Neuroprotection by both NMDA and non-NMDA receptor antagonists in in vitro ischemia.

We have investigated the relative contributions of oxygen and glucose deprivation to ischaemic neurodegeneration in organotypic hippocampal slice cultures. Cultures prepared from 10-day-old rats were maintained in vitro for 14 days and then deprived of either oxygen (hypoxia), glucose (hypoglycaemia), or both oxygen and glucose (ischaemia). Hypoxia alone induced degeneration selectively in CA1 pyramidal cells and this was greatly potentiated if glucose was removed from the medium. We have also characterised the effects of both pre- and post-treatment using glutamate receptor antagonists and the sodium channel blocker tetrodotoxin (TTX). Neuronal death following either hypoxia or ischaemia was prevented by pre-incubation with CNQX, MK-801 or tetrodotoxin. MK-801 or CNQX also prevented death induced by either hypoxia or ischaemia if added immediately post-insult, however, post-insult addition of TTX prevented hypoxic but not ischaemic damage. Organotypic hippocampal slice cultures are sensitive to both NMDA and non-NMDA glutamate receptor blockade and thus represent a useful in vitro system for the study of ischaemic neurodegeneration paralleling results reported using in vivo models of ischaemia.

Urokinase-type plasminogen activator expression by neurons and oligodendrocytes during process outgrowth in developing rat brain.

The expression of tissue- and urokinase-type plasminogen activators has been studied in developing cerebellum, hippocampus, cerebral cortex, olfactory bulb and olfactory mucosa of the rat by in situ hybridization. All identifiable neurons express urokinase mRNA from an early stage in their development, and this expression appears to coincide with the onset of axogenesis. For cerebellar granule cells, both axonal growth and urokinase expression are initiated before they migrate from the external granule layer; for the majority of neocortical neurons, however, both processes are commenced after the cells have migrated to the cortical plate. Neurons continue to express this protease in the adult. The large projection neurons exhibit the highest levels of message, the smaller interneurons having much lower levels except for hippocampal granule cells, which have notably high levels of expression. Glial cells generally do not express urokinase message, except for transient expression by oligodendrocytes in developing fibre tracts during the period of myelination. Thus for both neurons and oligodendrocytes, the onset of urokinase-type plasminogen activator expression coincides with their initiation of major process outgrowth, although neurons maintain this expression in the adult, possibly to retain a degree of synaptic plasticity. In contrast, although high levels of message for the related protease, tissue plasminogen activator, are found in the embryonic floor plate, in postnatal brain it is abundantly expressed only by ventricular ependymal cells and by cells in connective tissue surrounding the olfactory nerve.

The expression of tissue and urokinase-type plasminogen activators in neural development suggests different modes of proteolytic involvement in neuronal growth.

Tissue and urokinase-type plasminogen activators are serine proteases with highly restricted specificity, their best characterised role being to release the broad specificity protease plasmin from inactive plasminogen. It has frequently been suggested that these, and similar proteases, are involved in axonal growth and tissue remodelling associated with neural development. To help define what this role might be, we have studied the expression of the plasminogen activators in developing rat nervous tissue. Urokinase-type plasminogen activator mRNA is strongly expressed by many classes of neurons in peripheral and central nervous system. We have analysed its appearance in spinal cord and sensory ganglia, and found the mRNA is detectable by in situ hybridisation very early in neuronal development (by embryonic day 12.5), at a stage compatible with it playing a role in axonal or dendritic growth. Tissue plasminogen activator mRNA, on the other hand, is expressed only by cells of the floor plate in the developing nervous system, from embryonic day 10.5 and thereafter. Immunohistochemical and enzymatic analysis showed that active tissue plasminogen activator is produced by, and retained within, the floor plate. A mechanism is suggested by which high levels of tissue plasminogen activator produced by the stationary cells of the floor plate could influence the direction of growth of commissural axons as they pass through this midline structure.

Selective inhibition of neurite outgrowth on mature astrocytes by Thy-1 glycoprotein.

THY-1, the smallest member of the immunoglobulin superfamily, is a major cell-surface component expressed by several tissues. The protein, carbohydrate and gene structures of this molecule are known, yet its function is not. It is highly expressed in nervous tissue, where it appears on virtually all neurons after the cessation of axonal growth. Here we show that expression of Thy-1 by a neural cell line inhibits neurite outgrowth on mature astrocytes, but not on other cellular substrata which include Schwann cells and embryonic glia. This inhibition of neurite extension on astrocytes can be reversed by low concentrations (nanomolar) of soluble Thy-1. If a similar interaction between neuronal Thy-1 and astrocytes occurs in vivo, it could stabilize neuronal connections and suppress axonal regrowth after injury in the astrocyte-rich areas of adult central nervous system.

Monoclonal antibodies reveal molecular differences between terminal fields in the rat dentate gyrus.

We have derived a number of monoclonal antibodies which detect molecular differences correlating with the afferent inputs to the molecular layer of the adult rat hippocampal dentate gyrus. One group, dubbed OM-1 to OM-4, strongly stain the outer zone of the molecular layer, which receives its major innervation from the ipsilateral entorhinal cortex. A second group, IM-1 and IM-2, show a complementary pattern and preferentially stain the inner molecular layer, which receives inputs from the ipsilateral and contralateral hippocampus. These antigens are not, however, restricted to these layers, being found outside the hippocampus in several other areas of neuropil in the adult brain. In the developing brain the IM-1 antigen appears ubiquitously from the earliest age studied, embryonic day 12. Within the dentate gyrus, its restriction to the inner terminal field of the molecular layer only occurs during the second postnatal week. In contrast, OM staining appears only sparsely and late in the prenatal brain, appearing in developing cortical white matter between embryonic days 18 and 20. The outer dentate molecular layer becomes OM-positive from birth onwards, corresponding to the time of arrival of entorhinal axons during the first postnatal week. These two groups of monoclonal antibodies recognize a number of different glycoproteins. Ultrastructural immunohistochemistry shows they are cell surface molecules, and as such may be involved in the recognition events required for the establishment of specific patterns of neuronal connectivity.

Cultured epithelioid astrocytes migrate after transplantation into the adult rat brain.

A highly purified population of dividing epithelioid astrocytes has been prepared from postnatal rat corpus callosum. These cells were labelled in culture by incorporation of either [3H]thymidine or fluorescent microspheres and transplanted in a fibrin clot into the hippocampi of adult syngeneic rats. Transplanted cells divided in vivo and progressively migrated into the host brain from the site of implantation up to distances of about 1 mm. After a 1-week survival, transplant cells stained strongly for glial fibrillary acidic protein and had the thick sinuous processes characteristic of stellate astrocytes. Artefactual transfer of radiolabel to host cells was ruled out by control experiments in which either the proportion of transplant cells that were radiolabelled was varied or radiolabelled transplant cells were killed prior to implantation. Astrocyte migration over the first days after implantation was determined to occur at a rate of approximately 100 microns per day. Transplant cells moved into both grey and white matter areas of the host brain and over the migratory period were commonly observed to be associated with blood vessels. Some transplant cells were directly juxtaposed against neuronal perikarya and dendrites. Many labelled astrocytes were located in areas that were apparently completely free of damage caused by implantation. These results define a class of mature astrocytic cells that have the ability to migrate through the adult brain. The existence of pathways for cell movement in the adult CNS has implications for the mechanisms of tissue remodelling after injury and transplantation, for regenerative repair of the CNS, and for the dynamics of cell-cell contacts in the normal adult mammalian brain.

Selective innervation of embryonic hippocampal transplants by adult host dentate granule cell axons.

Fragments containing different cytoarchitectonic fields were dissected out of late embryonic rat hippocampal primordia and transplanted into the hippocampus or septum of adult syngeneic hosts. Field CA3 transplants contained clusters of large, angular (pyramidal) cell bodies surrounded by a radiating corona of dendrites. These cells stained selectively with our monoclonal antibody Py, and a proportion were labelled by [3H]thymidine administered on the 15th day of embryonic life. Field CA1 transplants contained smaller, angular, Py-negative cells, which formed elongated laminae rather than globular clusters. The ability of the host dentate granule cells to project to the transplants was examined by (1) the Timm stain for mossy fibres, (2) electron microscopy of Golgi-impregnated CA3 pyramidal neurons in the transplants, and (3) quantitative electron microscopic assessment of the proportions of large mossy fibre terminals in the synaptic population of the transplants. The Timm stain showed that CA3 transplants received a projection from host dentate granule cells when the transplants were placed in direct contact with the axons in the host mossy fibre pathway. As in the normal host field CA3, the ingrowing mossy fibres terminated selectively on the juxtacellular regions of the dendritic tree and ignored the major part of the dendrites in the radiating corona. The electron micrographs showed that within this territory the host mossy fibres formed synaptic terminals with all the complex features typical of normal mossy fibres, and were presynaptic to complex spines arising from the juxtacellular region of Golgi-impregnated donor CA3 pyramidal cells. The quantitative electron microscopic study demonstrated that the mossy fibre-innervated juxtacellular regions of the field CA3 transplants had up to 20% of the normal density of mossy fibre synapses found in the stratum lucidum of field CA3 in situ. CA3 transplants which were placed in the septum, remote from the host mossy fibres, had either trivial numbers of mossy fibre synapses or none. This confirmed that the abundant mossy fibre terminals in the intrahippocampal CA3 transplants were of host origin, and not due to donor dentate granule cells inadvertently included in the grafts. The selectivity of the host dentate projection for field CA3 transplants was demonstrated by the observation that CA1 transplants in the same locations received only slight mossy fibre projections in the Timm stain, and in electron micrographs their synaptic population had only insignificant numbers of large mossy fibre terminals.(ABSTRACT TRUNCATED AT 400 WORDS)

Selective growth of hippocampal neurites on cryostat sections of rat brain.

Dissociated rat hippocampal neurons were cultured on horizontal cryostat sections from neonatal and adult rat brain and their growth patterns visualized by brightfield and interference contrast microscopy. Cells adhered to the sections as individuals or in small clusters and grew extensive neurites. Neurites grew over all areas of neonatal sections without apparent selectivity. For adult sections, however, neurites grew almost exclusively on areas of grey matter: there was no neurite growth on areas of white matter, irrespective of the location of that white matter within the brain. The transition from the neonatal to the adult pattern of growth occurred for sections from animals aged between 14 and 21 days.

Microtransplantation of neural cells into adult rat brain.

Epithelioid ("type 1") astrocytes and hippocampal neurons have been stereotaxically grafted into adult rat brain by a new "microtransplantation" method and the results of grafting assessed at various survival times by conventional histological methods using light and electron microscopes. The extent of bleeding that accompanied grafting was assessed by peroxidase staining of extravascular red cells. Grafts were small, compact and reproducible in terms of their volume and location. Implantation was achieved with very little trauma to host tissue. There was no apparent disruption of host tissue adjacent to the graft and very little damage to host blood vessels from earliest survival times. Donor astrocytes were in direct contact with cells of the host immediately after grafting. This situation was compared with conventional implantation of astrocytes in which much damage, necrosis and bleeding occurred and for which cells of graft and host were initially isolated from one another. Microtransplanted astrocytes were observed to migrate. Similar, comparatively non-traumatic microtransplantation of hippocampal neurons was also carried out. Long-term survival of grafted neurons was demonstrated.

A monoclonal antibody, Py, distinguishes different classes of hippocampal neurons.

A monoclonal antibody, Py, was produced by immunizing mice with a glycoprotein fraction isolated from 3-week-old rat hippocampus. Py antibodies gave strong immunocytochemical staining of the perikarya and dendrites of large neurons in many areas of the rat brain, including the cerebral cortex, hippocampus, cerebellum, brain stem, and olfactory bulb. Immunoelectron microscopy showed the antigen to be predominantly intracellular, although its presence on the neuronal cell surface was not excluded. The antibody gave differential staining of adult hippocampal neurons, large pyramids of field CA3 being strongly immunoreactive, while CA1 pyramids and the dentate granule cells were unstained. Some interneurons were positive in each of the hippocampal fields. In developing hippocampus, the Py antigen appeared by the middle of the first postnatal week, and the adult pattern of staining was achieved by the end of the second week. Immunoblotting showed the antigen to have a relative mobility of 146 kDa with an additional faint band at 166 kDa. Differential Py staining of neurons was seen in dissociated cultures of embryonic hippocampus and in subdissected hippocampal fragments transplanted into adult host brains. This antibody can therefore be used for identification of hippocampal neurons that have been removed from their normal anatomical context.

Fetal medial habenula transplants: innervation of the rat interpeduncular nucleus.

The effects of donor age and site of placement on the survival of fetal medial habenula (MH) transplants into adult rats hosts were examined. The innervation of the interpeduncular nucleus (IPN) in such cases was also examined. Explants of MH consisting of the medial-dorsal lip of the third ventricle were held in vitro for 1-2 days. Colloidal gold conjugated to wheat germ agglutinin was added for the last 18 hours to label the cells. Four of 16 cases with E19 derived transplants contained donor neurons. Markedly larger transplants were present in 95% of 20 cases with E16 derived transplants. Sites in the ventral midbrain were successful, while limited or no survival occurred at sites more remote from IPN. Retrograde labeling of transplant neurons was present in each case studied with HRP injection into host IPN. Colloidal gold-labeled macrophages, some oriented capillaries and GFAP-positive processes marked the donor-host interface. In EM the interface was evident only by the difference in tissue elements in the transplant versus host. Numerous synapses of Gray types I and II were present in the transplant. Excellent survival of MH neurons, donor/host interfaces, innervation of IPN by the transplant and fine structure in and around the transplants, all suggest that such preparations are suitable for further experimental analysis of the habenulo-interpeduncular system.

Visualization of migration of transplanted astrocytes using polystyrene microspheres.

Fluorescent polystyrene microspheres have been used to mark rat astrocytes for transplantation. Highly fluorescent cells were generated by incorporation of microspheres over periods of the order of 10 h. Microspheres ranging in average diameter from 50 to 200 nm and derivatized with either rhodamine or fluorescein have been used to label cells. There were no apparent cytotoxic effects of microsphere incorporation. Loaded astrocytes retained their complement of microspheres over periods of at least several weeks. The microspheres could be visualized in the transmission electron microscope. They were most likely phagocytosed by a coated-pit mechanism and accumulated in various types of lysosomal vesicles. Labelled astrocytes from neonatal PVG rats were implanted stereotaxically (as a plasma clot) into hippocampi of recipient syngeneic adult rats. Donor cells migrated from transplant to host over about 7 days. Transplant cells tended to be close to blood vessels over this period. Their location in paravascular spaces was determined from observation of microsphere-bearing cells in electron microscopy. Microsphere-loading of astrocytes is a simple method for marking cells for extended periods of time for transplantation which allows direct identification of marked cells with both fluorescence and electron microscopes.

Use of colloidal gold complexes of wheat germ agglutinin as a label for neural cells.

We have made stable complexes between wheat germ agglutinin and either 5 or 10 nm particles of colloidal gold. These complexes were phagocytosed by neuronal and glial cells in embryonic rat hippocampal cultures and the incorporated gold gave intense, low-background staining in the light microscope either directly, for the most heavily labelled cells, or after intensification by physical development of silver. Cells were labelled in a punctate fashion over perikarya and processes. In the electron microscope, particles of gold were observed in lysosomal vesicles, frequently in an aggregated form. Gold complex incorporated into cells in culture was retained by those cells over periods up to 20 days. Embryonic hippocampal cells were labelled in suspension culture by incorporation of wheat germ agglutinin-gold complexes and transplanted into the brains of syngeneic adult host rats. Grafted neurons and glia were observed in the electron microscope to retain high levels of gold label over periods up to 30 days. Receipt of synaptic connections by transplanted neurones was observed. Complexes of wheat germ agglutinin with 10 nm gold particles were injected unilaterally into field CA3 of the hippocampus of adult rats. Specific retrograde transport of gold was observed in the light and electron microscopes to pyramidal and hilar neurones of the contralateral hippocampus and to neurones of the medial septal nucleus. Colloidal gold-wheat germ agglutinin complexes appear to be useful cellular markers that can be visualized at both light and electron microscope levels.

Rapid regulation of neuronal growth cone shape and surface morphology by nerve growth factor.

Scanning electron microscopy was used to study regulation of growth cone shape and surface morphology by nerve growth factor (NGF). The growth cones of cultured rat sympathetic neurons and neuronally-differentiated PC12 cells were observed under conditions of continuous NGF exposure, NGF withdrawal, and NGF readdition. Growth cones of cells cultured in the continuous presence of NGF were mostly spread in shape and about 60% possessed surface ruffles. Ruffles appeared to be largely restricted to growth cones in that few were observed on cell bodies and neurites. Withdrawal of NGF for 4-5 hr caused most of the growth cones to take on a non-spread or contracted appearance and to lose their ruffles. Readdition of NGF promoted rapid changes in growth cone properties. Within 30 sec, ruffling was again evident on the growth cones and remained prominent there throughout the course of treatment (up to 5 hr). This was in contrast to cell bodies on which, as previously reported, ruffling also occurred following NGF readdition, but only transiently (for less than 15 min). Respreading of growth cones also occurred under these conditions. This was evident within 1 min of NGF readdition and reached the levels observed in continuously-treated cultures within 1-2 hr. Neurites were also examined. Ruffles were only rarely present in the continuous presence of NGF and were absent after NGF withdrawal. NGF readdition elicited ruffling along neurites within 30 sec; the prevalence of such ruffles diminished to that seen in continuously-treated cultures within about an hour.(ABSTRACT TRUNCATED AT 250 WORDS)

Intracerebral transplantation of cultured neurons after reaggregation in a plasma clot.

In order to be able to transplant neural cells which have been either manipulated in vitro or maintained in culture for the purpose of cell-type enrichment, we have developed a novel plasma clot method which permits reaggregation of previously dissociated cells such that they can be implanted as highly localized transplants rather than as dispersion-prone cell suspension grafts. To establish the method, enzymatically dissociated cells prepared from hippocampal primordia of late embryonic rats were immediately reaggregated into plasma clots and transplanted to the hippocampal formation of adult recipients. By using fluorescein-labelled bovine plasma to form the plasma clot grafts of reaggregated cells, the fate of the plasma clot protein matrix was followed at different post-operative survival times. Initially, 4-5 days post-operative, the plasma clot maintained the grafted cells in a loose sponge-like sack at the site of implantation. After 2-3 weeks, the transplanted cells were more compact and fused with the host neuropil, and the plasma clot matrix had largely been degraded. At 1 month or longer survival, there was no distinguishable boundary between transplant and host, and there was little or no evidence of any remaining plasma clot matrix or proteins. The plasma clot method was subsequently applied to the transplantation of cultures enriched in pyramidal cells. Enrichment for pyramidal cells was achieved by eliminating mitotic cells (dentate granule cells and glia) by brief (200 rad) irradiation of hippocampal primordia followed by dissociation and maintenance in monolayer culture for 4-6 days. Fibres from host dentate granule cells grew into the pyramidal cell-enriched transplants and established mossy fibre terminals on the donor cells. In transplants between embryonic and adult rats, donor cells were identified at long survival times by prelabelling donor cells in utero or in vitro with [3H]thymidine prior to transplantation. In transplants between embryonic and adult mice, donor tissue from A Thy-1.1 strain mice was transplanted to congenic A strain (Thy-1.2) mice such that the donor cells bearing the Thy-1.1 cell surface glycoprotein could be later identified by immunocytochemical staining with antibodies specific for the Thy-1.1 antigen. Reaggregation and transplantation of dissociated cells in a plasma clot thus provides a novel method whereby prior manipulation of neural tissue (separation of neurons and glia, enrichment for specific types of neurons, or glia etc.) can be used to great advantage in studying host-transplant connectivity and in assessing those factors which are critical in sustaining the survival of grafted neural tissue.

Lithium ion inhibits nerve growth factor-induced neurite outgrowth and phosphorylation of nerve growth factor-modulated microtubule-associated proteins.

LiCl (2.5-20 mM) reversibly suppressed nerve growth factor (NGF)-induced neurite outgrowth by cultured rat PC 12 pheochromocytoma cells. Similar concentrations of LiCl also reversibly blocked NGF-dependent regeneration of neurites by PC12 cells that had been primed by long-term pre-exposure to NGF and by cultured newborn mouse sympathetic neurons. In contrast, transcription-dependent responses of PC12 cells to NGF such as priming and induction of the NGF-inducible large external glycoprotein, occurred despite the presence of Li+. SDS PAGE analysis of total cellular phosphoproteins (labeled by 2-h exposure to 32P-orthophosphate) from neurite-bearing primed PC12 cells revealed that Li+ reversibly inhibited the phosphorylation of a band of Mr 64,000 that was barely detectable in NGF-untreated PC12 cells. However, Li+ did not appear to affect the labeling of other phosphoproteins in either NGF-primed or untreated PC12 cultures, nor did it affect the rapid increase in phosphorylation of several proteins that occurs when NGF is first added to unprimed cultures. Several criteria indicated that the NGF-inducible phosphoprotein of Mr 64,000 is a microtubule-associated protein (MAP). Of the NGF-inducible phosphorylated MAPs that have been detected in PC12 cells (Mr 64,000, 72,000, 80,000, and 320,000), several (Mr 64,000, 72,000, and 80,000) were found to be substantially less phosphorylated in the presence of Li+. Neither a phorbol ester tumor promotor nor permeant cAMP analogs reversed the inhibitory effects of Li+ on neurite outgrowth or on phosphorylation of the component of Mr 64,000. Microtubules are a major and required constituent of neurites, and MAPs may regulate the assembly and stability of neuritic microtubules. The observation that Li+ selectively inhibits NGF-induced neurite outgrowth and MAP phosphorylation suggests a possible causal relationship between these two events.

Regulation of tyrosine hydroxylase phosphorylation in PC12 pheochromocytoma cells by elevated K+ and nerve growth factor. Evidence for different mechanisms of action.

A specific antiserum was used to compare phosphorylation of tyrosine hydroxylase (TH) (EC 1.14.16.2, tyrosine 3-monooxygenase) as regulated by elevated K+ and nerve growth factor (NGF) in cultured PC12 pheochromocytoma cells. Exposure of cultures to either elevated K+ or to NGF significantly enhanced the incorporation of [32P]orthophosphate into TH. The effect of elevated K+ was evident at 10 mM and was maximal by 40-80 mM. Increased phosphorylation of TH was detected at 0.1 nM (3 ng/ml) NGF and reached a maximal level by 0.3-1 nM (10-30 ng/ml) NGF. Elevated K+ showed a biphasic time course of action with one maximum of phosphorylation at about 30 sec of exposure and a second after about 10 min of exposure. In contrast, the NGF effect showed an initial lag of several minutes followed by a monophasic increase in phosphorylation to reach a plateau. Both treatments enhanced TH activity, but in each case the time courses of this did not strictly correlate with that of phosphorylation. The effect of elevated K+ on TH phosphorylation required the presence of extracellular Ca2+ and was suppressed by trifluoperazine (100 microM). N-(6-Aminohexyl)-5-(chloronaphthalene)-1-sulfonamide (W-7) (100 microM), a potent inhibitor of calmodulin activity, also blocked the enhancement of phosphorylation by elevated K+, whereas N-(6-aminohexyl)-1-(naphthalene)sulfonamide (W-5) (100 microM), a less potent analogue of W-7, did not. In contrast to these findings, the increase in TH phosphorylation brought about by NGF did not require extracellular Ca2+, and was only slightly affected by trifluoperazine or W-7. When TH phosphorylated under various conditions (control medium, elevated K+, NGF) was subjected to peptide mapping after exposure to Staphylococcus aureus protease V8, multiple phosphorylated peptides were observed. Elevated K+ and NGF each produced increases in labeling of each of the peptides. However, the relative degree of labeling of different peptides was distinct for each condition. These data suggest that elevated K+ and NGF bring about rapid enhancement of the phosphorylation of TH by means of different mechanisms.

Regulation of growth cone morphology by nerve growth factor: a comparative study by scanning electron microscopy.

The object of this study was to document and analyze local regulation by nerve growth factor (NGF) of neuronal growth cone properties and to explore the possible diversity of this effect in various NGF-responsive preparations. In particular, scanning electron microscopy was used to characterize the morphology of neuronal growth cones in cultures of dissociated chick embryo dorsal root ganglia (DRG) under conditions of continuous NGF exposure, withdrawal of NGF for 5-6 hr, and restoration of NGF for various times. Comparison was made with similarly manipulated cultures of dissociated newborn rat sympathetic ganglia and neurite-bearing PC12 pheochromocytoma cells. The growth cones of most of the continuously NGF-treated DRG neurons (cultured on poly-L-lysine or collagen-coated glass coverslips) had relatively compact central flattened areas and numerous prominent filopodia. Withdrawal of NGF resulted in a marked spreading of the central growth cone area so that the average maximum width of this structure increased by about threefold as compared to nondeprived cultures. The mean number and lengths of filopodia were unaffected. Restoration of NGF brought about, over a time course of tens of minutes, a return of the original type of growth cone morphology. Rather different responses were observed for the sympathetic neuron and PC12 cultures. Here, surface ruffles, only rarely seen in the chick cultures, were a major feature of the growth cones, whereas filopodia, though present, were less prominent. Removal of NGF led to loss of ruffles and to rounding up of the growth cones; NGF readdition elicited a rapid (less than 30 sec) reinitiation of ruffling and a more gradual (over tens of minutes) respreading of growth cones. These findings illustrate not only that NGF can regulate growth cone properties, but also that there is a diversity as to how this is manifested. Possible mechanisms and biological roles for this regulation are discussed.