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.     

Effects of soluble laminin on organelle transport and neurite growth in cultured mouse dorsal root ganglion neurons: difference between primary neurites and branches

Laminin, an extracellular matrix molecule, is known to promote neurite growth. In the present study, the effects of soluble laminin on organelle transport and their relation to neurite growth were investigated in cultured dissociated mouse dorsal root ganglion (DRG) neurons. Laminin added into the extracellular medium was deposited on the surface of DRG neurons. DRG neurons incubated with soluble laminin exhibited branched, long, and thin neurites. Time-lapse study demonstrated that many small-diameter branches were newly formed after the addition of laminin. Thus, the growths of large-diameter primary neuritis, arising from cell bodies and branches extended from growth cones of primary neuritis, were analyzed separately. Laminin decreased the growth rate of primary neurites but increased that of branches. In primary neurites, acute addition of laminin rapidly decreased organelle movement in the neurite shaft and growth cone, accompanied by slowing of the growth cone advance. Branching of primary neurites occurred in response to laminin in some growth cones. In these growth cones, organelles protruded into nascent branches. In branches, soluble laminin increased organelle movement in the growth cone and the distal portion of the shaft. These results suggest that laminin inhibits the elongation of primary neurites but promotes branching and elongation of branches, all of which seem to be closely related to organelle transport.     

In vitro studies on the control of nerve fiber growth by the extracellular matrix of the nervous system

1. Cultured neurons from embryonic chick sympathetic ganglia or dorsal root ganglia grow nerve fibers extensively on simple substrata containing fibronectin, collagens (types I, III, IV), and especially laminin. 2. The same neurons cultured on substrata containing glycosaminoglycans grow poorly. Glycosaminoglycans (heparin) inhibit nerve fiber growth on fibronectin substrata. 3. Proteolytic fragments of fibronectin support nerve fiber growth only when the cell attachment region is intact. For example, a 105 kD fragment, encompassing the cell attachment region, supports growth when immobilized in a substratum, but a 93 kD subfragment, lacking the cell attachment region, is unable to support fiber growth. When it is added to the culture medium, the 105 kD fragment inhibits fiber growth on substrata containing native fibronectin. 4. In culture medium lacking NGF, DRG neurons extend nerve fibers only on laminin and not on fibronectin, collagen or polylysine. Studies with radioiodinated laminin indicate that laminin binds with a relatively high affinity (kd approximately equal to 10(-9) M) to DRG neurons, and to a variety of other neural cells (NG108 cells, PC12 cells, rat astrocytes, chick optic lobe cells). We have isolated a membrane protein (67 kD) by affinity chromatography on laminin columns and are characterizing this putative laminin receptor. 5. Dissociated DRG neurons or ganglionic explants cultured on complex substrata consisting of tissue sections of CNS or PNS tissues extend nerve fibers onto the PNS (adult rat sciatic nerve) but not CNS (adult rat optic nerve) substrata. Other tissue substrata which support fiber growth in vivo (embryonic rat spinal cord, goldfish optic nerve) support growth in culture. While substrata from adult CNS, which support meager regeneration in vivo (adult rat spinal cord) support little fiber growth in culture. 6. Ganglionic explants cultured in a narrow space between a section of rat sciatic nerve and optic nerve grow preferentially onto the sciatic nerve suggesting that diffusible growth factors are not responsible for the differential growth on the two types of tissues. 7. Dissociated neurons adhere better to sections of sciatic nerve than optic nerve. Laminin, rather than fibronectin or heparan sulfate proteoglycan, is most consistently identifiable by immunocytochemistry in tissues (sciatic nerve, embryonic spinal cord, goldfish optic nerve) which support nerve fiber growth. Taken together, these data suggest that ECM adhesive proteins are important determinants of nerve regeneration.     

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.     

Neurite outgrowth on a step gradient of chondroitin sulfate proteoglycan (CS-PG).

Sulfated proteoglycans (PGs) may play a significant role in the regulation of neurite outgrowth. They are present in axon-free regions of the developing nervous system and repel elongating neurites in a concentration-dependent manner in vitro. The addition of growth-promoting molecules, such as laminin, can modify the inhibitory effect of PGs on neurite outgrowth (Snow, Steindler, and Silver, 1990b). Substrata containing a high-PG/low-laminin ratio completely inhibit neurite outgrowth, while normal, unimpeded outgrowth is observed on low-PG/high-laminin substrata. Therefore, different patterns of neurite outgrowth may result from regulation of the ratio of growth-promoting molecules to growth-inhibiting molecules. Using video microscopy, embryonic chicken dorsal root ganglia neurons (DRG), chicken retinal ganglia neurons (RGC), and rat forebrain neurons (FB) were analyzed as they extended processes from a substratum consisting of laminin alone onto a step gradient of increasing concentrations of chondroitin sulfate proteoglycan (CS-PG) bound to laminin. In contrast to neurite outgrowth inhibition that occurs at the border of a single stripe of high concentration of CS-PG (Snow et al., 1990b and this study), growth cones grew onto and up CS-PG presented in a step-wise graded distribution. Although the behavior of the different cell types was unique, a common behavior of each cell type was a decrease in the rate of neurite outgrowth with increasing CS-PG concentration. These data suggest that appropriate concentrations of growth-promoting molecules combined with growth-inhibiting molecules may regulate the direction and possibly the timing of neurite outgrowth in vivo. The different responses of different neuronal types suggest that the presence of sulfated PG may have varying effects on different aspects of neuronal development.     

A second cell-binding domain on fibronectin (RGDS-independent) for neurite extension of human neuroblastoma cells

Human neuroblastoma cells (Platt and La-N1) have previously been shown to adhere and extend neurites on tissue-culture substrata coated with a 120K chymotryptic cell-binding fragment (CBF) of plasma fibronectin (pFN), a fragment which lacks heparan sulfate- and collagen-binding activities, and to adhere to—but not extend neurites on—substrata coated with the heparan sulfate (HS)-binding protein, platelet factor-4 (PF4) ([3.]). The mechanisms of these processes on CBF, on the intact pFN molecule, or on heparin-binding fragments of pFN have been tested using a heptapeptide (peptide A) containing the Arg---Gly---Asp---Ser (RGDS) sequence which recognizes a specific ‘receptor’ on the surface of a variety of cells or a control peptide with a single amino acid substitution. Adherence and neurite extension were completely inhibited on the 120K CBF by peptide A but not by control peptide; these results indicate that the RGDS-dependent ‘receptor’ is solely responsible for adhesive responses to the 120K CBF-containing region of the pFN molecule. When peptide A was added to cells on CBF which had already formed neuntes to test reversibility, retraction of all neurite processes was induced by 1 h and cells eventually detached. In contrast, on intact pFN, peptide A had very limited effects on either initial adherence or neurite extension, revealing a second ‘cell-binding’ domain on the fibronectin molecule outside of the 120K region competent for neurite differentiation; addition of peptide A at later times to pFN-adherent, neurite-containing cells could induce only a small subset of neurites to retract, thus supporting evidence for the presence of this second domain. A second ‘cell-binding’ domain was further confirmed by quantitation of neurite outgrowth on these substrata and by analyses of cells on substrata coated with mixtures of CBF/PF4. When substrata coated with chymotrypsin-liberated HBF were tested in a similar fashion, adherence was rapid but neurite outgrowth required much longer times and was completely sensitive to RGDS peptides; supplementation of cells with the complex ganglioside GT1b could not induce RGDS-resistant neurites on heparin-binding fragments (HBF). These latter results indicate that neurite extension on HBF is a consequence of a low concentration of RGDS-dependent activity in HBF (but not to HS-binding activity as characterized by Tobey et al. [3]) and that the second ‘cell-binding’ domain is sensitive to chymotrypsin digestion of pFN during the liberation of HBF. Possible candidate molecules for this second activity as well as its preliminary location in the pFN molecule are discussed and evidence, is provided in ref. [37] ([37.]) for the potential role for one class of molecules as a ‘receptor’. These neural tumor cells therefore have multiple and alternative mechanisms of adherence and differentiation on fibronectin matrices.     

Fibronectin-like immunoreactivity in Helisoma buccal ganglia: evidence that an endogenous fibronectin-like molecule promotes neurite outgrowth

We examined the distribution of fibronectin-like (FNL) immunoreactivity associated with intact buccal ganglia, cell-cultured buccal ganglia neurons and nonneuronal cells, and brain-conditioned medium from the snail Helisoma. In addition, the possible roles of fibronectin in the regulation of neurite outgrowth were studied. Immunofluorescent staining for FNL antigens revealed intense staining in patches and fibrous arrays over the connective tissue sheaths of buccal ganglia and nerve trunks. Within the ganglia, heavy staining was seen surrounding neurons and in track-like arrangements. In cell cultures, specific staining was associated with nonneuronal cell surfaces and to a lesser degree with the surface of identified neurons. In addition, a noncellular, substrate-bound component of brain-conditioned medium displayed FNL immunoreactivity. Since cultured Helisoma neurons require a substrate-associated, brain-derived conditioning factor (CF) in order to elaborate neurites with motile growth cones, we tested whether the FNL immunoreactive substance might act as a neuritotropic agent. Fibronectin antiserum suppressed, in a dose-dependent manner, the CF-induced sprouting of identified neurons in isolated cell culture. When added at increasing concentrations to neurons already growing in response to CF, fibronectin antiserum exerted a biphasic effect on neurite elongation; outgrowth was accelerated at low, but inhibited at high, antiserum concentrations. In contrast, growth cone structures associated with motility (filopodia and lamellipodia) were progressively reduced by increasing levels of antiserum. A short peptide derived from fibronectin's cell-binding domain (Arg-Gly-Asp-Ser) also greatly reduced neurite outgrowth. The combined results of this study indicate an abundance of FNL immunoreactive molecules within the CNS of Helisoma, their probable production by nonneuronal cells, and their function as a substrate-associated component of CF which promotes growth cone filopodial and lamellipodial activity.     

Ganglioside-dependent adhesion events of human neuroblastoma cells regulated by the RGDS-dependent fibronectin receptor and proteoglycans

Human neuroblastoma cells (Platt and La-N1) adhere and extend neurites on a ganglioside GM1-binding substratum provided by cholera toxin B (CTB). These adhesive responses, similar to those on plasma fibronectin (pFN), require the mediation of one or more cell-surface proteins [G. Mugnai and L. A. Culp (1987) Exp. Cell Res. 169, 328]. The involvement of two pFN receptor molecules in ganglioside GM1-mediated responses on CTB have now been tested. In order to test the role of cellular FN binding to its glycoprotein receptor integrin, a soluble peptide containing the Arg-Gly-Asp-Ser (RGDS) sequence was added to the medium. It did not inhibit attachment on CTB but completely inhibited formation of neurites; in contrast, the RGDS peptide minimally inhibited attachment or neurite formation on pFN. Once formed, neurites on CTB became resistant to the peptide. In order to test the role of cell-surface heparan sulfate proteoglycan (HS-PG), two approaches were used. First, the HS-binding protein platelet factor-4 (PF4) was used to dilute CTB or pFN on the substratum or, alternatively, added to the medium. Diluting the substratum ligand with PF4 had no effects on attachment on either CTB or pFN. However, neurite formation on CTB was readily inhibited and on pFN partially inhibited; the effects of PF4 were far greater than a similar dilution with nonbinding albumin. When PF4 was added to the medium of cells, attachment on either substratum was unaffected as was neurite outgrowth on pFN, revealing differences in PF4's inhibition as the substratum-bound or medium-borne component. In contrast, PF4 in the medium at low concentrations (1 microgram/ml) was highly inhibitory for neurite formation on CTB. The second approach utilized the addition of bovine cartilage dermatan sulfate proteoglycan (DS-PG), shown to bind to pFN as well as to substratum-bound CTB by ELISA, or cartilage chondroitin sulfate/keratan sulfate proteoglycan (CS/KS-PG) to the substratum or to the medium. At low concentrations, DS-PG but not CS/KS-PG actually stimulated neurite formation on CTB while at higher concentrations DS-PG completely inhibited attachment and neurite formation. While DS-PG partially inhibited attachment on pFN, it had no effect on neurite formation of the attached cells. Neuroblastoma cells adhered to some extent to substrata coated only with DS-PG, indicating "receptors" for PGs that permit stable interaction.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

Distinct molecular interactions mediate neuronal process outgrowth on non-neuronal cell surfaces and extracellular matrices

We have compared neurite outgrowth on extracellular matrix (ECM) constituents to outgrowth on glial and muscle cell surfaces. Embryonic chick ciliary ganglion (CG) neurons regenerate neurites rapidly on surfaces coated with laminin (LN), fibronectin (FN), conditioned media (CM) from several non-neuronal cell types that secrete LN, and on intact extracellular matrices. Neurite outgrowth on all of these substrates is blocked by two monoclonal antibodies, CSAT and JG22, that prevent the adhesion of many cells, including neurons, to the ECM constituents LN, FN, and collagen. Neurite outgrowth is inhibited even on mixed LN/poly-D-lysine substrates where neuronal attachment is independent of LN. Therefore, neuronal process outgrowth on extracellular matrices requires the function of neuronal cell surface molecules recognized by these antibodies. The surfaces of cultured astrocytes, Schwann cells, and skeletal myotubes also promote rapid process outgrowth from CG neurons. Neurite outgrowth on these surfaces, though, is not prevented by CSAT or JG22 antibodies. In addition, antibodies to a LN/proteoglycan complex that block neurite outgrowth on several LN-containing CM factors and on an ECM extract failed to inhibit cell surface-stimulated neurite outgrowth. After extraction with a nonionic detergent, Schwann cells and myotubes continue to support rapid neurite outgrowth. However, the activity associated with the detergent insoluble residue is blocked by CSAT and JG22 antibodies. Detergent extraction of astrocytes, in contrast, removes all neurite- promoting activity. These results provide evidence for at least two types of neuronal interactions with cells that promote neurite outgrowth. One involves adhesive proteins present in the ECM and ECM receptors on neurons. The second is mediated through detergent- extractable macromolecules present on non-neuronal cell surfaces and different, uncharacterized receptor(s) on neurons. Schwann cells and skeletal myotubes appear to promote neurite outgrowth by both mechanisms.     

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.     

Cell-substratum adhesion of neurite growth cones, and its role in neurite elongation.

The adhesion of chick embryo sensory neurons to glass coverslips was examined with interference reflection optics. On untreated glass, adhesive contacts are common only beneath growth cones and are small. On polylysine-treated glass growth cones are highly spread, microspikes reach treat lengths and extensive adhesive contacts underlie growth cones, microspikes and nerve fibers. Veils, expanded from the growth cone, are adherent to the substratum either centrally or laterally, while the extending edge of the cell margin is non-adherent. Linear adhesions are frequent beneath microspikes and pass centrally beneath the growth cone margin. The distribution of linear adhesions resembles that of microfilament bundles seen within whole mounts of growth cones. Adhesive contacts stabilize extensions of the growth cone margin and may influence the organization of the microfilamentous network within the growth cone. Regulation of microfilament organization by adhesion may influence microfilament functions in growth cone mobility and the assembly of neurite structures.     

Regulation of neurite outgrowth mediated by localized phosphorylation of protein translational factor eEF2 in growth cones

Nerve growth cones contain mRNA and its translational machinery and thereby synthesize protein locally. The regulatory mechanisms in the growth cone, however, remain largely unknown. We previously found that the calcium entry‐induced increase of phosphorylation of eukaryotic elongation factor‐2 (eEF2), a key component of mRNA translation, within growth cones showed growth arrest of neurites. Because dephosphorylated eEF2 and phosphorylated eEF2 are known to promote and inhibit mRNA translation, respectively, the data led to the hypothesis that eEF2‐mediating mRNA translation may regulate neurite outgrowth. Here, we validated the hypothesis by using a chromophore‐assisted light inactivation (CALI) technique to examine the roles of localized eEF2 and eEF2 kinase (EF2K), a specific calcium calmodulin‐dependent enzyme for eEF2 phosphorylation, in advancing growth cones of cultured chick dorsal root ganglion (DRG) neurons. The phosphorylated eEF2 was weakly distributed in advancing growth cones, whereas eEF2 phosphorylation was increased by extracellular adenosine triphosphate (ATP)‐evoked calcium transient through P2 purinoceptors in growth cones and resulted in growth arrest of neurites. The increase of eEF2 phosphorylation within growth cones by inhibition of protein phosphatase 2A known to dephosphorylate eEF2 also showed growth arrest of neurites. CALI of eEF2 within growth cones resulted in retardation of neurite outgrowth, whereas CALI of EF2K enhanced neurite outgrowth temporally. Moreover, CALI of EF2K abolished the ATP‐induced retardation of neurite outgrowth. These findings suggest that an eEF2 phosphorylation state localized to the growth cone regulates neurite outgrowth. © 2012 Wiley Periodicals, Inc. Develop Neurobiol, 2013     

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.     

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.     

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.     

Morphology and Nanomechanics of Sensory Neurons Growth Cones following Peripheral Nerve Injury

A prior peripheral nerve injury in vivo, promotes a rapid elongated mode of sensory neurons neurite regrowth in vitro. This in vitro model of conditioned axotomy allows analysis of the cellular and molecular mechanisms leading to an improved neurite re-growth. Our differential interference contrast microscopy and immunocytochemistry results show that conditioned axotomy, induced by sciatic nerve injury, did not increase somatic size of adult lumbar sensory neurons from mice dorsal root ganglia sensory neurons but promoted the appearance of larger neurites and growth cones. Using atomic force microscopy on live neurons, we investigated whether membrane mechanical properties of growth cones of axotomized neurons were modified following sciatic nerve injury. Our data revealed that neurons having a regenerative growth were characterized by softer growth cones, compared to control neurons. The increase of the growth cone membrane elasticity suggests a modification in the ratio and the inner framework of the main structural proteins.     

Laminin and fibronectin modulate inner ear spiral ganglion neurite outgrowth in an in vitro alternate choice assay

Extracellular matrix (ECM) molecules have been shown to function as cues for neurite guidance in various populations of neurons. Here we show that laminin (LN) and fibronectin (FN) presented in stripe micro-patterns can provide guidance cues to neonatal (P5) inner ear spiral ganglion (SG) neurites. The response to both ECM molecules was dose-dependent. In a LN versus poly-L-lysine (PLL) assay, neurites were more often observed on PLL at low coating concentrations (5 and 10 microg/mL), while they were more often on LN at a high concentration (80 microg/mL). In a FN versus PLL assay, neurites were more often on PLL than on FN stripes at high coating concentrations (40 and 80 microg/mL). In a direct competition between LN and FN, neurites were observed on LN significantly more often than on FN at both 10 and 40 microg/mL. The data suggest a preference by SG neurites for LN at high concentrations, as well as avoidance of both LN at low and FN at high concentrations. The results also support a potential model for neurite guidance in the developing inner ear in vivo. LN, in the SG and osseus spiral lamina may promote SG dendrite growth toward the organ of Corti. Within the organ of Corti, lower concentrations of LN may slow neurite growth, with FN beneath each row of hair cells providing a stop or avoidance signal. This could allow growth cone filopodia increased time to sample their cellular targets, or direct the fibers upward toward the hair cells.     

Extracellular Nm23H1 stimulates neurite outgrowth from dorsal root ganglia neurons in vitro independently of nerve growth factor supplementation or its nucleoside diphosphate kinase activity

The nucleoside diphosphate (NDP) kinase, Nm23H1, is a highly expressed during neuronal development, whilst induced over-expression in neuronal cells results in increased neurite outgrowth. Extracellular Nm23H1 affects the survival, proliferation and differentiation of non-neuronal cells. Therefore, this study has examined whether extracellular Nm23H1 regulates nerve growth. We have immobilised recombinant Nm23H1 proteins to defined locations of culture plates, which were then seeded with explants of embryonic chick dorsal root ganglia (DRG) or dissociated adult rat DRG neurons. The substratum-bound extracellular Nm23H1 was stimulatory for neurite outgrowth from chick DRG explants in a concentration-dependent manner. On high concentrations of Nm23H1, chick DRG neurite outgrowth was extensive and effectively limited to the location of the Nm23H1, i.e. neuronal growth cones turned away from adjacent collagen-coated substrata. Nm23H1-coated substrata also significantly enhanced rat DRG neuronal cell adhesion and neurite outgrowth in comparison to collagen-coated substrata. These effects were independent of NGF supplementation. Recombinant Nm23H1 (H118F), which does not possess NDP kinase activity, exhibited the same activity as the wild-type protein. Hence, a novel neuro-stimulatory activity for extracellular Nm23H1 has been identified in vitro, which may function in developing neuronal systems.     

Strength in the periphery: growth cone biomechanics and substrate rigidity response in peripheral and central nervous system neurons

There is now considerable evidence of the importance of mechanical cues in neuronal development and regeneration. Motivated by the difference in the mechanical properties of the tissue environment between the peripheral (PNS) and central (CNS) nervous systems, we compare substrate-stiffness-dependent outgrowth and traction forces from PNS (dorsal root ganglion (DRG)) and CNS (hippocampal) neurons. We show that neurites from DRG neurons display maximal outgrowth on substrates with a Young's modulus of ～1000 Pa, whereas hippocampal neurite outgrowth is independent of substrate stiffness. Using traction force microscopy, we also find a substantial difference in growth cone traction force generation, with DRG growth cones exerting severalfold larger forces compared with hippocampal growth cones. The traction forces generated by DRG and hippocampal growth cones both increase with increasing stiffness, and DRG growth cones growing on substrates with a Young's modulus of 1000 Pa strengthen considerably after 18–30 h. Finally, we find that retrograde actin flow is almost three times faster in hippocampal growth cones than in DRG. Moreover, the density of paxillin puncta is significantly lower in hippocampal growth cones, suggesting that stronger substrate coupling of the DRG cytoskeleton is responsible for the remarkable difference in traction force generation. These findings reveal a differential adaptation of cytoskeletal dynamics to substrate stiffness in growth cones of different neuronal types, and highlight the potential importance of the mechanical properties of the cellular environment for neuronal navigation during embryonic development and nerve regeneration.