Synthesis and effects of basement membrane components in cultured rat Schwann cells

Laminin promotes differentiation, adhesion and proliferation of cell cultures derived from human acoustic nerve schwannoma

The influence of laminin on cell cultures derived from unilateral acoustic nerve schwannomas was investigated. Cell cultures were initiated from 12 schwannomas, removed via the enlarged middle cranial fossa approach. Tumor tissue was dispersed by collagenase treatment and cells seeded in uncoated or laminin-coated culture dishes. Confluent cultures were immunocytochemically characterized with antibodies against S-100, CD 68, factor VIII-related antigen and type IV collagen. Cell adhesion in response to different doses of laminin was evaluated with an electronic cell counter. The effect of laminin on cell proliferation was assessed by measuring the incorporation of 5-bromo-2'-deoxy-uridine (BRDU) into cellular DNA. Cells cultured on laminin as substrate appeared more differentiated with long, fusiform, cytoplasmic processes. Cultured cells stained positive for S-100, not for factor VIII-related antigen or CD 68. Only cells cultured on laminin deposited a dense extracellular network of type IV collagen. When laminin was added to the culture medium, cell attachment and proliferation was stimulated in a dose dependent manner. Maximal stimulation of both was observed with a laminin concentration of 50 micrograms/ml, which induced a nearly 2-fold increase in cell attachment and an approximately 66% increase in DNA content. Since laminin is a major component of the extracellular matrix in schwannomas, the possibility exists that laminin is also mitogenic for human neoplastic Schwann cells in situ.

Schwann cells in neuroblastoma

Why should we consider Schwann cells when we are interested in the biology of neuroblastomas (NBs)? Although we are familiar with the term "stroma-rich" NB, we basically think of a favourable prognostic subgroup, histologically distinguished by the development of a prominent Schwann cell-stroma. According to current opinion on the maturation processes in NBs, the NB-associated Schwann cell is believed to represent a differentiation product of the NB cell, and we therefore do not envisage the Schwann cell as having any important role in NBs. However, our interest was raised after having realised that Schwann cells in NBs are normal cells, very likely attracted to the neoplastic neuroblasts. But what role does this cell play in these tumours? Can we still reduce the appearance of Schwann cells in NBs to an epi-phenomenon or is this cell population responsible for the differentiation of certain NBs? If so, will it be possible to use their strategies to induce differentiation of neuroblasts and so render them non-aggressive, mature ganglionic cells? To shed light on the possible interactions between normal Schwann cells and NB cells, the maturation capacity of NBs and the genetic constitution of the two main cell populations in these tumours are briefly reviewed. Some data leading to the current view on the origin of the Schwann cells in NBs, and several physiological aspects of the Schwann cells, including normal neurone-Schwann cell interactions, are detailed.

Axotomy of rat facial nerve induces TGF-beta and latent TGF-beta binding protein

Transforming growth factor-beta (TGF-beta) has been found to be abundantly and specifically expressed in the nervous system. However, the function of TGF-beta during nerve regeneration is still unknown. We have examined the expression of TGF-beta isoforms and the latent TGF-beta binding protein (LTBP) by immunohistochemistry in the rat facial nuclei after unilateral axotomy. An increased immunoreactivity for all the TGF-beta isoforms and the LTBP was observed in the facial nuclei of the injured side during the regeneration period examined until Day 24. These differences were tested statistically by nominal logistic regression analysis. When the intensity of the immunoreactivity in the injured side was compared to that of the contralateral side, significantly increasing differences were found for TGF-beta 2 (p < 0.003) and LTBP (p < 0.002). Strong immunostaining was detected in the neuronal perikarya and their axons. No clear immunoreactivity was seen in either microglia or astrocytes. The enhanced immunoreactivity was seen in the operated side already at Day 3, remaining at high level with some fluctuations until Day 12 or 24 after axotomy. These findings suggest that TGF-beta might play a functional role in the regeneration of motor neurons.

Laminin SIKVAV peptide-induced angiogenesis in vivo is potentiated by neutrophils

Angiogenesis has been investigated in vivo using subcutaneously injected reconstituted basement membrane (Matrigel) supplemented with angiogenic factors. Previously we found that the laminin-derived synthetic peptide containing SIKVAV (ser-ile-lys-val-ala-val) promoted angiogenesis in vivo. In parallel studies, it was observed that new vessel formation in response to this peptide occurred several days after basic fibroblast growth factor-induced angiogenesis. Since this delay suggested that SIKVAV-induced angiogenesis may be secondary to other events, we investigated here earlier time points to determine if both indirect and direct mechanisms of angiogenesis are involved. We found that neutrophils are continuously recruited to the SIKVAV-containing plugs between 4 hours to 3 days following the initial injection. By day 7, columns of endothelial cells begin to migrate into the plug and form small blood vessels. In contrast, neutropenic mice had a 62% reduction in SIKVAV-induced angiogenesis when compared to control mice. Freshly isolated neutrophils also degraded laminin, the major component of the basement membrane Matrigel. These cells also produced factors in response to SIKVAV peptide which induced proliferation of human umbilical vein endothelial cells relative to a control peptide. In vitro experiments utilizing human neutrophils demonstrated that these cells migrate to the SIKVAV peptide and possess a specific cell surface SIKVAV binding protein of approximately 56 kD. These data suggest that neutrophils are induced to migrate to the Matrigel plugs, at least in part, by SIKVAV peptide, where they may release their own angiogenic factors and degrade the matrix, thus physically facilitating cell migration and liberating additional angiogenic matrix fragments and/or cytokines.

Beta 4 integrin expression in myelinating Schwann cells is polarized, developmentally regulated and axonally dependent

In developing and regenerating peripheral nerve, Schwann cells interact with axons and extracellular matrix in order to ensheath and myelinate axons. Both of these interactions are likely to be mediated by adhesion molecules, including integrins, which mediate cell-cell and cell-extracellular matrix interactions. Recently, the beta 4 integrin subunit was reported to be expressed by Schwann cells in peripheral nerve. We have examined the expression of beta 4, beta 1 and their common heterodimeric partner, the alpha 6 integrin subunit, in developing and regenerating rat peripheral nerve. beta 4 and alpha 6 are enriched in peripheral nerve and they co-localize at the abaxonal surface of myelinating Schwann cells, opposite the Schwann cell basal lamina, which contains possible ligands of alpha 6 beta 4. In contrast, beta 4 and alpha 6 are expressed in a different pattern in non-myelinating Schwann cells. The level of beta 4, but not alpha 6 or beta 1 mRNAs, increases progressively in developing nerves, reaching a peak in adult nerves well after the peak of the myelin-specific mRNAs. After axotomy, the expression of beta 4 mRNA and protein, but not alpha 6 or beta 1 mRNAs, fall rapidly but subsequently are reinduced by regenerating axons. Similarly, in cultured Schwann cells, the expression of beta 4 mRNA, but not alpha 6 mRNA, is significantly modulated by forskolin, a drug that elevates cAMP and mimics some of the effects of axonal contact. beta 4 integrin expression in Schwann cells, therefore, is regulated by Schwann cell-axon interactions, which are known to be critical in determining the Schwann cell phenotype. Furthermore, the polarized expression of alpha 6 beta 4 to the abaxonal surface of myelinating Schwann cells suggests that alpha 6 beta 4 may mediate in part the morphological changes required of Schwann cells in the process of myelination in the peripheral nervous system.

Effects of nerve segment supernatants on cultured Schwann cell proliferation and laminin production

Mouse sciatic nerves were transected and 3 hr to 16 days later proximal segments were removed and homogenized. Supernatants of these segments or of normal sciatic nerves were added to Schwann cells maintained in Dulbecco's modified Eagle's medium (DMEM) + 15% fetal calf serum (FCS). After 6 days, Schwann cells were solubilized and the protein content was measured using a Bio-Rad (Melville, NY) protein assay. Samples containing the same amounts of protein were then applied to microtiter plates and the laminin content was determined by enzyme-linked immunosorbent assay (ELISA). Lysates of cultures treated with 24 hr proximal segment supernatants contained significantly higher levels of laminin than those prepared from other intervals, from distal segments, or from control nerves. Increased surface and cytoplasmic anti-laminin immunoreactivity also was found in Schwann cells treated with 24 hr supernatants. To identify the source(s) of this effect, proximal segments removed 24 hr after transection were bisected; supernatants were prepared from each half and tested. Significant increases in laminin production were produced by supernatants from both halves. When supernatants from proximal and distal halves were compared, the latter produced significantly higher laminin levels. Electron microscopic examination of both halves showed that distal halves contained sprouting neurites and growth cones ensheathed by Schwann cells which had a basal lamina and resembled those seen during development and regeneration. Proximal halves appeared normal. Schwann cell proliferation also was compared in supernatant-treated cultures by using a bromodeoxy-uridine (BrdU) ELISA. The 24 hr and 2 day supernatants increased Schwann cell proliferation significantly; 12 hr, 4 day, and 8 day supernatants produced smaller increases. Our observations suggest that axons undergoing early regenerative changes are one of several possible sources of substance(s) in our proximal segment supernatants which increased Schwann cell proliferation and laminin production.

Serum activity induces Schwann cell proliferation in vitro

The present series of experiments demonstrate that a polypeptide activity present in rat serum induces a proliferative response in cultured rat Schwann cells. Schwann cells in multi-well tissue culture plates were incubated in medium containing 10% heat-inactivated fetal bovine serum and serial dilutions of normal rat serum, and control preparations were incubated in the same culture medium without rat serum. Rates of cell proliferation were assayed by measuring DNA incorporation of tritiated thymidine using liquid scintillation counting. A prominent dose-dependent proliferative response was observed among Schwann cells incubated with rat serum and rat plasma dilutions as compared to controls; this activity is abolished by heat inactivation and by proteolytic digestion, and was not affected by dialysis against a cellulose ester membrane that excludes molecules larger than 10,000 daltons. In contrast, no increase in DNA uptake of tritiated thymidine was observed when astrocyte and oligodendrocyte cultures were incubated with serial dilutions of rat serum. No proliferative effect was observed when rat Schwann cells were incubated with a dilution of standard adult bovine serum. These results suggest there is an intravascular plasma polypeptide with a molecular weight greater than 10,000 daltons that specifically stimulates Schwann cell proliferation, and it is proposed that this factor may be the mitogen responsible for the Schwann cell proliferative response known to occur after nerve injury.

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)

Localization of a laminin-binding protein in brain

A 110,000 mol.wt laminin-binding protein from newborn mouse brain recognizes a neurite promoting laminin A chain site and is related to the beta-amyloid precursor protein. In the present study, we examined the expression of 110,000 mol.wt laminin-binding protein in brains of adult mice, rats, and non-human primates. Essentially identical immunoreactivities were observed across species with distinct staining of cortical pyramidal neurons with apical dendrites, cerebellar basket cell axons, hippocampal mossy fibers, and fine labeling of processes throughout the brain. Colocalization of immunoreactivities to 110,000 mol.wt laminin-binding protein and to laminin in neurons of the adult rat brain was observed. Electron microscopy demonstrated that 110,000 mol.wt laminin-binding protein-like immunoreactivity is intracellular and is possibly associated with the neuronal cytoskeleton. Western blot analysis revealed that anti-110,000 mol.wt laminin-binding protein also recognizes a 140,000 mol.wt protein in the pellet, in addition to the 110,000 mol.wt protein in the Triton soluble extract. Antibody fractions specific to the two reactive protein species (110,000 mol.wt and 140,000 mol.wt) exhibited cross-reactivity on immunoblots and revealed similar immunohistochemical staining in adult brain. Results suggest a significant interaction between laminin-like molecules and 110,000 mol.wt laminin-binding protein-like molecules in normal brain function, in response to CNS injury and possibly in the pathogenesis of Alzheimer's disease.

Plexiform schwannoma. Immunohistochemistry of Schwann cell markers, intermediate filaments and extracellular matrix components

An immunohistochemical study using a comprehensive panel of antibodies to Schwann cell markers, intermediate filaments and extracellular matrix components has been performed on three cases of plexiform schwannoma. All tumour cells expressed S 100 protein, Leu 7-HNK 1 antigen and vimentin; glial fibrillary acidic protein was detected in many tumour cells. In addition, expression of cytokeratin was also demonstrated in one case. The associated extracellular matrix was found to be reactive with antibodies to laminin, heparan sulfate proteoglycan, fibronectin, type I, III, IV and VI collagen. It is concluded that Schwann cells producing their own extracellular matrix are the main components of these tumours. The significance of the cytokeratin expression and the possible role of the extracellular matrix in regulating Schwann cells' proliferation in peripheral nerve tumours are discussed.

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.

Regulation of cell function by extracellular matrix

The extracellular matrix (ECM) provides structural support and adhesive substrates for the body tissues. Recent advances in our understanding of the biology of matrix indicate that the ECM also plays a significant role in regulating the behavior of cells. Matrix proteins engender changes in cell shape and movement, bind growth factors, and facilitate cell-cell and cell-matrix interactions. Matrix-induced differentiation results from multiple stimuli that include: tensile forces on the cell, cytokine- or growth factor-mediated stimulation, and interaction with bioactive domains of matrix glycoproteins. Because these signals are important determinants of cell behavior, pharmacological manipulation of cell-matrix interactions may offer a valuable new approach to disease treatment.

The laminins: a family of basement membrane glycoproteins important in cell differentiation and tumor metastases

Laminins are a family of basement membrane-derived glycoproteins that are very biologically active with a number of diverse cell types. The response of the cells is dependent on the cell type and various cell-specific intracellular events are activated. Multiple active sites on laminin and cellular receptors have been described. Both laminin and the synthetic peptides that define the active sites may have important clinical uses. For example, the neurite-promoting peptides may be useful in vivo in regeneration studies because of their potent activity with neural cells and their lack of antigenicity. Also, peptides, such as YIGSR, that inhibit angiogenesis are potentially useful for treating the vascularization of the eye that occurs in conditions such as diabetes mellitus. Likewise, the angiogenic peptide SIKVAV, because of its role in endothelial cell block vessel formation, may be useful for treating ischemia. The recent progress that has been made in characterizing basic mechanisms of action of laminin has laid the groundwork for more direct studies of its clinical relevance.

Role of laminin in endothelial cell recognition and differentiation

The vascular endothelium normally is maintained in a quiescent state, but under certain conditions it is induced to undergo marked changes in behavior and form new vascular structures. A complex interaction among various growth and differentiation factors and the extracellular milieu regulates this behavior. One series of signals affecting endothelial behavior is provided by laminin, a major structural protein of basement membrane. These signals have been studied using Matrigel, a reconstituted basement membrane preparation from the murine Englebreth-Holm-Swarm sarcoma, in an in vitro assay of endothelial cell differentiation. Three biologically-active sequences from the laminin molecule have been evaluated. Synthetic peptides that include the sequences -RGD-, -YIGSR-, and -SIKVAV- mediate, respectively, cell binding to Matrigel, alterations in cell morphology, and induction of migration and collagenase activity. Preliminary data indicate that observations made with this system may be relevant to endothelial function in vivo. Endothelial cell differentiation on Matrigel may thus be a useful in vitro model for the study of certain steps in angiogenesis.

Tenascin: a modulator of cell growth

The large, multidomain extracellular matrix protein tenascin displays a markedly restricted tissue distribution during embryogenesis and remains present only in a few adult tissues. The protein is reexpressed, however, during wound healing and in the stroma of malignant tumours. While a variety of studies have dealt with the important role of tenascin in the development of neural and non-neural tissues, there is growing evidence that tenascin expression may be associated with proliferation of cells lining these tissues. The presence of repeating domains in tenascin similar to those in epidermal growth factor prompted us to investigate the ability of tenascin to modulate the growth of different cell types. Tenascin was actually found to be mitogenic for several cell types. This mitogenic activity, however, appears to be associated with a region in the fibronectin type III domains. The mitogenic mechanism is clearly distinct from pathways used by peptide growth factors such as epidermal growth factor and platelet-derived growth factor, which activate the intrinsic tyrosine kinase activity of their cell-surface receptors. However, we show that this large extracellular matrix molecule is efficiently internalised and may be processed by responding cells.

Laminin--developmental expression and role in axonal outgrowth in the peripheral nervous system of the chick

The possible role of laminin on axon outgrowth and guidance in vivo was examined by: (1) determining its developmental expression, and relationship to outgrowth of sensory, motor and sympathetic axons in the chick embryo; and (2) evaluating the changes in the pattern of sympathetic preganglionic projections subsequent to injections of laminin, antilaminin and other laminin function blockers (JG22, INO) into their pathways during axon outgrowth. Double immunofluorescent staining for laminin and neurofilaments in peripheral nerves prior to and during initial outgrowth showed no obvious relationship between laminin and potential nerve pathways. Even though weak laminin immunostaining is apparent throughout the mesenchyme through which axons grow, the most prominent laminin immunostaining is on basement membranes of the neural tube, notochord and dermamyotome. However, as peripheral nerves mature, laminin becomes localized to nerve fascicles throughout the peripheral nervous system, beginning with the dorsal and ventral roots, and progressing later to more distal spinal nerves. Microinjections of antilaminin, JG22 (a monoclonal antibody against laminin/fibronectin receptors) and INO (a monoclonal antibody against a laminin-heparan sulfate proteoglycan complex) into the pathway of sympathetic preganglionic axons prior to and during outgrowth had no effect on the spatio-temporal patterns of sympathetic preganglionic projections. An alternate laminin-rich pathway produced by injecting laminin into the region of the sympathetic trunk immediately adjacent but caudal to the T1 spinal level also did not alter the projection of T1 preganglionic axons. These results suggest that laminin may not be crucial to the initial of peripheral axons. The localization of laminin in nerve fascicles in later stages of development suggests instead that laminin may be important in the maintenance of these structures.

Laminin immunohistochemistry in brain is dependent on method of tissue fixation

Normal adult and lesioned rat and mouse brains were fixed by formaldehyde perfusion by two methods that differ primarily in the length of the post-fixation period. Sections were subsequently immunostained using monoclonal and polyclonal antibodies to laminin. With relatively short post-fixation periods (up to 4 h), vascular basement membrane (BM)-laminin was immunostained, but intraneuronal laminin-like immunoreactivity was faint. With longer post-fixation periods (18-24 h), intraneuronal laminin-like immunoreactivity was distinct, while vascular BM-laminin immunoreactivity was reduced drastically. These findings are particularly relevant to studies examining laminin immunoreactive blood vessels in response to lesions, especially ischemic stroke. In fact, the present results suggest that the apparent neovascularization or up-regulation of vascular BM-laminin following CNS injury likely relates to differences in regional tissue fixation.

The mutant axolotl Short toes exhibits impaired limb regeneration and abnormal basement membrane formation

The mutant axolotl Short toes develops with abnormal kidneys, Mullerian ducts, and limbs and provides one of the few experimental systems for developmental studies in amphibia. The present paper describes another deviation from this animal's normal physiology, which is very characteristic of the wild type: amputated limbs of Short toes fail to regenerate. A blastema is formed but differentiation does not occur. Detailed histological analysis provides evidence of abnormal formation of the basement membrane and accumulation of extracellular matrix within the blastema, which could be attributed to an imbalance of extracellular matrix and basement membrane proteins. The basement membrane develops much thicker and is convoluted in the arrested blastema of mutant animals. In contrast to the limbs, the tails of Short toes regenerated normally with no apparent abnormalities. No gross genomic aberrations have been detected between normal and mutant DNA, indicating that a large deletion or insertion is not likely to be the cause of this mutation.

Dual and asynchronous deposition of laminin chains at the epithelial-mesenchymal interface in the gut

The production of laminin by 14-day fetal rat intestinal endoderm and mesenchyme was investigated. The amount of neosynthesized laminin was measured after purification using affinity chromatography. Chain composition of laminin was analyzed by immunoblotting and immunofluorescence staining. The data show that both embryonic intestinal tissue components synthesize laminin and that A and B1/B2 chains were detected in both endodermal and mesenchymal cells. The cellular source of laminin found at the epithelial basement membrane has been studied by immunocytochemistry in rat/chick or mouse/chick interspecies hybrid intestines taken at various stages of development. Immunodetection of the whole laminin molecule and of the individual A and B1/B2 chains by rodent-specific polyclonal and monoclonal antibodies at the basement membrane level in these hybrid intestines revealed (a) laminin molecules, which originate from both mesenchymal and endodermal cells; (b) deposition of A and B1/B2 chains by endodermal cells, regardless of the stage of growth of the hybrid intestines; and (c) asynchronous deposition of the various chains of laminin into the basement membrane by the mesenchyme. B1/B2 chains are deposited concomitant with contact with the epithelium, whereas A chains appear only later (13 days after grafting). These data reinforce the suggestion from previous studies that cooperation between epithelium and mesenchyme is necessary for the formation of a complete basement membrane in the developing intestine.

Establishment and characterization of a mouse Schwann cell line which produces myelin in vivo

A Schwann cell line (MSC 80) was established from purified mouse Schwann cell cultures using large doses of serum. MSC 80 cell line is an aneuploid cell line which has a doubling time of 17 hr and has been maintained through more than 110 passages. Most of MSC 80 cells are of bipolar or stellate (3-5 processes) shape. A few others are irregular in shape, gigantic, and multinucleated. All MSC 80 cells express antigens of myelin-forming Schwann cells such as S-100, 224/58, laminin, and other glycoproteins of the extracellular matrix. However, they also express the non-myelin-forming Schwann cell antigen GFAP. By time-lapse cinematography, MSC 80 cells exhibit the Schwann cell characteristic rhythmical undulations. When induced to form aggregates in agar, they form intercellular junctions and basement membrane-like structures. In addition, after transplantation in or at a distance from a lysolecithin induced lesion, MSC 80 cells form myelin around the host demyelinated axons. MSC 80 cells thus express, when isolated in vitro, some of the normal myelin-forming Schwann cell phenotype. In addition, they present the major advantage of forming myelin when associated with axons in vivo.

Basement membrane and fibronectin matrix are distinct entities in the developing mouse blastocyst

Immunocytochemical techniques were used to study the distribution of fibronectin, type IV collagen (collagen-IV), and laminin in four different stages of mouse blastocyst development. Immunoreactivity for collagen-IV and laminin is present in a granular pattern inside the inner cell mass (ICM) cells in stage 1 blastocysts, while these blastocysts are negative for fibronectin. Fibronectin immunoreactivity appears extracellularly under the trophectoderm (TE) in stage 2 blastocysts, in the form of homogeneously distributed dots, and/or fibrils located preferentially close to cell boundaries. It is followed by the appearance of both collagen-IV and laminin immunoreactivity in patches on the basal side of the TE in stage 3 blastocysts. These patches are initially localized under the central region of TE cells, thus in a location clearly different from that of fibronectin-positive fibrils. As development proceeds the collagen-IV- and laminin-positive patches become larger, covering, by stage 4, an extensive portion of the inner lining of the blastocoel. Fibronectin-positive material is still present in a fibrillar form in stage 3 blastocysts, but is generally reduced to thin strands by stage 4. These results indicate that fibronectin is independent of the mouse blastocyst basement membrane, but may play a transient role in cell adhesion during its deposition. In addition, the results suggest that the ICM plays a major role in the production of collagen-IV and laminin, while the basal surface of TE cells is the primary site of basement membrane assembly.

The olfactory nerve contains two populations of glia, identified both in vivo and in vitro

The peripheral olfactory nervous system exhibits, uniquely, neuronal cell body replacement and reestablishment of central connections in adult mammals. The role of the olfactory nerve glia in these phenomena is unknown, but information might be provided by in vitro systems. This paper reports on the characterization of olfactory nerve glia in dissociated cell cultures of newborn rat nasal mucosal tissues. The predominant type of glial cell resembled Schwann cells and immunostained for the S-100 protein, found in all glial cell types; glial fibrillary acidic protein (GFAP), found in astrocytes and nonmyelinating Schwann cells; and showed binding of 217C, a monoclonal Schwann-cell marker that binds to the low-affinity NGF receptor in glioma cells. They were negative for A2B5. The Schwann-cell-like olfactory glia changed morphology upon culturing in serum-free medium, with further shape changes after plating on laminin. Plating on laminin increased cell numbers. A second population, found only after GFAP-immunostaining, was astrocyte-like in morphology and represented approximately 10 percent of all glial cells. These were S-100-, A2B5-, and 217C-negative, a unique glial cell immunological profile. At low dilutions of anti-GFAP (1/10,000), or with weak fluorescent secondary antibodies, astrocyte-like glia were immunostained but Schwann-cell-like glia were not detectable. Astrocyte-like glia were not an artifact of the dissection, since they were detectable in tissue sections of newborn-rat olfactory nerves immunostained with a low dilution of anti-GFAP. The presence of two types of glial cells in culture suggests similarities between olfactory glia and enteric glia.

Extracellular matrix of newly forming vessels--an immunohistochemical study

During wound healing, embryological development, and solid tumor growth, the established vasculature gives rise to large numbers of new blood vessels. This neovascular response occurs at the level of the capillary bed, where endothelial cells divide rapidly, locally remodel the surrounding stroma, and migrate away from existing vessels to form capillary sprouts. In order to examine the environment of these newly forming vessels, actively growing blood vessels in neovascularized rabbit and guinea pig corneas were examined immunohistochemically using antibodies against laminin, type IV collagen, heparan sulfate proteoglycans, entactin, and factor VIII-related antigen. Sequential serial 5-microns sections taken from the unfixed frozen corneas in a plane perpendicular to the direction of vessel growth were stained with these antibodies. It was possible to follow well-defined lumenized vessels out through sequential sections to the point where they became single factor VII-R positive cells in the region of the capillary sprout. Examination of these stained sections has shown the presence of four important basement membrane components--laminin, type IV collagen, heparan sulfate proteoglycan, and entactin--associated with actively migrating and invading capillary sprouts. These results suggest that the extracellular matrix of the actively invading capillary sprouts does not differ qualitatively from that of the established vasculature.

Mitogenic response of rat Schwann cells to fibroblast growth factors is potentiated by increased intracellular cyclic AMP levels

Rat sciatic nerve Schwann cells either do not proliferate, or proliferate very slowly, in medium containing 10% fetal bovine serum (FBS). They were previously shown to respond only to a limited number of mitogens associated with cells of central and peripheral nervous systems, which appeared to be distinct from FGFs and PDGF, and to agents that raise intracellular cAMP levels. In a basal medium consisting of 75% DMEM, 25% Ham's F-12, 5 nM sodium selenite, 50 microM 2-amino ethanol, and 2 mM histidine, supplemented with 5% FBS, we showed that aFGF, bFGF, and PDGF were all capable of stimulating Schwann cell growth and the stimulation was greatly potentiated by forskolin and dibutyryl-cAMP. In addition, pretreating culture surface with purified matrix proteins such as laminin, fibronectin, or type 1 collagen, was necessary for obtaining a better cellular response to the mitogenesis of these growth factors even in 10% FBS. Our results clearly indicated that providing a suitable medium and substratum, aFGF, bFGF and PDGF are mitogens for rat sciatic nerve Schwann cells in medium with and without forskolin or dibutyryl-cAMP.

Age-related changes in attachment and proliferation of mouse Schwann cells in vitro

Schwann cells can be cultured readily from the peripheral nerves of the neonatal animal but not from the adult. To correlate the physiological properties of Schwann cells relevant to such a difference, we examined age-related changes in attachment and proliferation of mouse Schwann cells in vitro. The capacity of Schwann cells to attach to polylysine-coated coverslips at 1 day in vitro declined rapidly between 3 and 30 days of age, followed by a more gradual decrease with age. Attachment of Schwann cells from younger mice (but not older mice) was enhanced by precoating coverslips with laminin or to a lesser degree with fibronectin, suggesting an age-dependent decrease in receptors for these substrates. Indeed, the staining for fibronectin receptor could be demonstrated in vivo, and was more intense and diffuse in neonatal sciatic nerves. In vitro, although staining of Schwann cells and fibroblasts was clear, there was no age-related difference for the intensity or distribution of the staining. Proliferation, as assessed by thymidine incorporation at 1 day in vitro, was high when Schwann cells were isolated from younger mice but declined as a function of the age of mice from which cells were prepared. Removal of axonal and myelin debris from cultures 3 h after plating resulted in a reduction of thymidine uptake by Schwann cells from 30-day-old mice, but much less from 10-day-old mice. Schwann cell growth was faster in the cells from younger mice than older ones, thus leading to early confluency and cell-contact inhibition in the former. In addition, evidence is presented that in medium supplemented with fetal bovine serum, thymidine uptake by Schwann cells from mice at 3-30 days of age was three times higher than that by Schwann cells from age-matched rats. These results indicate that the methodology usually used for purification of rat Schwann cells involving antimitotics is not suitable for highly proliferating mouse Schwann cells.

Adhesion and proliferation are enhanced in vitro in Schwann cells from nerve undergoing Wallerian degeneration

Proliferation of Schwann cells during nerve degeneration or regeneration is well documented in vivo. We investigated whether the proliferative response of Schwann cells to injury is retained in vitro. Using 5-month-old male C57BL mice, Schwann cells were isolated from sciatic nerves under 3 experimental conditions: (1) uninjured, (2) after permanent nerve-transection, or (3) after nerve-crush, which permits axonal regeneration. Schwann cells rarely attached to polylysine-coated coverslips when isolated from uninjured or 1 day posttransection/crush nerves. The number of adherent cells increased when Schwann cells were isolated 3 days after nerve-transection or -crush. When cells were isolated from transected nerves, cell adhesion reached a peak 2 weeks after the injury and then declined. Maximal attachment of Schwann cells occurred when the cells were isolated 2-4 weeks after nerve-crush. The percentage of Schwann cells with spreading processes corresponded closely with the number of thymidine-labeled cells at 1 day in vitro. The in vitro capacity of cells to spread and incorporate thymidine reached maximal levels at 5 days posttransection/crush. Capacity of cells to spread and incorporate thymidine subsequently decreased with time following transection. However, a biphasic elevation in cell spreading and thymidine incorporation was observed in Schwann cells isolated from crushed nerves. Maximal growth of Schwann cells in vitro occurred at 1-2 weeks posttransection and at 1-4 weeks postcrush. Adhesion and spreading of Schwann cells were promoted by coating coverslips with laminin or fibronectin. Preincubation of Schwann cells with soluble laminin or fibronectin prevented the initial cell attachment induced by the corresponding protein. Our results suggest that Schwann cells from injured nerves possess binding sites for laminin and fibronectin, which are, in part, responsible for the enhanced adhesion of Schwann cells in vitro. This study provides a new method for preparation of Schwann cells from peripheral nerves of adult mice.

Neutrophil chemotactic factors

Polymorphonuclear leukocytes (neutrophils) are recruited to inflammatory sites by a variety of soluble mediators (chemoattractants) that stimulate neutrophil directed migration (chemotaxis). Many neutrophil chemoattractants such as neutrophil activating proteins, leukotriene B4 (LTB4), platelet activating factor, and complement-derived C5a, are generated endogenously by host cells or enzymatic cleavage of host proteins. Other chemoattractants such as N-formyl peptides are generated exogenously by bacteria that invade the host. Oxidative modification of methionine residues or changes in the amino acid sequence of peptide chemoattractants dramatically alter their chemoattractive properties. Many of the well-defined neutrophil chemotactic factors and studies of their structure-function relationships will be reviewed.

Laminin through its long arm E8 fragment promotes the proliferation and differentiation of murine neuroepithelial cells in vitro

The epigenetic factors involved in regulating the proliferation and differentiation of cells of the developing mammalian central nervous system are largely unknown. In this study, laminin, a molecule which is present in the basal lamina from the earliest stage of neural tube formation, has been examined in vitro for its possible regulatory role in mammalian neural development. Purified populations of murine neuroepithelial (NEP) cells isolated from the 10-day embryonic telencephalon and mesencephalon respond in vitro to laminin by undergoing aggregation, proliferation, and extensive neurite elaboration. The proliferation and differentiation of NEP cells induced by the interaction with laminin were dependent upon an early cell aggregation, since precoating of wells with poly-L-ornithine, a procedure which prevented such aggregation, completely blocked these responses. The previously reported proliferative effect of acidic fibroblast growth factor (FGF) on NEP cells was found to be synergistic with that of laminin. This observation is consistent with the idea that laminin may regulate cell responses in several ways: by direct stimulation via laminin receptors; by optimal presentation of FGF molecules to neural cells; and finally by upregulation of FGF receptor numbers on responsive cells. The in vitro response of laminin is mimicked by its long arm elastase digestion fragment, E8, whereas the cross arm fragment of laminin, E1-4, had no effect. In addition, antibodies specific for epitopes on the long arm blocked the effect seen with the whole laminin molecule. Binding studies of 125I-labeled laminin and its fragment performed on freshly isolated NEP cells confirmed the specificity of the in vitro observations: whole laminin and the E8 fragment bound to the NEP cell surface whereas the E1-4 fragment did not. These studies demonstrate mechanisms by which laminin, specifically through its long arm fragment, may assert a regulatory function during development of the mammalian central nervous system.

Schwann cell proliferation in vitro is under negative autocrine control

In healthy adult peripheral nerve, Schwann cells are believed to be generally quiescent. Similarly, cultures of isolated rat sciatic nerve Schwann cells hardly proliferate in serum-supplemented medium. The possibility that Schwann cells negatively regulate their own proliferation was supported by the demonstration that conditioned media from Schwann cell cultures inhibited the proliferation of mitogen-stimulated test cultures. The inhibition could be complete, was dose dependent, and was exhibited when the test Schwann cells were under the influence of different types of mitogens such as cholera toxin, laminin, and living neurons. The inhibition of proliferation was completely reversible and a rapid doubling of cell number resulted when treatment with conditioned medium was withdrawn from mitogen-stimulated Schwann cells. Conditioned medium from cholera toxin-stimulated and immortalized Schwann cell cultures contained less antiproliferative activity than that found in medium from quiescent Schwann cell cultures. However, media conditioned by two actively proliferating rat Schwannoma cell lines were rich sources of antiproliferative activity for Schwann cells. Unlike the mitogen-stimulated Schwann cells, whose proliferation could be inhibited completely, the immortalized and transformed Schwann cell types were nearly unresponsive to the antiproliferative activity. The antiproliferative activity in Schwann and Schwannoma cell conditioned media was submitted to gel filtration and SDS-PAGE. The activity exists in at least two distinct forms: (a) a high molecular weight complex with an apparent molecular mass greater than 1,000 kD, and (b) a lower molecular weight form having a molecular mass of 55 kD. The active 55-kD form could be derived from the high molecular weight form by gel filtration performed under dissociating conditions. The 55-kD form was further purified to electrophoretic homogeneity. These results suggest that Schwann cells produce an autocrine factor, which we designate as a "neural antiproliferative protein," which completely inhibits the in vitro proliferation of Schwann cells but not that of immortalized Schwann cells or Schwannoma lines.

Tissue-specific distribution of a novel component of epithelial basement membranes

Monoclonal antibodies against basement membrane (BM) were generated using the matrix deposited by cultured rabbit corneal epithelial cells as immunogen. BM antibodies were identified by immunofluorescent staining of frozen tissue sections and of extracellular matrix of living cultured cells. BM localization was confirmed by immunoelectron microscopy. Antibody AE26 immunoprecipitates a 140,000 Mr component from radiolabeled corneal epithelial cells and recognizes this component plus a 95,000 Mr band on Western blots. The antigen resists extraction by high and low salt and by nonionic detergents, but is solubilized in 4 M urea/1% mercaptoethanol. On isoelectric focusing and nonequilibrium pH gradient gels, AE26 antigen migrates to the acidic region (pI less than 3). The molecule is destroyed by trypsin, but is insensitive to bacterial collagenase. In frozen tissue sections, AE26 stains only BM of stratified epithelia plus trachea, ureter, lung, and intestine, but no other epithelial or nonepithelial BM. AE26 antigen is detected on Western blots of cornea, skin, and lung extracts, but not liver, kidney, or muscle, indicating that this is not due to masking of the epitope. This tissue distribution is different from any previously described BM molecule. Although we have not ruled out the possibility that AE26 recognizes a modification or fragment of a known BM component (particularly entactin), the acidic pI, collagenase resistance, and unusual tissue specificity suggest that AE26 recognizes a new BM protein. The BM heterogeneity demonstrated by AE26 may play a structural role or provide positional signals to the overlying epithelium.

Immunoelectron microscopic localization of laminin in normal and regenerating mouse sciatic nerve

Laminin, the major non-collagenous protein of basement membranes, has been shown to be a potent stimulator of neurite outgrowth, to potentiate neuronal survival and to stimulate Schwann cell division in vitro. The aim of the present study was to determine the ultrastructural localization of laminin in the mouse sciatic nerve during development and regeneration in order to elucidate whether laminin might also evoke similar effects in vivo. For this purpose polyclonal antibodies against laminin were used for pre-embedding electron microscopic immunocytochemistry of tissue sections from mouse sciatic nerves. In the adult, although laminin immunoreactivity was found to be predominantly associated with basement membranes as expected, the surface membranes of Schwann cells also displayed weak labelling. This distribution pattern was similar in developing sciatic nerves with the exception that laminin immunoreactivity was generally higher and also found to be present on interstitial collagen fibres. One week following sciatic nerve transection, strong laminin immunoreactivity was seen on regenerating axons growing along laminin-positive basement membrane tubes in the distal stump of the transected nerve. Our results demonstrate that laminin immunoreactivity is not restricted to basement membranes of the mouse sciatic nerve, but is also found in direct contact with adult, developing and regenerating axons as well as on the surface of Schwann cells. The finding of laminin immunoreactivity on extracellular matrix components, axons and Schwann cell membranes under conditions of growth and regeneration makes it more likely that axons are able to interact with laminin not only in vitro but also in vivo.

Proliferation and differentiation of a transfected Schwann cell line is altered by an artificial basement membrane

Rapidly dividing transfected Schwann cells were grown on Matrigel, a reconstituted basement membrane gel. Matrigel decreased the proliferation of the cells by 75% when compared to sister cultures that were grown on an untreated plastic substrate. Some transfected cells plated onto a Matrigel substrate formed colonies similar to that observed when the cells were plated on a plastic substrate. Additionally, many cells on Matrigel assembled themselves into fascicles projecting away from the colonies. These fascicles were composed of transfected Schwann cells that had assumed a bipolar appearance reminiscent of quiescent secondary Schwann cells in culture. Transfected cells grown on Matrigel contained approximately 10-fold less glial fibrillary acidic protein when compared to sister cultures grown on an untreated plastic substrate. By indirect immunofluorescence laminin immunoreactivity appeared as globules within the cytoplasm of the cells which were cultured on a plastic substrate. However, cells that were grown on the Matrigel substrate appear to organize laminin in a linear array around themselves. These results demonstrate that the presence of an artificial basement membrane alters the morphology, rate of proliferation, and state of differentiation of a transfected Schwann cell line.

Transforming growth factor-beta and gamma-interferon have dual effects on growth of peripheral glia

The influence of transforming growth factor-beta (TGF-beta) and gamma-interferon on DNA synthesis in Schwann cells and enteric glia in culture has been studied. TGF-beta stimulated the DNA synthesis of short-term (less than 2 weeks in culture) Schwann cells, whereas gamma-interferon was ineffective. The stimulatory effect of TGF-beta was additive to the stimulation of DNA synthesis due to axonal membrane fragments. In contrast to their effect on short-term Schwann cells, both TGF-beta and gamma-interferon inhibited DNA synthesis in enteric glial cells and in long-term (over 3 months in culture) Schwann cells. When short-term Schwann cells were stimulated to divide by axolemma or glial growth factor, gamma-interferon did not inhibit this enhanced DNA synthesis although it suppressed DNA synthesis induced by cAMP analogues. These results raise the possibility that TGF-beta and gamma-interferon might have a role in controlling glial proliferation during development and/or regeneration of the peripheral nervous system.

Transforming growth factors-beta 1 and beta 2 are mitogens for rat Schwann cells

Transforming growth factor-beta 1 (TGF-beta 1) and TGF-beta 2 were found to be potent mitogens for purified rat Schwann cells, each stimulating DNA synthesis in quiescent cells and also increasing their proliferation rate. Half-maximal stimulation of DNA synthesis occurred at approximately 0.1 ng/ml TGF-beta 1 or TGF-beta 2. Mitogenic stimulation by TGF-beta 1 and TGF-beta 2 was enhanced by forskolin, which activates adenylate cyclase, at concentrations up to 0.5 microM forskolin. However, at 5 microM forskolin, the synergistic interaction between forskolin and TGF-beta 1 was abolished. These results are in contrast to the observed synergy between forskolin and another Schwann cell mitogen, glial growth factor (GGF). Both 0.5 and 5 microM forskolin were found to enhance the stimulation of DNA synthesis by partially purified GGF (GGF-CM). As well as being functionally distinct, TGF-beta 1 and GGF-CM activities were also physically separable by chromatography on a Superose 12 gel permeation column. Thus, TGF-beta 1 and beta 2 are rat Schwann cell mitogens, and Schwann cells are one of the few normal cell populations to respond mitogenically to TGF-beta.

Rat sciatic nerve Schwann cell microcultures: responses to mitogens and production of trophic and neurite-promoting factors

During embryonic development and in response to injury, the growing axons of peripheral neurons may influence the migration and proliferation of Schwann cells which, in return, may present neurons with a critical supply of factors required for neuronal survival, growth and differentiation. The identification and characterization of agents influencing the proliferation of Schwann cells as well as Schwann cell production of factors affecting neurons is greatly facilitated by the use of in vitro techniques. We describe here a simplified method of obtaining large numbers of purified neonatal rat sciatic nerve Schwann cells for use in generating large numbers of replicate microcultures. We then illustrate the use of these microcultures to examine Schwann cell: i) morphology and survival; ii) proliferation; and iii) production of neuronotrophic and neurite-promoting activities. We report that rat Schwann cells in microculture proliferate in response to serum, laminin and fibronectin, cholera toxin, and chick embryo parasympathetic ciliary neurons. Also, extracts of Schwann cell microcultures contain independently regulated activities which support the survival and neurite outgrowth of peripheral ganglionic neurons.

Basement membrane heterogeneity and variation in corneal epithelial differentiation

We have previously shown that the expression of a major 64-Kda keratin (K3) in corneal epithelium is site-related. It is found suprabasally in limbal epithelium, but uniformly (basal cells included) in central corneal epithelium. In the present study, we used a panel of antibodies against various components of corneal epithelial basement membrane to investigate a possible correlation between basement membrane heterogeneity and differential (basal vs. suprabasal) K3 keratin expression. One of these antibodies, AE27, stains human conjunctival basement membrane weakly, limbal basement membrane heterogeneously, and central corneal basement membrane strongly. Basal cells resting on basement membrane that stains strongly with AE27 tend to stain with monoclonal antibody AE5, which recognizes keratin K3. Basal cells on basement membrane staining weakly with AE27 tend not to stain with AE5. No such correlation exists between AE5 staining and type IV collagen, which is detectable immunohistochemically in conjunctival and limbal basement membrane, but not in corneal basement membrane overlying Bowman's layer. These results suggest that basement membrane of human corneal/conjunctival epithelium can be divided into at least three domains: the conjunctival basement membrane (type IV collagen-positive, AE27-weak), the limbal basement membrane (type IV collagen-positive, AE27-strong), and corneal basement membrane (type IV collagen-negative, AE27-strong). The results also raise the possibility that basement membrane heterogeneity may play a functional role in regulating keratin expression and other aspects of differentiation of corneal epithelium; more experiments are needed to test this hypothesis.

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)

Type I collagen preparations inhibit DNA synthesis in glial cells of the peripheral nervous system

The mechanisms underlying cessation of glial proliferation in the developing peripheral nervous system are obscure. One possibility, as yet little explored, is that mitotic inhibitory signals play a part in regulating glial cell numbers. In this study we demonstrate that type I collagen preparations from several different sources can inhibit the rate of DNA synthesis in purified populations of enteric glia and both short-term and long-term secondary Schwann cells in dissociated cell cultures. When these cells are grown on gelled or dried type I collagen substrata, they proliferate at substantially lower rates than on polylysine substrata. In contrast, type III or V collagen preparations do not inhibit glial DNA synthesis and laminin, fibronectin, type IV collagen, and secreted matrix from bovine corneal endothelial cells all stimulate thymidine incorporation. The inhibitory effect is not observed with heat denatured type I collagen preparations, but is seen equally in serum-containing medium, in medium containing fibronectin-free serum, or in serum-free medium, suggesting that the interaction of collagen with the cells requires structurally intact collagen molecules and does not occur via intermediary linkage to fibronectin. The inhibition on collagen is accompanied by a shape change from a more flattened morphology to a narrow spindle form. The labeling index of a rat Schwannoma cell line, 33B, is not inhibited on type I collagen substrata. These results demonstrate that type I collagen preparations inhibit the DNA synthesis levels of early postnatal peripheral glial cells in vitro. It remains to be determined whether this effect occurs via direct collagen-cell membrane interactions or whether it depends on accessory molecules, perhaps present in the collagen preparations themselves, since these are not purified to absolute homogeneity.

Antagonistic effects of laminin and fibronectin on the expression of the myogenic phenotype

Skeletal myoblasts from fetal muscle respond adversely to fibronectin and laminin substrata: when primary mouse skeletal myoblasts are plated onto laminin, more myosin and desmin-positive myoblasts (myo+ cells) develop than on plates coated with fibronectin or collagen. In clonal cultures virtually all cells differentiate into postmitotic, fusion-capable myo + myoblasts on laminin after 3 days. In contrast, on fibronectin, the majority of the cells becomes myosin- and desmin-negative, partially due to proliferation of undifferentiated myoblast precursor cells, partially due to dedifferentiation or modulation of myoblasts into fibroblast-like myo- cells. Loss of the myogenic phenotype on fibronectin was also observed in cloned mouse myoblasts and in cultures of a differentiating mouse satellite cell line, MM14Dy, confirming that the appearance of desmin-negative cells is a result of myoblast modulation and not due simply to overgrowth by muscle fibroblasts. In the light of other effects of laminin on myoblasts, such as the stimulation of migration, differentiation and proliferation, our findings are consistent with the notion that laminin and fibronectin may be counteracting factors in the control of muscle differentiation.