Differentiation of axon-related Schwann cells in vitro. I. Ascorbic acid regulates basal lamina assembly and myelin formation

Cold storage of peripheral nerves: an in vitro assay of cell viability and function

The development of a nerve bank as a source of donor material to repair large defects in peripheral nerve injuries requires an understanding of the influence of cold storage on cell viability and function in these potential nerve grafts. Segments of peripheral nerves from both human and rat were stored in University of Wisconsin Cold Storage Solution (UW) at 4 degrees C for < 12 h, 3 days, and 1, 2, or 3 weeks. Cellular viability was initially assessed by the degree of cellular outgrowth from explants of the stored nerves placed in culture, and then further quantitated by dissociating the cultured nerve explants and calculating the type and number of cells per milligram of peripheral nerve. Rat Schwann cells (SCs) obtained from the stored (control and 1 and 2 weeks) nerves were tested for their functional ability to myelinate dorsal root ganglion (DRG) neurons in culture. Our findings indicate that human and rat peripheral nerves contain few viable SCs and fibroblasts after 3 weeks of cold storage with the quantity of viable cells within the human cold stored peripheral nerves decreasing significantly after 1 week of cold storage. Despite their reduced number, some SCs from rat nerves stored up to 2 weeks are capable of myelinating DRG axons in culture. These results suggest that short intervals (< 1 week) of cold storage will result in potential peripheral nerve grafts containing large populations of functional cells, while long-term (> or = 3 weeks) cold stored peripheral nerves will contain few viable cells.

Dorsal root ganglia cocultured with macrophages: an in vitro model to study experimental demyelination

The present investigation introduces an in vitro model to study macrophage properties during demyelination. Rat dorsal root ganglia (DRG) were cultured for obtaining myelinated peripheral nerve fibers. These cultures were exposed to non-resident macrophages. In untreated control cultures, there was no indication of myelin removal by the added macrophages. DRG were exposed to enzymatically generated oxygen radicals using the xanthin/xanthin oxidase or the glucose/glucose oxidase system. Assessment of Schwann cell viability and ultrastructural morphology revealed different patterns of cell cytotoxicity and morphological changes in different experiments. High concentrations caused complete tissue necrosis of the DRG, while low concentrations did not affect either cell viability or ultrastructural morphology. Under intermediate experimental conditions, oxygen radicals caused non-lethal Schwann cell damage leading to Schwann cell retraction and myelin sheath rejection. Myelin lamellae were disrupted and decompacted. These changes were followed by a selective macrophage attack on myelin sheaths, resulting in demyelination. Axons, Schwann cells and sensory ganglion cells survived this attack. The specificity of the oxygen radical effects was tested in experiments using the oxygen radical scavengers catalase and superoxide dismutase. Catalase prevented the described effects on cell morphology and subsequently blocked demyelination by non-resident macrophages.

Myelination in cerebellar slice cultures: development of a system amenable to biochemical analysis

Myelin deposition and maintenance are critical to proper function of the mammalian nervous system. Previous investigations of myelination in the central nervous system (CNS) were hampered by the lack of an in vitro system that can faithfully reproduce in vivo events yet is amenable to biochemical investigation. We have developed a procedure, based on organotypic cultures, which permits efficient preparation of large numbers of cerebellar slice cultures that can be easily manipulated. Cultures have been examined to document myelination biochemically (by incorporation of [35S]sulfate into sulfolipids), immunohistochemically (by labeling the myelin components myelin basic protein and galactocerebroside), and morphologically (by both light and electron microscopy). We tested the effects of biologically active peptides and antibodies on myelination in the thin slices. The results indicate that the cultures provide an in vitro system that can be used to examine specific cellular events that occur during CNS myelination.

Axonal regulation of Schwann cell integrin expression suggests a role for alpha 6 beta 4 in myelination

Ensheathment and myelination of axons by Schwann cells in the peripheral nervous system requires contact with a basal lamina. The molecular mechanism(s) by which the basal lamina promotes myelination is not known but is likely to reflect the activity of integrins expressed by Schwann cells. To initiate studies on the role of integrins during myelination, we characterized the expression of two integrin subunits, beta 1 and beta 4, in an in vitro myelination system and compared their expression to that of the glial adhesion molecule, the myelin-associated glycoprotein (MAG). In the absence of neurons, Schwann cells express significant levels of beta 1 but virtually no beta 4 or MAG. When Schwann cells are cocultured with dorsal root ganglia neurons under conditions promoting myelination, expression of beta 4 and MAG increased dramatically in myelinating cells, whereas beta 1 levels remained essentially unchanged. (In general agreement with these findings, during peripheral nerve development in vivo, beta 4 levels also increase during the period of myelination in sharp contrast to beta 1 levels which show a striking decrease.) In cocultures of neurons and Schwann cells, beta 4 and MAG appear to colocalize in nascent myelin sheaths but have distinct distributions in mature sheaths, with beta 4 concentrated in the outer plasma membrane of the Schwann cell and MAG localized to the inner (periaxonal) membrane. Surprisingly, beta 4 is also present at high levels with MAG in Schmidt-Lanterman incisures. Immunoprecipitation studies demonstrated that primary Schwann cells express beta 1 in association with the alpha 1 and alpha 6 subunits, while myelinating Schwann cells express alpha 6 beta 4 and possibly alpha 1 beta 1. beta 4 is also downregulated during Wallerian degeneration in vitro, indicating that its expression requires continuous Schwann cell contact with the axon. These results indicate that axonal contact induces the expression of beta 4 during Schwann cell myelination and suggest that alpha 6 beta 4 is an important mediator of the interactions of myelinating Schwann cells with the basal lamina.

Expression of the protein zero myelin gene in axon-related Schwann cells is linked to basal lamina formation

A Schwann cell has the potential to differentiate into either a myelinating or ensheathing cell depending upon signals received from the axon that it contacts. Studies focusing on the pathway leading to myelination demonstrated that Schwann cells must form a basal lamina in order to myelinate an axon. In this report, we describe studies that indicate that initiation of basal lamina synthesis is required for Schwann cells to distinguish between myelination-inducing axons and axons that do not induce myelination, and to respond by undergoing the appropriate genetic and cellular changes. We have used high resolution in situ hybridization, immunocytochemistry and electron microscopy to examine changes in gene expression and morphology of Schwann cells differentiating into myelin-forming cells in vitro. These experiments were carried out in dorsal root ganglion neuron/Schwann cell co-cultures maintained in either serum-free, serum-only or serum-plus-ascorbate-containing medium. We have made four novel observations that contribute significantly to our understanding of how basal lamina and myelination are linked. (1) The addition of ascorbate (in the presence of serum), which promotes basal lamina production, appears to induce expression of the protein zero gene encoding the major structural protein of myelin. Moreover, expression of protein zero mRNA and protein, and its insertion into myelin membranes, occurs only in the subset of Schwann cells contacting myelination-inducing axons. Schwann cells in contact with axons that do not induce myelination, or Schwann cells that have not established a unitary relationship with an axon, do not express protein zero mRNA although they produce basal lamina components. (2) In serum-free conditions, a majority of Schwann cells express protein zero mRNA and protein, but this change in gene expression is not associated with basal lamina formation or with elongation of the Schwann cell along the axon and elaboration of myelin. (3) In the presence of serum (and the absence of ascorbate), Schwann cells again fail to form basal lamina or elongate but no longer express protein zero mRNA or protein. (4) Myelin-associated glycoprotein and galactocerebroside, two additional myelin-specific components, can be expressed by Schwann cells under any of the three culture conditions. Therefore, we have demonstrated that axonal induction of protein zero gene expression in Schwann cells is subject to regulation by both serum- and ascorbate-dependent pathways and that not all myelin-specific proteins are regulated in the same manner.(ABSTRACT TRUNCATED AT 400 WORDS)

Expanding roles for the Schwann cell: ensheathment, myelination, trophism and regeneration

Schwann cells show remarkable versatility in undertaking a broad repertoire of functions. It is now clear that the well known functions of ensheathment and myelination are specifically regulated by contact with axons, that the Schwann cell is centrally involved in extracellular matrix production in the peripheral nerve trunk, and that the Schwann cell plays a critical role in promoting axonal regeneration in the peripheral nervous system. The Schwann cell's ability to promote regenerative efforts in many central neurons has led to an increasing interest in using Schwann cell autografts for central nervous system repair.

Negative regulation of Schwann cell myelin protein gene expression by the dorsal root ganglionic microenvironment

In vivo, the surface glycoprotein Schwann cell myelin protein (SMP) is expressed in the quail peripheral nervous system exclusively by Schwann cells. It is not detectable at any developmental stage either in enteric glia or in ganglionic satellite cells. We demonstrate here that the satellite glial cells of the dorsal root ganglia start to express SMP on their surface when they are dissociated into single cells and cultivated in vitro. Activation of SMP synthesis is a rapid event observed in mass cultures of dorsal root ganglia dissociated cells as soon as 4 h after the onset of the culture. Confocal microscope analysis revealed that satellite cells may acquire the Schwann cell marker when still in close contact with the neuronal soma. Clonal cultures of satellite cells from E8 dorsal root ganglia demonstrated that the progeny of these SMP-negative cells steadily express SMP. This, together with similar results previously obtained with enteric glia, suggests that the SMP-positive phenotype is a constitutive trait of the peripheral glial cell lineage which is inhibited in satellite cells in vivo by the microenvironment prevailing in the peripheral nervous system ganglia.

Neuron-Schwann cell signals are conserved across species: purification and characterization of embryonic chicken Schwann cells

A monoclonal antibody, 1E8, which recognizes the peripheral myelin protein, P0, specific for chicken Schwann cells and their precursors (Bhattacharyya et al., Neuron 7:831-844, 1991), was used to immunoselect Schwann cells from embryonic day 14 (E14) chicken sciatic nerve. When cultured, these immunoselected cells displayed properties characteristic of perinatal rodent Schwann cells, including S100-immunoreactivity and O4 antigen-immunoreactivity. In addition, the purified chicken Schwann cells divided slowly when cultured alone, but when co-cultured with chicken or rat sensory neurons, they bound to axons and proliferated. Proliferation was also stimulated by the addition of bovine brain membrane extracts or chicken brain membranes. The 1E8 monoclonal antibody was also used to test the effect of axonal contact on P0 expression. Chicken Schwann cells purified using the 1E8 monoclonal antibody gradually lost P0 when cultured alone. These cells remained 1E8-negative even after prolonged co-culture with embryonic rat dorsal root ganglion neurons or chicken sensory ganglia. These results demonstrate that chicken Schwann cells behave like rodent Schwann cells in their expression of specific antigens, interactions with axons, and regulation of P0 expression. In addition, chicken Schwann cells respond to neuronal signals from the rat and cow, illustrating the cross-species conservation of these signals.

Fibroblasts are required for Schwann cell basal lamina deposition and ensheathment of unmyelinated sympathetic neurites in culture

The ability to purify and recombine populations of peripheral neurons, Schwann cells and fibroblasts in tissue culture has enabled us to examine the contribution of fibroblasts to Schwann cell basal lamina assembly and ensheathment of unmyelinated rat superior cervical ganglion neurites in vitro. Purified perinatal superior cervical ganglion neurons were grown in culture either with Schwann cells or with Schwann cells plus fibroblasts derived from either superior cervical ganglion capsule or cranial periosteum. The cultures were maintained for 2-8 weeks on a collagen substratum in a medium known to promote Schwann cell differentiation (myelin, basal lamina formation) in the presence of dorsal root ganglion neurons. The extent of Schwann cell differentiation (ensheathment, basal lamina formation) in the presence of superior cervical ganglion neurons was evaluated in this study using electron microscopy. In superior cervical ganglion neuron plus Schwann cell cultures (without fibroblasts), Schwann cells achieved only a moderate degree of ensheathment; also, Schwann cell basal lamina was discontinuous and extracellular collagen fibrils were sparse. Although only discontinuous basal lamina was demonstrable by electron microscopy in these cultures, surprisingly, Schwann cell/neurite fascicles were uniformly immunostained for laminin, type IV collagen, and heparan sulfate proteoglycan. The addition of fibroblasts to superior cervical ganglion neuron plus Schwann cell cultures increased the deposition of basal lamina around the Schwann cell/neurite units, the number of collagen fibrils, and the extent of neurite ensheathment. We propose that the presence of basal lamina increases the Schwann cell's ability to ensheathe superior cervical ganglion neurites, possibly through an augmentation of specific extracellular matrix components or by increasing in some way the capacity of these components to become organized into basal lamina. We conclude that, unlike dorsal root ganglion neurons, superior cervical ganglion neurons are unable to stimulate full Schwann cell extracellular matrix expression with the result that these Schwann cells require the extraneuronal influence of fibroblasts to deposit basal lamina and attain their mature phenotype in culture.

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.

Myelin protein expression in dissociated superior cervical ganglia and dorsal root ganglia cultures

Schwann cells of the adult rat superior cervical ganglia (SCG) synthesize negligible levels of the major myelin glycoprotein, P0, in vivo. This suggests that the sympathetic axons of the SCG are deficient in one of more components involved in the regulation of myelin protein expression. Here we have compared the ability of neurites from neonatal rat SCG and embryonic rat dorsal root ganglia (DRG) to induce Schwann cell expression of myelin proteins after growth in culture using a serum-free medium. Steady-state P0 mRNA levels in the SCG and DRG culture paradigms were determined with a sensitive polymerase chain reaction (PCR) assay that amplified cDNA produced by reverse transcription of mRNA. This semiquantitative assay showed a linear response to increasing amounts of P0 and actin mRNA and required substantially less cellular RNA than typical hybridization techniques. Using the PCR assay, we found that SCG cultures contained significantly lower amounts of P0 mRNA than did DRG cultures. To further confirm that SCG cultures have negligible expression of myelin proteins, immunoblot analyses were done to examine the steady-state levels of both P0 and myelin basic protein. While nonmyelinating DRG cultures had readily detectable amounts of these myelin-specific proteins, neither could be demonstrated in the SCG cultures. The data indicate that SCG neurites lack one or more signals needed to induce myelin protein expression. Employing SCG and DRG cultures in comparative biochemical studies should prove useful in identifying the axonal molecule(s) involved in the regulation of myelin protein expression.

Isolation and characterization of neonatal Schwann cells from cryopreserved rat sciatic nerves

Much of our knowledge about the development and maintenance of the peripheral nervous system has been learned through studying the interaction of neurons, or their isolated membranes, with Schwann cells (SC), in tissue culture. Numerous approaches have been employed to obtain an adequate quantity of SC, but all have been limited by either the uncertainty of obtaining a sufficient amount of starting material, the time and expertise required to isolate the SC, or by the limited number of SC that can be generated. We have developed a procedure to isolate SC from cryopreserved sciatic nerves. This procedure allows for sciatic nerves to be pooled until adequate numbers of nerves are obtained, yet still produces cells that retain the functional abilities of SC isolated from fresh nerves. Sciatic nerves were isolated from 2 day old rat pups, placed in either DME media and used fresh or placed in a freezing solution containing DME media (25%), DMSO (25%), fetal calf serum (50%), frozen at -70 degrees C and stored in liquid nitrogen. The frozen nerves were rapidly thawed to 37 degrees C and single cells were prepared from both fresh and frozen nerves using enzymatic and mechanical disruption as previously described (Brockes et al., Brain Res 165: 105-118, 1979). Comparable cell yields were obtained for SC isolated from both frozen and fresh nerves. Immunohistochemical staining of both fresh and frozen SC produced similar staining patterns with antibodies to GFAP, laminin, CNPase, S100, MBP, and P0 protein. Addition of axolemmal enriched membrane fractions to both the frozen and fresh SC gave a similar dose response curve of 3H-thymidine incorporation, with SC from frozen sciatic nerves responding even better than fresh sciatic nerves at higher doses (50 micrograms and 100 micrograms of protein/ml). As demonstrated by the cell yield, immunohistochemical staining and responses to axolemmal mitogens, this procedure produces SC from frozen sciatic nerves with similar characteristics to those isolated from fresh nerves. This procedure will allow the production and utilization of a large number of SC, which will be critical in further studies on the development and maintenance of the peripheral nervous system.

Clustering of voltage-dependent sodium channels on axons depends on Schwann cell contact

In myelinated nerves, segregation of voltage-dependent sodium channels to nodes of Ranvier is crucial for saltatory conduction along axons. As sodium channels associate and colocalize with ankyrin at nodes of Ranvier, one possibility is that sodium channels are recruited and immobilized at axonal sites which are specified by the subaxolemmal cytoskeleton, independent of glial cell contact. Alternatively, segregation of channels at distinct sites along the axon may depend on glial cell contact. To resolve this question, we have examined the distribution of sodium channels, ankyrin and spectrin in myelination-competent cocultures of sensory neurons and Schwann cells by immunofluorescence, using sodium channel-, ankyrin- and spectrin-specific antibodies. In the absence of Schwann cells, sodium channels, ankyrin and spectrin are homogeneously distributed on sensory axons. When Schwann cells are introduced into these cultures, the distribution of sodium channels dramatically changes so that channel clusters on axons are abundant, but ankyrin and spectrin remain homogeneously distributed. Addition of latex beads or Schwann cell membranes does not induce channel clustering. Our results suggest that segregation of sodium channels on axons is highly dependent on interactions with active Schwann cells and that continuing axon-glial interactions are necessary to organize and maintain channel distribution during differentiation of myelinated axons.

Schwann cells infected with a recombinant retrovirus expressing myelin-associated glycoprotein antisense RNA do not form myelin

To elucidate the role of myelin-associated glycoprotein (MAG) in the axon-Schwann cell interaction leading to myelination, neonatal rodent Schwann cells were infected in vitro with a recombinant retrovirus expressing MAG antisense RNA or MAG sense RNA. Stably infected Schwann cells and uninfected cells were then cocultured with purified sensory neurons under conditions permitting extensive myelination in vitro. A proportion of the Schwann cells infected with the MAG antisense virus did not myelinate axons and expressed lower levels of MAG than control myelinating Schwann cells, as measured by immunofluorescence. Electron microscopy revealed that the affected cells failed to segregate large axons and initiate a myelin spiral despite having formed a basal lamina, which normally triggers Schwann cell differentiation. Cells infected with the MAG sense virus formed normal compact myelin. These observations strongly suggest that MAG is the critical Schwann cell component induced by neuronal interaction that initiates peripheral myelination.

P0 gene expression in cultured Schwann cells

This study examines the expression of the major myelin protein gene P0 in cultured Schwann cells, grown on their own or in association with neurons. Many freshly dissociated Schwann cells from actively myelinating nerves express Po mRNA in high abundance. If neurons are not present, signal intensity falls markedly with time so that by 7 days in culture only a basal expression is evident which is negligible compared to the level in vivo. Dorsal root ganglia from embryo day 16 (E16) rats contain no significant levels of Po mRNA but when grown in full myelinating medium (containing serum and embryo extract) increasing expression is seen from 4 to 5 days onward even though myelination does not occur until after the second week. In this intervening period the intensity of P0 mRNA expression is lower than that found in the actively myelinating cell. Neurons from sympathetic ganglia are also capable of inducing P0 mRNA expression. Schwann cells in dorsal root ganglia explants grown in serum-free defined medium do not assemble a basal lamina and will not wrap or myelinate axons. Nevertheless P0 mRNA, but not protein, is expressed in levels similar to those found in full myelinating medium prior to myelination. Such Schwann cells also exhibit galactocerebroside and the sulphatide recognised by the 04 antibody. It appears that in defined medium or in myelinating medium prior to myelination axonal signals can induce P0 mRNA expression to a certain degree. However, full up-regulation is usually associated with the rapid membrane expansion accompanying myelination. Whether this augmented up-regulation is due to further axonal signalling or events in the Schwann cell is unknown, but the results suggest that P0 expression can be regulated at several stages of synthesis.

Regeneration of axons from adult human retina in vitro

In an effort to establish an in vitro model of regenerating adult human central nervous system (CNS) neurons, we have investigated the potential for neurite growth from explants prepared from normal adult human retina. Eyes (donated for corneal transplantation) were removed within 2.0 h postmortem and stored on ice for 1.5 to 7.0 days. Retinal explants (1 mm2) were prepared and cultured at 37 degrees C on cellular or acellular substrata in an oxygen-rich, humidified atmosphere. Neurite outgrowth, visualized by neurofilament immunofluorescence, was observed only in the presence of Schwann cells, after a quiescent period of approximately 6 days in vitro. Of 50 explants cultured for 7 days or more on substantia containing Schwann cells, 43 showed evidence of viability in vitro and 28 extended neurites onto Schwann cell surfaces. Estimated rates of neurite growth on Schwann cell substrata reached a maximum of 0.22 mm/day. Neurites did not grow beyond the explant border onto culture substrata composed of either polylysine, laminin, type-I collagen, or monolayers of adult human retinal glia. These results demonstrate that under selected conditions, explants prepared from adult human retina harbor viable neurons and that Schwann cells promote and support regeneration of neurites from these neurons in vitro, allowing systematic analysis of conditions favorable to axonal regeneration from adult human CNS neurons.

In vitro demyelination by serum antibody from patients with Guillain-Barré syndrome requires terminal complement complexes

Serum from 7 patients who had acute-phase Guillain-Barré syndrome with high anti-peripheral nerve myelin antibody activity (54 to 210 units/ml) was compared with serum from 3 patients in the recovery phase (0 to 17 units/ml) and serum from 7 disease control subjects (0 to 24 units/ml) and 7 normal control subjects (0 to 7 units/ml) for its ability to demyelinate rodent dorsal root ganglion cultures. The demyelinating capacity of each serum was quantitated by counting the percent of damaged internodal segments in each of four cultures. All sera from patients in the acute phase GBS caused 50 to 78% demyelination, in contrast with 6 to 19% by the sera from all 3 patients in the recovery phase and all other control subjects. The degree of demyelination correlated with anti-peripheral nerve myelin antibody activity of the sera and demyelination was complement-dependent. Further, cultures were treated with an immunoglobulin M (IgM) fraction of an acute-phase Guillain-Barré syndrome plasma plus normal human serum depleted of complement component C7. Only those cultures treated with IgM and C7-depleted human serum reconstituted with purified C7 resulted in 50.8% demyelination, which was significantly greater than the 14.2 to 16.2% demyelination observed in the presence of heat-inactivated, C7-depleted human serum plus purified C7 or in the absence of C7 or antibody. In summary, our work suggests that anti-peripheral nerve myelin antibody in Guillain-Barré syndrome mediated complement dependent-demyelination of rodent dorsal root ganglion cultures. Further, this in vitro demyelination required generation of activation complexes of the terminal complement cascade.

Axons induce differentiation of neurofibroma Schwann-like cells

Neurofibromatosis type 1 (NF-1, von Recklinghausen's disease) is characterized by the focal accumulation of Schwann-like cells (SLC) to form subcutaneous and plexiform neurofibromas and schwannomas. The aim of the present study was to determine whether NF-SLC are competent to differentiate in the presence of axons. Five dermal neurofibromas from five patients with NF-type 1 were enzymatically dissociated and the resultant cells were co-cultured with fetal rat dorsal root ganglion neurons. The cultures were studied by indirect immunofluorescence microscopy using antibodies against galactocerebroside (galC), P0 glycoprotein, human nerve growth factor receptor (NGFR) and human myelin-associated glycoprotein (MAG). SLC were strongly NGFR+ but galC- and MAG-SLC for the 2 weeks of coculture. After 3 weeks in vitro, SLC-NGFR was down-regulated but some of the spindle shaped cells had become galC+. MAG-SLC first appeared after 5 weeks in vitro but P0 glycoprotein was never detected when studied up to 6 weeks. Our data demonstrate that axons induce SLC to down-regulate surface NGFR and to express some myelin components in a qualitatively normal fashion.

L-3,4-dihydroxyphenylalanine synthesis by genetically modified Schwann cells

We have investigated whether Schwann cells can be modified by gene transfer to synthesize L-3,4-dihydroxyphenylalanine (L-DOPA), the immediate precursor in the formation of dopamine. By using a retrovirus containing a rat tyrosine hydroxylase (TH) cDNA, we established an immortalized rodent Schwann cell line that stably expressed high levels of TH and secreted L-DOPA in vitro when supplied with tyrosine and the essential cofactor biopterin. We also infected primary Schwann cells and demonstrated that cells expressing TH secreted L-DOPA while maintaining their capacity to myelinate neurons in vitro. This study indicate that it may be feasible to utilize autotransplantation of genetically modified Schwann cells to alleviate the movement disorders in Parkinson's disease.

Nucleosides influence the myelination of dorsal root ganglion cells in vitro; a quantitative comparison

alpha-Modified minimal essential medium (alpha MEM) is the most useful commercial medium for survival and myelin formation of dorsal root ganglia (DRGs). When components of alpha MEM are compared with those of other commercial media, nucleosides are found only in alpha MEM. We examined the effects of nucleosides on myelin formation in rat DRG cultures. When myelin formation was viewed quantitatively, cultures using alpha MEM with nucleosides yielded 2- to 3-fold more myelin segments than cultures using alpha MEM without nucleosides.

Modulation of endothelial cell surface glycoconjugate expression by organ-derived biomatrices

Cell surface molecules play an important role in cellular communication, migration, and adherence. Here, we show the effect of organ-derived biomatrices on endothelial cell surface glycosylation. Five different lectins (with and without neuraminidase treatment) have been used as probes in an enzyme-linked lectin assay to quantitatively detect glycoconjugates on endothelial cells (BAEC) grown on tissue culture plastic or biomatrices isolated from bovine lung, liver, and kidney. BAEC generally exhibit strong binding of concanavalin A (Con A), Ricinus communis agglutinin I (RCA-I), wheat germ agglutinin (WGA), and soybean agglutinin, and peanut agglutinin after neuraminidase pretreatment of cells (Neu-SBA and Neu-PNA), while SBA and PNA consistently bind weakly to BAEC. BAEC grown on organ-derived biomatrices exhibit significantly altered binding intensities of Con A, RCA-I, WGA, and Neu-PNA: BAEC cultured on lung- or kidney-derived biomatrices express significantly stronger binding affinities for Con A and RCA-I than BAEC grown on liver-derived biomatrix or tissue culture plastic. In contrast, BAEC binding of WGA and PNA (after treatment of cells with neuraminidase) is significantly reduced when BAEC are grown on liver- or kidney-derived biomatrix. Quantitative lectin immunogold electron microscopy reveals consistently stronger lectin binding over nuclear regions compared to junctional regions between neighboring cells. These results indicate that extracellular matrix components regulate endothelial cell surface glycoconjugate expression, which determines cellular functions, e.g., preferential adhesion of lymphocytes or metastatic tumor cells.

Evidence for electrogenic sodium-dependent ascorbate transport in rat astroglia

The dependence of ascorbate uptake on external cations was studied in primary cultures of rat cerebral astrocytes. Initial rates of ascorbate uptake were diminished by lowering the external concentrations of either Ca2+ or Na+. The Na(+)-dependence of astroglial ascorbate uptake gave Hill coefficients of approximately 2, consistent with a Na(+)-ascorbate cotransport system having stoichiometry of 2 Na+:1 ascorbate anion. Raising external K+ concentration incrementally from 5.4 to 100 mM, so as to depolarize the plasma membrane, decreased the initial rate of ascorbate uptake, with the degree of inhibition depending on the level of K+. The depolarizing ionophores gramicidin and nystatin slowed ascorbate uptake by astrocytes incubated in 5.4 mM K+; whereas, the nondepolarizing ionophore valinomycin did not. Qualitatively similar results were obtained whether or not astrocytes were pretreated with dibutyryl cyclic AMP (0.25 mM for 2 weeks) to induce stellation. These data are consistent with the existence of an electrogenic Na(+)-ascorbate cotransport system through which the rate of ascorbate uptake is modulated by endogenous agents, such as K+, that alter astroglial membrane potential.

Schwann cell plasminogen activator is regulated by neurons

The synthesis and release of plasminogen activators (PAs) in co-cultures of embryonic rat dorsal root ganglion nerve cells (NCs) and Schwann cells (SCs) were examined by metabolic labeling, immunoprecipitation, immunodepletion, SDS-PAGE, zymography, and a two-step esterolytic assay. Metabolic labeling of SC cultures followed by immunoprecipitation of the conditioned medium (CM) demonstrated that cultured SCs synthesized and released tissue type PA (tPA). Failure of amiloride to inhibit PA activity in SCCM indicated that urokinase PA (uPA) was unlikely to contribute significantly to PA activity in SCCM. Experimental manipulation of the NCs and SCs suggested that NCs regulated SC derived PA. Total PA activity increased in SCCM 10-14-fold by 6 days after removal of NCs. Multiple molecular weight forms of PAs were detected by SDS-PAGE followed by zymography. A PA approximately 95 kDa was absent in co-cultures of SCs + NCs but prominent by 4 days postdenervation; PA approximately 50-70 kDa increased through 8 days postdenervation and PA approximately 25 kDa, present in SC + NC cultures, was absent 8 days after removal of NCs. Upon reintroduction of NCs to denervated cultures (SCs), the pattern of PAs detected in culture medium was transitional between innervated and denervated cultures. Immunodepletion experiments using conditioned medium from denervated SC cultures indicated that various molecular weight forms of PA detected in SCCM by zymography were immunologically related to tPA. These studies demonstrate that SCs synthesized and released tPA in a tissue culture model of peripheral nerve and that one mechanism for regulation of PA released by SCs was by association with NCs. This regulation occurred in cultures of both myelinating and nonmyelinating Schwann cells and thus was not dependent on the state of myelination.

Retinal neurite growth on astrocytes is not modified by extracellular matrix, anti-L1 antibody, or oligodendrocytes

Two factors that may influence the course of axonal regeneration in the central nervous system (CNS) are extracellular matrix (ECM) and cell surface molecules that may enhance or inhibit neurite outgrowth. Whereas cultured astrocytes have been reported to be a good substratum for neurite outgrowth, there is recent evidence that cultured oligodendrocytes are inhibitory. To test the influences of 1) ECM components, 2) the L1 adhesion molecule, and 3) the inhibitory potential of mature oligodendrocytes in the astrocytic environment, we have utilized a culture system in which neurites from embryonic rat retina grow vigorously on astrocyte monolayers. The major ECM components were assembled in neonatal rat cortical astrocyte-retina co-cultures only when the medium contained serum. In electron microscopic studies of serum containing cultures, retinal neurites were seen to be related to astrocyte surfaces but rarely were found in contact with ECM; in serum-free medium the association between neurites and astrocytes was similar. In addition, the growth of neurites was vigorous whether ECM was present or absent. Presence of antibodies against the cell surface adhesion molecule L1 did not inhibit retinal neurite elongation on glial fibrillary acidic protein-positive astrocytes. When oligodendrocytes from adult rat spinal cord were combined with the astrocytes, retinal neurites grew as well on the mixed glial population as on astrocytes alone. Immunostaining for galactocerebroside showed many oligodendrocyte processes to be aligned in the direction of neurite growth, suggesting association between the two cell types. This association was verified by electron microscopy. Furthermore, retinal explants extended neurites among myelin basic protein-positive oligodendrocytes cultured without astrocytes. Thus, the astrocyte surface is a strong promoter of neurite growth from embryonic rat retina. This growth did not depend upon either ECM or the L1 adhesion molecule. Because neurites grew on astrocytes in the presence of mature oligodendrocytes or among oligodendrocytes alone, we conclude that oligodendrocytes do not inhibit neurite growth under certain conditions.

Schwann cell precursors and their development

During development of peripheral nerves, an apparently homogeneous pool of embryonic Schwann cells gives rise to two morphologically and antigenically distinct mature Schwann cell types. These are the myelin-forming cells associated with axons of larger diameter and the non-myelin-forming cells associated with axons of smaller diameter. The development of these cells from precursors that can be identified in early embryonic nerves can be followed with the help of antigenic differentiation markers. This development depends on Schwann cells retaining a close association with axons. The effect of axons can be mimicked in vitro by agents that elevate cAMP levels. This has given rise to the idea that the effects of axon-associated signals in Schwann cell development are to a significant extent mediated via elevation in Schwann cell cAMP levels. In vitro, the cAMP induced progression of cells from a premyelination state to a myelination state depends on withdrawal from the cell cycle. It is therefore possible that in vivo, the timing of myelin formation by individual Schwann cells is determined by signals that suppress proliferation.

Laminin and s-laminin are produced and released by astrocytes, Schwann cells, and schwannomas in culture

Components of the extracellular matrix (ECM) have been implicated in the regulation of neuronal migration, axonal growth, and synaptogenesis. We have examined cultures of glial cells, Schwann cells, and schwannomas for the expression of two components of the ECM, laminin and s-laminin, using immunohistochemical and Western blot techniques. Laminin is a potent promotor of neurite outgrowth in cultures of both central and peripheral neurons, and is present in all ECMs. In contrast, s-laminin (for synaptic laminin), a recently described homolog of laminin, is highly localized at the neuromuscular synaptic cleft (Sanes and Chiu, Cold Spring Harbor Symp. Quant. Biol. 1983;48:667-678; Chiu and Sanes, Dev. Biol. 1984;103:456-467) and shows selective adhesivity for motor neurons (Hunter et al. Cell 1989;59:905-913). While the distribution of these ECM components have been well documented in situ, the sources of these extracellular molecules are unclear. We report that astrocytes cultured in serum-free medium maintain an organized ECM that only bears laminin immunoreactivity; s-laminin appears to be sequestered intracellularly. However, both molecules are found in the astrocyte conditioned medium. Thus, under these growth conditions, astrocytes produce and release laminin and s-laminin, but only incorporate the former into an ECM. In contrast, neither molecule is present in comparable cultures of oligodendrocytes. Although no established ECM is seen in cultures of Schwann cells or schwannomas, laminin and s-laminin immunoreactivity are present within cells and in the conditioned media. These results indicate that certain populations of non-neuronal support cells and cell lines can produce and release both synaptic and extrasynaptic components of the ECM. The assembly of these different molecules into an organized basal lamina may require the presence of additional factors or interaction with neurons.

In vitro myelination of regenerating adult rat retinal ganglion cell axons by Schwann cells

Schwann cell cultures provide a highly favorable substrate for retinal ganglion cell (RGC) survival and axon growth in vitro (Bähr and Bunge, Exp Neurol 106:27, 1989; Hopkins and Bunge, Glia 4:46, 1991). In this report we have extended former studies to obtain axon regeneration, long-term survival, and myelination of adult rat RGC axons in co-cultures of retinal explants with purified Schwann cells. By using modified co-culture conditions, we observed myelination of regenerating adult RGC axons by Schwann cells after 3-4 weeks in vitro. Myelination was associated with a one-to-one Schwann cell-axon relationship, characteristic of the formation of peripheral myelin. Under culture conditions that supported myelination, long-term survival (more than 12 weeks) of a small population of RGCs was observed. These findings highlight the remarkable ability of Schwann cells to support long-term survival of adult rat RGCs in the absence of either central nervous system (CNS) target tissue or other peripheral nervous system (PNS) components. This tissue culture system may serve as a model for the systematic study of the molecular mechanisms which are involved in axon regeneration and myelination of adult CNS neurons.

Studies of the initiation of myelination by Schwann cells

The rapid morphologic changes in Schwann cells and in their relationships to axons during the transition from the premyelinating to the myelinating state have been known for more than 15 years. The sorting of axons by dividing Schwann cells, the establishment of a 1:1 relationship between a postmitotic Schwann cell, and the onset of myelin sheath formation have all been described in detail. However, the chain of molecular events and mechanisms by which these morphologic changes are regulated has not been elucidated. In this chapter we have reviewed results that strongly suggest that the adhesion molecule L1 is one of the important determinants that mediate the elongation of the Schwann cell along the axon, and the extension of Schwann processes to engulf axons. Thus, L1 functions to promote the spreading of the Schwann cell process over the surface of the axon. L1 does not appear to be exclusively involved in the adhesion of Schwann cells to axons, in the activation of Schwann cell proliferation by axons, or in the induction of synthesis of extracellular matrix proteins. The results from the anti-L1 blocking experiments further provided clues for an understanding of how the expression of GalC and MAG, which are both likely to be involved in the initiation of myelination, are regulated. These results imply that the overall regulation of expression of these early myelin components could require controls other than a single signaling mechanism derived from contact with axons. We propose that the deposition of basal lamina or one of its components could also be involved. Finally, the results from anti-GalC-blocking experiments indicated that GalC is involved in the mechanism of early growth of the myelin spiral.

Organ-preference of metastasis. The role of endothelial cell adhesion molecules

The initial, site-specific colonization of secondary organs by blood-borne cancer cells appears to be mediated by endothelial cell adhesion molecules. These molecules are part of the organ-specific microvascular phenotype and are regulated through complex interactions of the endothelium with the extracellular matrix (e.g., distinct matrix macromolecules and growth factors). They are induced in vitro by growing 'unspecific' (large vessel) endothelial cells on extracts of organ-specific biomatrices. In many respects, these molecules are similar to the various classes of chemically different adhesion molecules that regulate lymphocyte traffic, but are believed to be distinct from the inducible adhesion molecules that govern leukocyte adhesion during acute episodes of inflammation. Biochemical and biophysical data indicate that preference of tumor cell adhesion to organ-specific microvascular endothelium may not require qualitative differences of such homing receptors between endothelia, but may be explained on the basis of quantitative receptor differences as well as differences of receptor avidity. Following adhesion, the metastatic cascade proceeds by the establishment of metabolic conduits between the endothelium and adherent tumor cells. This heterotypic coupling represents an early step in the extravasation of cancer cells from the microvasculature, initiating endothelial cell retraction from its basement membrane and recanalization around the arrested tumor cell. These events, together with local growth promoting effects exerted by the metastasized organ, are believed to provide the basis for Paget's 'seed and soil' hypothesis of metastasis.

P0 mRNA expression in cultures of Schwann cells and neurons that lack basal lamina and myelin

Schwann cells of the peripheral nervous system depend on the presence of both axons and basal lamina to achieve a myelinating phenotype. Furthermore, removal of axonal influence results in the cessation of myelination and down-regulation of myelin protein expression by Schwann cells. Here we examine whether both axons and basal lamina are required by Schwann cells for the expression of mRNA encoding the major myelin glycoprotein, P0. Cultures of Schwann cells and neurons obtained from dorsal root ganglia of 15 day embryonic rat pups were grown for up to 20 days in vitro under conditions that either allowed or prohibited basal lamina and myelin formation. These cultures were assayed for the expression of P0 mRNA by using an S1 nuclease-protection assay. After 20 days in vitro, the cultures that did not assemble basal lamina and that were incapable of myelin formation expressed P0 mRNA at a level which was comparable to that seen in identically aged, myelinating cultures. Both the myelinating and nonmyelinating cultures demonstrated an appreciable increase in P0 mRNA when compared to the starting embryonic dorsal root ganglia Schwann cells. The latter had a low, but detectable, level of mRNa for this myelin glycoprotein. The cultures that were devoid of basal lamina and myelin showed a clear increase in P0 mRNA by 11-15 days in culture. This increase in expression depended on the presence of neurons/neurites, since Schwann cells which were grown in neuron-depleted cultures expressed little, if any, P0 mRNA. In contrast to the levels of P0 mRNA, the nonmyelinating cultures had a significantly lower amount of P0 glycoprotein than did the cultures which assemble myelin. This suggests that the nonmyelinating Schwann cells regulate the level of this glycoprotein at the translational and/or the posttranslational level. The data presented here suggest that myelin protein mRNA expression and myelin assembly by Schwann cells are separable events, with the former depending on one or more neuronal/axonal factors.

Resolution of the pathway taken by implanted Schwann cells to a spinal cord lesion by prior infection with a retrovirus encoding beta-galactosidase

This series of experiments is designed to follow the fate of implanted Schwann cells by first labeling them with a recombinant retrovirus encoding the bacterial beta-galactosidase gene, then injecting them into the spinal cord after a demyelinating lesion has been produced. The label provides a means of distinguishing the exogenous Schwann cells from endogenous ones and of determining their travel pattern and myelinating or ensheathing behavior in the central nervous system (CNS). Neonatal rat primary Schwann cells were stimulated to divide by administering glial growth factor and forskolin. Fresh virus-containing supernatant from Psi2 cells producing retrovirus LZ1 was placed in cell culture to label the cells. The capacity of infected Schwann cells to form myelin was verified by coculturing in vitro with neurons from embryonic dorsal root ganglia. Infected cells were injected into the right side of adult syngenic rat spinal cords after a lysolecithin-induced demyelinating lesion had been produced 1 cm caudal on the left side. After 3 weeks the animals were killed, perfused for electron microscopy, and spinal cord sections histochemically stained for beta-galactosidase activity using the chromogenic substrate 5-bromo-4-chloro-3-indoyl-beta-D-galactosidase (X-Gal) which forms a blue precipitate in infected cells. The labeled cells, easily recognized macro- and microscopically, were clustered at the cell injection site, in the dorsal meninges and, at the area of demyelination, bilaterally in the superficial aspect of the dorsal funiculi. Labeled cells were not evident in the neuropil midway between the injection and demyelination sites.(ABSTRACT TRUNCATED AT 250 WORDS)

Expression of recombinant myelin-associated glycoprotein in primary Schwann cells promotes the initial investment of axons by myelinating Schwann cells

Myelin-associated glycoprotein (MAG) is an integral membrane protein expressed by myelinating glial cells that occurs in two developmentally regulated forms with different carboxyterminal cytoplasmic domains (L-MAG and S-MAG). To investigate the role of MAG in myelination a recombinant retrovirus was used to introduce a MAG cDNA (L-MAG form) into primary Schwann cells in vitro. Stably infected populations of cells were obtained that constitutively expressed MAG at the cell surface without the normal requirement for neuronal contact to induce expression. Constitutive expression of L-MAG did not affect myelination. In long term co-culture with purified sensory neurons, the higher level of MAG expression on infected Schwann cells was reduced to control levels on cells that formed myelin. On the other hand, unlike normal Schwann cells, infected Schwann cells associated with nonmyelinated axons or undergoing Wallerian degeneration expressed high levels of MAG. This suggests that a posttranscriptional mechanism modulates MAG expression during myelination. Immunostaining myelinating cultures with an antibody specific to L-MAG showed that L-MAG was normally transiently expressed at the earliest stages of myelination. In short term co-culture with sensory neurons, infected Schwann cells expressing only L-MAG segregated and ensheathed larger axons after 4 d in culture provided that an exogenous basal lamina was supplied. Similar activity was rarely displayed by control Schwann cells correlating with the low level of MAG induction after 4 d. These data strongly suggest that L-MAG promotes the initial investment by Schwann cells of axons destined to be myelinated.

A new medium for in vitro peripheral nervous tissue myelination without the use of antimitotics

This paper describes a new medium which promotes myelin formation in cultures of rat dorsal root ganglia, and controls fibroblast proliferation. The medium, medium 'M', contains D-valine rather than L-valine and is added to cultures after seven days in vitro (DIV). The presence of D-amino acid oxidase in Schwann cells and neurons permits these cells to convert D-valine to L-valine, an essential amino-acid. Fibroblasts however lack D-amino acid oxidase but as some L-valine is present in the fetal calf serum component of medium 'M' those fibroblasts already present in the cultures by day 7 are maintained. Further fibroblast proliferation is however inhibited. The use of medium 'M' does not require the use of specific antimitotic agents making it cheaper and quicker to obtain myelinated cultures than with previous methods. The medium results in widespread myelin formation by 21 DIV. Cultures may be grown on plastic or collagen coated glass coverslips.

Regulation of ascorbic acid concentration in embryonic chick brain

The relationship between ascorbic acid concentration and cellular transport mechanisms was studied in chicken embryos (Gallus gallus domesticus). Unincubated (Day 0) fertile eggs did not contain detectable levels of ascorbic acid as assayed by high performance liquid chromatography with electrochemical detection. However, ascorbic acid concentration in brain increased to 5.6 nmol/mg tissue by Day 10 in ovo and then gradually declined 32% before birth. These levels were an order of magnitude greater than in skeletal muscle, where ascorbic acid concentration decreased sixfold between Days 8-20. Uptake of ascorbic acid was measured in brain cells that were either freshly isolated or grown in primary culture. Saturable, temperature- and Na(+)-dependent ascorbic acid transport was evident in freshly isolated cells as early as Day 6 and persisted throughout the period of ontogenic development. Primary cultures of embryonic chick brain cells were observed to take up ascorbic acid through a high-affinity (apparent Km = 37 microM, Vmax = 106 nmol ascorbic acid/g protein/min) mechanism. This transport system may maintain the high concentrations of ascorbic acid observed in the central nervous system during the ontogenic period when the levels of ascorbic acid in peripheral tissues change drastically.

Role of axons in the regulation of P0 biosynthesis by Schwann cells

The role of axons in the expression of the major myelin glycoprotein, P0, has been investigated using neuron/Schwann cell cultures. These cultures were either nonmyelinating or myelinating due to growth in defined medium or in medium containing serum and chick embryo extract, respectively. The neurons and Schwann cells used in the studies were derived from embryonic day 15 rat dorsal root ganglia (DRG), and the Schwann cells from these ganglia are shown not to synthesize appreciable levels of P0 prior to growth in culture. Myelinating cultures of Schwann cells and neurons grown together for 18-21 days synthesize P0 that is readily identified by immunoblotting. The nonmyelinating cultures, which do not assemble basal lamina, also synthesize P0 that is detectable by either [3H]mannose precursor incorporation or by immunoblotting. The steady-state level of P0 in the nonmyelinating cultures is less than that of the myelinating cultures, and the P0 that is synthesized by the former appears to be catabolized shortly after its biosynthesis. Since nonmyelinating Schwann cells synthesize P0 when in contact with neurites in vitro, we have examined the ability of such nonmyelinating cells to express the glycoprotein in vivo. Very little steady-state P0 is detected in immunoblots of the adult rat cervical sympathetic trunk (CST), a nerve in which approximately 99% of the axons are nonmyelinated. Similarly, the amounts of [3H]mannose and [3H]amino acids that are incorporated into newly synthesized P0 are much lower in the CST than in the adult sciatic nerve.(ABSTRACT TRUNCATED AT 250 WORDS)

Implantation of cultured sensory neurons and Schwann cells into lesioned neonatal rat spinal cord. I. Methods for preparing implants from dissociated cells

Our goal was to devise methods of implanting defined populations of the cellular constituents of peripheral nerve into regions of spinal cord injury. This objective derived from the knowledge that the cellular environment of peripheral nerve is known to be supportive of axon regeneration from both central and peripheral neurons. Two of the constituents of the peripheral nerve environment known to influence axonal growth are the Schwann cell and extracellular matrix (particularly basal lamina), both of which can be obtained in culture. We describe here large-scale methods of establishing purified populations of rat sensory neurons to which purified populations of Schwann cells were added. These essentially monolayer preparations were then scrolled and cut into lengths of proper shape and size to provide implants for sites of spinal cord injury in newborn rats. We also describe methods enabling the addition of leptomeningeal components to the implants; this addition contributes a proliferating population of vascular endothelial cells (identified by immunostaining) to the otherwise vasculature-free neuron/Schwann cell implant. Light and electron microscopic observations were made to characterize the implants. When the implant was ready for use, it contained Schwann cells that were differentiated, i.e., had begun to ensheathe axons and form basal lamina. The use of a medium containing human plasma to foster endothelial cell growth led to increased neurite fasciculation and Schwann cell migratory activity in the outgrowth, particularly when the neurons and Schwann cells were cultured on leptomeninges. The second paper in this series reports the deportment of these implants and their influence on corticospinal tract growth after placement into regions of dorsal column injury in neonatal rats (Kuhlengel et al., J. Comp. Neurol 293:74-91, 1990).

Catabolic regulation of the expression of the major myelin glycoprotein by Schwann cells in culture

Previous studies have suggested that neonatal Schwann cell cultures deprived of axonal contact do not express components of the myelin membrane, including the major myelin glycoprotein, P0. In contrast, Schwann cells from permanently transected, adult nerve exhibit continued biosynthesis of P0 after culture, suggesting that the ability to express the myelin glycoprotein may depend on the degree of cellular differentiation. To examine further the ability of Schwann cell cultures to express P0 as a function of age, we have performed precursor incorporation studies on endoneurial explants from 4- to 12-day-old rat sciatic nerves after 5 days in culture. The data reveal that explants from 12-day-old animals synthesize detectable levels of this integral myelin protein when assayed by [3H]mannose incorporation, even though there is no apparent myelin assembly in the cultures. Pulse-chase analysis of cultures from 12-day-old rats demonstrates that [3H]mannose-labeled P0 is substantially degraded within 3 h. This catabolism largely can be prevented by the addition of swainsonine, ammonium chloride, or L-methionine methyl ester to the pulse-chase media. The former agent alters oligosaccharide processing whereas the latter two compounds inhibit lysosomal function. The P0 synthesized by the 12-day explant cultures following the addition of swainsonine is readily fucosylated, implying that the protein has progressed at least as far as the medial Golgi before its exit and subsequent catabolism. If cultures from 4-, 6-, and 8-day-old animals are analyzed for P0 biosynthesis by [3H]mannose incorporation in the presence of swainsonine, detectable levels of the glycoprotein are seen.(ABSTRACT TRUNCATED AT 250 WORDS)

Growth of adult rat retinal ganglion cell neurites on astrocytes

Astrocytes, as well as Schwann cells (SC), can provide suitable substrata for embryonic neurites during development, but their abilities to support adult regenerating neurites have not been directly compared. The aim of the present study was to determine the ability of astrocytes to promote adult rat retinal ganglion cell (RGC) regeneration in vitro and to compare this to previously determined growth on the surface of Schwann cells. We prepared Type I astrocytes (Raff et al: J. Neurosci. 3:1289-1300, 1983) from perinatal rats. These were subcultured and maintained in either a serum-free medium for at least 2 weeks (stellate astrocytes with little immunoreactivity for laminin) or in serum containing medium for 7 to 10 days (flat and polygonal astrocytes with immunoreactivity for laminin). Stellate astrocytes might therefore represent mature astrocytes in vivo (Ard and Bunge: J. Neurosci. 8:2844-2858, 1988), while flat astrocytes might resemble immature brain astrocytes (Liesi et al: J. Cell Biol. 96:920-924, 1983). Adult RGC survival and axonal regrowth on these glia populations was compared to that observed on different SC populations, as previously reported (Baehr and Bunge: Exp. Neurol. 106:27-40, 1989). Both astrocyte populations (either flat or stellate astrocytes) did not enhance RGC survival. Stellate astrocytes were less effective in supporting RGC axon regeneration than flat astrocytes. When these date were compared to RGC survival and axon growth on SC (Baehr and Bunge: Exp. Neurol. 106:27-40, 1989) only "activated" mature SC populations were superior to astrocytes in enhancing RGC survival and neurite regrowth.(ABSTRACT TRUNCATED AT 250 WORDS)

Schwann cells depleted of galactocerebroside express myelin-associated glycoprotein and initiate but do not continue the process of myelination

Two peripheral myelin components, galactocerebroside (GalC) and myelin-associated glycoprotein (MAG), are known to be expressed early in Schwann cell differentiation, prior to the formation of definitive myelin segments containing compacted membrane. To discern the relative roles of these myelin components, cultures of Schwann cells and dorsal root ganglion neurons were treated with antigalactocerebroside mAbs in order to remove GalC from the Schwann cell surface (Ranscht et al., 1987). In the continuous presence of anti-GalC antibodies and in a medium containing serum plus ascorbic acid, Schwann cells assemble a basal lamina and progress to the one:one stage of Schwann cell:axon interaction but do not differentiate further. Immunostaining with anti-MAG antibodies revealed that GalC-depleted Schwann cells expressed high levels of MAG. Double staining with anti-MAG and anti-P0 antibodies showed that there was essentially no P0 immunoreactivity in the same cells. In those Schwann cells that had attained a one:one association with large-diameter axons, the inner-axon-related cytoplasmic process had passed under the outer mesaxon but had not completed a full turn around the axon. The expression of MAG on the single cytoplasmic process apposed to the axon in Schwann cells depleted of GalC further implicates MAG in the initial envelopment of the axon during myelination.

Substrate regulation of ascorbate transport activity in astrocytes

Astrocytes possess a concentrative L-ascorbate (vitamin C) uptake mechanism involving a Na(+)-dependent L-ascorbate transporter located in the plasma membrane. The present experiments examined the effects of deprivation and supplementation of extracellular L-ascorbate on the activity of this transport system. Initial rates of L-ascorbate uptake were measured by incubating primary cultures of rat astrocytes with L-[14C]ascorbate for 1 min at 37 degrees C. We observed that the apparent maximal rate of uptake (Vmax) increased rapidly (less than 1 h) when cultured cells were deprived of L-ascorbate. In contrast, there was no change in the apparent affinity of the transport system for L-[14C]ascorbate. The increase in Vmax was reversed by addition of L-ascorbate, but not D-isoascorbate, to the medium. The effects of external ascorbate on ascorbate transport activity were specific in that preincubation of cultures with L-ascorbate did not affect uptake of 2-deoxy-D-[3H(G)]glucose. We conclude that the astroglial ascorbate transport system is modulated by changes in substrate availability. Regulation of transport activity may play a role in intracellular ascorbate homeostasis by compensating for regional differences and temporal fluctuations in external ascorbate levels.

Functional status influences the ability of Schwann cells to support adult rat retinal ganglion cell survival and axonal regrowth

Properties of Schwann cells (SC) within the environment of the peripheral nerve can differ depending on their state of differentiation (e.g., quiescent, proliferating or mature SCs). In the present study we have tested the efficacy of SCs in different functional states to promote adult rat retinal ganglion cell (RGC) survival and neurite growth. We have used culture conditions which allowed regenerating retinal axons to contact SCs (1) as quiescent SCs that had not been in contact with axons, (2) as SCs that had been proliferating in contact with neurites, and (3) as mature SCs which had myelinated axons and deposited basal lamina around the axon-SC unit. Both proliferating and mature SCs were activated, i.e., were removed from axonal contact by inducing Wallerian degeneration, 2-3 days prior to testing their ability to support neuronal survival and neurite growth. Activated SCs, (derived from either proliferating or mature SCs) supported adult rat RGC survival and axonal regrowth significantly better than quiescent SC monolayers. Conditioned media (CM) derived from corresponding SC preparations (quiescent, proliferating, or mature SCs) supported short-term survival of RGCs and neurite outgrowth on defined substrata. A dissociation of substrate adsorbable neurite-promoting and nonadsorbable neurotrophic factors could be observed. The neurite-promoting activities found in CM were trypsin and heat sensitive, suggesting that the active component(s) is protein(s). None of the CM tested was able to support adult rat RGC survival and axonal growth as effectively as activated SCs (either proliferating or mature SCs). Long-term survival (greater than 4 days) of RGCs in explant cultures were especially dependent on RGC-neurite contact with preactivated SCs; CM derived from corresponding SCs (mature and proliferating SC-CM) were significantly less effective in supporting long-term survival. From these data we conclude that consideration must be given to the functional state of the SCs in experiments designed to utilize SCs in promoting CNS regeneration.

Movements of the Schwann cell nucleus implicate progression of the inner (axon-related) Schwann cell process during myelination

Although it has been known for several decades that peripheral myelin is formed from an extended, spiraled, and compacted sheet of Schwann cell (SC) plasma membrane, the mechanism by which this unique spiraling is accomplished remains unknown. We have studied the movements of SC nuclei before, during, and subsequent to myelin formation (over periods of 24-72 h) to determine if this nuclear motion (noted in earlier reports) would provide useful insights into the mechanism of myelinogenesis. We used rodent sensory neuron and SC cultures in which initiation of myelinogenesis is relatively synchronized and bright field conditions that allowed resolution of the axon, compact myelin, and position of the SC nucleus. Observed areas were subsequently examined by electron microscopy (EM); eight myelinating SCs with known nuclear movement history were subjected to detailed EM analysis. We observed that, prefatory to myelination, SCs extended along the length of larger axons, apparently competing with adjacent SCs for axonal surface contact. This lengthening preceded the deposition of compact myelin. SC nuclear circumnavigation of the axon was found to attend early myelin sheath formation. This movement was rarely greater than 0.25 turns per 3 h; on the average, more nuclear motion was seen in relation to internodes that formed during observation (0.8 +/- 0.1 turns/24 h) than in relation to those that had begun to form before observation (0.3 +/- 0.1 turns/24 h). Nuclear circumnavigation generally proceeded in one direction, could be in similar or opposite direction in neighboring myelinating SCs on the same axon, and was not proportional to the number of major dense lines within the myelin sheath. A critical finding was that, in all eight cases examined, the overall direction of nuclear movement was the same as that of the inner end of the spiraling SC process, and thus opposite the direction of the outer end of the spiral. We conclude that the correspondence of the direction of nuclear rotation and inner end of the spiraling cytoplasmic lip implicates active progression of the inner lip over the axonal surface to form the membranous spiral of myelin, the nuclear motion resulting from towing by the advancing adaxonal lip. This interpretation fits with finding basal lamina and macular adhering junctions associated with the external lip of SC cytoplasm; these attributes would imply anchorage rather than movement of this region of the SC.

Cultured Schwann cells assemble normal-appearing basal lamina only when they ensheathe axons

Previous work demonstrated that Schwann cells (SCs) must interact with nerve cells (NCs) in order to generate their basal lamina (BL) in culture (M. B. Bunge, A. K. Williams, and P. M. Wood, 1982, Dev. Biol. 92, 449-460). The present study was undertaken to determine if this interaction requires proximity of NCs to SCs. Coverslips carrying isolated SCs were placed into culture dishes containing normally contacting SCs + NCs, NCs alone, or SCs alone and were maintained in these dishes for 3-4 weeks in medium known to foster the differentiation of axon-related SCs (BL formation, myelination). The SCs on the coverslip were not allowed to contact the cells in the culture dish. In other experiments, SCs isolated on coverslips were simply cultured in medium conditioned by contacting SCs + NCs, NCs alone, or SCs alone. The accumulation of BL components was monitored by light microscopic immunocytochemistry and the assembly of BL structure assessed by electron microscopy. When SCs were cocultured with but not contacted by neurons, immunostaining for BL constituents revealed a patchy deposition of material in sharp contrast to the linear deposition observed on axon-related SCs. Electron microscopy of these isolated SCs revealed short segments of BL, strands or clumps of BL-like material extending away from the cell surface, and accumulation of this material between cells. A greater number of isolated SCs were immunostained when grown with contacting SCs + NCs than with NCs or SCs. The conditioned medium experiments yielded similar results; only patchy BL was observed and more immunostaining was detected on isolated SCs when the medium had been conditioned by contacting SCs + NCs than by NCs alone or SCs alone. Immunostaining was less overall in the conditioned medium experiments than in the cell coculture work. In addition, standard SC + NC cultures grown in differentiation-supporting medium were studied by electron microscopy. SCs that were not contacted by axons but were positioned between fascicles of normally contacting SCs + NCs were identified under phase microscopy and then examined for the presence of BL. These SCs exhibited only occasional segments of BL or detached BL-like material. Lastly, within differentiated fascicles, nonensheathing SCs were compared with neighboring myelinating SCs that were in substantial contact with axons. BL-deficient nonensheathing SCs were found directly adjacent to axons and BL-coated myelinating SCs.(ABSTRACT TRUNCATED AT 400 WORDS)

Membrane anchoring of heparan sulfate proteoglycans by phosphatidylinositol and kinetics of synthesis of peripheral and detergent-solubilized proteoglycans in Schwann cells

Previous studies have shown that Schwann cells synthesize both peripheral and integral hydrophobic cell surface heparan sulfate proteoglycans (HSPGs). The experiments reported here were undertaken to investigate the mode of attachment of these proteins to the cell surface and their potential interrelationship. The binding of the hydrophobic HSPGs to membranes appears to be via covalently linked phosphatidylinositol based on the observation that incubation of the detergent-solubilized protein with purified phosphatidylinositol-specific phospholipase C significantly reduces the ability of the HSPGs to associate with phospholipid vesicles in a reconstitution assay. The peripherally associated HSPGs were released from the cells by incubation in the presence of heparin (10 mg/ml), 10 mM phytic acid (inositol hexaphosphate), or 2 M NaCl. These treatments also solubilized basement membrane HSPGs synthesized by the Schwann cells. These data suggest that the peripheral HSPGs are bound to the surface by electrostatic interactions. The peripheral and hydrophobic HSPGs were identical in overall size, net charge, length of glycosaminoglycan chains, and patterns of N-sulfation. To determine whether the peripheral HSPGs were derived from the membrane-bound form by cleavage of the membrane anchor, we examined the kinetics of synthesis and degradation of the two forms of HSPGs. The results obtained indicated the existence of two pools of detergent-solubilized HSPG with fast (t1/2 = 6 h) and slow (t1/2 = 55 h) turnover kinetics. The data were consistent with a model in which the peripheral HSPGs were derived from the slowly turning over pool of detergent-solubilized HSPGs.

Perineurium originates from fibroblasts: demonstration in vitro with a retroviral marker

A cellular sheath, the perineurium, forms a protective barrier around fascicles of nerve fibers throughout the peripheral nervous system. In a study to determine the cellular origin of perineurium, a culture system was used in which perineurium forms after purified populations of sensory neurons, Schwann cells, and fibroblasts are recombined. Before recombination, the Schwann cells or the fibroblasts were labeled by infection with a defective recombinant retrovirus whose gene product, beta-galactosidase, is histochemically detectable in the progeny of infected cells. Perineurial cells were labeled when fibroblasts had been infected but not when Schwann cells had been infected. Thus, perineurium arises from fibroblasts in vitro and, by implication, in vivo as well.

Laminin and other basal lamina proteins with neurite promoting activity in medium conditioned by C6 glioma cells

Neurite promoting activities (NPFs) are essential factors in neuronal differentiation. Some of them are associated with proteins of the extracellular matrix (ECM). C6 cells, a rat glioma cell line, release NPF activities into the cell culture medium. We used antibodies against ECM-proteins for enrichment and partial characterization of these activities. Results show that, (1) C6 cells express and release laminin; (2) the C6-laminin consists of 260 kD chains only and is therefore different from typical basal lamina laminin (220 and 440 kD chains), but comparable to other laminins of glial origin (chains in the 200 kD range only); (3) C6-laminin partially purified by affinity chromatography shows NPF-activity; (4) laminin concentration in C6 cell-conditioned medium is not sufficient to account for the total neurite promoting activity of the medium, and (5) in addition to laminin C6 cells express and release fibronectin and possibly type IV collagen.

Evidence for an early role for myelin-associated glycoprotein in the process of myelination

The expression of myelin-associated glycoprotein (MAG) in purified rat Schwann cells following coculture with dorsal root ganglion neurons was compared with the expression of galactocerebroside (GalC) and Po using immunocytochemistry. In defined serum-free medium, lacking ascorbic acid, in which Schwann cells proliferate but neither ensheathe nor myelinate axons, axonal interaction up-regulated the cell surface expression of MAG and GalC but not of Po. Excision of neuronal cell bodies resulted in a down-regulation of both MAG and GalC from the Schwann cell surface. When cocultures were switched to complete medium (serum plus ascorbic acid) to promote myelination, Schwann cells committed to form myelin continued to express high levels of MAG and GalC on their surface, but nonmyelinating Schwann cells down-regulated MAG and GalC. There was significant MAG immunoreactivity associated with the external aspect of the apparent nodal region of developing myelin sheaths. Permeabilization prior to immunostaining revealed that all of the Schwann cell cytoplasmic processes of nascent internodes were significantly stained with anti-MAG antibodies before the appearance of Po immunoreactivity. The amount of MAG on the surface of mature myelin segments was reduced compared with developing myelin segments, but there was a considerable amount of anti-MAG staining in the paranodes and Schmidt-Lanterman incisures. The time of expression and localization of MAG indicates that it may be a critical molecule in the process by which the Schwann cell engulfs an axon destined to be myelinated and establishes the extent of the future internode.