Basal lamina formation by cultured microvascular endothelial cells

The production of a basal lamina by microvascular endothelial cells (MEC) cultured on various substrata was examined. MEC were isolated from human dermis and plated on plastic dishes coated with fibronectin, or cell-free extracellular matrices elaborated by fibroblasts, smooth muscle cells, corneal endothelial cells, or PF HR9 endodermal cells. Examination of cultures by electron microscopy at selected intervals after plating revealed that on most substrates the MEC produced an extracellular matrix at the basal surface that was discontinuous, multilayered, and polymorphous. Immunocytochemical studies demonstrated that the MEC synthesize and deposit both type IV collagen and laminin into the subendothelial matrix. When cultured on matrices produced by the PF HR9 endodermal cells MEC deposit a subendothelial matrix that was present as a uniform sheet which usually exhibited lamina rara- and lamina densa-like regions. The results indicate that under the appropriate conditions, human MEC elaborate a basal lamina-like matrix that is ultrastructurally similar to basal lamina formed in vivo, which suggests that this experimental system may be a useful model for studies of basal lamina formation and metabolism.     

Basal lamina of avian ovarian follicle: influence on morphology of granulosa cells in-vitro

Experiments were conducted to determine the influence of basal lamina on the morphology of ovarian granulosa cells in vitro. Pure and intact basal lamina was isolated from the large preovulatory follicles of the chicken ovary and designated basal lamina of avian ovarian follicle (BLAOF). Examination of the isolated basal lamina with electron microscope revealed an ultrastructure that is similar to that of basal lamina in the intact ovarian follicle. Pieces of the intact basal lamina were attached to the bottom of 32 mm culture dishes (BLAOF-coated dishes) in which differentiated granulosa cells isolated from the largest preovulatory follicle or undifferentiated granulosa cells isolated from immature small yellow chicken ovarian follicles were cultured; uncoated dishes served as controls. Granulosa cells incubated on intact basal lamina assumed spherical shape, whereas granulosa cells incubated directly on plastic in control dishes became highly flattened. Interestingly, granulosa cells that attached to plastic close to BLAOF (in BLAOF-containing dishes) became rounded. The storage of BLAOF-coated culture dishes at 4°C for 2 years had no apparent effect on its ability of the matrix material to induce changes in granulosa cell shape. Some components of the basal lamina could be solubilized with guanidine–HCl alone (fraction 1; 90–95% of total protein in BLAOF) with the remaining components solubilized with β-mercaptoethanol containing guanidine–HCl (fraction 2; 5–10% of total protein in BLAOF). Differentiated and undifferentiated chicken granulosa cells became rounded when incubated in fraction 1-pre-coated wells; whereas those incubated directly on plastic in control wells were flattened. Similarly, when fraction 1 of solubilized basal lamina was added as liquid to incubation mixture, it caused both differentiated and undifferentiated granulosa cells to assume spherical shapes. The storage of fraction 1-coated culture dishes at 4°C for 12 or more months had no apparent effect on its ability to influence granulosa cell shape. Fraction 1-induced changes in granulosa cell shape were similar to those observed for complete and intact basal lamina (BLAOF). These findings demonstrate that intact homologous basal lamina (BLAOF) or its solubilized (fluidized) form can induce normal (in vivo) morphology in granulosa cells. It is suggested that BLAOF or its solubilized form can be used to culture cells in experiments designed to examine the influence of the natural basal lamina microenvironment on cellular behavior and function.     

Synthesis by Schwann cells of basal lamina and membrane-associated heparan sulfate proteoglycans

Primary cultures that contain only Schwann cells and sensory nerve cells synthesize basal lamina. The assembly of this basal lamina appears to be essential for normal Schwann cell development. In this study, we demonstrate that Schwann cells synthesize two major heparan sulfate-containing proteoglycans. Both proteoglycans band in dissociative CsCl gradients at densities less than 1.4 g/ml, and therefore, presumably, have relatively low carbohydrate-to-protein ratios. The larger of these proteoglycans elutes from Sepharose CL-4B in 4 M guanidine hydrochloride (GuHCl) at a Kav of 0.21 and contains heparan sulfate and chondroitin sulfate chains of Mr 21,000 in a ratio of approximately 3:1. This proteoglycan is extracted from cultures by 4 M GuHCl but not Triton X-100 and accumulates only when Schwann cells are actively synthesizing basal lamina. The smaller proteoglycan elutes from Sepharose CL-4B at a Kav of 0.44 and contains heparan sulfate and chondroitin sulfate chains of Mr 18,000 in a ratio of approximately 4:1. This proteoglycan is extracted by 4 M GuHCl or by Triton X-100. The accumulation of this proteoglycan is independent of basal lamina production.     

Basal lamina secreted by MDCK cells has size- and charge-selective properties

The role electrical charge plays in determining glomerular permeability to macromolecules remains unclear. If the glomerular basement membrane (GBM) has any significant role in permselectivity, physical principles would suggest a negatively charged GBM would reject similarly charged more than neutral species. However, recent in vivo studies with negative and neutral glomerular probes showed the opposite. Whether this observation is due to unique characteristics of the probes used or is a general physiological phenomenon remains to be seen. The goal of this study was to use the basement membrane deposited by Madin-Darby canine kidney epithelial cells as a simple model of a biologically derived, negatively charged filter to evaluate size- and charge-based sieving properties. Fluorescein isothiocyanate-labeled carboxymethylated Ficoll 400 (FITC-CM Ficoll 400) and amino-4-methyl-coumarin-labeled Ficoll 400 (AMC Ficoll 400) were used as negatively charged and neutral tracer molecules, respectively, during pressure-driven filtration. Streaming potential measurement indicated the presence of fixed, negative charge in the basal lamina. The sieving coefficient for neutral Ficoll 400 decreased by ～0.0013 for each 1-? increment in solute radius, compared with a decrease of 0.0023 per ? for the anionic Ficoll 400. In this system, molecular charge played a significant role in determining the sieving characteristics of the membrane, pointing to solute charge as a potential contributor to GBM permselectivity.     

Basal lamina and the organization of neuromuscular synapses

Fast chemical synapses are comprised of presynaptic and postsynaptic specializations precisely aligned across a protein-filled synaptic cleft. At the vertebrate neuromuscular junction (NMJ), the synaptic cleft contains a structured form of extracellular matrix known as a basal lamina (BL). Synaptic BL is molecularly differentiated from the BL that covers the extrasynaptic region of the myofiber. This review summarizes current understanding of the morphology, composition, and function of the synaptic BL at the vertebrate NMJ. Considerable evidence supports the conclusion that the synaptic BL organizes and maintains pre- and postsynaptic specializations during development and regeneration, and promotes robust neurotransmission in the adult.     

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)     

Basal lamina formation by porcine thyroid cells grown in collagen- and laminin-deficient medium

Summary Porcine thyroid cells isolated by dispase treatment were cultured in either (a) Matrigel, (b) agarose with the addition of different combinations of basic fibroblast growth factor and laminin, or (c) on agarose-coated dishes. The formation of follicles and the presence of a basal lamina was investigated by routine electron microscopy of Araldite-embedded material and by light and electron microscopical immunocytochemical detection of the basal lamina components, laminin and collagen type IV. After 10 days of culture in Matrigel or agarose, a basal lamina-like structure surrounded most follicles. Follicles of cells growing in agarose and overlaid with a medium containing thyrotropin and fibroblast growth factor showed a fluorescent band at the basal side of the follicles after immunocytochemical staining with anti-laminin and anti-collagen antibodies. Routine electron microscopy showed that a basal lamina-like structure lined the outside of the follicle. This structure could be subdivided into a lamina lucida and a lamina densa. Electron microscopical immunogold labelling revealed that immunologically detectable laminin was confined to the lamina densa. These findings suggest that even in the absence of basal lamina components in the culture medium, thyroid cells are able to form follicles with a regular basal lamina when they are cultured in a three-dimensional environment.     

Basal lamina of ovarian follicle regulates an inward Cl- current in differentiated granulosa cells

Patch-clampexperiments were conducted to study the effects of basal lamina(basement membrane) of preovulatory chicken ovarian follicle onmembrane currents in differentiated chicken granulosa cells in ahomologous system. The membrane capacitance (measure of total membranearea) was smaller in cells cultured on intact basal lamina than that ofcontrol cells. The granulosa cells expressed outward and two inwardcurrents. A small fraction of the cells (3%) expressed only atransient fast-activating and -inactivating inward current carried byCa²⁺. The majority of the cells, however, expressed aslowly activating and inactivating inward current (carried byCl) that was superimposed on the transientCa²⁺ current. All cells expressed an outward currentcharacteristic of the delayed-rectifier K⁺ current. Theremoval of extracellular Ca²⁺ led to elimination of theslow inward Cl current, indicating that it is aCa²⁺-dependent Cl current. Both peakamplitude and current density of the inward Cl currentwere significantly lower in cells cultured on freshly isolated intactbasal lamina (or basal lamina stored at 4°C for 12 mo) than those ofcontrol cells; however, basal lamina had no significant effect on thedensity of the outward current. Similar to the observations made forintact basal lamina, solubilized basal lamina suppressed the inwardCl current in differentiated granulosa cells. These datashow that homologous basal lamina modulates aCa²⁺-dependent Cl current in differentiatedgranulosa cells. These findings provide a partial explanation for themechanisms that subserve the reported effects of basal lamina (basementmembrane) on the metabolic functions of differentiated granulosa cells.

     

Role of basal lamina in Schwann cell glycolipid biosynthesis

Schwann cells that are deprived of axonal contact switch their glycolipid metabolic pathway from primarily galactocerebroside (GalCe) synthesis to the formation of glucocerebroside (GlcCe) and its homologs. The removal of axonal influence has a dual effect on Schwann cell phenotype; they lose the ability to assemble both myelin and basement membrane. To determine whether a loss of basement membrane directly affects glycolipid expression, we have examined lipid biosynthesis in Schwann cells which were allowed to interact with axons of dorsal root ganglion neurons but which were deprived of the ability to assemble basal lamina. These Schwann cells resemble those from myelinating nerve in that they synthesize a large amount of galactohydroxycerebroside. This suggests that axon contact, even in the absence of basement membrane, is sufficient to induce the GalCe metabolic pathway.Abbreviations DRG dorsal root ganglia - GalCe galactocerebroside - GalCe-OH galactohydroxycerebroside - GlcCe glucocerebroside - GL-2 lactosylceramide - GL-3 trihexosylceramide - GL-4 tetrahexosylceramide - HPTLC high-performance thin-layer chromatography - MGDG monogalactosyl diacylglycerol - NL non-polar lipids - PC phosphatidylcholine - Su sulfatide - Su-OH hydroxysulfatide     

Basal lamina and other extracellular matrix produced by bovine granulosa cells in anchorage-independent culture

Bovine granulosa cells from 3–7 mm follicles were cultured without anchorage in soft agar/methylcellulose solution for 14 days, with or without 50 ng/ml basic fibroblast growth factor. The granulosa cells divided to form colonies of cells. These were analysed by light and electron microscopy, immunohistochemistry and Western immunoblotting. In approximately 20% of the colonies extracellular matrix was clearly visible at the light-microscope level. Ultrastructurally the matrix resembled a basal lamina 30–100 nm thick and was composed of tangled fibres or cords. Unidentified spherical structures of less than 50 nm diameter were sometimes present and attached to this basal lamina. The basal lamina of follicles had similar features, except that the basal lamina produced in vitro was a large aggregate of many convoluted layers. The cells produced collagen type IV and the cellular form of fibronectin. Intercellular areas not associated with basal lamina were identified. Ruthenium red staining revealed these areas to be rich in proteoglycan granules. Free granules were clustered near the cell surface, and the lumina of these areas were rich in fibres decorated with ruthenium red. This material did not resemble follicular fluid of antral follicles. Thus, granulosa cells in anchorage-independent cultures have a follicular cell morphology and secrete two distinct extracellular matrices, one similar to the follicular basal lamina.This study was funded by the Flinders Medical Centre Research Foundation, Flinders University, and the National Health and Medical Research Council of Australia     

Schwann cells,basement lamina,and collagen in developing rat dorsal root gangliain vitro

Observations on developing rat dorsal root gangliain vitro indicated that the formation of a basement lamina associated with the Schwann cells did not occur until after migration had ceased and the cells had become committed to an axon or another Schwann cell. The presence of a basement lamina was therefore characteristic only of committed Schwann cellsin vitro. It also appeared that Schwann cells produced collagen following formation of the basement lamina.     

Basal lamina degradation: the identification of mammalian-like collagenase activity in mesenchymal-derived matrix vesicles.

Isolated matrix vesicles from 26-day embryonic New Zealand White rabbit incisor tooth organs were incubated on ¹⁴C labeled reconstituted Type I collagen at 25°C for 18 hours. Under these conditions the matrix vesicles demonstrated the ability to degrade collagen as demonstrated by radio-activity solubilized. Analysis of the released radioactivity using SDS-PAGE demonstrated the presence of two molecular species with molecular weights of 67,000 and 32,000 daltons. These results are in accordance with the presence of a mammalian-like collagenase associated with the matrix vesicles, whose function may be the degradation of the basal lamina.     

Abnormal enwrapment of intramuscular axons by distal Schwann cells with defective basal lamina in the muscular dysgenic mouse embryo

In the muscular dysgenic (mdg/mdg) mouse embryo, both muscle and nerve are affected early during embryogenesis, from Embryonic Day 13 (E13). We now find that the mutation affects not only the degree of differentiation of the muscle and the pattern of motor innervation but also the relationship between Schwann cell and axon. We studied the sciatic nerve of normal and mdg/mdg embryos between E13 and E18 at the ultrastructural level. We found that in mdg/mdg nerve, (1) Schwann cells do not totally enwrap the growing axons in their most distal part, close to the growth cone, and (2) the terminal Schwann cells do not correctly surround the nerve endings and seal the corresponding synaptic contacts. Moreover, both types of mutant Schwann cell lack a normal electron-dense basal lamina. We found that there is an excess of axons relative to the Schwann cell population in the intramuscular portions of the mdg/mdg sciatic nerve. Our observations point toward a possible defect of the mechanism of migration and maturation of Schwann cells. Such a defect may in turn affect primarily or secondarily the mutual influences between Schwann cell and axon and lead to some or all of the major abnormalities observed in the mdg/mdg neuromuscular system, namely, multifocal polyinnervation, immature axon-myotube contacts, and abnormal T-tubule-sarcoplasmic reticulum junctions.     

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

Rat Schwann cells cultured with dorsal root ganglion neurons in a serum-free defined medium fail to ensheathe or myelinate axons or assemble basal laminae. Replacement of defined medium with medium that contains human placental serum (HPS) and chick embryo extract (EE) results in both basal lamina and myelin formation. In the present study, the individual effects of HPS and EE on basal lamina assembly and on myelin formation by Schwann cells cultured with neurons have been examined. Some batches of HPS were unable to promote myelin formation in the absence of EE, as assessed by quantitative evaluation of cultures stained with Sudan black; such HPS also failed to promote basal lamina assembly, as assessed by immunofluorescence using antibodies against laminin, type IV collagen, and heparan sulfate proteoglycan. The addition of EE or L-ascorbic acid with such HPS led to the formation of large quantities of myelin and to the assembly of basal laminae. Pretreatment of EE with ascorbic acid oxidase abolished the EE activity, whereas trypsin did not. Other batches of HPS were found to promote both basal lamina and myelin formation in the absence of either EE or ascorbic acid. Ascorbic acid oxidase treatment or dialysis of these batches of HPS abolished their ability to promote Schwann cell differentiation, whereas the subsequent addition of ascorbic acid restored that ability. Ascorbic acid in the absence of serum was relatively ineffective in promoting either basal lamina or myelin formation. Fetal bovine serum was as effective as HPS in allowing ascorbic acid (and several analogs but not other reducing agents) to manifest its ability to promote Schwann cell differentiation. We suggest that ascorbic acid promotes Schwann cell myelin formation by enabling the Schwann cell to assemble a basal lamina, which is required for complete differentiation.     

Peripheral glia: Schwann cells in motion

Neuregulin signaling through ErbB receptors is known to play an essential role in Schwann cell proliferation, survival and myelination. Recent studies in zebrafish provide a peek at living Schwann cells migrating along axons in vivo and suggest that ErbB signaling, while not required for cell movement per se, is required to maintain the directed migration of these cells.     

Spontaneous immortalisation of Schwann cells in culture: short-term cultured Schwann cells secrete growth inhibitory activity.

In the developing peripheral nerve, Schwann cells proliferate rapidly and then become quiescent, an essential step in control of Schwann cell differentiation. Cell proliferation is controlled by growth factors that can exert positive or inhibitory influences on DNA synthesis. It has been well established that neonatal Schwann cells divide very slowly in culture when separated from neurons but here we show that when culture was continued for several months some cells began to proliferate rapidly and non-clonal lines of immortalised Schwann cells were established which could be passaged for over two years. These cells had a similar molecular phenotype to short-term cultured Schwann cells, except that they expressed intracellular and cell surface fibronectin. The difference in proliferation rates between short- and long-term cultured Schwann cells appeared to be due in part to the secretion by short-term cultured Schwann cells of growth inhibitory activity since DNA synthesis of long-term, immortalised Schwann cells was inhibited by conditioned medium from short-term cultures. This conditioned medium also inhibited DNA synthesis in short-term Schwann cells stimulated to divide by glial growth factor or elevation of intracellular cAMP. The growth inhibitory activity was not detected in the medium of long-term immortalised Schwann cells, epineurial fibroblasts, a Schwannoma (33B), astrocytes or a fibroblast-like cell-line (3T3) and it did not inhibit serum-induced DNA synthesis in epineurial fibroblasts, 33B cells or 3T3 cells. The activity was apparently distinct from transforming growth factor-beta, activin, IL6, epidermal growth factor, atrial natriuretic peptide and gamma-interferon and was heat and acid stable, resistant to collagenase and destroyed by trypsin treatment. We raise the possibility that loss of an inhibitory autocrine loop may contribute to the rapid proliferation of long-term cultured Schwann cells and that an autocrine growth inhibitor may have a role in the cessation of Schwann cell division that precedes differentiation in peripheral nerve development.     

The culturing of human Schwann cells: a new contribution to the study of polyneuropathy

We have established 44 Schwann cell cultures from human peripheral nerves that underwent biopsy for diagnostic purposes using a new "sandwich" connective tissue and cut into 1 mm cubic explants which were placed between two glass coverslips coated with D-poly-L-lysine, in HAM-F10 medium, 15% FCS, 600 mg/dl glucose and antibiotics. In the first 3 weeks this new sandwich technique yields a fairly great and homogeneous amount of Schwann cell growth, with only a few fibroblasts and virtually no macrophages and provides a suitable substrate on which immuno cytochemical studies could be performed.