Growth cone motility.

Neurons obtain their stereotyped morphologies and connections as a result of growth cone migration. In the past year, studies on growth cone migration and pathfinding have helped to define certain properties of cytoskeletal filaments and cell membranes that may be important in growth cone function. Antisense mRNAs have proved to be particularly useful for examining the roles of specific neurite proteins.

Inhibition of intercellular adhesion by concanavalin A is associated with concanavalin A-mediated redistribution of surface receptors.

The inhibition of adhesion between aggregates and layers of embryonic retinal cells by concanavalin A (Con A) and Con A-mediated rearrangements of Con A receptors on retinal cells were studied. A short incubation of aggregates and layers with 10 micrograms/ml Con A substantially reduced aggregate-to-layer adhesion in a subsequent assay without soluble lectin present. This effect of Con A was dose-dependent, temperature-sensitive, involved events subsequent to Con A binding, and was reduced by cytochalasin B. The inhibition produced by succinylated Con A was substantially increased by incubation with antibody to Con A. Visualization of ConA- receptor complexes by fluorescence microscopy revealed that binding of Con A induced clearing of Con A receptors from filopodia, flattened regions of growth cones, and the edges of axons. This clearing reaction was prevented by the same agents that reduced Con A's inhibition of cell adhesion: low temperature, succinylation of Con A, or cytochalasin B. Aggregate-layer adhesion was restored by releasing Con A at 37 degrees C. Inhibitors of protein and ATP synthesis did not prevent recovery of ability to make adhesions. However, release of Con A at lowered temperatures did not prevent recovery. The results suggest that intercellular adhesion is inhibited by events associated with redistribution of Con A-receptor complexes on retinal cells.

Differences in the organization of actin in the growth cones compared with the neurites of cultured neurons from chick embryos.

Sensory neurons from chick embryos were cultured on substrata that support neurite growth, and were fixed and prepared for both cytochemical localization of actin and electron microscopic observation of actin filaments in whole-mounted specimens. Samples of cells were treated with the detergent Triton X-100 before, during, or after fixation with glutaraldehyde to determine the organization of actin in simpler preparations of extracted cytoskeletons. Antibodies to actin and a fluorescent derivative of phallacidin bound strongly to the leading margins of growth cones, but in neurites the binding of these markers for actin was very weak. This was true in all cases of Triton X-100 treatment, even when cells were extracted for 4 min before fixation. In whole-mounted cytoskeletons there were bundles and networks of 6-7-nm filaments in leading edges of growth cones but very few 6-7-n filaments were present among the microtubules and neurofilaments in the cytoskeletons of neurites. These filaments, which are prominent in growth cones, were identified as actin because they were stabilized against detergent extraction by the presence of phallacidin or the heavy meromyosin and S1 fragments of myosin. In addition, heavy meromyosin and S1 decorated these filaments as expected for binding to F-actin. Microtubules extended into growth cone margins and terminated within the network of actin filaments and bundles. Interactions between microtubule ends and these actin filaments may account for the frequently observed alignment of microtubules with filopodia at the growth cone margins.

Growth of neurites without filopodial or lamellipodial activity in the presence of cytochalasin B.

To examine the role in neurite growth of actin-mediated tensions within growth cones, we cultured chick embryo dorsal root ganglion cells on various substrata in the presence of cytochalasin B. Time-lapse video recording was used to monitor behaviors of living cells, and cytoskeletal arrangements in neurites were assessed via immunofluorescence and electron microscopic observations of thin sections and whole, detergent-extracted cells decorated with the S1 fragment of myosin. On highly adhesive substrata, nerve cells were observed to extend numerous (though peculiarly oriented) neurites in the presence of cytochalasin, despite their lack of both filopodia and lamellipodia or the orderly actin networks characteristic of typical growth cones. We concluded that growth cone activity is not necessary for neurite elongation, although actin arrays seem important in mediating characteristics of substratum selectivity and neurite shape.

Rapid retraction of neurites by sensory neurons in response to increased concentrations of nerve growth factor.

The phenomenon of growth cone (GC) and neurite retraction resulting from a rapid incrase in concentration of the trophic molecule NGF was studied. Neurite outgrowth from explants of 8-d chick embryo dorsal root ganglia was achieved at very low NGF concentrations with heart conditioned medium during overnight culture. Quickly incrasing the NGF concentration in the growth medium dramatically affected GC and neurite morphology: the majority of GCs and neurites collapsed and retracted towards the cell body over a course of approximately 2-5 min. Retraction was elicited by increasing NGF levels from 0 to 0.05 ng/ml to as little as 0.5 ng/ml but did not occur if the NGF concentration during the initial overnight culture period exceeded 0.8 ng/ml, regardless of how much the concentration was elevated. Similar concentration changes of cytochrome c or insulin did nt result in retraction. Neurites that had been separated from their cell bodies by cutting close to their exit from the explant still retracted when NGF levels were raised. Cytochalasin B reversible inhibits retraction, whereas colchicine allows retraction to occur. Observation of cell-substratum adhesion during retraction revealed that some adhesion points remain during retraction and that they correspond to the ends of NGF leels and that it may involve microfilaments in the neurite cytoskeleton. The NGF concentration changes that elicit neurite retraction suggest that a primary event in retraction may be increased occupancy of a high-affinity NGF receptor on neurites.

Migratory cell locomotion versus nerve axon elongation: differences based on the effects of lanthanum ion.

The effects of lanthanum ions (La(+++)) on the locomotion and adhesion of g lial cells and elongating nerve axons are reported. La(+++) increases adhesion of both glia and of nerve growth cones to a plastic substratum. La(+++) also markedly reduces glia locomotion, but it does not inhibit nerve elongation. Electron-opaque deposits are seen on the cell surface and within cytoplasmic vesicles of glia and nerves cultured in a La(+++)-containing medium. Possible modes of action for La(+++) are discussed, particularly the possibilities that Ca(++) fluxes or Ca(++) involvement in adhesion are altered by La(+++). The results are consistent with the hypothesis that cell migration and nerve axon elongation differ in mechanism, with respect to both adhesive interactions and the activity of microfilament systems.

Evidence that calcium may control neurite outgrowth by regulating the stability of actin filaments.

We investigated the effects of calcium removal and calcium ionophores on the behavior and ultrastructure of cultured chick dorsal root ganglia (DRG) neurons to identify possible mechanisms by which calcium might regulate neurite outgrowth. Both calcium removal and the addition of calcium ionophores A23187 or ionomycin blocked outgrowth in previously elongating neurites, although in the case of calcium ionophores, changes in growth cone shape and retraction of neurites were also observed. Treatment with calcium ionophores significantly increased growth cone calcium. The ability of the microtubule stabilizing agent taxol to block A23187-induced neurite retraction and the ability of the actin stabilizing agent phalloidin to reverse both A23187-induced growth cone collapse and neurite retraction suggested that calcium acted on the cytoskeleton. Whole mount electron micrographs revealed an apparent disruption of actin filaments in the periphery (but not filopodia) of growth cones that were exposed to calcium ionophores in medium with normal calcium concentrations. This effect was not seen in cells treated with calcium ionophores in calcium-free medium or cells treated with the monovalent cation ionophore monensin, indicating that these effects were calcium specific. Ultrastructure of Triton X-100 extracted whole mounts further indicated that both microtubules and microfilaments may be more stable or extraction resistant after treatments which lower intracellular calcium. Taken together, the data suggest that calcium may control neurite elongation at least in part by regulating actin filament stability, and support a model for neurite outgrowth involving a balance between assembly and disassembly of the cytoskeleton.

Inhibition of neurite initiation and growth by taxol.

We cultured sensory neurons from chick embryos in media containing the alkaloid taxol at concentrations from 7 X 10(-9) to 3.5 X 10(-6) M. When plated at taxol concentrations above 7 X 10(-8) M for 24 h, neurons have short broad extensions that do not elongate on the culture substratum. When actively growing neurites are exposed to these levels of taxol, neurite growth stops immediately and does not recommence. The broad processes of neurons cultured 24 h with taxol contain densely packed arrays of microtubules that loop back at the ends of the process. Neurofilaments are segregated from microtubules into bundles and tangled masses in these taxol-treated neurons. At the ends of neurites treated for 5 min with taxol, microtubules also turn and loop back abnormally toward the perikaryon. In the presence of 7 X 10(-9) M taxol neurites do grow, although they are broader and less branched than normally. The neurites of these cells appear to have normal structure except for a large number of microtubules. Taxol probably stimulates microtubule polymerization in these cultured neurons. At high levels of the drug, this action inhibits neurite initiation and outgrowth by removing free tubulin from the cytoplasm and destroying the normal control of microtubule assembly in growing neurites. The rapid inhibition suggests that microtubule assembly may occur at neurite tips. At lower concentrations, taxol may slightly enhance the mechanisms of microtubule assembly in neurons, and this alteration of normal processes changes the morphogenetic properties of the growing neurites.

A novel intermediate filament-associated protein, NAPA-73, that binds to different filament types at different stages of nervous system development.

The antigen recognized by the E/C8-monoclonal antibody is expressed in various avian embryonic cell types known also to express neurofilament (NF) immunoreactivity. To determine whether the E/C8-antigen corresponds to any of the known NF components, we compared their subcellular locations, immunocross-reactivities, and electrophoretic behaviors. We found that the E/C8-antibody binds to NF bundles in electron microscope preparations of neurons, but does not correspond to any of the known NF proteins by immunological or electrophoretic criteria. Immunoadsorption with the monoclonal antibody resulted in co-purification of a 73,000-D protein with one of the known NF proteins in homogenates from 20-d embryonic chick brains, but with vimentin intermediate filament protein in similarly prepared homogenates from 4-d embryonic chicks. We suggest that the E/C8-antigen is an intermediate filament-associated protein that binds to different filament types at different stages of development. We have named it NAPA-73, an acronym for neurofilament-associated protein, avian-specific, 73,000 D, on the basis of its binding specificity in mature neurons.

Synthetic peptides from the carboxy-terminal globular domain of the A chain of laminin: their ability to promote cell adhesion and neurite outgrowth, and interact with heparin and the beta 1 integrin subunit.

The large carboxy-terminal globular domain (G domain; residues 2,110-3,060) of the A chain of murine-derived laminin has been shown to promote heparin binding, cell adhesion, and neurite outgrowth. This study was conducted to define the potential sequence(s) originating from the G domain of laminin with any of these functional activities. A series of peptides were synthesized from the G domain, termed GD peptides, each approximately 20 amino acids long and containing multiple positively charged amino acids. In direct 3H-heparin binding assays, peptides GD-1 and GD-2 bound high levels of 3H-heparin, while peptides GD-3 and GD-4 bound lower levels of 3H-heparin, and GD-5 bound essentially no 3H-heparin. The binding of 3H-heparin to peptides GD-1 and GD-2 appeared to be of high affinity, since significant binding of 3H-heparin to these two peptides was still observed even when the NaCl concentration was raised to 1.0 M. Four of the peptides, GD-1, GD-2, GD-3, and GD-4, directly promoted the adhesion and spreading of HT-1080 human fibrosarcoma cells as well as the outgrowth of neurites from chick spinal cord and dorsal root ganglia neurons. In addition, solutions of these peptides or antibodies generated against these peptides inhibited laminin-mediated HT-1080 cell adhesion. Antibodies against the beta 1 integrin subunit inhibited HT-1080 cell adhesion and neurite outgrowth on surfaces adsorbed with peptides GD-3 and GD-4. Therefore, laminin appears to have multiple, independent sequences in the G domain that serve a similar cell adhesion promoting function for different cell types. Furthermore, these results suggest that the sequences comprising peptides GD-3 and GD-4 use an integrin as a receptor, of which the beta 1 integrin subunit is a component for these various cell types.

A test of microtubule translocation during neurite elongation.

In a previous study using PC-12 cells (Lim, S. S., P. J. Sammak, and G. G. Borisy, 1989. J. Cell Biol. 109:253-263), we presented evidence that the microtubule component of the neuronal cytoskeleton is differentially dynamic but stationary. However, neurites of PC-12 cells grow slowly, hindering a stringent test of slow axonal transport mechanisms under conditions where growth was substantial. We therefore extended our studies to primary cultures of dorsal root ganglion cells where the rate of neurite outgrowth is rapid. Cells were microinjected with X-rhodamine-labeled tubulin 7-16 h after plating. After a further incubation for 6-18 h, the cells were photobleached with an argon ion laser. Using a cooled charged couple device and video microscopy, the cells were monitored for growth of the neurite and movement and recovery of fluorescence in the bleached zone. As for PC-12 cells, all bleached zones in the neurite recovered their fluorescence, indicating that incorporation of tubulin occurred along the neurite. Despite increases in neurite length of up to 70 microns, and periods of observation of up to 5 h, no movement of bleached zones was observed. We conclude that neurite elongation cannot be accounted for by the transport of a microtubule network assembled only at the cell body. Rather, microtubules turn over all along the length of the neurite and neurite elongation occurs by net assembly at the tip.

Selective interaction of peripheral and central nervous system cells with two distinct cell-binding domains of fibronectin.

Mechanisms of cell interaction with fibronectin have been studied with proteolytic fibronectin fragments that have well-defined ligand binding properties. Results of a previous study (Rogers, S. L., J. B. McCarthy, S. L. Palm, L. T. Furcht, and P. C. Letourneau, 1985, J. Neurosci., 5:369-378) demonstrated that (a) central (CNS) and peripheral (PNS) nervous system neurons adhere to, and extend neurites on a 33-kD carboxyl terminal fibronectin fragment that also binds heparin, and (b) neurons from the PNS, but not the CNS, have stable interactions with a 75-kD cell-binding fragment and with intact fibronectin. In the present study domain-specific reagents were used in inhibition assays to further differentiate cell surface interactions with the two fibronectin domains, and to define the significance of these domains to cell interactions with the intact fibronectin molecule. These reagents are (a) a soluble synthetic tetrapeptide Arg-Gly-Asp-Ser (RGDS; Pierschbacher, M. D., and E. Ruoslahti, 1984, Nature (Lond.), 309:30-33) representing a cell-binding determinant in the 75-kD fragment, and (b) an antibody raised against the 33-kD fragment that binds specifically to that fragment. Initial cell attachment to, and neurite extension upon, fibronectin and the two different fragments was evaluated in the presence and absence of the two reagents. Attachment of both PNS and CNS cells to intact fibronectin was reduced in the presence of RGDS, the former more so than the latter. In contrast, the antibody to the 33-kD fragment did not affect attachment of PNS cells to fibronectin, but significantly decreased attachment of CNS cells to the molecule. RGDS inhibited attachment of CNS cells to the molecule. RGDS inhibited attachment of both cell types to the 75-kD fragment to a greater degree than it did attachment to the intact molecule. Cell interaction with the 33-kD fragment was not affected by RGDS. Reduction of neurite lengths (determined after 24 h of culture) by the domain-specific reagents paralleled the reduction in initial adhesion to each substratum. Therefore, it appears that (a) both PNS and CNS cells have receptors for each cell-binding domain of fibronectin, (b) the receptor(s) for the two domains are distinct, with attachment to the 33-kD fragment being independent of RGDS, and (c) the relative importance of each domain to cell interaction with intact fibronectin is different for CNS and PNS cells.

Recognition of the A chain carboxy-terminal heparin binding region of fibronectin involves multiple sites: two contiguous sequences act independently to promote neural cell adhesion.

Cellular interactions with fibronectin-treated substrata have a complex molecular basis involving multiple domains. A carboxy-terminal cell and heparin binding region of fibronectin (FN) is particularly interesting because it is a strong promoter of neurite outgrowth (Rogers, S.L., J.B. McCarthy, S.L. Palm, L.T. Furcht, and P.C. Letourneau, 1985. J. Neurosci. 5:369-378) and cell attachment (McCarthy, J.B., S.T. Hagen, and L.T. Furcht. 1986. J. Cell Biol. 102:179-188). To further understand the molecular mechanisms of neuronal interactions with this region of FN, we screened two peptides from the 33-kD heparin binding fragment of the FN A chain, FN-C/H II (KNNQKSEPLIGRKKT) and CS1 (Humphries, M.J., A. Komoriya, S.K. Akiyama, K. Olden, and K.M. Yamada. 1987. J. Biol. Chem. 262:6886-6892), for their ability to promote B104 neuroblastoma cell-substratum adhesion and neurite outgrowth. Both FN-C/H II and CS1 promoted B104 cell attachment in a concentration-dependent and saturable manner, with attachment to FN-C/H II exceeding attachment to CS1. In solution, both exogenous FN-C/H II or CS1 partially inhibited cell adhesion to the 33-kD fragment. Similar results were obtained with anti-FN-C/H II antibodies. In contrast, soluble GRGDSP did not affect B104 cell adhesion to FN-C/H II. These results indicate that both FN-C/H II and CS1 represent distinct, RGD-independent, cell adhesion-promoting sites active within the 33-kD fragment, and further define FN-C/H II as a novel neural recognition sequence in FN. B104 adhesion to FN-C/H II and CS1 differs in sensitivity to heparin, yet each peptide inhibited adhesion to the other peptide, suggesting cell adhesion is somehow related at the cellular level. Within the A chain 33-kD fragment, FN-C/H II and CS1 are contiguous, and might represent components of a larger domain with greater neurite-promoting activity since only the 33-kD fragment, and neither individual peptide, was effective at promoting B104 neurite outgrowth. These data further support the hypothesis that cell responses to FN are mediated by multiple sites involving both heparin-sensitive and -insensitive mechanisms.

Characterization of spontaneous calcium transients in nerve growth cones and their effect on growth cone migration.

This study examines the mechanisms of spontaneous and induced [Ca2+]i spiking in nerve growth cones and the effect of spikes on growth cone migration. Over a 10-20 min observation period, 29% of DRG growth cones undergo spontaneous and transient elevations in physiological extracellular Ca2+ ((Ca2+)o; 2 mM), whereas 67% of growth cones exposed to 20 mM (Ca2+)o exhibit similar [Ca2+]i spikes. Spontaneous [Ca2+]i spiking was not observed in neuronal cell bodies or nonneuronal cells. Ca2+ influx through non-voltage-gated Ca2+ channels was required for spontaneous [Ca2+]i spikes in growth cones, since removal of (Ca2+)o, or addition of the general Ca2+ channel blockers La3+ or Ni2+, reversibly blocked [Ca2+]i spiking, while blockers of the voltage-gated Ca2+ channels did not. Experiments using agents that influence intracellular Ca2+ stores suggest that Ca2+ stores may buffer and release Ca2+ during growth cone [Ca2+]i spikes. Growth cone migration was immediately and transiently inhibited by [Ca2+]i spikes, but eventually returned to prespike rates.

Extracellular matrix and neurite outgrowth.

The complex relationship between neuronal cells and the extracellular matrix molecules with which they interact both positively and negatively is currently being investigated on many fronts. Major areas of experimental emphasis include the characterization of an increasing number of extracellular matrix and cell surface associated molecules, the identification of receptors for these molecules, and the analysis of the function of extracellular matrix molecules with respect to neuronal process outgrowth.

Axon guidance: GTPases help axons reach their targets.

During development and regeneration of the nervous system, axons must correctly navigate to their specific targets through a complex molecular environment. Recent work has shed light on how GTPases of the Ras family are involved in transducing extracellular signals into responses that lead to directed neurite outgrowth.

Axon guidance: A balance of signals sets axons on the right track.

Axon guidance depends on the transduction of extracellular guidance cues into motile responses by the axonal growth cone. Recent studies in vivo have elucidated mechanisms required for this process that involve kinases and phosphatases, calcium dynamics and remodeling of the actin cytoskeleton.

Different contributions of microtubule dynamics and transport to the growth of axons and collateral sprouts.

Axonal growth is believed to depend on microtubule transport and microtubule dynamic instability. We now report that the growth of axon collateral branches can occur independent of microtubule dynamic instability and can rely mostly on the transport of preassembled polymer. Raising embryonic sensory neurons in concentrations of either taxol or nocodazole (NOC) that largely inhibit microtubule dynamics significantly inhibited growth of main axonal shafts but had only minor effects on collateral branch growth. The collaterals of axons raised in taxol or nocodazole often contained single microtubules with both ends clearly visible within the collateral branch ("floating" microtubules), which we interpret as microtubules undergoing transport. Furthermore, in these collaterals there was a distoproximal gradient in microtubule mass, indicating the distal accumulation of transported polymer. Treatment of cultures with a high dose of nocodazole to deplete microtubules from collaterals, followed by treatment with 4-20 nM vinblastine to inhibit microtubule repolymerization, resulted in the time-dependent reappearance and subsequent distal accumulation of floating microtubules in collaterals, providing further evidence for microtubule transport into collateral branches. Our data show that, surprisingly, the contribution of microtubule dynamics to collateral branch growth is minor compared with the important role of microtubule dynamics in growth cone migration, and they indicate that the transport of microtubules may provide sufficient cytoskeletal material for the initial growth of collateral branches.

Embryonic neurons adapt to the inhibitory proteoglycan aggrecan by increasing integrin expression.

The primary mediators of cell migration during development, wound healing and metastasis, are receptors of the integrin family. In the developing and regenerating nervous system, chondroitin sulfate proteoglycans (CSPGs) inhibit the integrin-dependent migration of neuronal growth cones. Here we report that embryonic sensory neurons cultured on the growth-promoting molecule laminin in combination with the inhibitory CSPG aggrecan rapidly adapt to inhibition. Adaptation is associated with a two- to threefold increase in the levels of RNA and surface protein for two laminin receptors, integrin alpha6beta1 and alpha3beta1, indicating that integrin expression is regulated by aggrecan. Increased integrin expression is associated both with increases in neuronal cell adhesion/outgrowth and with decreases in the ability of aggrecan to inhibit cell adhesion. Directly increasing integrin expression by adenoviral infection is sufficient to eliminate the inhibitory effects of aggrecan, indicating that upregulation of integrin receptors may promote neuronal regeneration in the presence of inhibitory matrix components.

Micropatterning gradients and controlling surface densities of photoactivatable biomolecules on self-assembled monolayers of oligo(ethylene glycol) alkanethiolates.

BACKGROUND: Bioactive molecules that are covalently immobilized in patterns on surfaces have previously been used to control or study cell behavior such as adhesion, spreading, movement or differentiation. Photoimmobilization techniques can be used, however, to control not only the spatial pattern of molecular immobilization, termed the micropattern, but also the surface density of the molecules--a characteristic that has not been previously exploited. RESULTS: Oligopeptides containing the bioactive Arg-Gly-Asp cell-adhesion sequence were immobilized upon self-assembled monolayers of an oligo(ethylene glycol) alkanethiolate in patterns that were visualized and quantified by autoradiography. The amount and pattern of immobilized peptide were controlled by manipulating the exposure of the sample to a UV lamp or a laser beam. Patterns of peptides, including a density gradient, were used to control the location and number of adherent cells and also the cell shape. CONCLUSIONS: A photoimmobilization technique for decorating surfaces with micropatterns that consist of variable densities of bioactive molecules is described. The efficacy of the patterns for controlling cell adhesion and shape has been demonstrated. This technique is useful for the study of cell behavior on micropatterns.