Morphological properties and membrane channels of the growth cones induced in PC12 cells by nerve growth factor

A novel Microproteomic Approach Using Laser Capture Microdissection to Study Cellular Protrusions

Cell–cell communication is vital to multicellular organisms, and distinct types of cellular protrusions play critical roles during development, cell signaling, and the spreading of pathogens and cancer. The differences in the structure and protein composition of these different types of protrusions and their specific functions have not been elucidated due to the lack of a method for their specific isolation and analysis. In this paper, we described, for the first time, a method to specifically isolate distinct protrusion subtypes, based on their morphological structures or fluorescent markers, using laser capture microdissection (LCM). Combined with a unique fixation and protein extraction protocol, we pushed the limits of microproteomics and demonstrate that proteins from LCM-isolated protrusions can successfully and reproducibly be identified by mass spectrometry using ultra-high field Orbitrap technologies. Our method confirmed that different types of protrusions have distinct proteomes and it promises to advance the characterization and the understanding of these unique structures to shed light on their possible role in health and disease.

NGF-induced cell differentiation and gene activation is mediated by integrative nuclear FGFR1 signaling (INFS)

Nerve growth factor (NGF) is the founding member of the polypeptide neurotrophin family responsible for neuronal differentiation. To determine whether the effects of NGF rely upon novel Integrative Nuclear FGF Receptor-1 (FGFR1) Signaling (INFS) we utilized the PC12 clonal cell line, a long-standing benchmark model of sympathetic neuronal differentiation. We demonstrate that NGF increases expression of the fgfr1 gene and promotes trafficking of FGFR1 protein from cytoplasm to nucleus by inhibiting FGFR1 nuclear export. Nuclear-targeted dominant negative FGFR1 antagonizes NGF-induced neurite outgrowth, doublecortin (dcx) expression and activation of the tyrosine hydroxylase (th) gene promoter, while active constitutive nuclear FGFR1 mimics the effects of NGF. NGF increases the expression of dcx, th, βIII tubulin, nurr1 and nur77, fgfr1and fibroblast growth factor-2 (fgf-2) genes, while enhancing binding of FGFR1and Nur77/Nurr1 to those genes. NGF activates transcription from isolated NurRE and NBRE motifs. Nuclear FGFR1 transduces NGF activation of the Nur dimer and raises basal activity of the Nur monomer. Cooperation of nuclear FGFR1 with Nur77/Nurr1 in NGF signaling expands the integrative functions of INFS to include NGF, the first discovered pluripotent neurotrophic factor.

Fluorescent saxitoxins for live cell imaging of single voltage-gated sodium ion channels beyond the optical diffraction limit

A desire to better understand the role of voltage-gated sodium channels (Na(V)s) in signal conduction and their dysregulation in specific disease states motivates the development of high precision tools for their study. Nature has evolved a collection of small molecule agents, including the shellfish poison (+)-saxitoxin, that bind to the extracellular pore of select Na(V) isoforms. As described in this report, de novo chemical synthesis has enabled the preparation of fluorescently labeled derivatives of (+)-saxitoxin, STX-Cy5, and STX-DCDHF, which display reversible binding to Na(V)s in live cells. Electrophysiology and confocal fluorescence microscopy studies confirm that these STX-based dyes function as potent and selective Na(V) labels. The utility of these probes is underscored in single-molecule and super-resolution imaging experiments, which reveal Na(V) distributions well beyond the optical diffraction limit in subcellular features such as neuritic spines and filopodia.

NCS-1 differentially regulates growth cone and somata calcium channels in Lymnaea neurons

Local voltage-gated calcium channels, which regulate intracellular Ca2+ levels by allowing Ca2+ influx, play an important role in guiding and shaping growth cones, and in regulating the outgrowth and branching of neurites. Therefore, elucidating the mechanisms that regulate the biophysical properties of whole-cell calcium currents in the growth cones and somata of growing neurons is important to improving our understanding of neuronal development and regeneration. In this study, taking advantage of the large size of the pedal A (PeA) neurons in Lymnaea stagnalis, we compared the biophysical properties of somata and growth cone whole-cell calcium channel currents using Ba2+ and Ca2+ as current carriers. We found that somata and growth cone currents exhibit similar high-voltage activation properties. However, Ba2+ and Ca2+ currents in growth cones and somata are differentially affected by a dominant-negative peptide containing the C-terminal amino acid sequence of neuronal calcium sensor-1 (NCS-1). The peptide selectively reduces the peak and sustained components of current densities and the slope conductance in growth cones, and shifts the reversal potential of the growth cone currents to more hyperpolarized voltages. In contrast, the peptide had no significant effect on the somata calcium channels. Thus, we conclude that NCS-1 differentially modulates Ca2+ currents in the somata and growth cones of regenerating neurons, and may serve as a key regulator to facilitate the growth cone calcium channel activity.

Cell volume regulatory ion channels in cell proliferation and cell death

Alterations of cell volume are key events during both cell proliferation and apoptotic cell death. Cell proliferation eventually requires an increase of cell volume, and apoptosis is typically paralleled by cell shrinkage. Alterations of cell volume require the participation of ion transport across the cell membrane, including appropriate activity of Cl(-) and K(+) channels. Cl(-) channels modify cytosolic Cl(-) activity and mediate osmolyte flux, and thus influence cell volume. Most Cl(-) channels allow exit of HCO(3)(-), leading to cytosolic acidification, which in turn inhibits cell proliferation and favors apoptosis. K(+) exit through K(+) channels decreases cytosolic K(+) concentration, which may sensitize the cell for apoptotic cell death. K(+) channel activity further maintains the cell membrane potential, a critical determinant of Ca(2+) entry through Ca(2+) channels. Ca(2+) may, in addition, enter through Ca(2+)-permeable cation channels, which, in some cells, are activated by hyperosmotic shock. Increases of cytosolic Ca(2+) activity may trigger both mechanisms required for cell proliferation and mechanisms, leading to apoptosis. Thereby cell proliferation and apoptosis depend on magnitude and temporal organization of Ca(2+) entry, as well as activity of other signaling pathways. Accordingly, the same ion channels may participate in the stimulation of both cell proliferation and apoptosis. Specific ion channel blockers may thus abrogate both cellular mechanisms, depending on cell type and condition.

Sub-cellular Ca2+ dynamics affected by voltage- and Ca2+-gated K+ channels: Regulation of the soma-growth cone disparity and the quiescent state in Drosophila neurons

Using Drosophila mutants and pharmacological blockers, we provide the first evidence that distinct types of K(+) channels differentially influence sub-cellular Ca(2+) regulation and growth cone morphology during neuronal development. Fura-2-based imaging revealed in cultured embryonic neurons that the loss of either voltage-gated, inactivating Shaker channels or Ca(2+)-gated Slowpoke BK channels led to robust spontaneous Ca(2+) transients that preferentially occurred within the growth cone. In contrast, loss of voltage-gated, non-inactivating Shab channels did not show such a disparity and sometimes produced soma-specific Ca(2+) transients. The fast spontaneous transients in both the soma and growth cone were suppressed by the Na(+) channel blocker tetrodotoxin, indicating that these Ca(2+) fluctuations stemmed from increases in membrane excitability. Similar differences in regional Ca(2+) regulation were observed upon membrane depolarization by high K(+)-containing saline. In particular, Shaker and slowpoke mutations enhanced the size and dynamics of the depolarization-induced Ca(2+) increase in the growth cone. In contrast, Shab mutations greatly prolonged the Ca(2+) increase in the soma. Differential effects of these excitability mutations on neuronal development were indicated by their distinct alterations in growth cone morphology. Loss of Shaker currents increased the size of lamellipodia and the number of filopodia, structures associated with the actin cytoskeleton. Interestingly, loss of Slowpoke currents strongly influenced tubulin regulation, enhancing the number of microtubule loop structures per growth cone. Together, our findings support the idea that individual K(+) channel subunits differentially regulate spontaneous sub-cellular Ca(2+) fluctuations in growing neurons that may influence activity-dependent growth cone formation.

Ion channels in cell proliferation and apoptotic cell death

Cell proliferation and apoptosis are paralleled by altered regulation of ion channels that play an active part in the signaling of those fundamental cellular mechanisms. Cell proliferation must--at some time point--increase cell volume and apoptosis is typically paralleled by cell shrinkage. Cell volume changes require the participation of ion transport across the cell membrane, including appropriate activity of Cl- and K+ channels. Besides regulating cytosolic Cl- activity, osmolyte flux and, thus, cell volume, most Cl- channels allow HCO3- exit and cytosolic acidification, which inhibits cell proliferation and favors apoptosis. K+ exit through K+ channels may decrease intracellular K+ concentration, which in turn favors apoptotic cell death. K+ channel activity further maintains the cell membrane potential, a critical determinant of Ca2+ entry through Ca2+ channels. Cytosolic Ca2+ may trigger mechanisms required for cell proliferation and stimulate enzymes executing apoptosis. The switch between cell proliferation and apoptosis apparently depends on the magnitude and temporal organization of Ca2+ entry and on the functional state of the cell. Due to complex interaction with other signaling pathways, a given ion channel may play a dual role in both cell proliferation and apoptosis. Thus, specific ion channel blockers may abrogate both fundamental cellular mechanisms, depending on cell type, regulatory environment and condition of the cell. Clearly, considerable further experimental effort is required to fully understand the complex interplay between ion channels, cell proliferation and apoptosis.

EGFP-tagged vasopressin precursor protein sorting into large dense core vesicles and secretion from PC12 cells

1. Hypothalamic magnocellular neurons synthesize, store, and secrete large quantities of the neuropeptides, vasopressin (VP) and oxytocin (OT), which are synthesized as protein precursors also containing proteins called neurophysins. These protein precursors are sorted through the regulated secretory pathway (RSP), packaged into large dense core vesicles LDCVs, and their peptide products are secreted from nerve terminals in the posterior pituitary. 2. It has been hypothesized that this efficient packaging is dependent on the interaction of the peptide with neurophysin in a complex that forms the granule core. To test this, PC12 cells were transfected with vasopressin precursor DNA constructs that either contained or deleted the neurophysin moiety and tagged with enhanced green fluorescent protein (EGFP) as reporters. The intracellular routing and secretion of the EGFP-tagged VP precursor proteins were studied by in differentiated PC12 cells by fluorescence microscopy, electron microscopic immunocytochemistry, and fluorescent imaging techniques. 3. The data showed that only when the neurophysin was present in the VP precursor construct did the fluorescent fusion protein become routed to the RSP and get efficiently packaged into LDCVs and secreted. These data are consistent with the view that routing of the precursor to LDCVs requires the amino acids that encode the intravesicular chaperone, neurophysin.

The effect of endogenous dopamine in rotenone-induced toxicity in PC12 cells

Deficiencies in Complex I have been observed in Parkinson's disease (PD) patients. Systemic exposure to rotenone, a Complex I inhibitor, has been shown to lead to selective dopaminergic cell death in vivo and toxicity in many in vitro models, including dopaminergic cell cultures. However, it remains unclear why rotenone seems to affect dopaminergic cells more adversely. Therefore, the role of dopamine (DA) in rotenone-induced PC12 cell toxicity was examined. Rotenone (1.0 muM) caused significant toxicity in differentiated PC12 cells, which was accompanied by decreases in ATP levels, changes in catechol levels, and increased DA oxidation. To determine whether endogenous DA makes PC12 cells more susceptible to rotenone, cells were treated with the tyrosine hydroxylase inhibitor alpha-methyl-p-tyrosine (AMPT) to reduce DA levels prior to rotenone exposure, and then cell viability was measured. No changes in rotenone-induced toxicity were observed with or without AMPT treatment. However, a potentiation of toxicity was observed following coexposure of PC12 cells to rotenone and methamphetamine. To determine whether this effect was due to DA, PC12 cells were depleted of DA prior to methamphetamine and rotenone cotreatment, resulting in a large attenuation in toxicity. These findings suggest that DA plays a role in rotenone-induced toxicity and possibly the vulnerability of DA neurons in PD.

Neurotrophins and synaptic plasticity

Despite considerable evidence that neuronal activity influences the organization and function of circuits in the developing and adult brain, the molecular signals that translate activity into structural and functional changes in connections remain largely obscure. This review discusses the evidence implicating neurotrophins as molecular mediators of synaptic and morphological plasticity. Neurotrophins are attractive candidates for these roles because they and their receptors are expressed in areas of the brain that undergo plasticity, activity can regulate their levels and secretion, and they regulate both synaptic transmission and neuronal growth. Although numerous experiments show demonstrable effects of neurotrophins on synaptic plasticity, the rules and mechanisms by which they exert their effects remain intriguingly elusive.

Neurotrophin regulation of ionic currents and cell size depends on cell context

Trk receptor activation by neurotrophins is often considered to have a defined set of actions on target neurons, including supporting neuronal survival, inducing morphological differentiation, and regulating a host of target genes that specify neuronal phenotype. It is not known if all such regulatory effects are obligatory, or if some may vary depending on the cell context in which the receptors are expressed. We have examined this issue by comparing neurotrophin effects on the regulation of electrical excitability and morphological differentiation in two strains of PC12 cells. We found that while neurotrophins induced neurite extension and increased calcium currents in both PC12 cell types, sodium current levels were regulated in only one of these strains. Moreover, we found little correlation between calcium current levels and the extent of morphological differentiation when compared in individual cells of a single strain. Thus, the regulatory effects of neurotrophins on cell phenotype are not fully determined by the Trk receptors that they activate; rather, they can vary with differences in cell context that arise not only between different cell lineages, but also between individual cells of clonal relation.

Reduced electrical excitability of PC12 cells deficient in GAP-43: comparison with GAP-43-positive cells

The electrical excitability of 3 lines of rat pheochromocytoma (PC12) cells were determined under current-clamp recording conditions. In the presence of nerve growth factor (NGF), PC12(A) 'control' cells expressed high levels of GAP-43 protein, PC12(B) cells were highly deficient in GAP-43, and PC12(AB) cells, created by transfection of PC12(B) cells with a rat GAP-43 gene construct, expressed high levels of GAP-43. All 3 lines had similar resting membrane potentials, but significantly greater proportions of GAP-43-containing PC12(A) and PC12(AB) cells exhibited spiking in response to depolarizing current pulses. These spikes were resistant to TTX, were greatly enhanced in TEA and TTX, and were substantially reduced by L-type Ca(2+)-channel antagonists. GAP-43 expression may regulate PC12 cell excitability following NGF treatment, as reflected in a lower proportion of cells capable of discharging with Ca(2+)-spikes in a GAP-43-deficient cell line.

A single pulse of nerve growth factor triggers long-term neuronal excitability through sodium channel gene induction

The continuous presence of nerve growth factor (NGF) is thought to be required for the elaboration of neuronal-like traits in PC12 cells. Surprisingly, we find that a 1 min exposure to NGF is sufficient to engage a longer-term genetic program leading to the acquisition of membrane excitability. Whereas continuous exposure to NGF causes the induction of a family of sodium channels, the effect of a brief exposure is to induce selectively expression of the peripheral nerve-type sodium channel gene PN1, through a distinct signaling pathway requiring immediate-early genes. A 1 min exposure of PC12 cells to interferon-gamma also causes PN1 gene induction, suggesting that the "triggered" NGF and interferon-gamma signaling pathways share common molecular intermediates.

Presynaptic excitability

Based on functional characterizations with electrophysiological techniques, the channels in nerve terminals appear to be as diverse as channels in nerve cell bodies (Table I). While most presynaptic Ca2+ channels superficially resemble either N-type or L-type channels, variations in detail have necessitated the use of subscripts and other notations to indicate a nerve terminal-specific subtype (e.g., Wang et al., 1993). Variations such as these pose a serious obstacle to the identification of presynaptic channels based solely on the effects of channel blockers on synaptic transmission. Pharmacological sensitivity alone is not likely to help in determining functional properties. Crucial details, such as voltage sensitivity and inactivation, require direct examination. It goes without saying that every nerve terminal membrane contains Ca2+ channels as an entry pathway so that Ca2+ can trigger secretion. However, there appears to be no general specification of channel type, other than the exclusion of T-type Ca2+ channels. T-type Ca2+ channels are defined functionally by strong inactivation and low threshold. Some presynaptic Ca2+ channels inactivate (posterior pituitary and Xenopus nerve terminals), and others have a somewhat reduced voltage threshold (retinal bipolar neurons and squid giant synapse). Perhaps it is just a matter of time before a nerve terminal Ca2+ channel is found with both of these properties. The high threshold and strong inactivation of T-type Ca2+ channels are thought to be adaptations for oscillations and the regulation of bursting activity in nerve cell bodies. The nerve terminals thus far examined have no endogenous electrical activity, but rather are driven by the cell body. On functional grounds, it is then reasonable to anticipate finding T-type Ca2+ channels in nerve terminals that can generate electrical activity on their own. The rarity of such behavior in nerve terminals may be associated with the rarity of presynaptic T-type Ca2+ channels. In four of the five preparations reviewed in this chapter--motor nerve, squid giant synapse, ciliary ganglion, and retina bipolar neurons--evidence was presented that supports a location for Ca2+ channels that is very close to active zones of secretion. All of these synapses secrete from clear vesicles, and the speed and specificity of transduction provided by proximity may be a common feature of these rapid synapses. In contrast, the posterior pituitary secretion apparatus may be triggered by higher-affinity Ca2+ receptors and lower concentrations of Ca2+ (Lindau et al., 1992). This would correspond with the slower performance of peptidergic secretion, but because of the large stimuli needed to evoke release from neurosecretosomes, the possibility remains that the threshold for secretion is higher than that reported. While the role of Ca2+ as a trigger of secretion dictates a requirement for voltage-activated Ca2+ channels as universal components of the presynaptic membrane, the presence of other channels is more difficult to predict. Depolarizations caused by voltage-activated Na+ channels activate the presynaptic Ca2+ channels, but whether this depolarization requires Na+ channels in the presynaptic membrane itself may depend on the electrotonic length of the nerve terminal. Variations in density between motor nerve terminals may reflect species differences in geometry. The high Na+ channel density in the posterior pituitary reflects the great electrotonic length of this terminal arbor. Whether Na+ channels are abundant or not in a presynaptic membrane, K+ channels provide the most robust mechanism for limiting depolarization-induced Ca2+ entry. K+ channel blockers enhance transmission at most synapses. In general, K+ channels are abundant in nerve terminals, although their apparent lower priority compared to Ca2+ channels in the eyes of many investigators leaves us with fewer detailed investigations in some preparations. Most nerve terminals have more than

Nerve growth factor regulates the abundance and distribution of K+ channels in PC12 cells

We examined the effect of nerve growth factor (NGF) treatment on expression of a neuronal delayed rectifler K+ channel subtype, Kv2.1 (drk1), in PC12 cells. Anti-Kv2.1 antibodies recognized a single polypeptide population of M(r) = 132 kD in PC12 cell membranes, distinct from the more heterogeneous population found in adult rat brain. In response to NGF treatment, levels of Kv2.1 polypeptide in PC12 membranes increased fourfold. This increase in polypeptide levels could be seen within 12 h, and elevated levels were maintained for at least 6 d of continuous NGF treatment. RNase protection assays indicate that this increase in Kv2.1 protein occurs without an increase in steady state levels of Kv2.1 mRNA following NGF treatment. Immunofluorescent localization of the Kv2.1 polypeptide revealed plasma membrane-associated staining of cell bodies in both untreated and NGF-treated PC12 cells. In undifferentiated cells, intense staining is seen at sites of cell-cell and cell-substratum contact. In differentiated cells the most intense Kv2.1 staining is observed in neuritic growth cones. These studies show that in PC12 cells both the abundance and distribution of the Kv2.1 k+ channel are regulated by NGF, and suggest that PC12 cells provide a model for the selective expression of Kv2.1 in neuritic endings.

Selection of transmitter responses at sites of neurite contact during synapse formation between identified leech neurons

1. Pressure sensitive (P) neurons of the leech Hirudo medicinalis show both an inhibitory, Cl(-)-dependent response and a depolarizing, cationic response to pipette application of serotonin (5-HT). Serotonergic Retzius (R) neurons in culture reform inhibitory, Cl(-)-dependent synapses with P neurons but fail to elicit the extrasynaptic, depolarizing response to 5-HT. We have examined the localization of the selection of 5-HT responses by testing the sensitivity of P cell growth cones and neurites to 5-HT application. 2. As measured by intracellular recording at the P cell soma, synaptic release of 5-HT from R cell processes activated only the Cl(-)-dependent response in P cell neurites. Focal application of 5-HT from a micropipette depolarized uncontacted P cell growth cones and neurites. In contrast, processes from the same P cells that were contacted by R cells were rarely depolarized by 5-HT application unless the application pipette was moved along the neurites away from the sites of contact. 3. The channels underlying the depolarizing response to 5-HT were identified in patch clamp recordings from P cell growth cones. These cation channels showed rare, brief openings in the absence of 5-HT. Application of 5-HT in the bath (outside the patch pipette) increased channel activity in uncontacted P cell growth cones but not in growth cones of the same P cells contacted by R cells. 4. We conclude that the selection of transmitter responses during synapse formation was localized to discrete sites of contact between the synaptic partners.

Comparison of adenosine triphosphate- and nicotine-activated inward currents in rat phaeochromocytoma cells

1. The adenosine triphosphate (ATP)-activated inward current was compared to the nicotine-activated inward current in nerve growth factor (NGF)-treated rat phaeochromocytoma PC12 cells. 2. Both ATP and nicotine activated an inward current at negative holding potentials. The concentration of ATP necessary to activate the inward current was about 10-fold higher than that of nicotine; the EC50 was 20.5 microM for ATP and 2.4 microM for nicotine. The maximal responses induced by ATP and nicotine were almost identical in the same cells. The current-voltage relationship for the ATP-activated current was very similar to that for the nicotine-activated current, and both currents reversed around 0 mV in a physiological saline. 3. The ATP-activated current and the nicotine-activated current were not additive; the current activated by a combined administration of ATP (100 microM) and nicotine (10 microM) was only about 20% larger than the current activated by either ATP or nicotine alone. Nicotine (100 microM) did not increase the current activated by 1 microM-ATP. 4. ATP could activate an inward current in the cells even after desensitization to nicotine had developed. 5. Hexamethonium (100 microM) selectively blocked the nicotine-activated current whereas suramin (100 microM), a purinoceptor antagonist, selectively blocked the ATP-activated current. 6. Ionic selectivity was studied by changing compositions of extracellular solutions. When external Na+ was replaced with Cs+, both ATP and nicotine activated inward currents. However, with an extracellular solution containing Tris or glucosamine as a major cation, only ATP, not nicotine, activated an inward current. 7. ATP- and nicotine-activated currents were also recorded from cells bathed in a solution containing 1.8 mM-Ca2+ as the only external cation, suggesting that both pathways are Ca2+ permeable. 8. The results suggest that the ATP-sensitive ionic pathway is not independent of the nicotine-sensitive pathway in these cells. Our working hypothesis is that ATP and nicotine activate the same channels but the binding sites and the open-states of the channels are different between these two agonists.

Sodium currents during differentiation in a human neuroblastoma cell line

The electrophysiological properties of a human neuroblastoma cell line, LA-N-5, were studied with the whole-cell configuration of the patch clamp technique before and after the induction of differentiation by retinoic acid, a vitamin A metabolite. Action potentials could be elicited from current clamped cells before the induction of differentiation, suggesting that some neuroblasts of the developing sympathetic nervous system are excitable. The action potential upstroke was carried by a sodium conductance, which was composed of two types of sodium currents, described by their sensitivity to tetrodotoxin (TTX) as TTX sensitive and TTX resistant. TTX-sensitive and TTX-resistant sodium currents were blocked by nanomolar and micromolar concentrations of TTX, respectively. The voltage sensitivity of activation and inactivation of TTX-resistant sodium current is shifted -10 to -30 mV relative to TTX-sensitive sodium current, suggesting that TTX-resistant sodium current could play a role in the initiation of action potentials. TTX-sensitive current comprised greater than 80% of the total sodium current in undifferentiated LA-N-5 cells. The surface density of total sodium current increased from 24.9 to 57.8 microA/microF after cells were induced to differentiate. The increase in total sodium current density was significant (P less than 0.05). The surface density of TTX-resistant sodium current did not change significantly during differentiation, from which we conclude that an increase in TTX-sensitive sodium current underlies the increase in total current.

Role of activity in the selection of new electrical synapses between adult Helisoma neurons

Our aim was to determine whether neural activity in the form of sodium-dependent action potentials play a role in the formation, maintenance and specificity of electrical synapses between regenerating neurons. We axotomized buccal neurons of the mollusc, Helisoma trivolvis, and placed ganglia into organ culture in the absence or presence of tetrodotoxin (TTX), a specific sodium channel blocker. Electrical coupling was measured using intracellular microelectrodes positioned within the soma of identified neurons. Neurite outgrowth was assessed by epifluorescence microscopy after filling neurons by iontophoresis with Lucifer yellow. Previous studies found that two days after axotomy transient electrical synapses form between heterologous neurons (e.g. buccal neurons 4 and 5). Five days after axotomy these transient connections disappeared and a new electrical synapse was stabilized between the paired buccal neurons 5. To determine whether blocking neural activity with TTX affected the specificity and formation of new electrical synapses, we examined electrical coupling between the heterologous neurons 4 and 5 two days after axotomy, and the paired buccal neurons 5 five days after axotomy. Our electrophysiological recordings indicated that different neurons in the buccal ganglion varied in their sensitivity to TTX (i.e. sensitivity of buccal neurons 19 greater than 5 greater than 4), but spontaneous activity was abolished in all 3 neurons by 2 x 10(-5) M TTX. Furthermore, the inhibitory effects of TTX occurred within seconds of superfusion and persisted for at least 6 days. Inhibition of activity by TTX could be reversed after superfusion with normal saline. Neurite outgrowth from axotomized neurons was not appreciably altered in the presence of TTX. Furthermore, no differences in the incidence of electrical coupling or the coupling resistance were detected between neurons 4 and 5 two days after axotomy and organ culture in the presence of TTX. However, electrical coupling between the symmetrically paired neurons 5 was elevated in the presence of TTX after 5 days. We conclude from these results that neural activity in the form of sodium-dependent action potentials does not play an important role in the formation or breaking of transient electrical synapses during neuronal regeneration in the mollusc Helisoma trivolvis.

Characterization of sodium currents in mammalian sensory neurons cultured in serum-free defined medium with and without nerve growth factor

The influence of nerve growth factor (NGF) on Na currents of rat dorsal root ganglia (DRG) was studied in neurons obtained from newborns and cultured for 2-30 hr in serum-free defined medium (SFM). Cell survival for the period studied was 78-87% both with and without NGF. Na currents were detected in all cells cultured for 6-9 hr. They were also detected after 2 hr in culture in 21.5% of the cells cultured without NGF (-NGF cells), and in 91.5% of the cells cultured with NGF (+NGF cells). Current density of the -NGF cells was 2.3 and 2 pA/microns 2 after growth for 2 and 6-9 hr, respectively, compared to 3.0 and 3.9 pA/microns 2 for the +NGF cells. The +NGF cells were separated into fast (F), Intermediate (I) and slow (S) cells, based on the Na current they expressed, while -NGF cells were all of the I type. F, I and S currents differed in their voltage-dependent inactivation (Vh50 = -79, -28 and -20 mV), kinetics of inactivation (tau h = 0.55, 1.3 and 7.75 msec), and TTX sensitivity (Ki = 60, 550 and 1100 nM). All currents were depressed by [Ca]0 with a KdCa of 22, 17 and 8 mM for F, I and S currents, respectively. Current density of F and S currents was 5.5 and 5 pA/micron 2 for the I current. The concentration-dependent curve of I current vs. TTX indicated that I current has two sites: one with F-like and another with S-like Ki for TTX. Hybridization of F and S currents yielded I-like currents. Thus, the major effect of NGF on Na currents in SFM is the acceleration of Na current acquisition and diversity, reflected in an increase of either the S or F type in a cell.

Nerve growth factor acts through cAMP-dependent protein kinase to increase the number of sodium channels in PC12 cells

cAMP-dependent protein kinase (PKA) and phospholipid-dependent protein kinase (PKC) play a role in nerve growth factor (NGF)-mediated differentiation. In PC12 cells, NGF causes neurite outgrowth and increases the number of voltage-gated Na+ channels. Neurite outgrowth involves in part activation of PKC. How NGF regulates Na+ channel number is unknown. Using patch-clamp techniques, we find that agents activating PKC, including phorbol esters and a ras oncogene product (p21) that induces neurites, caused little increase in channel number. In contrast, agents increasing intracellular cAMP were as effective as NGF. A specific protein inhibitor of the PKA catalytic subunit blocked increases by NGF or cAMP. Thus, NGF increases Na+ channel number in PC12 cells in part by activating PKA but apparently not PKC.

Existence of muscarinic suppression of a K current in PC-12 pheochromocytoma cells

Muscarinic influence on membrane currents of PC-12 pheochromocytoma cells were investigated with whole cell voltage-clamp methods. An outward K current was observed when depolarizing voltage steps were applied to the cells. Methacholine (MCh, 300 microM), a selective agonist for muscarinic receptors, partially suppressed the K current, and the suppression was enhanced by removal of external Ca. The effect of MCh was antagonized by a low dose (100 nM) of atropine. Nicotine (10 microM) induced an inward current in these cells but did not affect the K current activated by depolarizing voltage steps. A Ba current flowing through voltage-gated Ca channels was not changed by MCh. The results indicate the existence of a MCh-sensitive K current in PC-12 cells and suggest that the membrane currents of these cells are modulated by cholinergic agents through muscarinic mechanisms in addition to well-known nicotinic mechanisms.

Na+ channel accumulation on axolemma of afferent endings in nerve end neuromas in Apteronotus

In mammals, cut sensory axons trapped in a nerve end neuroma have been shown to develop hyperexcitability, and to become a source of ectopic afferent discharge and abnormal sensation. We have explored cellular mechanisms underlying neuroma electrogenesis. First we confirmed that ectopic neuroma discharge develops in injured afferents in the electrosensory lateral line nerve of the weakly electric fish Apteronotus, as it does in mammals. Then, using previously characterized antibodies that specifically recognize Na+ channel proteins in this species, we obtained light and electron microscopic evidence of abnormally intense immunolabelling of axolemma at the injury site. Accumulation of excess Na+ channels in afferent endings in neuromas could account for their electrical hyperexcitability.

Effects of calcium ion on neurite outgrowth of rat spinal cord neurons in vitro: the role of non-neuronal cells in regulating neurite sprouting

The interactions of nerve cells with their environment and other cells are specific to different stages of cellular differentiation. Neurite outgrowth was measured from cultured spinal cord neurons under the influence of different Ca2+ concentrations. We used fluorodeoxyuridine (FuDr), an antimitotic agent which reduces significantly the proportion of non-neuronal cells in spinal cord cell cultures, to examine the effects of non-neuronal cells on neurite outgrowth. Spinal cord neurons responded to changes in their environment by means of two types of neurite outgrowth: sprouting and elongation. The concurrent presence of non-neuronal cells led to increased sprouting of neurites in certain ionic environments, thus lending support to the idea that non-neuronal cells release diffusible factors which influence sprouting and guide neurite outgrowth.

Selective induction of brain type II Na+ channels by nerve growth factor

Cells derived from a rat pheochromocytoma (PC12 cells) can generate an action potential only upon treatment with nerve growth factor. Using electrophysiological methods, we found that the appearance of action potentials in nerve growth factor-treated PC12 cells can be explained by an increase in the density of Na+ channels. The functional properties of Na+ channels in PC12 cells are similar to those described for peripheral nerves but appear to be different from Na+ channels synthesized in Xenopus oocytes injected with brain type II Na+ -channel mRNA. To determine if PC12 cells express the brain type II Na+ -channel gene, we performed RNase-protection analyses using probes that can distinguish between the brain type I and type II Na+ -channel mRNAs. The results from these studies indicate that undifferentiated PC12 cells express the type II but not the type I Na+ -channel gene. Treatment with nerve growth factor increases expression of the type II Na+ -channel gene but has no effect on type I gene expression. Our findings suggest that Na+ -channel excitability in PC12 cells is due to the specific induction of the brain type II gene by nerve growth factor.

Dopamine and serotonin inhibition of neurite elongation of different identified neurons

This study demonstrates that a second classical neurotransmitter, dopamine, can act to suppress regenerative neurite outgrowth. Single identified neurons were dissected from two central ganglia of the snail Helisoma, and growth cone motility was studied as neurites regenerated in cell culture. Both dopamine and serotonin inhibited growth cone motility and elongation of neurites. Outgrowth inhibition ranged from sustained arrest to a similar but transient response. The effects of dopamine and serotonin are neuron-selective. Specific neurons affected by dopamine and serotonin represent distinct sets. One neuron was found that responds to both agents. The implications of neurotransmitter regulation of the dynamics of neuronal morphology are discussed.

Calcium current in growth balls from isolated Helix aspersa neuronal growth cones

Growth cones were severed from their neurites in primary cultures of Helix aspersa neurons. Following isolation, growth cones rolled up into 5-10-micron-diameter spheres, which remained attached to a poly-L-lysine or lectin-coated glass coverslip. Whole-cell-configuration patch-clamp recordings from isolated growth cones revealed inward calcium currents upon block of outward currents with internally perfused CsCl. Up to 50 microM tetrodotoxin did not affect this current. In 20-micron-diameter spheres, a peak current of 1.2 nA was reached within 3 ms under voltage-clamp conditions for a 60-mV pulse from a holding potential of -50 mV. Channel density calculations averaged to approximately one channel per square micrometer. A two-phase inactivation was evident under voltage-clamp steps from -50 mV to +15 mV. The growth balls described can be internally perfused and voltage clamped to measure ionic currents involved in growth cone function.

Voltage dependent calcium currents in PC12 growth cones and cells during NGF-induced cell growth

The role of calcium currents in the regulation of neurite outgrowth is still rather speculative. As a contribution to this field, macroscopic voltage dependent calcium currents were investigated in relation to the nerve growth factor (NGF)-induced outgrowth of neurites in PC 12 cells. Calcium currents were recorded in isolated growth cones of PC 12 cells using the whole cell patch clamp method. The currents were activated at high voltages and only slightly inactivated with time. The currents were identical to those found in the cell soma of PC 12 cells and similar to the classical high-voltage-activated calcium current found in many neuronal cells. The peak current density in the growth cones was in the same range as in the cell somata. The calcium currents of the cell somata were not modified during the early phase of NGF application, despite the occurrence of NGF-induced soma growth and outgrowth of neurites. The current density at this time was therefore lower in NGF-treated cells than in untreated cells. In a later phase, maximal current amplitudes of NGF-treated cells were higher than in untreated cells indicating an increase in current density to values similar to that found in the untreated cells. In addition, the calcium current inactivation was found to be more pronounced in the NGF-treated cells by that time. The results are discussed with regard to a possible role of calcium currents in the regulation of NGF-induced neurite outgrowth in these cells.

Action potentials, macroscopic and single channel currents recorded from growth cones of Aplysia neurones in culture

Action potentials, macroscopic ionic currents and single channel currents were recorded from growth cones of Aplysia right upper quadrant (r.u.q.) cells in culture, using the patch-clamp technique. Recordings were obtained from both intact growth cones and from growth cones that had been mechanically isolated from the rest of the neurone. In current-clamp mode, greater than half of the isolated growth cones display an all-or-none action potential when depolarized above 0 mV with outward current pulses. The remaining growth cones display only a graded depolarization that is unaffected by tetrodotoxin (TTX). In whole-cell voltage clamp almost all isolated growth cones display a rapidly activating and inactivating inward current followed by a delayed outward current in response to depolarizations positive to -20 mV. The rapid inward current reverses direction at around +70 to +80 mV and is completely suppressed by 100 microM-TTX, which suggests that this current is carried by the fast Hodgkin-Huxley sodium current channels. The delayed outward current appears to result from the activation of both the delayed rectifier potassium current, IK, and the calcium-activated potassium current, IC. The growth cones do not display any prominent early transient outward current, IA. The sodium current, INA, was studied in isolation by substituting caesium for potassium ions in the pipette solution. INa is half-inactivated at a holding potential of -36 mV, reaches half-maximal activation with a depolarization to 0 mV, and has a mean peak current density of 13 microA/cm2. The time course of inactivation is well described by a single exponential (tau = 3 ms at 0 mV). In cell-attached patches, a rapidly activating and inactivating inward current channel was recorded with an average unit conductance of 6.9 pS. The activation and inactivation parameters of the ensemble averaged current closely match the measured values from the macroscopic sodium current. At very positive potentials we recorded a voltage-dependent outward current channel with a conductance of around 35 pS. No significant inward calcium current was observed in whole-cell measurements and few single calcium channel currents were measured in cell-attached patches, suggesting a sparse distribution of calcium channels in the r.u.q. growth cones.

Nerve growth factor modulates the drug sensitivity of neurotransmitter release from PC-12 cells

The release of catecholamines from adrenal chromaffin cells is known to be blocked by dihydropyridines, such as nitrendipine, and enhanced by others, such as BAY K8644. On the other hand, release from sympathetic neurons is predominantly insensitive to these agents. Release of [3H]norepinephrine from undifferentiated PC-12 pheochromocytoma cells resembles that from chromaffin cells in that it is extremely sensitive to dihydropyridines. Following differentiation, however, release of catecholamine becomes predominantly insensitive to both nitrendipine and BAY K8644. Under both growth conditions, release remains completely blocked by 3 mM Co2+ or by removal of Ca2+ from the release media. Dose-response curves to K+ show that following differentiation, cells become more sensitive, releasing transmitter at lower K+ concentrations. In contrast, depolarization-induced uptake of 45Ca2+ remains sensitive to dihydropyridines and shows similar sensitivity to K+ stimulation in both growth conditions. These results can be explained by invoking a model involving dihydropyridine-sensitive and -insensitive types of voltage-sensitive calcium channels.