Laminin is associated with the "neurite outgrowth-promoting factors" found in conditioned media

Suppression of terminal axonal sprouting at the neuromuscular junction by monoclonal antibodies against a muscle-derived antigen of 56,000 daltons

After the partial denervation or paralysis of a muscle, the remaining motor axon terminals may sprout fine, neuritic processes (terminal sprouts) which escape the endplate region of the neuromuscular junction. We previously identified a muscle-derived, protein antigen of 56,000 daltons (56 kD) which plays a necessary role in terminal sprouting. A panel of monoclonal antibodies have been produced against the 56-kD antigen, some of which also partially suppress motor axon terminal sprouting. These monoclonal antibodies define at least two different epitopes upon the surface of the antigen, one of which is necessary for it to effect its biological role in vivo.

Fibroblast growth factor promotes survival of dissociated hippocampal neurons and enhances neurite extension

Basic fibroblast growth factor (FGF) has been found to increase neuronal survival and neurite extension in a highly purified population of fetal rat hippocampal neurons under well-defined serum-free cell culture conditions. In the presence of FGF, neuronal survival after 7 days in culture on a simple plastic substrate is increased 4-fold, to 54% of the initial population. Survival is increased 2-fold to 40% on polyornithine-laminin. When FGF was bound to plastic or heparin substrates, neurite outgrowth was significantly increased to lengths comparable to those seen with laminin; however, FGF produced no further increase in neurite outgrowth on laminin. Half-maximal survival was observed at FGF concentrations of about 15 pg/ml (1 pM); half-maximal process outgrowth occurred at about 375 pg/ml (20 pM). The responsive cells were identified as neurons by their labeling with tetanus toxin and by antibodies to neurofilaments and to the neuron-specific enolase. Astrocytes, identified by the presence of glial fibrillary acidic protein, constituted about 10% of cells present at 1 week both in the presence and in the absence of FGF. These results strongly suggest that, in addition to its known mitogenic effects on nonneuronal cells, FGF possesses neurotrophic activity for hippocampal neurons.

Expression of several adhesive macromolecules (N-CAM, L1, J1, NILE, uvomorulin, laminin, fibronectin, and a heparan sulfate proteoglycan) in embryonic, adult, and denervated adult skeletal muscle

Levels of the neural cell adhesion molecule N-CAM in muscle are regulated in parallel with the susceptibility of muscle to innervation: N-CAM is abundant on the surface of early embryonic myotubes, declines in level as development proceeds, reappears when adult muscles are denervated or paralyzed, and is lost after reinnervation (Covault, J., and J. R. Sanes, 1985, Proc. Natl. Acad. Sci. USA, 82:4544-4548). Here we used immunocytochemical methods to compare this pattern of expression with those of several other molecules known to be involved in cellular adhesion. Laminin, fibronectin, and a basal lamina-associated heparan sulfate proteoglycan accumulate on embryonic myotubes after synapse formation, and their levels change little after denervation. L1, J1, nerve growth factor-inducible large external protein, uvomorulin, and a carbohydrate epitope (L2/HNK-1) shared by several adhesion molecules are undetectable on the surface of embryonic, perinatal, adult, or denervated adult muscle fibers. Thus, of the molecules tested, only N-CAM appears on the surface of muscle cells in parallel with the ability of the muscle cell surface to accept synapses. However, four antigens--N-CAM, J1, fibronectin, and a heparan sulfate proteoglycan--accumulate in interstitial spaces near denervated synaptic sites; regenerating axons traverse these spaces as they preferentially reinnervate original synaptic sites. Of particular interest is J1, antibodies to which block adhesion of central neurons to astrocytes (Kruse, J., G. Keihauer, A. Faissner, R. Timpl, and M. Schachner, 1985, Nature (Lond.), 316:146-148). J1 is associated with collagen and other fibrils in muscle and thus may be an extracellular matrix molecule employed in both the central and peripheral nervous systems.

A heparin-binding domain from N-CAM is involved in neural cell-substratum adhesion

Cell-substratum adhesion in the embryonic chicken nervous system has been shown to be mediated in part by a 170,000-mol-wt polypeptide that is a component of adherons. Attachment of retinal cells to the 170,000-mol-wt protein is inhibited by the C1H3 monoclonal antibody and by heparan sulfate (Cole, G. J., D. Schubert, and L. Glaser, 1985, J. Cell Biol., 100:1192-1199). In the present study we have demonstrated that the 170,000-mol-wt C1H3 polypeptide is immunologically identical to the neural cell adhesion molecule N-CAM, and that the 170,000-mol-wt component of N-CAM is preferentially secreted by cells as a component of adherons. We have identified a monoclonal antibody, designated B1A3, that inhibits heparin binding to N-CAM and cell-to-substratum adhesion. A 25,000-mol-wt heparin (heparan sulfate)-binding domain of N-CAM has been identified by limited proteolysis, and this fragment promotes cell attachment when bound to glass surfaces. The fragment also partially inhibits cell binding to adherons when bound to retinal cells, and the B1A3 monoclonal antibody inhibits retinal cell attachment to substrata composed of intact N-CAM or the heparin-binding domain. These data are the first evidence that N-CAM is a multifunctional protein that contains both cell-and heparin (heparan sulfate)-binding domains.

Neurite-promoting activity from fetal skeletal muscle: partial purification of a high-molecular-weight form

Neurite extension from sensory neuroblasts dissociated from chick embryo dorsal root ganglia can be stimulated by precoating the polylysine culture surface with extracts of skeletal muscle from bovine fetuses. The active factor(s) may be partially purified from cytosolic extracts of muscle by chromatography on Sepharose 6B and affinity chromatography on wheat germ agglutinin or Helix pomatia agglutinin columns. Extract concentrations of 10-50 micrograms protein per 1 ml were active in promoting neurite extension when the neurons were cultured without serum or nerve growth factor (beta NGF). However, levels of 1-10 micrograms/ml produced dramatic neurite extension when 10% (v/v) fetal or newborn calf serum or 0.5 ng/ml beta NGF was added to the medium. The biological activity was not blocked by antiserum that was raised against purified mouse laminin and that abolished the neurite-promoting activity of mouse laminin. The activity of the muscle extract was destroyed by trypsin or heparitinase, in contrast to the biological activity of purified mouse laminin, which was not abolished by heparitinase treatment. The activity could be resolved into two broad peaks on a Sepharose 2B column (apparent Mr between 2 X 10(6) and in 10 X 10(6) in native form). Treatment with dithiothreitol was necessary to dissociate the factor for electrophoresis in 4.25% polyacrylamide-SDS gels, revealing three major polypeptide bands at Mr = 160,000, 195,000 and 200,000. This preliminary characterization indicates that the neurite-promoting activity from bovine skeletal muscle tissue consists of a high-molecular-weight complex, one essential component of which is a heparan sulfate.

Tumor cell metastasis

Local tissue invasion and the formation of metastatic lesions are characteristic properties of many malignant tumors. The formation of metastases is a complex process involving the passage of tumor cells from the site of the primary bulk tumor through successive connective tissue barriers, ultimately resulting in the growth of secondary tumor cell colonies in distinct target organ locations. At many stages in the metastatic process, tumor cells interact with multiple components of the extracellular matrix. Recently, the importance of basement membrane as a barrier to invasive cells has been recognized. In the course of the transition from in situ to invasive carcinoma, normal or dysplastic epithelial cells residing on a basement membrane are replaced by neoplastic cells which subsequently invade the basement membrane and enter the underlying stroma. Once in the stroma, tumor cells can then penetrate the walls of blood vessels or the lymphatic system and enter into the circulation. Circulating tumor cells next arrest in the lumina of small vessels, invade the vessel wall, and leave the circulation. These cells are now directly exposed to the extracellular matrix of a target organ where they may grow to form secondary tumors. Throughout the metastatic process tumor cells are thus in contact with, and are potentially responsive to, various components of the extracellular matrix. This review provides a survey of the recent advances in our understanding of the interactions of metastatic tumor cells with the extracellular matrix. Specifically, the role of basement membrane as a barrier to metastatic tumor cells is examined.

The expression and localization of synaptic vesicle antigens at neuromuscular junctions in vitro

To examine the biochemical differentiation of presynaptic nerve terminals in vitro, we studied the expression and localization at synapses of two synaptic vesicle-specific antigens, synapsin I and protein p65. We purified these proteins from brain and raised a rabbit antiserum against each of them. Chick synapsin I had a slightly smaller molecular weight than its mammalian homologue, although the two share several properties. With the anti-p65 serum, the protein p65 could be detected consistently in presynaptic terminals at the neuromuscular junction in vivo, as had been previously shown for synapsin I. These antisera proved sufficiently sensitive to allow a study of the developmental expression of the antigens in embryonic chick brain, using protein blots. The two antigens are not coordinately regulated; protein p65 was detected substantially sooner in development that was synapsin I. Both synapsin I and protein p65 are expressed by ciliary ganglion neurons in vitro, as assessed by immunofluorescence using the affinity-purified antisera. The two antigens co-localized at all times in culture. Neurons grown alone were reliably stained only after 4 to 5 days in culture, but comparable levels of staining were found after 1 day when neurons were co-cultured with embryonic myotubes. In the co-cultures, staining was initially high in growth cones and neurites, but the brightest staining became confined to sites of nerve-muscle contact over 4 to 5 days in culture. In mature cultures, patches of bright staining for the vesicle antigens coincided with patches of acetylcholine receptors, suggesting that the antigens had become localized at synapses. The time course of this localization process suggests that it corresponds to the morphological maturation of synapses. It should be possible to exploit this system to obtain information about the molecules and processes involved in the induction of presynaptic differentiation.

The expression and localization of synaptic vesicle antigens at neuromuscular junctions in vitro

To examine the biochemical differentiation of presynaptic nerve terminals in vitro, we studied the expression and localization at synapses of two synaptic vesicle-specific antigens, synapsin I and protein p65. We purified these proteins from brain and raised a rabbit antiserum against each of them. Chick synapsin I had a slightly smaller molecular weight than its mammalian homologue, although the two share several properties. With the anti-p65 serum, the protein p65 could be detected consistently in presynaptic terminals at the neuromuscular junction in vivo, as had been previously shown for synapsin I. These antisera proved sufficiently sensitive to allow a study of the developmental expression of the antigens in embryonic chick brain, using protein blots. The two antigens are not coordinately regulated; protein p65 was detected substantially sooner in development that was synapsin I. Both synapsin I and protein p65 are expressed by ciliary ganglion neurons in vitro, as assessed by immunofluorescence using the affinity-purified antisera. The two antigens co-localized at all times in culture. Neurons grown alone were reliably stained only after 4 to 5 days in culture, but comparable levels of staining were found after 1 day when neurons were co-cultured with embryonic myotubes. In the co-cultures, staining was initially high in growth cones and neurites, but the brightest staining became confined to sites of nerve-muscle contact over 4 to 5 days in culture. In mature cultures, patches of bright staining for the vesicle antigens coincided with patches of acetylcholine receptors, suggesting that the antigens had become localized at synapses. The time course of this localization process suggests that it corresponds to the morphological maturation of synapses. It should be possible to exploit this system to obtain information about the molecules and processes involved in the induction of presynaptic differentiation.

Trophic effects of skeletal muscle extracts on ventral spinal cord neurons in vitro: separation of a protein with morphologic activity from proteins with cholinergic activity

Protein factors derived from skeletal muscle separately promote neurite elongation and acetylcholine synthesis in cultured rat ventral spinal neurons. Morphologic factor activity (neurite-inducing activity) is specifically found in rat skeletal muscle and cord neuron extracts, decreases with the postnatal age of the rats from which muscle extract is prepared, and increases in rat hindlimb muscle after 5 d of denervation. Cholinergic factor activity (acetylcholine synthesis-stimulating activity) is found in extracts of rat cerebral cortex and cardiac muscle in addition to spinal cord and skeletal muscle, increases with animal age, and decreases following 5 d of denervation. Biochemically, the factors responsible for these activities differ in their lability to denaturing conditions, apparent molecular weights, isoelectric points, and lectin-binding specificities. Under reducing conditions, morphologic activity is isolated in a single acidic glycoprotein with an Mr of 35,000, while acetylcholine synthesis-stimulating activity is found in multiple species of different molecular weights. Thus, acetylcholine synthesis-promoting activities and neurite growth-promoting activity appear to reside in different molecules. Significant purification of several of these factors has been achieved.

Purification of a factor that promotes neurite outgrowth: isolation of laminin and associated molecules

When culture medium, conditioned by any of several cell types, is applied to a polycationic substratum, a substance is adsorbed that causes neurons cultured on that substratum to extend processes (neurites) rapidly and profusely. We have purified the factor responsible for this effect from medium conditioned by bovine corneal endothelial cells, and have shown that it is composed of the glycoprotein laminin and two associated laminin-binding molecules: a sulfated protein known as entactin, and a large heparan sulfate proteoglycan. Of these molecules, only laminin was found to be present throughout the purification in all fractions possessing neurite outgrowth-promoting activity and absent from all fractions lacking activity. Laminin, purified from other sources, has been shown previously to promote extensive outgrowth by cultured neurons. These and other data presented here support the conclusion that laminin is responsible for the neurite outgrowth-promoting activity of the conditioned medium factor. Evidence is also presented that the association of a proteoglycan with laminin promotes efficient attachment of laminin to polycationic substrata, particularly in the presence of competing molecules.

Selective packaging of human growth hormone into synaptic vesicles in a rat neuronal (PC12) cell line

We have introduced the gene for human growth hormone (hGH) into PC12 cells, a rat pheochromocytoma-derived cell line with neuronal characteristics, and have isolated stable cell lines that express this protein. hGH is stored within the cells in membrane-bounded vesicles that are indistinguishable from the endogenous catecholaminergic synaptic vesicles. When the transfected cells are stimulated by carbachol or direct depolarization, they release norepinephrine and hGH with parallel kinetics. Treatment of the transfected cells with nerve growth factor results in a twofold increase in the amounts of hGH stored in and secreted from the cells. Not all proteins are packaged into the synaptic vesicles, since the rate of release of laminin, a soluble secreted protein endogenous to PC12 cells, is not stimulated by carbachol. This neuronal cell line therefore possesses at least two distinct pathways for secretion and can selectively package a foreign endocrine hormone into the regulated pathway.

Atypical distribution of asymmetric acetylcholinesterase in mutant PC12 pheochromocytoma cells lacking a cell surface heparan sulfate proteoglycan

We studied the distribution of the molecular forms of acetylcholinesterase (AChE) in a stable variant (F3) of the rat pheochromocytoma cell line, PC12, that lacks a heparan sulfate proteoglycan on the cell surface. After treatment with nerve growth factor F3 cells synthesize less 4S enzyme, and more 10S and 16S enzyme than normal PC12 cells. This distribution is similar to that seen in normal cells after incubation with beta-D-xylosides, molecules that interfere with proteoglycan assembly. Using collagenase treatment and membrane-permeable and -impermeable inhibitors of AChE, we determined the cellular location of the AChE forms. Although in normal cells greater than 90% of the 16S AChE is on the cell surface, approximately 60% is present in an internal pool in the variant. Following irreversible inhibition of all forms of AChE in the variant, the newly synthesized 16S AChE appears in the internal pool after a 1-h lag, but is not detected on the cell surface until after 2.5 h. Our results thus show that 16S AChE is assembled internally within neuronal cells and that alterations in the synthesis and distribution of proteoglycans affect the total amount and cellular localization of the 16S AChE form.