gal, [3H]Glc, or [35S]sulfate into the endoneurium of rat sciatic nerve. In the normal adult nerve, where the level of myelin assembly is substantially reduced and Schwann cells are principally involved in maintaining the existing myelin membrane, [3H]Gal was primarily incorporated into monogalactosyl diacylglycerol (MGDG) and the galactocerebrosides (GalCe) with lower levels of incorporation into the sulfatides. Such incorporation was enhanced 35 days after crush injury of the adult rat sciatic nerve, which is characterized by active myelin assembly. In contrast, at 35 days after permanent nerve transection where there is no axonal regeneration or myelin assembly, the incorporation of [3H]Gal or [3H]Glc into GalCe was nearly undetected whereas the incorporation of [3H]Gal into MGDG was completely inhibited. Instead, the 3H-labeled glycolipids in transected nerve were identified as the glucocerebrosides (GlcCe) and oligohexosylceramide derivatives with tetrahexosylceramide being a major product. In contrast, [35S]sulfate was incorporated into endoneurial sulfatides in the transected nerve, which suggests that endogenous GalCe rather than newly synthesized GalCe served as the substrate for the sulfotransferase reaction. The GlcCe homologues are not considered as constituents of the myelin membrane but are likely plasma membrane components synthesized in the absence of myelin assembly. It is likely that the cells responsible for GlcCe biosynthesis are Schwann cells, since they comprise 90% of the total endoneurial cell area in the distal nerve segment at 35 days after transection.(ABSTRACT TRUNCATED AT 250 WORDS)     

Regulation of Myelination: Schwann Cell Transition from a Myelin-Maintaining State to a Quiescent State After Permanent Nerve Transection

Permanent nerve transection of the adult rat sciatic nerve forces Schwann cells in the distal nerve segment from a myelin-maintaining to a quiescent state. This transition was followed by serial morphometric evaluation of the percentage fascicular area having myelin (myelin percent of area) in transverse sections of the distal nerve segment and revealed a rapid decline from a normal value of 36.6% to 3.2% by 14 days for the sciatic nerve to less than 1.0% throughout the remaining time course (up to 105 days). No evidence of axonal reentry into the distal nerve segment or new myelin formation was observed at times under 70 days. In some of the distal nerve segments at 70, 90, and 105 days, new myelinated fibers were observed that usually consisted of only a few myelinated fibers at the periphery and in the worst case amounted to 1.6% (myelin percent of area). Radioactive precursor incorporation of [3H]mannose into endoneurial slices at 4 and 7 days after transection revealed two species of the major myelin glycoprotein, P0, with Mr of 28,500 and 27,700. By 14 days after nerve transection, only the 27,700 Mr species remained. Incorporation of [3H]mannose into the 27,700 Mr species increased progressively to 35 days after transection and then began to decline at 70 and 105 days. Alterations in the oligosaccharide structure of this down-regulated myelin glycoprotein accounted for the progressive increase in mannose incorporation. Lectin affinity chromatography of pronase-digested P0 glycopeptides on concanavalin A-Sepharose revealed that the 28,500 Mr species of P0 had the complex-type oligosaccharide as the predominant oligosaccharide structure (92%). In contrast, the high mannose-type oligosaccharide was the predominate structure for the 27,700 Mr form, which increased to 70% of the total radioactivity by 35 days after nerve transection. Since the biosynthesis of the complex-type oligosaccharide chains on glycoproteins involves high mannose-type intermediates, the mechanism of down-regulation in the biosynthesis of this major myelin glycoprotein, therefore, results in a biosynthetic switch from the complex-type oligosaccharide structure as an end product to the predominantly high mannose-type oligosaccharide structure as a biosynthetic intermediate. This biosynthetic switch occurs gradually between 7 and 14 days after nerve transection and likely reflects a decreased rate of processing through the Golgi apparatus. It remains to be determined if the high mannose-type oligosaccharide chain on P0 can undergo additional processing steps in this permanent nerve transection model.     

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.     

Glial and Neuronal Marker Proteins in the Silicone Chamber Model for Nerve Regeneration

Abstract: In the present study, neuronal and Schwann cell marker proteins were used to biochemically characterize the spatiotemporal progress of degeneration/regeneration in the silicone chamber model for nerve regeneration. Rat sciatic nerves were transected and the proximal and distal stumps were inserted into a bridging silicone chamber with a 10-mm interstump gap. Using dot immunobinding assays, S-100 protein and neuronal intermediate filament polypeptides were measured in different parts of the nerve 0–30 days after transaction. In the most proximal nerve segment, all the measured proteins were transiently increased. In the proximal and distal stumps adjacent to the transection, the studied proteins were decreased indicating degeneration of the nerve. Within the silicone chamber, the regenerating nerve expressed the Schwann cell S-100 protein already at 7 days, whereas the neurofilament polypeptides appeared later. These observations are corroborated by previous morphological studies. The biochemical method described provides a new and fast approach to the study of nerve regeneration.     

Visualizing Peripheral Nerve Regeneration by Whole Mount Staining

Peripheral nerve trauma triggers a well characterised sequence of events both proximal and distal to the site of injury. Axons distal to the injury degenerate, Schwann cells convert to a repair supportive phenotype and macrophages enter the nerve to clear myelin and axonal debris. Following these events, axons must regrow through the distal part of the nerve, re-innervate and finally are re-myelinated by Schwann cells. For nerve crush injuries (axonotmesis), in which the integrity of the nerve is maintained, repair may be relatively effective whereas for nerve transection (neurotmesis) repair will likely be very poor as few axons may be able to cross between the two parts of the severed nerve, across the newly generated nerve bridge, to enter the distal stump and regenerate. Analysing axon growth and the cell-cell interactions that occur following both nerve crush and cut injuries has largely been carried out by staining sections of nerve tissue, but this has the obvious disadvantage that it is not possible to follow the paths of regenerating axons in three dimensions within the nerve trunk or nerve bridge. To try and solve this problem, we describe the development and use of a novel whole mount staining protocol that allows the analysis of axonal regeneration, Schwann cell-axon interaction and re-vascularisation of the repairing nerve following nerve cut and crush injuries.     

Developmental changes in myelin-induced proliferation of cultured Schwann cells

Schwann cell proliferation induced by a myelin-enriched fraction was examined in vitro. Although nearly all the Schwann cells contained material that was recognized by antisera to myelin basic protein after 24 h, only 1% of the cells were synthesizing DNA. 72 h after the addition of the mitogen a maximum of 10% of the cells incorporated [3H]thymidine. If the cultures were treated with the myelin-enriched fraction for 24 h and then washed, the number of proliferating Schwann cells decreased by 75% when compared with those cells that were incubated with the mitogen continuously. When Schwann cells were labeled with [14C]thymidine followed by a pulse of [3H]thymidine 24 h later, every Schwann cell labeled with [3H]thymidine was also labeled with [14C]thymidine. Although almost every Schwann cell can metabolize the myelin membranes within 24 h of exposure, a small population of cell initially utilizes the myelin as a mitogen, and this population continues to divide only if myelin is present in the extracellular media. The percentage of the Schwann cells that initially recognize the myelin-enriched fraction as a mitogen is dependent upon the age of the animal from which the cells were prepared.     

Effect of Lithium on Schwann Cell Proliferation Stimulated by Axolemma- and Myelin-Enriched Fractions

Cultured Schwann cells stimulated with an axolemma- or myelin-enriched fraction incorporated 2.5 to three times as much [3H]thymidine when 10 mM lithium was added to the extracellular medium. The ability of lithium to enhance the mitogenic activity of either fraction was dose dependent. This result was not due to an increase in osmolarity, because addition of 10 mM NaCl had no effect on the amount of labeled thymidine accumulated by Schwann cells treated with either membrane fraction. In an earlier study, the effect of either membrane fraction could be potentiated with active phorbol esters. Lithium significantly enhanced the incorporation of [3H]thymidine into Schwann cells treated with a myelin-enriched fraction and phorbol esters. In contrast, lithium slightly increased the amount of labeled thymidine incorporated into Schwann cells stimulated with an axolemma-enriched fraction and phorbol esters. The mitogenic activity of either membrane fraction was impaired when the calcium channel blockers Mn2+ and nifedipine were added. Addition of lithium stimulated an increase in the amount of [3H]thymidine accumulated by Schwann cells treated with either the axolemma- or myelin-enriched fraction in the presence of either Mn2+ or nifedipine.     

Isolation and Partial Characterization of Plasmalemma from Quiescent Schwann Cells in Denervated Cat Sciatic Nerve

Fractions enriched in plasma membranes have been obtained from peripheral nerves enriched 89% in quiescent Schwann cells. Fractions were prepared from the intrafascicular tissue of desheathed distal stumps of cat sciatic nerve 8-10 weeks after transection and suture in the upper thigh. Tissue enriched in Schwann cells was minced, homogenized, and centrifuged to remove nuclei and undispersed tissue. Centrifugation of the resulting supernatant produced a pellet that was osmotically shocked, layered over a discontinuous sucrose gradient, and recentrifuged. Fractions enriched in plasma membrane (PM) markers were pooled, osmotically shocked for 16 h, layered over a second discontinuous sucrose density gradient, and recentrifuged. Membrane fractions (0.6 M:0.85 M and 0.85 M:1.0 M interfaces) contained a homogeneous population of unilamellar vesicles free of myelin. The 0.85 M fraction was enriched in 5'-nucleotidase, 2',3'-cyclic nucleotide 3'-phosphohydrolase. and specific [3H]ouabain binding, 4.8-, 3.0-, and 5.7-fold over the crude homogenate, respectively. These fractions also demonstrated low enzyme activities for succinate dehydrogenase, lactate dehydrogenase, and glucose-6-phosphatase (9, 13, and 15% of control values, respectively). Protein yield of the PM fraction (0.85 M) was approximately 0.6 mg/g of denervated nerve. This preparation should be suitable to characterize the surface properties of Schwann cells free of neuronal regulation.     

Intermediate Filaments of Schwann Cells

Abstract: Intermediate filaments were prepared from distal stumps of rabbit sciatic nerve 5 weeks after nerve section, at which time Schwann cells account for 85–90% of the cell area. A polypeptide of molecular weight 58,000 was the main component of this fraction. An antiserum raised in guinea pig against this polypeptide stained all cells present in the distal stump, as well as Schwann cells and 3T3 cells in culture. The identity of the molecular weight 58,000 polypeptide obtained from distal stumps with vimentin was proved with one and two-dimensional sodium dodecyl sulfate pol yacrylamide gel electrophoresis and with immunoautoradiography. It is concluded that the intermediate filament subunit of undifferentiated Schwann cells is vimentin. The possibility that Schwann cells in normal nerve may have another type of intermediate filament besides vimentin cannot be ruled out.     

Effect of Delayed Peripheral Nerve Repair on Nerve Regeneration,Schwann Cell Function and Target Muscle Recovery

Despite advances in surgical techniques for peripheral nerve repair, functional restitution remains incomplete. The timing of surgery is one factor influencing the extent of recovery but it is not yet clearly defined how long a delay may be tolerated before repair becomes futile. In this study, rats underwent sciatic nerve transection before immediate (0) or 1, 3, or 6 months delayed repair with a nerve graft. Regeneration of spinal motoneurons, 13 weeks after nerve repair, was assessed using retrograde labeling. Nerve tissue was also collected from the proximal and distal stumps and from the nerve graft, together with the medial gastrocnemius (MG) muscles. A dramatic decline in the number of regenerating motoneurons and myelinated axons in the distal nerve stump was observed in the 3- and 6-months delayed groups. After 3 months delay, the axonal number in the proximal stump increased 2–3 folds, accompanied by a smaller axonal area. RT-PCR of distal nerve segments revealed a decline in Schwann cells (SC) markers, most notably in the 3 and 6 month delayed repair samples. There was also a progressive increase in fibrosis and proteoglycan scar markers in the distal nerve with increased delayed repair time. The yield of SC isolated from the distal nerve segments progressively fell with increased delay in repair time but cultured SC from all groups proliferated at similar rates. MG muscle at 3- and 6-months delay repair showed a significant decline in weight (61% and 27% compared with contra-lateral side). Muscle fiber atrophy and changes to neuromuscular junctions were observed with increased delayed repair time suggestive of progressively impaired reinnervation. This study demonstrates that one of the main limiting factors for nerve regeneration after delayed repair is the distal stump. The critical time point after which the outcome of regeneration becomes too poor appears to be 3-months.     

Axonal Transport Reversal of Acetylcholinesterase Molecular Forms in Transected Nerve

Reversal of anterograde rapid axonal transport of four molecular forms of acetylcholinesterase (AChE) was studied in chick sciatic nerve during the 24-h period following a nerve transection. Reversal of AChE activity started ～1 h after nerve transection, and all the forms of the enzyme, except the monomeric ones, showed reversal of transport. The quantity of enzyme activity reversed 24 h after transection was twofold greater than that normally conveyed by retrograde transport. We observed no leakage of the enzyme at the site of the nerve transection and no reversal of AChE activity transport in the distal segment of the severed nerve, a result indicating that the material carried by retrograde axonal transport cannot be reversed by axotomy. Thus, a nerve transection induces both quantitative and qualitative changes in the retrograde axonal transport, which could serve as a signal of distal injury to the cell body. The velocity of reverse transport, measured within 6 h after transection, was found to be 213 mm/day, a value close to that of retrograde transport (200 mm/day). This suggests that the reversal taking place in severed sciatic nerve is similar to the anterograde-to-retrograde conversion process normally occurring at the nerve endings.     

Laminin B1 and Collagen Type IV Gene Expression in Transected Peripheral Nerve: Reinnervation Compared to Denervation

The expression of B1 laminin and type IV collagen was followed in the microsurgically isolated endoneurium of transected rat sciatic nerves from 3 days until 8 weeks. Northern hybridizations revealed that after nerve transection the proximal stumps of denervated, as well as freely regenerating, nerves showed a markedly increased expression of laminin and type IV collagen which lasted from 3 days up to 8 weeks. In the distal stumps, close to the site of transection (2-7 mm), the expression of laminin, and to a certain extent that of type IV collagen, seemed to be enhanced if free axonal reinnervation was allowed. Further distally (10-15 mm), the patterns of B1 laminin and type IV collagen expression were similar in both experimental groups, so that an increased expression was noticed during the first 2 weeks. The present results suggest that laminin and type IV collagen gene expression is markedly different in different parts of transected rat sciatic nerve. During peripheral nerve regeneration, there is a long-lasting basement membrane gene expression in the proximal stump. In the distal part of the transected nerve, the axonal reinnervation possibly up-regulates, but is not essential for, the expression of B1 laminin and type IV collagen.     

Immunoelectron microscopic localization of neural cell adhesion molecules (L1, N-CAM, and myelin-associated glycoprotein) in regenerating adult mouse sciatic nerve

The localization of the neural cell adhesion molecules L1, N-CAM, and the myelin-associated glycoprotein was studied by pre- and postembedding staining procedures at the light and electron microscopic levels in transected and crushed adult mouse sciatic nerve. During the first 2-6 d after transection, myelinated and nonmyelinated axons degenerated in the distal part of the proximal stump close to the transection site and over the entire length of the distal part of the transected nerve. During this time, regrowing axons were seen only in the proximal, but not in the distal nerve stump. In most cases L1 and N-CAM remained detectable at cell contacts between nonmyelinating Schwann cells and degenerating axons as long as these were still morphologically intact. Similarly, myelin-associated glycoprotein remained detectable in the periaxonal area of the degenerating myelinated axons. During and after degeneration of axons, nonmyelinating Schwann cells formed slender processes which were L1 and N-CAM positive. They resembled small-diameter axons but could be unequivocally identified as Schwann cells by chronical denervation. Unlike the nonmyelinating Schwann cells, only few myelinating ones expressed L1 and N-CAM. At the cut ends of the nerve stumps a cap developed (more at the proximal than at the distal stump) that contained S-100-negative and fibronectin-positive fibroblast-like cells. Most of these cells were N-CAM positive but always L1 negative. Growth cones and regrowing axons expressed N-CAM and L1 at contact sites with these cells. Regrowing axons of small diameter were L1 and N-CAM positive where they made contact with each other or with Schwann cells, while large-diameter axons were only poorly antigen positive or completely negative. 14 d after transection, when regrowing axons were seen in the distal part of the transected nerve, regrowing axons made L1- and N-CAM-positive contacts with Schwann cells. When contacting basement membrane, axons were rarely found to express L1 and N-CAM. Most, if not all, Schwann cells associated with degenerating myelin expressed L1 and N-CAM. In crushed nerves, the immunostaining pattern was essentially the same as in the cut nerve. During formation of myelin, the sequence of adhesion molecule expression was the same as during development: L1 disappeared and N-CAM was reduced on myelinating Schwann cells and axons after the Schwann cell process had turned approximately 1.5 loops around the axon. Myelin-associated glycoprotein then appeared both periaxonally and on the turning loops of Schwann cells in the uncompacted myelin.(ABSTRACT TRUNCATED AT 400 WORDS)     

GAP-43 is expressed by nonmyelin-forming Schwann cells of the peripheral nervous system.

Recently it has been demonstrated that the growth-associated protein GAP-43 is not confined to neurons but is also expressed by certain central nervous system glial cells in tissue culture and in vivo. This study has extended these observations to the major class of glial cells in the peripheral nervous system, Schwann cells. Using immunohistochemical techniques, we show that GAP-43 immunoreactivity is present in Schwann cell precursors and in mature non-myelin-forming Schwann cells both in vitro and in vivo. This immunoreactivity is shown by Western blotting to be a membrane-associated protein that comigrates with purified central nervous system GAP-43. Furthermore, metabolic labeling experiments demonstrate definitively that Schwann cells in culture can synthesize GAP-43. Mature myelin-forming Schwann cells do not express GAP-43 but when Schwann cells are removed from axonal contact in vivo by nerve transection GAP-43 expression is upregulated in nearly all Schwann cells of the distal stump by 4 wk after denervation. In contrast, in cultured Schwann cells GAP-43 is not rapidly upregulated in cells that have been making myelin in vivo. Thus the regulation of GAP-43 appears to be complex and different from that of other proteins associated with nonmyelin-forming Schwann cells such as N-CAM, glial fibrillary acidic protein, A5E3, and nerve growth factor receptor, which are rapidly upregulated in myelin-forming cells after loss of axonal contact. These observations suggest that GAP-43 may play a more general role in the nervous system than previously supposed.     

Cerebellar granule cells contain a membrane mitogen for cultured Schwann cells

Proliferation of Schwann cells is one of the first events that occurs after contact with a growing axon. To further define the distribution and properties of this axonal mitogen, we have (a) cocultured cerebellar granule cells, which lack glial ensheathment in vivo with Schwann cells; and (b) exposed Schwann cell cultures to isolated granule cell membranes. Schwann cells cocultured with granule cells had a 30-fold increase in the labeling index over Schwann cells cultured alone, suggesting that the mitogen is located on the granule cell surface. Inhibition of granule cell proteoglycan synthesis caused a decrease in the granule cells' ability to stimulate Schwann cell proliferation. Membranes isolated from cerebellar granule cells when added to Schwann cell cultures caused a 45-fold stimulation in [3H]thymidine incorporation. The granule cell mitogenic signal was heat and trypsin sensitive and did not require lysosomal processing by Schwann cells to elicit its proliferative effect. The ability of granule cells and their isolated membranes to stimulate Schwann cell proliferation suggests that the mitogenic signal for Schwann cells is a ubiquitous factor present on all axons regardless of their ultimate state of glial ensheathment.     

β,β''-Iminodipropionitrile Impairs Retrograde Axonal Transport

beta,beta'-Iminodipropionitrile (IDPN), a neurotoxin, causes redistribution of neurofilaments in axons followed by the development of proximal axonal swellings and, in chronic intoxication, a distal decrease in axonal caliber. The latter changes are caused by a selective impairment in the slow anterograde axonal transport of neurofilament proteins. To assess the role of retrograde axonal transport in IDPN toxicity, we used [3H]N-succinimidyl propionate ([3H]NSP) to label covalently endogenous axonal proteins in sciatic nerve of the rat and measured the accumulation of radioactively labeled proteins in the cell bodies of motor and sensory neurons over time. IDPN was injected intraneurally 6 h or intraperitoneally 1 day before subepineurial injection of [3H]NSP into the sciatic nerve, and the animals were killed 1, 2, and 7 days after [3H]NSP injection. Neurotoxicity was assessed by electron microscopic observation of the nerves of similarly treated animals. Both intraneural and intraperitoneal injection of IDPN caused an acute reduction in the amount of labeled proteins transported back to the cell bodies. The early appearance of these changes suggests that alterations in retrograde transport may play a role in the production of the neuropathic changes.     

Differential proliferative responses of cultured Schwann cells to axolemma- and myelin-enriched fractions. I. Biochemical studies

Cultured rat Schwann cells were treated for 72 h with axolemma- and myelin-enriched fractions prepared from rat brainstem. [3H]Thymidine was added to the cultures 48 h before the termination of the experiment. Although, both fractions produced a dose-dependent uptake of label into Schwann cells, the shape of the dose response curves and rates at which [3H]thymidine was incorporated were different. The axolemma-enriched fraction produced a sigmoid dose response curve with a Hill coefficient of 2.05. The dose response curve for myelin rose sharply and saturated at a level that was approximately 50% of the maximal response observed with axolemma. Schwann cells that had been treated with axolemma exhibited little change in the rate of [3H]thymidine incorporation from 36-72 h after the addition of the membranes. In contrast, Schwann cells accumulated label three times faster during the 48-72-h period following the addition of myelin to the cultures when compared with the rate during the preceding 12-h interval. Furthermore, the mitogenic activity of the myelin-enriched fraction was decreased by the addition of ammonium chloride, a lysosomal inhibitor, whereas the activity of the axolemmal fraction was not impaired.