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.     

Rapid growth cone translocation on laminin is supported by lamellipodial not filopodial structures

To determine the relationship between growth cone structure and motility, we compared the neurite extension rate, the form of individual growth cones, and the organization of f-actin in embryonic (E21) and postnatal (P30) sympathetic neurons in culture. Neurites extended faster on laminin than on collagen, but the P30 nerites were less than half as long as E21 neurites on both substrata. Growth cone shape was classified into one of five categories, ranging from fully lamellipodial to blunt endings. The leading margins of lamellipodia advanced smoothly across the substratum ahead of any filopodial activity and contained meshworks of actin filaments with no linear f-actin bundles, indicating that filopodia need not underlie lamellipodia. Rapid translocation (averaging 0.9-1.4 microns/min) was correlated with the presence of lamellipodia; translocation associated with filopodia averaged only 0.3-0.5 microns/min. This relationship extended to growth cones on a branched neurite where the translocation of each growth cone was dependent on its shape. Growth cones with both filopodial and lamellipodial components moved at intermediate rates. The prevalence of lamellipodial growth cones depended on age of the neurites; early in culture, 70% of E21 growth cones were primarily lamellipodial compared to 38% of P30 growth cones. A high percentage of E21 lamellipodial growth cones were associated with rapid neurite elongation (1.2 mm/day), whereas a week later, only 16% were lamellipodial, and neurites extended at 0.5 mm/day. Age-related differences in neurite extension thus reflected the proportion of lamellipodial growth cones present rather than disparities in basic structure or in the rates at which growth cones of a given type moved at different ages. Filopodia and lamellipodia are each sufficient to advance the neurite margin; however, rapid extension of superior cervical ganglion neurites was supported by lamellipodia independent of filopodial activity.     

Directional control of neurite outgrowth from cultured hippocampal neurons is modulated by the lectin concanavalin A.

Cell surface carbohydrates play an important role in the regulation of neurite outgrowth during neuronal development. We have investigated the actions of the plant lectin concanavalin A (Con A), a carbohydrate-binding protein, on neurite outgrowth from hippocampal pyramidal neurons in primary cell culture. Neurons plated in culture medium containing nanomolar concentrations of Con A have a larger number of primary neurites arising directly from the cell soma than do neurons plated in culture medium alone. Furthermore, Con A causes counterclockwise turning of neurites in over 70% of the cultured neurons. Both of these effects of Con A are blocked by the hapten sugar alpha-methyl-D-mannopyranoside, suggesting that they result from the interaction of Con A with a cell surface carbohydrate. Another lectin with a different sugar specificity, wheat germ agglutinin, does not modulate neurite outgrowth. Analysis of neurite outgrowth using video-enhanced microscopy reveals that the counterclockwise turning is accompanied by directionally biased extension of filopodia from the growth cones of growing neurites. Treatment of the neurons with cytochalasin, which disrupts actin polymerization, eliminates the neurite turning induced by Con A, suggesting that actin microfilaments are involved in directional control of neurite outgrowth.     

Neurite extension by neuroblastoma cells on substratum-bound fibronectin''s cell-binding fragment but not on the heparan sulfate-binding protein, platelet factor-4

Human and rat neuroblastoma cells extend neurites over plasma fibronectin (pFN)-coated substrata. For resolution of which fibronectin binding activities (the cell-binding domain (CBD), the heparan sulfate-binding domains, or a combination of the two) are responsible for neurite outgrowth, CBD was prepared free of heparan sulfate-binding activity as described by Pierschbacher et al. (Cell 26 (1981) 259-267). Neuroblastoma cells attached and extended neurites as stably and as effectively on CBD-coated substrata as on intact pFN, while cytoplasmic spreading was more extensive on pFN-coated substrata. The structures of growth cones on CBD or pFN were virtually identical. On substrata coated with the model heparan sulfate-binding protein, platelet factor 4 (PF4), cells attached and spread somewhat but never extended neurites. When cells were challenged with substrata coated with various ratios of CBD and PF4, PF4 was found to be an effective inhibitor of CBD-mediated neurite extension. Similarly, cells grown on substrata coated at different locations with CBD or PF4 in order to evaluate topographical dependence of growth cone formation extended neurites only onto the CBD-coated region or along the interface between these two proteins, but never onto the PF4 side of cells that bridged the interface. These studies indicate that (a) the CBD activity of pFN, and not its heparan sulfate-binding activity, is the critical determinant in neurite extension of these neural tumor cells from the central nervous system; (b) under some circumstances, heparan sulfate-binding activity can be antagonistic to neurite extension; (c) the chemical nature of the substratum controls the direction of neurite extension; (d) these neuroblastoma cells respond to these binding proteins very differently than fibroblasts or neurons from the peripheral nervous system.     

Requirement for specific protein kinase activities during the rapid redistribution of F-actin that precedes the outgrowth of neurites in PC12D cells.

Rapid changes in morphology of PC12D cells, a subline of PC12 cells, in response to various agents were studied in relation to the subsequent outgrowth of neurites. A few minutes after addition of NGF or of dbcAMP, staining of F-actin with rhodamine phalloidin revealed the formation of ruffles around the periphery of cells. Simultaneous relocalization of F-actin to the area of ruffles occurred in response to NGF. A moderate relocalization of F-actin occurred in dbcAMP-treated cells. Other neurite-promoting agents on PC12D cells, such as bFGF, EGF and PMA, also caused ruffling and an identical redistribution of F-actin. The actin bundles then condensed into several dot-like aggregates that subsequently became the growth cones of neurites. When an inhibitor of protein kinase, K-252a, was added, only the NGF-induced morphological change was selectively decreased. By contrast, an inhibitor of protein kinase A, H-89, selectively blocked the dbcAMP-induced change. These are analogous to the effects of those inhibitors on the outgrowth of neurites. These observations indicate that the formation of ruffles with the redistribution of F-actin might be one of the earliest steps in the neurite outgrowth and that the morphological changes might be triggered by the activation of specific protein kinases. Neither cytochalasin B nor colchicine prevented the series of morphological changes. However, processes formed in the presence of cytochalasin B had no filopodium and protrusions formed in the presence of colchicine were shaped like large filopodia. It appears that microtubules and microfilaments may not be absolutely required for the initiation of the rapid morphological changes, but that complete neurites might be formed with contribution by microtubules and by microfilaments.     

A cytomechanical investigation of neurite growth on different culture surfaces

We have examined the relationship between tension, an intrinsic stimulator of axonal elongation, and the culture substrate, an extrinsic regulator of axonal elongation. Chick sensory neurons were cultured on three substrata: (a) plain tissue culture plastic; (b) plastic treated with collagen type IV; and (c) plastic treated with laminin. Calibrated glass needles were used to increase the tension loads on growing neurites. We found that growth cones on all substrata failed to detach when subjected to two to threefold and in some cases 5-10-fold greater tensions than their self-imposed rest tension. We conclude that adhesion to the substrate does not limit the tension exerted by growth cones. These data argue against a "tug-of-war" model for substrate-mediated guidance of growth cones. Neurite elongation was experimentally induced by towing neurites with a force-calibrated glass needle. On all substrata, towed elongation rate was proportional to applied tension above a threshold tension. The proportionality between elongation rate and tension can be regarded as the growth sensitivity of the neurite to tension, i.e., its growth rate per unit tension. On this basis, towed growth on all substrata can be described by the simple linear equation: elongation rate = sensitivity x (applied tension - tension threshold) The numerical values of tension thresholds and neurite sensitivities varied widely among different neurites. On all substrata, thresholds varied from near zero to greater than 200 mudynes, with some tendency for thresholds to cluster between 100 and 150 mudynes. Similarly, the tension sensitivity of neurites varied between 0.5 and 5.0 microns/h/mudyne. The lack of significant differences among sensitivity or threshold values on the various substrata suggest to use that the substratum does not affect the internal "set points" of the neurite for its response to tension. The growth cone of chick sensory neurons is known to pull on its neurite. The simplest cytomechanical model would assume that both growth cone-mediated elongation and towed growth are identical as far as tension input and elongation rate are concerned. We used the equation above and mean values for thresholds and sensitivity from towing experiments to predict the mean growth cone-mediated elongation rate based on mean rest tensions. These predictions are consistent with the observed mean values.     

Directional control of neurite outgrowth from cultured hippocampal neurons is modulated by the lectin concanavalin A

Cell surface carbohydrates play an important role in the regulation of neurite outgrowth during neuronal development. We have investigated the actions of the plant lectin concanavalin A (Con A), a carbohydrate-binding protein, on neurite outgrowth from hippocampal pyramidal neurons in primary cell culture. Neurons plated in culture medium containing nanomolar concentrations of Con A have a larger number of primary neurites arising directly from the cell soma than do neurons plated in culture medium alone. Furthermore, Con A causes counterclock-wise turning of neurites in over 70% of the cultured neurons. Both of these effects of Con A are blocked by the hapten sugar α-methyl-d-mannopyranoside, suggesting that they result from the interaction of Con A with a cell surface carbohydrate. Another lectin with a different sugar specificity, wheat germ agglutinin, does not modulate neurite outgrowth. Analysis of neurite outgrowth using video-enhanced microscopy reveals that the counter-clockwise turning is accompanied by directionally biased extension of filopodia from the growth cones of growing neurites. Treatment of the neurons with cytochalasin, which disrupts actin polymerization, eliminates the neurite turning induced by Con A, suggesting that actin microfilaments are involved in directional control of neurite outgrowth. © 1992 John Wiley & Sons, Inc.     

Growth cone‐like waves transport actin and promote axonogenesis and neurite branching

Axonogenesis involves a shift from uniform delivery of materials to all neurites to preferential delivery to the putative axon, supporting its more rapid extension. Waves, growth cone‐like structures that propagate down the length of neurites, were shown previously to correlate with neurite growth in dissociated cultured hippocampal neurons. Waves are similar to growth cones in their structure, composition and dynamics. Here, we report that waves form in all undifferentiated neurites, but occur more frequently in the future axon during initial neuronal polarization. Moreover, wave frequency and their impact on neurite growth are altered in neurons treated with stimuli that enhance axonogenesis. Coincident with wave arrival, growth cones enlarge and undergo a marked increase in dynamics. Through their engorgement of filopodia along the neurite shaft, waves can induce de novo neurite branching. Actin in waves maintains much of its cohesiveness during transport whereas actin in nonwave regions of the neurite rapidly diffuses as measured by live cell imaging of photoactivated GFP‐actin and photoconversion of Dendra‐actin. Thus, waves represent an alternative axonal transport mechanism for actin. Waves also occur in neurons in organotypic hippocampal slices where they propagate along neurites in the dentate gyrus and the CA regions and induce branching. Taken together, our results indicate that waves are physiologically relevant and contribute to axon growth and branching via the transport of actin and by increasing growth cone dynamics. © 2009 Wiley Periodicals, Inc. Develop Neurobiol 2009     

Studies on the organization and localization of actin and myosin in neurons

The organization of actin in mouse neuroblastoma and chicken dorsal root ganglion (DRG) nerve cells was investigated by means of a variety of electron microscope techniques. Microspikes of neuroblastoma cells contained bundles of 7- to 8-nm actin filaments which originated in the interior of the neurite. In the presence of high concentrations of Mg++ ion, filaments in these bundles became highly ordered to form paracrystals. Actin filaments, but not bundles, were observed in growth cones of DRG cells. Actin was localized in the cell body, neurites, and microspikes of both DRG and neuroblastoma nerve cells by fluorescein-labeled S1. Myosin was localized primarily in the neurites of chick DRG nerve cells with fluorescein-labeled anti-brain myosin antibody. This antibody also stained stress fibers in fibroblasts and myoblasts but did not stain muscle myofibrils.     

Immunocytochemical evidence for colocalization in neurite growth cones of actin and myosin and their relationship to cell-substratum adhesions

Sensory neurons from 8- to 11-day chick embryos were cultured on polyornithine-treated coverslips, fixed with glutaraldehyde, and stained for immunofluorescent localization of actin. Actin was distributed in a fibrous form in the growth cones, extending into filopodia and lamellipodial expansions of the growth cone margin. Often, these actin fibers were located at sites of linear adhesions to the glass substratum, as viewed by interference reflection optics. Our antisera to myosin did not recognize myosin in glutaraldehyde-fixed cells, and paraformaldehyde, which preserves the antigenicity of myosin, did not fix embryonic neurons well. Thus, myosin was localized in NGF-stimulated PC12 cells, whose morphology is better preserved by paraformaldehyde. Within the growth cones of PC12 neurites, actin and myosin are distributed into fibrous arrays which resemble the actin fibers seen in the growth cones of sensory neurons. Thus, actomyosin-like contractile forces may be exerted in neurite growth cones. These forces may act in concert with cell-substratum adhesive bonds to move the growth cone across the substratum or move organelles within the growth cone.     

Alpha-actinins, calspectin (brain spectrin or fodrin), and actin participate in adhesion and movement of growth cones

We have used biochemical and immunocytochemical techniques to investigate the possible involvement of membrane cytoskeletal elements such as alpha-actinin, calspectin (brain spectrin or fodrin), and actin in growth cone activities. During NGF-induced differentiation of PC12 cells, alpha-actinin increased in association with neurite outgrowth and was predominantly distributed throughout the entire growth cone and the distal portion of neurites. Filopodial movements were sensitive to Ca2+ flux. Two types of alpha-actinin, with Ca2(+)-sensitive and -insensitive actin binding abilities, were identified in the differentiated cells. Ca2(+)-sensitive alpha-actinin and actin filaments were concentrated in filopodia. The Ca2(+)-insensitive protein was distributed from the body of the growth cone to the distal portion of neurites, corresponding to the substratum-adhesive sites. The location of calspectin in growth cones was similar to that of the Ca2(+)-insensitive alpha-actinin. These results are consistent with the hypothesis that Ca2(+)-sensitive alpha-actinin and actin filaments are involved in Ca2(+)-dependent filopodial movement and Ca2(+)-insensitive alpha-actinin and calspectin are associated with adhesion of growth cones.     

Tension and compression in the cytoskeleton of PC 12 neurites

We report in this article that the retraction of PC 12 neurites, unlike that of other cultured neurons, is due to tension within the neurite. Retraction is rapid and independent of metabolic energy. Transection of one arm of a branched neurite immediately causes the remaining arm to take up a new equilibrium position between attachment points. Similarly, detachment of one growth cone of a cell causes the cell body to move to a new equilibrium position between the remaining neurites. These observations provide direct evidence for the suspension of the cell soma among a network of tensioned neurites. We used retraction as an assay for neurite tension to examine the role of actin filaments and microtubules in neurite support and elongation. Our data suggest that microtubules (MTs) within PC 12 neurites are under compression, supporting tension within the actin network. Treatment of cells with drugs that disrupt actin networks, cytochalasin D or erythro-9-[3-(2-hydroxynonyl)]adenosine eliminates retraction regardless of the absence of MTs, lack of adhesion to the substratum, or integrity of the neurite. Conversely, stimulation of actin polymerization by injection of phalloidin causes retraction of neurites. Treatments that depolymerize MTs, nocodazole or cold, cause retraction of neurites, which suggests that microtubules support this tension, i.e., are under compression. Stabilization of MTs with taxol stabilizes neurites to retraction and under appropriate circumstances can drive neurite extension. Taxol-stimulated neurite extension is augmented by combined treatment with anti-actin drugs. This is consistent with the actin network's normally exerting a force opposite that of MT assembly. Cytochalasin and erythro-9-[3-(2-hydroxynonyl)] adenosine were found to increase slightly the dose of nocodazole required for MT depolymerization. This is consistent with the postulated balance of forces and also suggests that alteration of the compression borne by the microtubules could serve as a local regulator for MT polymerization during neurite outgrowth.     

The role of endogenous heparan sulfate proteoglycan in adhesion and neurite outgrowth from dorsal root ganglia

Some phases of dorsal root ganglion (DRG) substratum attachment and growth cone morphology are mediated through endogenous cell surface heparan sulfate proteoglycan. The adhesive behavior of intact embryonic chicken DRG (spinal sensory ganglia) is examined on substrata coated with fibronectin, fibronectin treated with antibody to the cell-binding site (anti-CBS), and the heparan sulfate-binding protein platelet factor four. DRG attach to fibronectin, anti-CBS-treated fibronectin, and platelet factor four. The ganglia extend an extensive halo of unfasciculated neurites on fibronectin and produce fasciculated neurite outgrowth on platelet factor four and anti-CBS antibody-treated FN. Treatment with heparinase, but not chondroitinase, abolishes adhesion to fibronectin and platelet factor four. Growth cones of DRG on fibronectin have well-spread lamellae and microspikes. On platelet factor four, and anti-CBS-treated FN, growth cones exhibit microspikes only. Isolated Schwann cells adhere equally well to fibronectin and platelet factor four, spreading more rapidly on fibronectin. Isolated DRG neurons adhere equally well on both substrata, but only 10% of the neurons extend long neurites on platelet factor four. The majority of the isolated neurons on platelet factor four exhibit persistent microspike production resembling that of the early stages of normal neurite extension. Endogenous heparan sulfate proteoglycan supports the adhesion of whole DRG, isolated DRG neurons, and Schwann cells, as well as extensive microspike activity by DRG neurons, one important part of growth cone activity.     

Cytochalasin separates microtubule disassembly from loss of asymmetric morphology

When neuroblastoma cells bearing neurites are incubated with colchicine or Nocodazole, the cytoplasmic microtubules are depolymerized and concomitantly the neurites retract. We report here that cytochalasin separates the two effects of these drugs: it quantitatively inhibits neurite retraction but does not inhibit microtubule assembly. The neurites that remain contain intermediate filaments and actin but are devoid of microtubules. Depletion of cellular ATP also blocks neurite retraction induced by colchicine or Nocodazole, but some assembled microtubules persist under these conditions. The results suggest that neurite retraction is an active cell process.     

Geometry of isolated sensory neurons in culture. Effects of embryonic age and culture substratum

Sensory neurons were dissociated from lumbar dorsal root ganglia of embryonic chick and put into culture, either directly or after removing non-neuronal cells by density gradient centrifugation. The cells were grown on culture substrata of various kinds in medium containing nerve growth factor (NGF). After 24 h the cultures were fixed, mounted and analysed. Lengths of neurites were measured, and the numbers of primary processes formed at the cell body and of growth cones were counted. From these values, the rates of growth cone advance and frequency of growth cone branching were calculated. Neuronal outgrowths increased strikingly in length and complexity with embryonic age; there was a 3.5-fold increase in total neurite length and a 3-fold increase in the number of growth cones when neurons from 15-day embryos (E15) were compared with those from 8-day embryos (E8) grown on the same substratum (glass). Growth was markedly greater on surfaces prepared with laminin or conditioned medium compared with plain glass or air-dried collagen. When E15 neurons grown on glass were compared with those grown on laminin, for example, a 2.5-fold increase in total neurite length and a 3-fold increase in the number of growth cones was observed. Calculations showed that a major factor in these changes was an increase in the frequency of growth cone branching. The number of initial processes emanating from the cell body changed with age, but not with the different substrata tested. Non-neuronal cells when present in low numbers and in contact with neurons did not appear to influence neuronal geometry in a systematic way. Our results document the fact that both external factors (in this case, the nature of the culture substratum) and intrinsic factors (stage of development of the neuron) can influence the geometry of neurite outgrowth.     

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.     

Rac1-dependent actin filament organization in growth cones is necessary for β1-integrin–mediated advance but not for growth on poly-D-lysine

The activity of filopodia and lamellipodia determines the advance, motility, adhesion, and sensory capacity of neuronal growth cones. The shape and dynamics of these highly motile structures originate from the continuous reorganization of the actin cytoskeleton in response to extracellular signals. The small GTPases, Rac1, Rho, and CDC42, regulate the organization of actin filament structures in nonneuronal cells; yet, their role in growth cone motility and neurite outgrowth is poorly understood. We investigated in vitro the function of Rac1 in neurite outgrowth and differentiation by introducing purified recombinant mutants of Rac1 into primary chick embryo motor neurons via trituration. Endogenous Rac1 was expressed in growth cone bodies as well as in the tips and shafts of filopodia, where it often colocalized with actin filament structures. The introduction of constitutively active Rac1 resulted in an increase in rhodamine–phalloidin staining, presumably from an accumulation of actin filaments in growth cones, while dominant negative Rac1 caused a decrease in rhodamine–phalloidin staining. Nevertheless, both Rac1 mutants retarded growth cone advance, and hence attenuated neurite outgrowth and inhibited differentiation of neurites into axons and dendrites on laminin and fibronectin. In contrast, on poly-D -lysine, neither Rac1 mutant affected growth cone advance, neurite outgrowth, or neurite differentiation despite inducing similar changes in the amount of rhodamine–phalloidin staining in growth cones. Our data demonstrate that Rac1 regulates actin filament organization in neuronal growth cones and is pivotal for β1 integrin–mediated growth cone advance, but not for growth on poly-D lysine. © 1998 John Wiley & Sons, Inc. J Neurobiol 37: 524–540, 1998     

Influence of ganglion age,nonneuronal cells and substratum on neurite outgrowth in culture

This study characterizes the outgrowth patterns of superior cervical ganglia (SCG) obtained from embryonic (E15), perinatal (E20–21), and adult (P35) rats when placed in culture on various substrata. Outgrowth morphology, degree of fasciculation, and outgrowth length were examined on collagen (COL), polyornithine (PO), polylysine (PL), fibronectin (FN), and nonneuronal cells (NNCs) from the ganglion. COL and FN supported extensive neuritic outgrowth; PO and PL provided poor support. Outgrowth pattern, degree of fasciculation, neurite growth rate, and the number of NNCs in the outgrowth varied considerably depending upon the COL configuration. When undiluted COL (～5 mg/ml) was air dried, a three-dimensional loose fibrillar network was formed. Upon COL dilution or gelling undiluted COL by ammoniation, an essentially two-dimensional layer was formed. On two-dimensional COL, NNCs were able to proliferate and migrate extensively from ganglia of all ages; their presence influenced the form and extent of neurite growth. E15, E20, and P35 neurites responded differently to their endogenous NNCs. E15 neurites extended in relation to NNC surfaces and were predominantly nonfasciculated. E20 neurites became more fasciculated in the presence of NNCs that exhibited morphological and behavioral differences from those migrating from E15 ganglia. E20 neurite bundles became defasciculated when they extended into E15 outgrowth. Far fewer neurites grew from P35 explants in the presence of their NNCs. Three-dimensional COL greatly slowed NNC migration and thus allowed investigation of neurite outgrowth from ganglia of differing age in the absence of NNCs. We conclude that neuritic outgrowth patterns on varying substrata reflect not only neurite differences depending upon ganglion age but also variation in the behavior of accompanying NNCs.     

Morphogenetic guidance cues can interact synergistically and hierarchically in steering nerve cell growth

Nerve cell growth is influenced by guiding properties of its substratum. Microfabricated cell culture substrata were used to determine whether rat dorsal root ganglia (DRG) nerve cells could detect and integrate simultaneous model adhesive and topographic guidance cues. Interference reflection microscopy demonstrated strips of surface contact under the marginal zone of growth cones on planar surfaces which were coincident with actin immunostaining at the periphery of the C-domain. Clusters of focal contacts below the growth cone C-domain delineated the track edges on adhesive gratings. Neurite extension was guided most effectively by adhesive gratings of 25-μm period where highly aligned cells were typically bipolar. Nanometric steps and differences in surface texture between the adhesive tracks was detected using atomic force microscopy (AFM). Neurites did not align to 12- to 100-μm pitch grooves which were less than 1 μm deep. The proportion of aligned neurites increased with groove depth. Maximum neurite alignment was seen when 6-μm-deep, 25-μm-wide grooves contained superimposed parallel adhesive tracks of matched pitch. Neurites aligned preferentially to adhesive tracks superimposed orthogonally over shallow grooves (1 μm deep). Primary neurites aligned increasingly to grooves with orthogonal adhesive tracks as their depth increased. These neurites frequently had highly branched terminal arbours aligned to the orthogonal adhesive tracks. We conclude that morphogenetic guidance cues can interact synergistically and hierarchically to steer nerve cell growth.