Studies on rat sympathetic neurons developing in cell culture. I. Growth characteristics and electrophysiological properties

Investigation of the input-output relationship of engineered neural networks using high-density microelectrode arrays

Bottom-up neuroscience utilizes small, engineered biological neural networks to study neuronal activity in systems of reduced complexity. We present a platform that establishes up to six independent networks formed by primary rat neurons on planar complementary metal-oxide-semiconductor (CMOS) microelectrode arrays (MEAs). We introduce an approach that allows repetitive stimulation and recording of network activity at any of the over 700 electrodes underlying a network. We demonstrate that the continuous application of a repetitive super-threshold stimulus yields a reproducible network answer within a 15 ms post-stimulus window. This response can be tracked with high spatiotemporal resolution across the whole extent of the network. Moreover, we show that the location of the stimulation plays a significant role in the networks' early response to the stimulus. By applying a stimulation pattern to all network-underlying electrodes in sequence, the sensitivity of the whole network to the stimulus can be visualized. We demonstrate that microchannels reduce the voltage stimulation threshold and induce the strongest network response. By varying the stimulation amplitude and frequency we reveal discrete network transition points. Finally, we introduce vector fields to follow stimulation-induced spike propagation pathways within the network. Overall we show that our defined neural networks on CMOS MEAs enable us to elicit highly reproducible activity patterns that can be precisely modulated by stimulation amplitude, stimulation frequency and the site of stimulation.

Evolutionary origins of chemical synapses

Synaptic transmission is a fundamental neurobiological process by which neurons interact with each other and non-neuronal cells. It involves release of active substances from the presynaptic neuron onto receptive elements of postsynaptic cells, inducing waves of spreading electrochemical response. While much has been learned about the cellular and molecular mechanisms driving and governing transmitter release and sensing, the evolutionary origin of synaptic connections remains obscure. Herein, we review emerging evidence and concepts suggesting that key components of chemical synapse arose independently from neurons, in different functional and biological contexts, before the rise of multicellular living forms. We argue that throughout evolution, distinct synaptic constituents have been co-opted from ancestral forms for a new role in early metazoan, leading to the rise of chemical synapses and neurotransmission. Such a mosaic model of the origin of chemical synapses agrees with and supports the pluralistic hypothesis of evolutionary change.

Neurotrophins and target interactions in the development and regulation of sympathetic neuron electrical and synaptic properties

The electrical and synaptic properties of neurons are essential for determining the function of the nervous system. Thus, understanding the mechanisms that control the appropriate developmental acquisition and maintenance of these properties is a critical problem in neuroscience. A great deal of our understanding of these developmental mechanisms comes from studies of soluble growth factor signaling between cells in the peripheral nervous system. The sympathetic nervous system has provided a model for studying the role of these factors both in early development and in the establishment of mature properties. In particular, neurotrophins produced by the targets of sympathetic innervation regulate the synaptic and electrophysiological properties of postnatal sympathetic neurons. In this review we examine the role of neurotrophin signaling in the regulation of synaptic strength, neurotransmitter phenotype, voltage-gated currents and repetitive firing properties of sympathetic neurons. Together, these properties determine the level of sympathetic drive to target organs such as the heart. Changes in this sympathetic drive, which may be linked to dysfunctions in neurotrophin signaling, are associated with devastating diseases such as high blood pressure, arrhythmias and heart attack. Neurotrophins appear to play similar roles in modulating the synaptic and electrical properties of other peripheral and central neuronal systems, suggesting that information provided from studies in the sympathetic nervous system will be widely applicable for understanding the neurotrophic regulation of neuronal function in other systems.

Target-dependent inhibition of sympathetic neuron growth via modulation of a BMP signaling pathway

Target-derived factors modulate many aspects of peripheral neuron development including neuronal growth, survival, and maturation. Less is known about how initial target contact regulates changes in gene expression associated with these developmental processes. One early consequence of contact between growing sympathetic neurons and their cardiac myocyte targets is the inhibition of neuronal outgrowth. Analysis of neuronal gene expression following this contact revealed coordinate regulation of a bone morphogenetic protein (BMP)-dependent growth pathway in which basic helix-loop-helix transcription factors and downstream neurofilament expression contribute to the growth dynamics of developing sympathetic neurons. BMP2 had dose-dependent growth-promoting effects on sympathetic neurons cultured in the absence, but not the presence, of myocyte targets, suggesting that target contact alters neuronal responses to BMP signaling. Target contact also induced the expression of matrix Gla protein (MGP), a regulator of BMP function in the vascular system. Increased MGP expression inhibited BMP-dependent neuronal growth and MGP expression increased in sympathetic neurons during the period of target contact in vivo. These experiments establish MGP as a novel regulator of BMP function in the nervous system, and define developmental transitions in BMP responses during sympathetic development.

Role of cell-cell interactions in the developmental regulation of Ca2+-activated K+ currents in vertebrate neurons

The functional expression of the Ca2+-activated K+ current (IK[Ca]) is dependent on cell-cell interactions in developing chick autonomic neurons. In chick ciliary ganglion (CG) neurons, expression of macroscopic IK[Ca] coincides with the formation of synapses with target tissues. CG neurons that develop in vivo in the absence of normal target tissues fail to express functional IK[Ca], although voltage-activated Ca2+ currents and most other ionic currents are expressed at normal amplitudes and densities. CG neurons placed in cell culture prior to formation of synapses with target tissues also fail to express macroscopic IK[Ca]. However, CG neurons cultured in the presence of a heat- and trypsin-sensitive extract of target tissues express IK[Ca] at normal levels. Similarly, interactions with target tissue appear to regulate the expression of whole-cell IK[Ca] in developing chick sympathetic ganglion neurons, although the relevant trophic factors appear to be different from those required by CG neurons. In addition to target tissue interactions, an intact preganglionic innervation is required for the normal in vivo development of IK[Ca] in chick CG neurons. The trophic effects of the afferent innervation do not require synaptic activation of the CG neurons, indicating secretion of a trophic factor, possibly an isoform of beta-neuregulin. The results are consistent with the hypothesis that target- and nerve terminal-derived trophic factors interact at a posttranslational level in the regulation of a functional IK[Ca]. Together, this body of data demonstrates an essential role for cell-cell interactions in the differentiation of neuronal excitability.

Appearance of a fast inactivating voltage-dependent K+ currents in developing cerebellar granule cells in vitro

To elucidate the molecular mechanisms that regulate the maturation of action potential, we began by examining voltage-dependent K+ currents, known to contribute to the maturation of action potential, of developing granule cells in mouse cerebellar microexplant cultures. The migration of developing granule cells in this culture is reported to mimic the in vivo process, but their specific identification is still incomplete. In this study, we identified and characterized granule cells in this culture. Immunocytochemical analysis found that granule cells migrated radially out from explants and subsequently formed small clusters and also that their morphology changed from a bipolar to a T shape during migration. Moreover, in the electrophysiological study, the GABA response of granule cells in this culture clarified that the electrophysiological properties of granule cells were normally maintained. We therefore have concluded, that this culture system is a powerful tool for investigating the differentiation of cerebellar granule cells. Based on these findings, we recorded voltage-dependent K+ currents of developing granule cells in this culture, while concurrently observing their morphology. Our results show that voltage-dependent K+ currents of developing granule cells change from delayed rectifier to A current in parallel with their morphological changes from bipolar to T-shaped cells.

A technique for culturing brain nuclei from postnatal rats

The technique for culturing brain nuclei from postnatal rats is described in detail. Key features of this simple method of culturing brain nuclei are: (a) to make brain slices of a particular brain region and to isolate the brain nucleus under direct visualization using a dissecting microscope; (b) to use papain for dissociation; (c) to grow neuron cultures over a glial feeder layer; and (d) to use rat serum (prepared in the laboratory) in the culture medium. We have developed neuronal cultures from several types of brain nuclei (such as the locus coeruleus) and identified the type of neurons immunocytochemically and histochemically. With this culture method, we can obtain high purity cultures of specific types of brain neurons. Our brain nucleus cultures are excellent materials for cellular and molecular physiological studies. Long-term changes of a single neuron belonging to a particular neuron type can be observed. Experiments using the patch clamp technique and intracellular injection of antibodies and antisense oligonucleotides are feasible.

Auditory cortical neurons in vitro: cell culture and multichannel extracellular recording

Self organization, pattern generation, and pattern processing in local cortical circuits are difficult to study in vivo. The complexities of cortical circuits require simplified systems for study. We have developed a simplified model of auditory cortical neurons growing as monolayer networks in culture. Neurons dissociated from auditory cortex of 14-day mouse embryos were grown on photoetched microelectrode array containing 64 transparent indium-tin oxide electrodes. Cultures were maintained in incubators for up to 113 days. Neurons developed processes and made synaptic connections. All cultures were spontaneously active and exhibited complex temporal burst patterns. In a data set of 12 cultures, the number of active channels varied from culture to culture and ranged from 6-17. Signal/noise ratios ranged from 3:1 to a maximum of 16:1. No significant correlations were found between age of the culture and number of active channels, or signal/noise ratios. Spontaneous firing patterns recorded from various channels showed complex bursting patterns in all cultures. Within a culture, coordinated synchronous bursting were found among some channels, and independent bursting on others. Preliminary histological analysis of cultures using the Loots-modified Bodian stain showed neurons with axonal and dendritic profiles growing extensively on top of the glial carpet. Neuronal processes crossing the electrodes singly or in small groups were also observed. Pyramidal and non-pyramidal cells could be identified. In a pool of 2,093 neurons in a 49-day-old culture, the average size of the somata was found to be 16 microns, with a mode of 12 microns.

Neuronal differentiation in cultures of murine neural crest. I. Neurotransmitter expression

This study examines the properties of neurons differentiating in cultures of mammalian neural crest cells. The neurons fall into two categories: (1) a population of early differentiating (ED) neurons generated from precursors that are postmitotic at the time of plating; and (2) a late differentiating (LD) population of neurons arising from dividing precursor cells. The ED population of neurons survive for only 2-3 days while the LD neurons survive for many weeks. Both groups of neurons express the neuronal marker, neurofilament, as well as adrenergic and cholinergic characteristics. The latter two traits are evident as immunoreactivity for tyrosine hydroxylase (TH)/dopamine-beta-hydroxylase (D beta H) and choline acetyltransferase (ChAT), respectively. The LD neurons also contain immunoreactivity for a number of neuropeptides including, substance P (SP), neuropeptide Y (NPY), vasoactive intestinal polypeptide (VIP), calcitonin gene related polypeptide (CGRP), and somatostatin (SOM). Immunoreactivity for SP, CGRP, and VIP are found in virtually all of the LD neurons while SOM and NPY are found in a smaller percentage of the neurons.

Functional expression of A-currents in embryonic chick sympathetic neurones during development in situ and in vitro

1. The functional expression of transient voltage-activated K+ currents (IA) was examined using whole-cell recording techniques in embryonic chick sympathetic ganglion neurones that developed in situ and under various growth conditions in vitro. 2. The density of IA increased dramatically during development in sympathetic neurones isolated acutely between embryonic days 7 and 20 (E7-E20). The time course of IA inactivation became significantly faster between E7 and E13. With these protocols, neuronal differentiation and development occurred entirely in situ. 3. Sympathetic neurones isolated at E9 and maintained in vitro for 4 days did not express a normal IA compared to neurones isolated acutely at E13. Those neurones that were in physical contact with other neurones expressed normal densities of IA, but the resulting inactivation kinetics were abnormally slow. Sympathetic neurones that were cultured on the membrane fragments of lysed neurones expressed normal densities of IA even when they failed to make visible connections with other viable neurones, but the resulting inactivation kinetics were abnormally slow. Those cultured neurones that were not in physical contact with other cells or their membranes had markedly reduced densities of IA with abnormally slow inactivation kinetics. 4. Application of 5-100 ng ml-12.5 S nerve growth factor by itself did not promote normal A density of kinetics in E9 sympathetic neurones cultured for 4 days. 5. Sympathetic neurones that developed in vitro in physical contact with ventral spinal cord explants, cardiac myocytes or aortic smooth muscle cells expressed normal densities of IA, but the inactivation kinetics were abnormally slow. Cell culture media conditioned by these tissues failed to promote normal IA expression. Sympathetic neurones cultured as explants or maintained under depolarizing conditions did not express a normal IA. 6. Embryonic chick sympathetic neurones exhibit developmental changes in the density and kinetics of IA that can be regulated independently by extrinsic environmental factors including interactions with insoluble components of the plasma membranes of some cells.

Morphological characteristics of cultured olfactory bulb cells

Cultured olfactory bulb cells from embryonic mice had ultrastructural characteristics similar to those of many cell types in the intact adult mouse olfactory bulb. Identified cultured cells included mitral/tufted cells, granule cells, short-axon cells, and fibrous and protoplasmic astrocytes. Cultured neurons were found as individual cells, clusters or aggregates. Clusters consisted of a loose array of neurons that appeared to be densely interconnected by neurites. However, few neurites or fascicles emanated from clusters to adjoining areas. Aggregates consisted of many small, usually rounded, neurons piled on top of one larger neuron, or on more than one, with typically many neurites and fascicles projecting to adjacent aggregates, clusters or individual neurons. Neurites of cultured olfactory bulb cells were well developed, and some were several millimeters long. Synapses were very prominent in these cultures, especially in aggregates, clusters, and fascicles. Electron-lucent, dense-core, and coated vesicles were present. Polarity, shape, and length of the long axis (size) of 815 cultured neurons, identified by positive anti-microtubule-associated protein 2 staining, were documented. Cultured neurons varied in size from 9 to 27 microns, with an average size of 16 microns. Elliptical bipolar (35%), triangular multipolar (21%), and round unipolar (15%) were the most common polarity/shape combinations found in culture. Multipolar, triangular, triangular multipolar, and elliptical bipolar cells increased in size with increasing age of culture. The relative proportions of triangular, multipolar, elliptical multipolar, and triangular multipolar cells decreased, whereas the relative proportions of round, unipolar, and round unipolar cells increased with increasing age of culture. These changes in population subtypes and cell size may indicate continued differentiation and maturation of cultured neurons.

Neurotransmitter properties of guinea-pig sympathetic neurons grown in dissociated cell culture--II. Fetal and embryonic neurons: regulation of neuropeptide Y expression

We report here the neurotransmitter characteristics of neurons cultured from the same ganglia of fetal and embryonic guinea-pigs. Both the celiac ganglion and the superior mesenteric ganglion were examined. In a previous paper we described the neurotransmitter properties of adult guinea-pig prevertebral sympathetic neurons grown in dissociated cell culture, including the expression by these cells of immunoreactivity for tyrosine hydroxylase, neuropeptide Y and somatostatin. Tyrosine hydroxylase immunoreactivity was ubiquitously expressed in all fetal embryonic cultures, as was the case for adult neurons. Fetal-derived celiac and superior mesenteric gangli neurons displayed neuropeptide Y and somatostatin immunoreactivity in the same percentage of neurons as in adult cultures but at markedly lower levels. Embryonic neurons also expressed somatostatin immunoreactivity in roughly the same proportion of neurons as in adult and fetal cultures; however, the expression of neuropeptide Y immunoreactivity in both celiac and superior mesenteric gangli cultures was significantly different. Specifically, neuropeptide Y immunoreactivity in embryonic celiac cultures was greatly reduced in both the number of positive-labeled neurons and the amount of immunoreactive product, while neuropeptide Y immunoreactivity in embryonic superior mesenteric gangli cultures was markedly increased compared to their adult and fetal counterparts. The expression of neuropeptide Y immunoreactivity in celiac neurons was found to be specifically elevated by culturing the neurons in medium conditioned by disassociated vascular cells, this treatment having no effect on tyrosine hydroxylase or somatostatin immunoreactivity. Heart cell-conditioned medium did not effect neuropeptide Y or somatostatin immunoreactivity, although it did result in a significant reduction of tyrosine hydroxylase immunoreactivity and an increase in 5-hydroxytryptamine immunoreactivity. We conclude that the expression of neuropeptide Y immunoreactivity develops independently in cultures of adult and near-term fetuses but that embryonic neurons require interactions with target cells to express this phenotype. Neuropeptide Y immunoreactivity can be induced in embryonic sympathetic neurons by a target-derived factor(s).

Neurotransmitter properties of guinea-pig sympathetic neurons grown in dissociated cell culture--I. Adult neurons

The autonomic nervous system of mammals displays extensive neurotransmitter diversity. The guinea-pig sympathetic nervous system has served as a model for in vivo studies of neurotransmitter co-expression. We have developed methods for the dissociation and long-term culture of adult guinea-pig prevertebral sympathetic ganglia. The neurotransmitter properties of cultured adult guinea-pig sympathetic neurons from the celiac and superior mesenteric ganglia were examined. Cultured principal neurons were found to display many of their in vivo neurotransmitter characteristics, including catecholamine-specific histofluorescence and immunoreactivity for tyrosine hydroxylase and the neuropeptides, neuropeptide Y, somatostatin and vasoactive intestinal polypeptide. In addition, the cultures of both ganglia displayed the various neurotransmitter characteristics in approximately the same percentage of the cultured neurons as reported in in vivo studies. A small percentage of principal neurons and many small, intensely fluorescent-like cells labeled with antibodies against 5-hydroxytryptamine. Many of the principal neurons were found to bear 5-hydroxytryptamine3 receptors, suggesting a possible role for this neurotransmitter in neuron-neuron and small, intensely fluorescent cell-neuron transmission. We conclude that adult guinea-pig sympathetic neurons retain their neurotransmitter phenotypes when grown in dissociated cell culture. These properties include the co-expression of the classical transmitters, norepinephrine, 5-hydroxytryptamine and neuropeptides. This culture preparation will prove to be valuable in future studies on the functional properties of these neurons and their development.

Two signal transduction mechanisms of substance P-induced depolarization in locus coeruleus neurons

Effects of substance P on cultured neurons of the locus coeruleus of the rat were studied using the whole-cell patch clamp technique. In some cells substance P produced a decrease in a K conductance which showed an inwardly rectifying property. In other cells substance P produced an initial inward current which was accompanied by a conductance increase. The rest of the cells showed responses which were mixtures of the above two responses. The measurement of the reversal potential of the initial inward current after suppressing the voltage-gated Ca and K conductances suggests that it is caused by an increase in a non-selective ionic conductance. In cells loaded with 260 microM GTP gamma S, application of substance P produced an irreversible reduction of the K conductance, while the initial inward current could still be recorded, suggesting that the former is mediated by a G protein, whereas the latter may be activated by a different signal transduction mechanism. The initial inward current was not eliminated by external application of high concentrations of tetrodotoxin, d-tubocurarine or amiloride. Nor was it affected by the intracellular application of cyclic GMP or cyclic AMP.

Involvement of pertussis toxin-sensitive and -insensitive mechanisms in alpha-adrenoceptor modulation of noradrenaline release from rat sympathetic neurones in tissue culture

1. Sympathetic neurones derived from superior cervical ganglia of neonatal rats and maintained in tissue culture were used to investigate the modulation of neurotransmitter release by presynaptic receptors. Three week old cultures of neurones were loaded with [3H]-noradrenaline to label endogenous neurotransmitter stores. Release of noradrenaline was evoked by depolarization with raised extracellular K+ in the presence of desipramine and corticosterone to prevent uptake of released catecholamine. 2. Potassium (55 mmol l-1) depolarization for 30 s caused more than a four fold increase in 3H overflow from basal levels but this increase was reduced by up to 40% in the presence of exogenous noradrenaline (1 mumol l-1). The inhibition by noradrenaline of depolarization-evoked overflow was blocked by the alpha 1/alpha 2-adrenoceptor antagonist, phentolamine. Phentolamine alone did not increase K(+)-evoked 3H overflow. 3. The alpha 2-adrenoceptor antagonist, yohimbine, produced a concentration-dependent block of the inhibition by noradrenaline of K(+)-evoked overflow, while the alpha 1-adrenoceptor antagonist, prazosin, was without effect at concentrations up to 0.1 mumol l-1. 4. The beta-adrenoceptor antagonist, propranolol, neither reduced K(+)-evoked overflow nor increased the degree of inhibition caused by the addition of 1 mumol l-1 noradrenaline. 5. The alpha 2-adrenoceptor agonist, clonidine (1 mumol l-1) was less effective than noradrenaline at inhibiting K(+)-evoked overflow, while the alpha 1-adrenoceptor agonist, phenylephrine (1 mumol l-1) had no significant effect. 6. The L-channel calcium blocker, nicardipine (1 mumol l-1) significantly inhibited 3H overflow evoked by K+. In the presence of L-channel block, however, noradrenaline still inhibited residual evoked overflow.7. In the presence or absence of nicardipine, pertussis toxin pretreatment (1 nmol 1-1) reduced, but did not prevent, the effect of noradrenaline (1 micromol 1-1). Pertussis toxin alone caused a significant enhancement of K+-evoked 3H overflow.8. The data indicate that on postganglionic neurones of cultured rat sympathetic ganglia there are alpha 2-adrenoceptors that modulate neurotransmitter release, but no functional beta-adrenoceptors that mediate an enhancement of transmitter release. The data suggest further that in this preparation the mechanism of alpha2-adrenoceptor modulation may involve pertussis toxin sensitive and insensitive G-proteins and effects on calcium channels other than L-type.

Vasoactive intestinal polypeptide presynaptically enhances the synaptic transmission in cultured sympathetic neurons

We studied the effects of vasoactive intestinal polypeptide (VIP) on the cholinergic synaptic transmission that was developed between rat sympathetic neurons in culture. Electrophysiological examinations revealed that the amplitude of fast excitatory postsynaptic potential (fast EPSP) was increased by VIP (0.2-0.8 microM) reversibly and dose-dependently, whereas transient nicotinic depolarization evoked by pressure application of acetylcholine (ACh) was not affected by VIP. In most of the cells examined, VIP depolarized membrane potential by a few millivolts with concomitant increases in membrane conductance. Furthermore, the VIP-induced depolarization was suppressed by Co2+ but not by hexamethonium or atropine. Hence it is highly likely that the peptide augmented the amplitude of fast EPSPs by increasing ACh release from the presynaptic cell. These results demonstrate that VIP influences the presynaptic phase of cholinergic synaptic transmission between sympathetic neurons.

Developmental changes in transmitter sensitivity and synaptic transmission in embryonic chicken sympathetic neurons innervated in vitro

Dispersed neurons from embryonic chicken sympathetic ganglia were innervated in vitro by explants of spinal cord containing the autonomic preganglionic nucleus or somatic motor nucleus. The maturation of postsynaptic acetylcholine (ACh) sensitivity and synaptic activity was evaluated from ACh and synaptically evoked currents in voltage-clamped neurons at several stages of innervation. All innervated cells are more sensitive to ACh than uninnervated neurons regardless of the source of cholinergic input. Similarly, medium conditioned by either dorsal or ventral explants mimics innervation by enhancing neuronal ACh sensitivity. This increase is due to changes in the rate of appearance of ACh receptors on the cell surface. There are also several changes in the nature of synaptic transmission with development in vitro, including an increased frequency of synaptic events and the appearance of larger amplitude synaptic currents. In addition, the mean amplitude of the unit synaptic current mode increases, as predicted from the observed changes in postsynaptic sensitivity. Although spontaneous synaptic current amplitude histograms with multimodal distributions are seen at all stages of development, histograms from early synapses are typically unimodal. Changes in the synaptic currents and ACh sensitivity between 1 and 4 days of innervation were paralleled by an increase in the number of synaptic events that evoked suprathreshold activity in the postsynaptic neurons. The early pre- and postsynaptic differentiation described here for interneuronal synapses formed in vitro may be responsible for increased efficacy of synaptic transmission during development in vivo.

Electrophysiological properties and cholinergic responses in guinea-pig celiac ganglion neurons in primary culture

Prevertebral neurons enzymatically dissociated from celiac ganglia of adult guinea-pigs were maintained in long-term primary culture. Cells were plated at a density of 95 +/- 15 cm-2, and intracellular electrical activity was measured between 2 and 7 weeks after dissociation. Neurite outgrowth began within 24 h of enzymatic dissociation. Cell survival dropped below 50% after more than two weeks in culture. The resting potential (-53 mV +/- 0.8), time constant (12 ms +/- 1.3), input resistance (47 M omega +/- 8.6), rheobase (0.33 nA +/- 0.02), degree of accommodation, spike amplitude (70 mV +/- 3.0), after hyperpolarization amplitude (-9.5 mV +/- 0.55), and after hyperpolarization duration (88 ms +/- 7.6) in these cells were not different from those recorded from neurons in intact celiac ganglia. A larger proportion (greater than 90%) of cells exhibited fast accommodation (phasic) in response to depolarizing current pulses. Unevoked (spontaneous) depolarizations and action potentials were observed. The cells responded to pressure ejected acetylcholine. Two types of responses consisted of an early rapid depolarization which was attenuated by hexamethonium and a later slow depolarization which was attenuated by atropine. We conclude that prevertebral neurons from guinea-pigs can be maintained in long-term primary culture, that they retain electrophysiological properties similar to intact ganglia and exhibit complex responsivity to acetylcholine.

Neurons from neonatal hypertensive rats exhibit abnormal membrane properties in vitro

The in vitro membrane properties of neurons from superior cervical ganglia (SCG) of neonatal spontaneously hypertensive (SH), Wistar-Kyoto (WKY), and Sprague-Dawley (SD) rats were studied with microelectrodes. Neurons were obtained by enzymatic dissociation, plated, irradiated, and studied after 2-5 wk. Most SH neurons showed multiple action potentials in response to an intracellular long-duration depolarizing pulse (multiple firing), whereas most neurons from WKY or SD rats generated only one or two action potentials. Multiple firing was inhibited by low concentrations of cobalt (10(-5) M) but not by tetrodotoxin (TTX) (3 x 10(-6) M). Neither high calcium (5-10 x 10(-3) M) nor the Ca2+(-)channel opener BAY K 8644 (10(-6) M) could induce multiple firing in SD or WKY neurons. However, multiple firing was readily induced by apamin (10(-6) M) or tetraethylammonium chloride (5 x 10(-3) M) (Ca2+(-)activated K+(-)channels blockers), with cobalt and TTX sensitivities similar to native multiple-firing neurons. We conclude that 1) multiple firing is characteristic of neonate SH rats SCG neurons in vitro and depends on regenerative Ca2+ currents; 2) multiple firing in SH neurons results from a lack of activation of a Ca2+(-)activated K+ conductance and not from a lack of internal Ca2+ availability; and 3) multiple firing in SCG neurons mirrors a default in K+ conductance common to all cells in genetically hypertensive individuals.

Modulation of inwardly rectifying channels by substance P in cholinergic neurones from rat brain in culture

1. Whole-cell recording was used to investigate the effects of substance P on cultured neurones from the rat nucleus basalis. 2. Brief applications of substance P produced a reduction, about 1 min in duration, of resting membrane conductance. The concentration producing a half-maximal effect was approximately 40 nM, with the continuous presence of substance P resulting in desensitization of the response. 3. The control current-voltage relation exhibited inward rectification over the voltage range -70 to -150 mV, and hyperpolarization produced a time-dependent decrease of current (inactivation). 4. The substance P-sensitive current, obtained by subtracting the current during the presence of the tachykinin from the control current, showed no time-dependent inactivation, though its current-voltage relation also revealed inward rectification, with the reversal potential being approximately equal to the potassium equilibrium potential, Vk. 5. The relation between the substance P-sensitive chord conductance and voltage could be fitted by a Boltzmann equation, with changes in [K+]o shifting this relation along the voltage axis roughly in parallel with the shift in Vk. The maximum conductance was proportional to [( K+]o). 6. Cs+ (0.1 mM) blocked the substance P-sensitive current in a voltage-dependent manner, with an equivalent valency for Cs+ of 1.9. Barium blockage of the substance P-sensitive current was less voltage dependent. 7. Replacement of external Na+ by tetramethylammonium (TMA+) ions reduced the substance P-sensitive current by only 18%. 8. These results indicate that substance P inhibits potassium channels with inward rectifier properties very similar to those of skeletal muscle. 9. Application of sodium nitroprusside did not alter the effect of substance P, suggesting that cyclic GMP plays no role in the channel modulation.

Visualisation of specific binding sites for atrial natriuretic peptide on non-neuronal cells of cultured rat sympathetic ganglia

The distribution of atrial natriuretic peptide binding sites on cells in dissociated culture preparations of neonatal rat superior cervical ganglia and in explant cultures of rat thoracic sympathetic chain ganglia has been studied. The autoradiographic visualisation of atrial natriuretic peptide binding sites has been combined with the use of specific immunocytochemical markers for glial cells (antiserum to S-100 protein), fibroblasts (antiserum to fibronectin) and neurones (antiserum to protein gene product 9.5) in order to achieve unambiguous identification of the cell types in culture. Specific binding sites for rat 125I-atrial natriuretic peptide(1-28) were observed over subpopulations of fibronectin-like-immunoreactive fibroblasts and S-100-like-immunoreactive glia in the dissociated superior cervical ganglion cultures. However, only a subpopulation of fibronectin-like-immunoreactive fibroblasts possessed atrial natriuretic peptide binding sites in the explant culture preparations. No atrial natriuretic peptide-like-immunoreactive cells were present in either culture. The distribution of autoradiographic grains over individual cell surfaces in culture was uniform, but there were distinct differences in the density of labelling of single cells of the same type. This apparent variation in the number of binding sites on glial cells and fibroblasts in culture did not seem to be related to the morphology of the cells or the surrounding cell types. No sympathetic neurones were labelled with autoradiographic grains in either the dissociated or explant culture preparations. However, the presence of atrial natriuretic peptide binding sites on non-neuronal cells of sympathetic ganglia in culture may be linked to the relationship between atrial natriuretic peptide and the sympathetic nervous system.

Nerve growth factor induces functional nicotinic acetylcholine receptors on rat sensory neurons in culture

Neonatal sensory neurons from rat nodose ganglia express nicotinic acetylcholine receptors when grown in tissue culture without other cell types. The present study investigates the role of nerve growth factor in inducing these receptors. Nerve growth factor has little effect on the growth and survival of nodose neurons in culture, although most neurons were found by quantitative radioautography to have high-affinity nerve growth factor receptors. Nerve growth factor strongly influenced the expression of nicotinic receptors on these neurons: the proportion of acetylcholine-sensitive neurons was approximately 60% in cultures with nerve growth factor compared with 15% in cultures grown without nerve growth factor. The proportion of acetylcholine-sensitive neurons increased over the first week, plateaued by day 12 and remained high for at least three weeks. In contrast, without NGF, the proportion of acetylcholine-sensitive neurons was low throughout the three-week period. The results indicate that nerve growth factor is an important factor in promoting nicotinic receptors on these neurons in culture.

Autoradiographic localization of muscarinic receptors on cultured, peptide-containing neurones from newborn rat superior cervical ganglion

In order to identify subpopulations of cultured rat superior cervical ganglion (SCG) neurones which express muscarinic receptors, a combination of immunocytochemistry and autoradiography was performed on these cultures. Antibodies to vasoactive intestinal polypeptide (VIP) and neuropeptide Y (NPY) were used to immunostain cultures that had previously been labelled with the irreversible muscarinic antagonist, [3H]propylbenzylylcholine mustard (PrBCM). Binding sites for [3H]PrBCM were observed on a large subpopulation of 65-85% of the ganglionic neuronal cell bodies. Specific labelling was not associated with non-neuronal cells found in these cultures. Approximately 60% of the SCG neurones were NPY-like immunoreactive (NPY-LI), a high proportion of which expressed muscarinic receptors. Five to 10% of the SCG neurones were VIP-LI, a small subpopulation of which displayed [3H]PrBCM binding sites. Receptor distribution on cell bodies was usually uniform, but occasionally, regions of high receptor density were seen. Dense networks of both varicose and non-varicose NPY-LI fibres were seen throughout the culture, a subpopulation of which expressed muscarinic receptors. Occasional VIP-LI fibres were also labelled with silver grains for [3H]PrBCM, but in less abundance than those for NPY-LI fibres. Conversely, neurones expressing muscarinic receptors were often immunonegative for either VIP or NPY: therefore, the identity of some of the neurones which express muscarinic receptors remains to be determined.

Survival and growth of hippocampal neurons in defined medium at low density: advantages of a sandwich culture technique or low oxygen

The study of development and plasticity of hippocampal circuitry would greatly benefit from methods which allow the long-term culture of neurons at low density under precisely defined culture conditions. We report that isolated hippocampal neurons from embryonic day 18 rats can be cultured for several weeks at low densities which permits the determination of individual connections. A serum-free medium was modified from the formulation of Romijn to include the biological anti-oxidants vitamin E, glutathione, pyruvate, catalase and superoxide dismutase. Neuronal survival of 80% and neuritogenesis greatly exceeded that seen in serum-based cultures. It appeared that vitamins E, A and linolenic acid promoted neuritogenesis. The beneficial effects of the antioxidants suggested a toxic role of oxygen. To directly test this, cultures were incubated in reduced oxygen (9%) and compared to those in the normal 19.7% oxygen (95% air). After 3 days in culture, neurons with processes in 9% oxygen were more than double those in normal oxygen. Neuronal survival and neurite growth could be improved if the cells were grown on a substrate-coated surface covered with a coverslip. Under this condition, cells show a ring of growth between the center and the edge of the coverslip. In 9% oxygen, this ring was closer to the edge of the coverslip than in normal oxygen. The coverslip did not serve as an additional substrate for attachment since it left the neurons attached to the original substrate. However, removal of the coverslip leads to cell death within 24 h, suggesting that the cells had been exposed to a toxic factor. Variations in glial cell content (less than 10%), pH, and pCO2 were demonstrated to be unlikely explanations of the higher survival. These results suggest that growth in a diffusion-limited space, reduction of oxygen concentration to physiological levels and control of toxic oxidation with physiological antioxidants can greatly improve the survival and neuritogenesis of isolated hippocampal neurons in primary culture.

Transient calcium current of retinal bipolar cells of the mouse

1. Isolated bipolar cells were obtained by enzymic (papain) dissociation of the adult mouse retina. The membrane voltage was clamped and the membrane currents were measured by the whole-cell version of the patch-clamp technique. Isolated bipolar cells and horizontal cells of the goldfish retina were also studied for comparison. 2. Hyperpolarization from the holding voltage, Vh, of -46 mV evoked a slowly activating, Cs+-sensitive, inward current (probably an h-current), and depolarization evoked a TEA- and Cs+-sensitive outward current (probably a combination of K+ currents). 3. Depolarization from a more negative Vh (e.g. -96 mV) evoked a transient inward current that had maximal amplitude between -40 and -20 mV. This current was identified as a Ca2+ current (ICa): its amplitude was increased with elevated [Ca2+]o and was decreased with reduced [Ca2+]o, and it was blocked by 4 mM-Co2+, but not by 5 microM-TTX. 4. Both the perikaryon and the axon terminal generated ICa with similar properties. 5. The plot of Ca2+ conductance (gCa) against membrane voltage (activation curve) was sigmoidal: in 10 mM [Ca2+]o, gCa increased for membrane voltages more positive than -65 mV, was half-maximal at about -25 mV, and reached saturation at about +30 mV. The plot of inactivation of gCa against membrane voltage was also sigmoidal: with 1 s conditioning depolarization in 10 mM [Ca2+]o, gCa decreased for membrane voltages more positive than -80 mV, was half-maximal at about -50 mV, and was fully suppressed for voltages greater than -30 mV. 6. ICa in the mouse bipolar cells was insensitive to 50 microM-Cd2+, 10 microM-nifedipine and 10 microM-Bay K 8644. In contrast, the calcium currents of bipolar and horizontal cells of the goldfish retina were markedly suppressed by 50 microM-Cd2+ and 10 microM-nifedipine, and were augmented several fold by 10 microM-Bay K 8644. The calcium currents of goldfish bipolar and horizontal cells were sustained, and were activated in a more positive range of potentials than the ICa of mouse bipolar cells. 7. The voltage range at which the ICa of mouse bipolar cells is activated includes the presumed range of membrane potentials spanned during light-evoked responses; thus, this current may participate in synaptic transmission. The transient character of ICa may also help to shape transient responses of ganglion cells.

Multiple muscarinic responses directly evoked in isolated neurones dissociated from rabbit sympathetic ganglia

Single sympathetic neurones, enzymatically isolated from the superior cervical ganglia of adult rabbits and maintained in culture medium, responded directly to DL-muscarine with a variety of electrical responses. The falling phase of the action potential was markedly accelerated while the late portion of the after-spike hyperpolarization was depressed. These changes occurred before any detectable change in membrane potential. The slow depolarizing changes in membrane potential induced by muscarine were associated with different changes in membrane conductance: a voltage-independent increase, a decrease at the levels of membrane potential positive to about -70 mV and a voltage-independent decrease. Muscarine can produce these multiple membrane changes often within the same cell, suggesting that the different effects are not due to heterogeneous cell types.

Effects of pineal factors on the action potentials of sympathetic neurons

Neurons from rat superior cervical ganglia were grown in coculture with pineal cells. Action potentials of neurons in cocultures were 25% longer and were 25% greater in amplitude than those recorded from neurons grown in the presence of ganglionic nonneuronal cells alone. Neurons showed an increase in action potential duration with increasing time in culture. This may have been related to the recovery of nonneuronal cell populations after an initial exposure to the antimitotic agent Ara-C. In cultures not initially exposed to Ara-C, a subsequent exposure after 7 days in culture resulted in a shortening of the action-potential duration. Neuronal cultures were exposed to gel slabs containing the pineal indolamines, serotonin, N-acetylserotonin, and melatonin. Serotonin and N-acetylserotonin showed no effect on the neuronal action potentials at the concentrations tested. Melatonin caused an increase in action-potential duration that was associated not with an increase in action-potential amplitude, but with a decrease in action-potential rise rates. The effects of long-term exposure in melatonin appeared to be reversible in some cells but not in all. Short-term effects of melatonin were observed in older cultures and in younger cultures after the cells were stimulated repeatedly. Older cultures also had higher levels of spontaneous activity. The dependence of the short-term effects of melatonin on electrical activity may suggest a role for melatonin as a neuromodulator.

Factors affecting the expression of acetylcholine receptors on rat sensory neurones in culture

Sensory neurones from nodose ganglia of new-born rats were grown in dissociated tissue culture either with or without satellite cells. When cultured without satellite cells, most neurones developed sensitivity to acetylcholine (ACh); time-course experiments indicated that the neurones acquire their sensitivity during the second to third week in culture. Most neurones co-cultured with satellite cells did not develop ACh sensitivity. Delayed removal of satellite cells 8-12 days after plating resulted in few neurones acquiring ACh sensitivity. Delayed addition of satellite cells to neuronal cultures that were initially grown without satellite cells had no effect on the number of ACh-sensitive neurones. The potential to develop ACh sensitivity in culture without satellite cells decreases with the age of the neurones at the time of culturing; few neurones from 2-week-old animals developed sensitivity to ACh when cultured without satellite cells. These results indicate that there is some influence from satellite cells that prevents nodose neurones from developing ACh sensitivity in culture and suggests that this influence may also operate in vivo.

Enkephalin and substance P modulate synaptic properties of chick ciliary ganglion neurons in cell culture

Since enkephalin- and substance P-like immunoreactive materials have been identified in preganglionic terminals of the avian ciliary ganglion, we tested the effects of enkephalin and substance P directly on chick ciliary ganglion neurons in dissociated cell culture. Under these conditions the neurons form cholinergic synapses with each other that are spontaneously active. Both peptides modulate properties of membrane components associated with synaptic transmission between the neurons. Enkephalin causes a 60% reduction in the mean amplitude of the excitatory synaptic potentials, and the effect appears to be presynaptic in origin: enkephalin does not alter acetylcholine sensitivity on the neurons, but does inhibit Ca2+ influx as reflected by a 38% shortening of the Ca2+ component of the action potential. Both the reduction in synaptic potential amplitude and the shortening of the Ca2+ action potential produced by enkephalin are blocked by naloxone. Substance P, on the other hand, has no effect on Ca2+ action potentials but does reduce the time course of acetylcholine responses in the neurons by a mechanism consistent with enhanced receptor desensitization. Decay of the acetylcholine voltage response in the absence of substance P is described by a single exponential process with a time constant of 4-5 s. Coapplication of acetylcholine and substance P results in a second exponential decay process with a time constant of about 1 s that appears after a 200-400 ms lag period. Preincubation with substance P alone does not decrease the peak voltage response or shorten the lag, suggesting that either agonist or activated receptor is necessary for the substance P effect. These findings suggest modulatory roles for the peptides in ganglionic transmission.

Neurons dissociated from rat myenteric plexus retain differentiated properties when grown in cell culture. II. Electrophysiological properties and responses to neurotransmitter candidates

We have used intracellular recordings to study the electrophysiological and pharmacological properties of neurons that have been grown in cell cultures after having been dissociated from the myenteric plexus of the small intestine of newborn rats. Studies of action potential mechanisms revealed that all of the neurons could generate Na+-dependent action potentials in the presence of Ca2+-channel blockers and that about 70% could generate Ca2+-dependent action potentials when Na+ channels were blocked with tetrodotoxin. No neurons generated long afterhyperpolarizations after single action potentials but about 50% of neurons did so following trains of action potentials. Over 95% of the neurons tested accommodated rapidly to sustained depolarization. The effects of several enteric neurotransmitter candidates were studied by superfusing or pressure-ejecting test solutions while recording neuronal responses. All of the cultured neurons tested had nicotinic responses to acetylcholine. Subsets of neurons responded to muscarinic cholinergic agonists (slow depolarization and increased excitability), serotonin (fast depolarization or slow depolarization and increased excitability), gamma-aminobutyrate (fast depolarization), substance P (slow depolarization, biphasic fast and slow depolarization or increased excitability without a change in membrane potential), vasoactive intestinal peptide (slow depolarization and increased excitability), or [Met]enkephalin (slow hyperpolarization and/or decreased action potential duration). We conclude that myenteric neurons grown in cell culture retain many of the physiological and pharmacological properties that they have in situ. Such cultures will permit detailed biophysical and pharmacological studies of the mechanisms of action of enteric neurotransmitter candidates.

Voltage-dependent potassium currents in developing neurones from quail mesencephalic neural crest

Neurones in explants cultured from quail mesencephalic neural crest were studied at different stages of their development using the voltage-clamp technique. A voltage-dependent outward current activated by membrane depolarization was identified as a potassium current by the sensitivity of its reversal potential to extracellular potassium. The voltage-dependent potassium current is made up of two components which differ in their sensitivity to 4-aminopyridine (4-AP) and tetraethylammonium (TEA). The component most sensitive to 4-AP has fast activation kinetics and inactivates quickly at sustained depolarized voltages. By analogy with a current described in other preparations, this current was called IA. The component most sensitive to TEA has slower activation kinetics and inactivates more slowly at sustained depolarized voltages. This current was called IK. IA and IK were already present in neurones cultured for 24 h. The ratio between the peak of IK and that of IA increased significantly between 24 h and 4 days in culture. This means that the two components of the voltage-dependent potassium current follow a different time course during development.

Dissociated cell culture of cholinergic neurons from nucleus basalis of Meynert and other basal forebrain nuclei

Degeneration of cholinergic neurons from the basal forebrain nuclei is suspected to be the cause of Alzheimer disease. We have developed dissociated cultures of cholinergic neurons from these nuclei (the nucleus basalis of Meynert, the medial septal nucleus, and the diagonal band nuclei). Brain slices of the forebrains were made by a vibratome, and the basal forebrain nuclei were dissected out, dissociated, and cultured. Choline acetyltransferase immunocytochemistry and acetylcholinesterase cytochemistry revealed large cholinergic cells (average diameter, 20-25 micron) in these cultures. About 75% of large neurons (20 micron or larger in diameter) were cholinergic. Electrophysiological experiments were performed on these large neurons. The neurons usually did not show spontaneous firing, but steady depolarizations produced trains of action potentials, which adapted quickly. The neurons responded with depolarization to the application of L-glutamic acid. Substance P produced depolarization (sometimes hyperpolarization), and during the depolarization membrane resistance was increased.

Differential regulation of peptide and catecholamine characters in cultured sympathetic neurons

Mechanisms regulating peptidergic, noradrenergic and cholinergic development were compared in dissociated cell cultures of neonatal rat sympathetic ganglia. The majority of cultured neurons contained at least two neurotransmitters and many neurons contained three or more. These studies were undertaken to determine whether co-existing transmitters were co-ordinately regulated by the environment. Co-culture of sympathetic neurons with ganglion non-neuronal cells increased substance P and choline acetyltransferase activity but decreased somatostatin and tyrosine hydroxylase activity. Conversely, elimination of non-neuronal cells virtually abolished neuronal expression of substance P and choline acetyltransferase and increased somatostatin and tyrosine hydroxylase. Consequently, under these conditions, somatostatin and tyrosine hydroxylase were similarly regulated, whereas substance P was associated with choline acetyltransferase. By contrast, stimulation of adenylate cyclase or treatment with membrane-permeable adenosine 3',5'-phosphate analogs increased tyrosine hydroxylase and decreased choline acetyltransferase, but had no effect on substance P or somatostatin levels. Moreover, potassium- or veratridine-induced membrane depolarization increased tyrosine hydroxylase but decreased substance P, somatostatin and norepinephrine levels. However, inhibition of neurotransmitter release with magnesium or calcium-free medium prevented the decrease in norepinephrine levels but not the decrease in substance P and somatostatin. Consequently, the effects of membrane depolarization on peptide levels cannot be ascribed to release and subsequent depletion of substance P and somatostatin and must result from decreased net synthesis (synthesis minus catabolism) of the transmitters. Nerve growth-factor treatment also differentially regulated transmitter metabolism; nerve growth factor increased protein-specific activities of tyrosine hydroxylase and choline acetyltransferase but did not increase the protein-specific content of substance P and somatostatin. Quantitative transmitter expression was also influenced by neuron density; increasing density elevated substance P and choline acetyltransferase activity but decreased somatostatin and tyrosine hydroxylase activity per neuron. Finally, culture of sympathetic neurons in a defined (serum-free) medium also altered some but not all traits, decreasing substance P, somatostatin and choline acetyltransferase without any change in tyrosine hydroxylase.(ABSTRACT TRUNCATED AT 400 WORDS)

Intrinsic control of electroresponsive properties of transplanted mammalian brain neurons

The present study presents the first analysis of neurons in mammalian brain transplants based on intracellular recording. The results, obtained in brain slices including both donor and host tissue, showed that neuronal precursor cells in embryonic transplants retained their ability to complete their normal differentiation of cell-type-specific electroresponsive properties. Distortions in cell aggregation and synaptic connectivity did not affect this aspect of neuronal differentiation.

Ultrastructural features of a human neuroblastoma cell line treated with retinoic acid

This report examines the morphological changes that occur in a line of human neuroblastoma cells (LA-N-5) following treatment with retinoic acid, in vitro. The results demonstrate that retinoic acid induces pronounced differentiation of these cells. Perikarya aggregate into tight clusters and extend long processes that are frequently fasciculated. Growth cones appear at the ends of these processes. Transmission electron microscopy reveals that after 10 days of treatment these long neurites give rise to varicosities which contain clusters of large dense-core vesicles and smaller clear vesicles. After 18 days of treatment the cultures cease to differentiate further. The pattern of neurite outgrowth is very complex by this point and the frequency of growth cones and vesicle-containing varicosities is greatly increased compared with shorter treatments. Most of these varicosities contain a mix of large dense-core vesicles and smaller clear vesicles and in some profiles the clear vesicles are round while in others they are pleomorphic. Despite this increase in the number of vesicle-containing profiles no membrane specializations were seen that resemble mature synapses. The present results demonstrate that retinoic acid can produce morphological changes in these cells in culture, and that these changes closely mimic those of normal differentiating neurons in culture. Considered with previous studies, these findings suggest that this cell line might provide a useful model system for studying neural differentiation.

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

Large growth cones were produced in vitro by nerve growth factor (NGF) treatment of multinucleate cells produced by chemical fusion of cells of the neuron-like clone PC12. These endings were studied both at the light microscopic and ultrastructural levels. The activity of ionic channels at growth cones was recorded with intracellular microelectrodes, patch recording of single channels, and whole cone recording from mechanically isolated growth cones. Morphologically, these large growth cones were characterized by the presence of microspikes and filopodia, by the presence of actin demonstrated immunohistochemically, and by the presence of catecholamine fluorescence. At the ultrastructural level they contained a broad spectrum of organelles with a distribution characteristic of neuronal growth cones, including dense core vesicles, abundant smooth membrane cisternae, microtubules, and a filamentous network. The presence of channels capable of generating action potentials was revealed by intracellular microelectrode recording from the growth cone in the presence of locally applied tetraethylammonium (TEA). TEA appeared to block outward current channels that could effectively shunt inward current activated by depolarization. Action potentials elicited by depolarizing current in the presence of TEA could be blocked reversibly by Cd2+, a specific blocker of Ca channels. These action potentials were often followed by a long after-hyperpolarization lasting hundreds of milliseconds. This after-hyperpolarization was similar to that recorded in the cell body of PC12 cells where it appears to be mediated by Ca-activated K current. Single channel recording from outside-out excised patches of membrane from the growth cones perfused with KF revealed the presence of voltage sensitive Na channels, Ca-activated K channels, and K channels resembling delayed rectifier K channels. Macroscopic currents recorded from mechanically isolated growth cones in the "whole cone" configuration showed rapid inward currents at potentials greater than or equal to -40 mV, followed by delayed outward currents at more positive potentials, a finding providing additional evidence for the presence of Na and K channels in growth cones.

A voltage-clamp analysis of membrane currents in solitary bipolar cells dissociated from Carassius auratus

Membrane properties of solitary bipolar cells, mechanically dissociated from the enzyme-treated goldfish retina, were studied under current- and voltage-clamp conditions with 'giga-seal' suction pipettes (pipette solution 138 mM-K). The resting potential of solitary bipolar cells was about -30 mV. They responded to depolarizing current pulses with sustained depolarization, and to hyperpolarizing current pulses with an initial hyperpolarizing transient followed by a sag to a less hyperpolarized level. The current-voltage relationship determined under voltage-clamp conditions showed strong outward and inward rectification. The membrane currents consisted of four components; Ca current (ICa), voltage- and Ca-dependent K currents (IK(V) and IK(Ca), respectively), and an inward current activated by membrane hyperpolarization (Ih). ICa was activated by membrane depolarization beyond -40 mV, was maximum at +10 mV and became smaller with further depolarization. No polarity reversal was seen. ICa was enhanced by equimolar replacement of Ca with Ba, and was blocked by 4 mM-Co. IK(Ca) was observed by membrane depolarization beyond -10 mV, was maximum at about +40 mV, and became smaller with further depolarization. This current was suppressed by 4 mM-Co, 1.6 mM-Ba, 35 mM-TEA or 30 microM-quinine. IK(V) was activated by membrane depolarization beyond -60 mV, and had slower kinetics that ICa or IK(Ca). The reversal potential of the tail current was close to the K equilibrium potential (EK), suggesting that this current is carried purely by K ions. IK(V) was inactivated slowly and nearly completely by sustained depolarization. IK(V) was blocked by 35 mM-TEA. Ih was activated by membrane hyperpolarization (less than -60 mV). The current showed a time-dependent increase. It was also dependent on the membrane potential, but not on the driving force of K ions. This current seems to be carried by a mixture of Na and K ions, since (1) in low Na solution, Ih became small in amplitude, and (2) the reversal potential of the tail current was between the Na equilibrium potential (ENa) and EK X Ih was blocked by 10 mM-Cs, but was resistant to 0.2 mM-Ba. The resting potential and voltage responses of solitary bipolar cells are discussed in reference to the characteristics of each membrane conductance isolated in the present study.

Synapse formation among developing sensory neurones from rat nodose ganglia grown in tissue culture

Sensory neurones from new-born rat nodose ganglia were grown in tissue culture, either with or without the ganglionic satellite cells, in order to investigate influences of satellite cells on sensory neurone development. To learn more about the post-natal development of nodose ganglia in rats neuronal counts of the ganglion were made at three different developmental stages. There were no significant differences of neuronal number in nodose ganglia in new-born rats, rats 3 weeks of age, and adult rats. Up to 60% of the neurones formed synapses with each other when they developed in culture without ganglion satellite cells. Pharmacological experiments indicated that the transmitter at these synapses was ACh and the post-synaptic receptors were nicotinic. Neurones co-cultured with satellite cells rarely formed functional synapses and most (85%) were not sensitive to ACh: 75% of neurones cultured without satellite cells were ACh sensitive. These results provide evidence that mammalian sensory neurones form synapses among each other in culture. The results also suggest that ganglionic satellite cells prevent functional synapses among these neurones from occurring, in part because the neurones do not express ACh sensitivity when co-cultured with satellite cells.

Fetal rat sympathetic neurons maintained in a serum-free medium retain induced cholinergic characteristics

When maintained in some serum-containing media, fetal rat sympathetic neurons acquire substantial choline acetyltransferase activity and form cholinergic synapses in vitro. However, when they are maintained in a serum-free, defined culture medium, choline acetyltransferase activity is not detected and cholinergic synapses are not observed. In this study, we have examined the effects of various times of exposure to a medium inducing cholinergic function on the properties of neurons subsequently maintained in defined medium. We report that 2-day, but not 2-h, exposure to this inducing medium causes a long-lasting (greater than 6 weeks) increase (7-10-fold) in the activity of choline acetyltransferase and that, under these conditions, sympathetic neurons in vitro form cholinergic, electrical and mixed function cholinergic and electrical synapses. We conclude that a relatively brief exposure to media inducing cholinergic function can cause long-lasting changes in the functional properties of sympathetic neurons in vitro.

A late slow depolarization unmasked in the presence of tetraethylammonium in neonatal rat sympathetic neurons in vitro

Neonatal rat superior cervical ganglia were mechanically dissociated, and the sympathetic neurons grown in dispersed cell cultures. Intracellular microelectrodes were used to study the effects of tetraethylammonium (TEA+), a blocker of outward K+ currents, on the excitable properties of these neurons. Addition of TEA+ to the perfusion media (TEA+-media) caused the resting potential to depolarize and the action potential to increase in duration. In TEA+-media (20-60 mM), a late delayed depolarization (LDD) followed the falling phase of the action potential with a delay of 1.5-2 s (n = 95). The LDD peak amplitude was in the range of 4-26 mV and the duration, to full return of the resting potential, was in the range of 18-90 s. For a given cell the amplitude and duration of the LDD were constant. The LDD was associated with a conductance increase. No LDD could be elicited in the presence of calcium channel blockers. Evidence was found for a Ca2+-dependence of the LDD: increasing the extracellular Ca2+ concentration caused increases in the amplitude and duration of the LDD. The significance of an endogenous LDD-like potential and possible explanations for the origin of the LDD are discussed.

Ionic currents of solitary horizontal cells isolated from goldfish retina

Solitary horizontal cells, dissociated from papain-treated goldfish retinas, produce action potentials and show a non-linear current-voltage relationship. Underlying ion-conductance mechanisms were analysed by a single-micro-electrode voltage-clamp technique. Pharmacological and ion-substitution experiments revealed that ionic currents could be separated into at least four voltage-dependent currents: a Ca current and three types of K currents. The Ca current was activated by membrane depolarization beyond -45 mV, reached a maximal value near 0 mV, and became smaller at more positive potentials. By extrapolation, the reversal potential was estimated to be approximately +50 mV. The Ca current was inactivated by accumulation of intracellular Ca ions but not by membrane depolarization. Co ions (4mM) blocked this current. The first type of K current showed anomalous (inward-going) rectification near the resting potential (congruent to -60 mV). Hyperpolarization from the resting level produced a large, almost steady inward current, while depolarization evoked only a small, steady outward current. The current-voltage relationship revealed a shallow negative resistance region at membrane potentials beyond -50 mV. The current was blocked by Cs (10 mM) or Ba (1 mM) ions. The second type of K current (the transient outward current) was activated by membrane depolarization beyond -25 mV. The peak amplitude increased almost exponentially as the membrane was depolarized. During steady depolarization this current decayed exponentially (time constant congruent to 500 ms at +20 mV). The current was inactivated by conditioning depolarization (greater than 10 s) beyond -30 mV and blocked by 4-aminopyridine (10 mM). The third type of K current was the maintained outward current which was activated by membrane depolarization beyond -20 mV, increased to a steady level in a few hundred milliseconds, and showed little inactivation. The amplitude increased as the membrane was depolarized. The current was blocked by tetraethylammonium ions (20 mM). A Ca-mediated K current was not detected. Action potentials and the non-linear current-voltage relationship of solitary horizontal cells can be explained qualitatively by the combination of the four ionic currents.

Regenerative impulses in taste cells

Taste cells and nongustatory epithelial cells in the isolated lingual mucosa from the mud puppy Necturus maculosus were impaled with microelectrodes. The taste cells, but not surrounding epithelial cells, were electrically excitable when directly stimulated with current passed through the recording electrode. Action potentials produced by taste cells had both a sodium and a calcium component.

The development of action potentials in cultures of explanted cortical neurons from chick embryos

Action potentials of explanted cortical neurons from 7- to 9-day chick embryos were investigated at different stages during culturing. The maximum rates of rise of action potentials gradually increased and reached a plateau level at about 1 month in culture. Action potentials were resistant to 10(-7) g/ml tetrodotoxin (TTX) at early stages, became sensitive to TTX in an age-dependent manner, and almost all action potentials were blocked by this concentration of TTX after 25 days. However, 10(-5) g/ml TTX suppressed action potentials at early stages. When action potentials were suppressed by TTX, impulses could still be obtained from immature neurons following addition of 10 mM Ca2+ to the saline. This effect was not observed in mature neurons. The application of 10 mM Mn2+ frequently enhanced action potentials in immature neurons. This effect was not blocked by TTX (10(-5) g/ml) or the removal of external Na+. These results suggest that action potentials in immature neurons depend on Ca2+ and Na+, that Mn2+ can pass through Ca channels, that the sensitivity to TTX develops as the contribution by Na+ becomes greater, and that the contribution by Ca2+ diminishes during maturation.

Morphological studies of synapses and varicosities in dissociated cell cultures of sympathetic neurons

Neurons dissociated from the superior cervical ganglia of newborn rats can be grown under conditions which support either adrenergic or cholinergic differentiation. In both cases, the neurons form numerous morphologically specialized synaptic terminals or synapses as well as relatively unspecialized varicosities. The ultrastructure of both types of terminal was compared in mature neuronal cultures and the effects of growth conditions on terminal morphology examined. After aldehyde-osmium fixation, synapses in cultures grown under adrenergic or cholinergic conditions were characterized by asymmetrical membrane specializations comparable to type I or asymmetric synapses; bismuth iodide and ethanolic phosphotungstic acid impregnation of neuronal cultures revealed the presence of characteristic synaptic membrane specializations: a presynaptic grid of dense projections and a wide postsynaptic dense band of uniform thickness. No membrane specializations were apparent in varicosities after aldehyde-osmium fixations or with these stains. Intramembranous particle distributions were examined in freeze-fracture replicas of neurons. Aggregates of large, 10-12 nm particles were found on P-face membrane leaflets of cell bodies and large diameter processes; this distribution is the same as that of synapses in thin-sectioned preparations. These particle aggregates may represent postsynaptic membrane specializations or acetylcholine receptors. The cytoplasmic leaflet of boutons contained large, 12-14 nm particles, which appeared to be concentrated at the region of synaptic contact at putative synapses, but were diffusely distributed in varicosity membranes. Similar large particles were also seen at a much lower density in the membrane E-face. None of these ultrastructural characteristics appeared to vary with transmitter identity or growth conditions. Synaptic vesicle shape, however, did vary in glutaraldehyde-fixed cultures. At all ages examined, neurons grown on monolayers of heart cells contained predominantly round vesicles, whereas neurons grown in the virtual absence of non-neuronal cells possessed pleiomorphic synaptic vesicles. This difference in vesicle shape appeared to be correlated more closely with growth in the presence of non-neuronal cells than with the transmitter present at the time of fixation.

Electrophysiological techniques in dissociated tissue culture

The application of electrophysiological techniques to tissue culture is still evolving. We have attempted in this chapter to give a practical summary of intracellular recording techniques used in our laboratory, as well as give some examples of new experimental strategies and electrophysiological methods that should provide further information on a number of interesting neurobiological questions. The combination of an increasing knowledge of the cell biology of cultured neurons and advances in electrophysiology should continue to be a fruitful interaction.