Neurotransmitter Responses Research Articles

Concanavalin a: a tool to investigate neuronal plasticity

Neuronal plasticity is the ability of neurons to alter their cellular properties in response to changes in their environment. These changes are typically triggered by the binding of specific ligands, such as neurotransmitters, growth factors or other neuromodulators, to receptors on the neuronal membrane surface. Since the extracellular domains of many of these receptors are glycosylated, they can also be bound by lectins - proteins with high affinity binding sites for polysaccharides. Different lectins have different affinities for various sugar residues. This feature has made lectins useful in the investigation of the regional localization and relative mobility of different classes of glycosylated membrane receptors, and in the subsequent purification of the receptors. This article reviews some of the different kinds of neuronal plasticity produced by the plant lectin concanavalin A (Con A), such as enhancement of neurite outgrowth, modulation of neurotransmitter responses, and alteration in the specificity and strength of synaptic connections.

Excitotoxic index — a biochemical marker of selective vulnerability

We have previously demonstrated that elevated intraischemic glutamate levels are insufficient, of themselves, to engender ischemic damage. Glycine and γ-aminobutyric acid (GABA), which modulate glutamatergic activity, may also play a significant role. We compared ischemia-induced changes in glutamate, glycine, and GABA release in a selectively vulnerable region (dorsolateral striatum) to the changes occurring in a region, although rendered ischemic, is usually spared with 20 min ischemia (anterior thalamus). Regional extracellular neurotransmitter levels were measured by microdialysis before, during, and after 20 min of global ischemia induced by 2-vessel occlusion plus systemic hypotension in the rat ( n = 5). Similar ischemia-induced increases in glutamate, GABA, and glycine were observed in both striatum and thalamus (19–25 fold, 43–52 fold, and 3–4 fold, respectively). During recirculation, both glutamate and GABA returned to baseline in both regions by 30 min of reperfusion. Glycine levels remained two-fold higher than baseline in the striatum but fell to baseline in the thalamus. To derive a quantitative descriptor reflecting the composite magnitude of aminoacid neurotransmitter changes with ischemia, we defined the ‘excitotoxic index’ as: [glutamate] × [glycine]/[GABA]. While increases in the excitotoxic index during ischemia were similar for striatum and thalamus, a marked and highly significant increase was found in the striatum compared to the thalamus at early (1 h = 91.5 ± 27.4 and 25.1 ± 6.3, P < 0.01, ANOVA) as well as later recirculation times (2 h = 111.3 ± 30.9 and 20.9 ± 3.6, P < 0.01). Thus, the excitotoxic index, which reflects the composite neurotransmitter response, appears to be a reliable biochemical marker of selective neuronal vulnerability.

Sex- and time-dependent changes in neurochemical and hormonal variables induced by predictable and unpredictable footshock

Previous experiments have revealed sex-dependent effects of inescapable shock in rats. Behavior of male rats was more severely disrupted by inescapable shock than behavior of female rats. These sex differences were found after 1- and 24-hour intervals but not after a 72-hour interval. The present experiment was designed to study various physiological parameters at 1-, 4- and 24-hour intervals after inescapable footshock. The predictability of shock was manipulated by adding a compound light and tone stimulus that preceded shock presentation for one group but was not correlated with shock presentation for another group of subjects. Noradrenaline, dopamine, serotonin, and metabolites of these 3 transmitters were measured in the frontal cortex. Transient shock-induced increments in dopamine and metabolites of dopamine and serotonin were found, but the sex of the animal did not differentially affect this neurotransmitter response. In addition to neurotransmitter concentrations in the frontal cortex, levels of corticosterone were measured in plasma. The pituitary-adrenal axis was activated for a longer period in females than males after shock. The present data do not provide evidence that behavioral sex differences induced by inescapable shock are paralleled by sex differences in neurotransmitter activity. In addition, sex-dependent effects of predictability of shock on neurotransmitter activity were not detected. The relevance of the observed sex-dependent responses in the pituitary-adrenal system is discussed.

Release of segmental amino acid neurotransmitters in response to peripheral afferent and motor cortex stimulation: A pilot study

The role of amino acid (AA) neurotransmitters in the spinal cord has been primarily studied using in vitro preparations and histochemical methods. The technology necessary to estimate AA levels in an intact animal has only recently become available. Such an investigation could yield valuable information regarding the segmental neurochemical environment. We measured the release of AAs into the rabbit lumbar spinal cord in response to sciatic nerve and transcranial stimulation with stereotaxically placed microdialysis catheters. Samples were obtained periodically during 90 minutes of continuous stimulation of either the left or right sciatic nerve, or motor cortex. Quantification of γ-amino butyric acid (GABA), aspartate, glutamate, glycine, and taurine was performed using high pressure liquid chromatography (HPLC). Adequate neural excitation was verified by recording somatosensory evoked potentials (SSEPs) or corticomotor evoked potentials (CMEPs). Sensory activation at intensities sufficient to activate small and large diameter peripheral fibers of the ipsilateral (to the microdialysis probe) sciatic nerve produced a significant change only in segmental glycine levels. Contralateral sciatic nerve stimulation failed to evoke a significant elevation of AAs. In addition, a significant increase in the release of glycine and taurine was measured after 90 minutes of transcranial stimulation. SSEP and CMEP components repeatedly showed adequate activation of primary afferent, descending motor fiber pathways, and segmental interneuron pools during dialysis sampling. Our data are consistent with the hypothesis that suprasegmental influence over peripheral afferent and motor activity may be, in part, through these amino acid neurotransmitters in the rabbit lumbar spinal cord.

Cell interactions regulate dendritic morphology and responses to neurotransmitters in embryonic chick sympathetic preganglionic neurons in vitro

The influence of non-neuronal cells and interneurons on the morphological development of chick sympathetic preganglionic neurons (SPNs) and on the responsiveness of these neurons to the neurotransmitters GABA, glycine, and glutamate was studied. SPNs were retrogradely labeled with the fluorescent dyes dil and diO, then separated from spinal-cord non-neuronal cells and interneurons by fluorescence-activated cell sorting. SPNs were grown in culture, either alone or in coculture with non-neuronal cells alone, with interneurons alone, or with both of these cell types (control cultures). The responsiveness of SPNs to neurotransmitters was assessed by whole-cell recording, while cell morphology was assessed after intracellular staining with 6-carboxyfluorescein. Cell size and morphology were affected by non-neuronal cells. In the absence of non-neuronal cells, SPNs had smaller cell bodies and fewer major processes, whether or not interneurons were present. In contrast, responses to the 3 neurotransmitters were affected by both non-neuronal cells and interneurons, but in ways that differed slightly for each transmitter. In the absence of both non-neuronal cells and interneurons, responses to all 3 transmitters were much smaller than in control cultures, with responses to glutamate most profoundly affected. The addition of either non-neuronal cells or interneurons slightly increased the amplitude of SPN responses to glutamate, but the level of responsiveness with either cell type alone was much lower than for SPNs grown in the presence of both cell types. The addition of interneurons also slightly increased the responsiveness of SPNs to GABA, but non-neuronal cells alone had no significant effect on the responses of SPNs to GABA. Finally, the glycine responsiveness of SPNs was raised to control levels when either non-neuronal cells or interneurons were added. These experiments demonstrate that, though interneurons can have a significant inductive effect on the responses of SPNs to neurotransmitters, not all of the changes in neurotransmitter responsiveness can be related to the formation of functional synapses.

The α1- and α2-adrenoceptor and muscarinic responses of normal and axotomized bullfrog sympathetic ganglia

When neurones in bullfrog paravertebral sympathetic ganglia are studied by means of the sucrose-gap technique, muscarinic agonists produce a biphasic response (an initial hyperpolarization of ganglionic C cells followed by a depolarization of ganglionic B cells). Activation of ganglionic alpha 2-adrenoceptors promotes hyperpolarization. The present experiments with selective alpha 1- and alpha 2-adrenoceptor agonists and antagonists provided evidence for the existence of hitherto undescribed alpha 1-adrenoceptors, which are responsible for the production of depolarizing responses in these ganglia. Fifteen to twenty-five days after cutting postganglionic axons (axotomy), there was a nonselective depression of both alpha 1- and alpha 2-adrenoceptor mechanisms but little change in muscarinic responses. These results argue against the hypothesis that C cells assume all the properties of B cells after axotomy. Since the alpha-selective agonist phenylephrine failed to depolarize axotomized ganglia, it is unlikely that an alpha 1-adrenoceptor mechanism is prominent in axotomized neurones as it is in some immature adrenergic neurones. The data are consistent with the idea that axotomy selectively affects the properties of certain types of cation channels and raise questions as to the mechanisms involved in regulating the expression and maintenance of specific neurotransmitter responses on ganglionic neurones.

Activity-dependent neuromodulation in Aplysia neuron R15: intracellular calcium antagonizes neurotransmitter responses mediated by cAMP

1. The effect of electrical activity on the response to the neuromodulators serotonin (5-HT) and the neuropeptide egg-laying hormone (ELH) was studied in the Aplysia bursting pacemaker neuron R15. 2. Previous work has shown that 5-HT and ELH augment R15s bursting activity by enhancing two ionic currents, an inwardly rectifying K+ current (IR) and a voltage-gated Ca2+ current (ICa), and that the enhancement of the currents is mediated by the intracellular second-messenger adenosine 3',5'-cyclic monophosphate (cAMP). Here we show that both spontaneous action potentials and voltage-clamp depolarizations suppress the modulation by 5-HT and ELH of these currents. Both spontaneous and evoked depolarizations decrease the magnitude and dramatically speed the decay of the modulation of IR and ICa. 3. The depolarization-induced suppression is blocked by intracellular ethylene glycol-bis(beta-aminoethyl ether)N,N,N',N',-tetraacetic acid (EGTA), indicating that the suppression is Ca-dependent. The suppression is specific for responses mediated by cAMP; a non-cyclic AMP-mediated response to acetylcholine is not affected by depolarizing pulses. 4. The Ca-dependent suppression of IR modulation differs from the Ca-dependent suppression of ICa modulation. Ca2+ influx decreases the sensitivity of IR to neuromodulators without reducing the maximal response elicited by high concentrations of neuromodulators. In contrast, Ca2+ not only decreases the sensitivity of ICa but also reduces the maximal effect elicited by high concentrations of neuromodulators. We have shown previously that intracellular Ca2+ also inactivates the basal IR and ICa in neuron R15 by distinct mechanisms. The inactivation of IR is due to an antagonistic action of Ca2+ on cAMP metabolism, whereas the inactivation of the basal ICa is due primarily to a more direct action of Ca2+, perhaps on the Ca channels themselves. 5. We also studied the interaction between action potentials and neuromodulator released onto R15 from an endogenous source: bag cell neurons, which release large amounts of ELH during an intense "afterdischarge." IR and ICa become greatly enhanced during the afterdischarge, even though R15 continually fires action potentials. In addition, Ca-dependent inactivation of IR is suppressed during the afterdischarge. We suggest that the bag cells release an amount of ELH sufficient to temporarily saturate the cAMP-mediated enhancement of IR and that this temporarily prevents the suppressive effects of Ca2+ on IR. 6. The activity-dependent suppression of neuromodulation in neuron R15 is an example of neuronal plasticity that results from interactions between intracellular messengers.(ABSTRACT TRUNCATED AT 400 WORDS)

Regional neurotransmitter responses after acute and chronic electroconvulsive shock

Regional neurotransmitter changes after acute and chronic electroconvulsive shock (ECS) were studied using the technique of repeated microdialysis. Microdialysis was carried out on alternate sides of the brains of anaesthetised rats before and during the first and the eighth ECS or sham (control) treatments. Extracellular fluid release of monoamines and their metabolites was measured in the frontal cortex, striatum and nucleus accumbens using HPLC with electrochemical detection. The first ECS produced selective regional responses, shown by increased concentrations of noradrenaline (NA) and dopamine (DA) in frontal cortex, by unchanged DA content in striatum, and by a small rise in NA and a fall in DA concentrations in nucleus accumbens. Concentrations of metabolites increased after ECS in all regions studied, and for homovanillic acid and dihydroxyphenylacetic acid, the temporal pattern of these changes did not resemble that of DA. Comparison of neurotransmitter responses as per cent of baseline release after the first and eighth ECS treatments showed they were identical. Basal release of monoamines and metabolites before the first ECS or sham treatment was similar in all regions studied. Prior to the eighth treatment, basal release of NA in the frontal cortex and DA in the striatum was elevated in the ECS-treated animals, while basal release of NA in the nucleus accumbens was reduced in both ECS- and sham-treated animals. These data suggest that acute and chronic ECS have different and region-specific effects on neurotransmitter release, although the overall pattern of these responses is not changed by chronic treatment.(ABSTRACT TRUNCATED AT 250 WORDS)

In vivo measures of monoamines during amphetamine-induced behaviors in rats

Kuczenski, Ronald and David S. Segal. In vivo measures of Monoamines During Amphetamine-Induced Behaviors in Rats. Prog. Neuro-Psychopharmacol. & Biol. Psychiat. 1990, 14 (Suppl): S37–S50. 1. 1. Using a removable in vivo microdialysis probe and remote sample collection, the temporal and dose-related behavioral and monoamine response to amphetamine (AMPH) were examined in freely-moving rats. Extracellular dopamine, serotonin and their metabolites were monitored concomitant with detailed characterization of the locomotor and stereotypy profiles. Consistent with previous results, AMPH (0.5 – 5.0 mg/kg) induced a rapid dose-dependent increase in dopamine concentration and decrease in the concentrations of the dopamine metabolites. Dopamine and metabolites exhibited contrasting temporal and dose-related patterns, suggesting that the decline in dopamine metabolites is functionally dissociated from the AMPH-enhanced dopamine release and that metabolite levels do not provide an accurate index of functional dopaminergic activity. 2. 2. Dose response comparisons revealed a significant relationship between AMPH-induced increases in behavioral perseveration and the magnitude and duration of the dopamine release. However, the temporal patterns of the neurotransmitter response and individual components of stereotypy were not parallel, suggesting that the presence of stereotypies is not associated simply with quantitative differences in striatal dopamine release. 3. 3. Consistent with this interpretation, we found that a variety of manipulations including reserpine, apomorphine and chronic amphetamine pretreatment, produced a dissociation between the alterations in the behavioral and dopaminergic responses to amphetamine. The behavioral response to amphetamine may be influenced by the interaction between levels of dopamine and serotonin, by the state of their respective receptors and by the relative contributions of additional dopaminergic systems.

Nonlinearity and facilitation in phosphoinositide signaling studied by the use of caged inositol trisphosphate in Xenopus oocytes

The phosphoinositide signaling pathway, which mediates neurotransmitter responses, was studied in Xenopus oocytes by recording membrane currents evoked using lightflash photolysis of caged inositol trisphosphate (caged IP3) to produce rapid and reproducible transients in intracellular IP3 levels. Photolysis of caged IP3 evoked currents which were carried largely by chloride ions and depended upon intracellular, but not extracellular, calcium. A given light flash evoked larger responses when the amount of caged IP3 loaded into the oocyte was increased, and illumination of the vegetal hemisphere gave larger responses than the animal. Long (10 sec) light exposures produced oscillatory currents, resembling responses to serotonin and other agonists, which became larger, more transient, and of shorter latency as the light intensity was increased. Brief (ca. 100 msec) flashes evoked a single "spike" of current. The caged IP3 response showed a threshold, in that light flashes had to be greater than a certain intensity and duration before currents could be detected. Associated with this, sub- and suprathreshold light flashes caused a long-lasting (seconds or minutes) potentiation of responses to subsequent test flashes. The lightflash response was also potentiated by a preceding intracellular injection of IP3 and by extracellular application of an agonist thought to induce IP3 liberation. However, intracellular injections of calcium depressed the response. We conclude that the liberation of calcium from intracellular stores varies nonlinearly with the intracellular level of IP3. This phenomenon may explain earlier observations, including the long latency of currents evoked by low doses of agonists such as acetylcholine and serotonin, and the nonlinear facilitation seen between these agonists. Further, it suggests a mechanism for "chemical integration," which may be important in the functioning of neurons and other cells which use IP3 as an intracellular messenger.

A quantitative description of excitatory amino acid neurotransmitter responses on cultured embryonic Xenopus spinal neurons

We have performed a quantitative analysis of excitatory amino acid neurotransmitter receptors on cultured embryonic Xenopus spinal neurons using the whole-cell patch-clamp technique. Neuroblasts and underlying mesodermal cells isolated from spinal regions of neural plate-stage embryos were placed into dissociated cell culture, and responses were studied soon after the appearance of neurites on embryonic neurons. Glutamate (Glu) receptors were separated into two general classes based on responses to the characteristic agonists quisqualate (Quis), kainate (Ka) and N-methyl- d-aspartate (NMDA); these were NMDA receptors (those activated by NMDA) and non-NMDA receptors (those activated by Ka and Quis). Half-maximal responses to Glu and other agonists on NMDA and non-NMDA receptors were determined from Hill analysis of dose response relations. The order of sensitivities observed was: Glu NMDA(ED 50 = 5.1 μM) >Glu non-NMDA(ED 50 = 28 μM), and for Glu receptor agonists, Quis (ED 50 = 1.5 μM) >NMDA(ED 50 = 41 μM) >Ka(ED 50 = 58 μM). The order of response amplitudes recorded at concentrations near the appropriate ED 50s was Glu NMDA > Glu non-NMDA, and Ka > NMDA > Quis. A 10-fold decrease in external [Na +] shifted the reversal potentials for Glu non-NMDA, Ka, and Quis to more negative voltages. Increasing external [Ca 2+] shifted the reversal potential for NMDA responses to more positive potentials, an observation consistent with Ca 2+ permeation of the embryonic NMDA-activated channel. NMDA-evoked currents could not be recorded in nominally glycine (Gly)-free media. Addition of Gly to external solutions potentiated NMDA responses (ED 50 = 644nM). NMDA responses were blocked by dl-2-amino-5-phosphonovaleric acid (APV;ED 50 = 1.9 μM) and by Mg 2+ at negative potentials. In their sensitivities to agonists and antagonists, and ionic dependences, amino acid neurotransmitter responses on embryonic Xenopus neurons closely resembled those previously observed for mature Xenopus and mammalian central neurons. The Glu NMDA receptors present on these immature neurons were sufficiently sensitive to be activated by endogenous concentrations of extracellular Glu, suggesting a possible role for receptor activation in modulating early neural development.

Human neuroblastoma cells acquire regulated secretory properties and different sensitivity to Ca2+ and alpha-latrotoxin after exposure to differentiating agents.

IMR-32 human neuroblastoma cells are unable to release [3H]dopamine in response to secretagogues. However, they express a normal complement of membrane receptors and ion channels which are efficiently coupled to second messenger production. In the present study we took advantage of the ability of this cell line to differentiate in vitro in the presence of either dibutyrryl-cAMP or 5-bromodeoxyuridine, to analyze any developmentally regulated changes in its secretory properties. Uptake, storage, and release of [3H]dopamine were studied biochemically and by autoradiography. The calcium ionophore ionomycin, phorbol 12-myristate 13-acetate and the presynaptic acting neurotoxin alpha-latrotoxin were used in both control and differentiated cells as secretagogue agents. The presence of secretory organelles was investigated by electron microscopy; the expression of secretory organelle markers, such as chromogranin/secretogranin proteins (secretory proteins) and synaptophysin (membrane protein), was detected by Western blotting and immunofluorescence. The results obtained indicate that IMR-32 cells acquire regulated secretory properties after in vitro drug-induced differentiation: (a) they assemble "de novo" secretory organelles, as revealed by electron microscopy and detection of secretory organelle markers, and (b) they are able to store [3H]dopamine and to release the neurotransmitter in response to secretagogue stimuli. Furthermore, secretagogue sensitivity was found to be different, depending on the differentiating agent. In fact, dibutyrryl-cAMP treated cells release [3H]dopamine in response to alpha-latrotoxin, but not in response to ionomycin, whereas 5-bromodeoxyuridine treated cells release the neurotransmitter in response to both secretagogues. All together these results suggest that IMR-32 cells represent an adequate model for studying the development of the secretory apparatus in cultured human neurons.

Concomitant characterization of behavioral and striatal neurotransmitter response to amphetamine using in vivo microdialysis

The temporal and dose-related behavioral and striatal monoamine response to amphetamine (AMPH) was examined using in vivo microdialysis in freely moving rats. Extracellular dopamine (DA), serotonin (5-HT), and their metabolites were monitored concomitant with detailed characterization of the locomotor and stereotypy profiles. Consistent with previous results, AMPH (0.5-5.0 mg/kg) induced a rapid dose-dependent increase in DA concentration and decrease in the concentrations of the DA metabolites, DOPAC and HVA. DA and its metabolites exhibited contrasting temporal and dose-related patterns, suggesting that the decline in DA metabolites is functionally dissociated from the AMPH-enhanced DA release. In addition, AMPH at doses of 2.0 mg/kg and greater significantly increased extracellular concentrations of 5-HT, which, in contrast to the changes in dopamine, persisted for only 20-40 min. Comparisons of concentrations of DA and 5-HT for individual animals revealed significant correlations both during baseline and drug response, suggesting a possible functional interdependence between dopaminergic and serotonergic activity in striatum. Dose-response comparisons revealed a significant relationship between AMPH-induced increases in behavioral perseveration and the magnitude and duration of the DA release. However, the temporal patterns of the neurotransmitter response and individual components of stereotypy were not parallel, suggesting that the presence of stereotypies is not associated simply with quantitative differences in striatal DA release. By contrast, some features of the behavioral response were significantly correlated with AMPH-induced changes in striatal 5-HT concentrations. Our results suggest that the behavioral response to AMPH may be influenced by the interaction between levels of DA and 5-HT release, as well as by the state of their respective receptors.

Protein kinase C modulates neurotransmitter responses in Xenopus oocytes injected with rat brain RNA

Oocytes of the frog Xenopus laevis express various exogenous neurotransmitter receptors and ion channels when injected with RNA from excitable tissues. The oocytes serve as a convenient model system in which modulation of neurotransmitter responses can be studied. We examined the effects of activators and an inhibitor of protein kinase C (PKC) on responses to serotonin (5-HT), acetylcholine (ACh), kainate, and γ-aminobutyric acid (GABA) in oocytes injected with RNA from rat brain. The PKC activators β-phorbol esters 4β-phorbol-12-myristate-13-acetate (PMA) and 4β-phorbol-12,13-dibutyrate (PDBu), as well as the synthetic diacylglycerol, 1-oleyl-2-acetylglycerol (OAG), significantly inhibited the responses to 5-HT and ACh (both known to be mediated by mobilization of intracellular Ca 2+); the first (transient) phase of these responses was affected stronger than the second, slow phase. PKC activators also reduced the response to GABA. The effect of PDBu on the response to kainate was dual; either inhibition or potentiation were observed at different concentrations of PDBu. The inactive analogue of PMA, the α-PMA, was without effect on the responses to 5-HT and GABA. The PKC inhibitor 1,5-isoquinolinesulfonyl-2-methylpiperazine (H7) suppressed the inhibitory effect of PDBu on 5-HT response. Amiloride, a blocker of the Na +/H + exchange (which is known to be activated by PKC in some tissues), did not suppress the effects of PDBu. We conclude that activation of PKC down-regulates the responses to 5-HT, ACh and GABA, and has a dual effect on response to kainate. Possible mechanisms of these effects are discussed.

Guanosine 5'-triphosphate analogue activates potassium current modulated by neurotransmitters in Aplysia neurones.

1. Identified neurones in the abdominal ganglion of Aplysia californica were voltage clamped in order to investigate how guanosine 5'-O-(3-thiotriphosphate) (GTP-gamma-S), a GTP analogue that irreversibly activates guanine nucleotide-binding (G) proteins, modifies activation by the neuropeptide FMRFamide (Phe-Met-Arg-Phe-NH2) of a slow K+ current resembling the serotonin- and adenosine 3',5'-cyclic monophosphate (cyclic AMP)-sensitive 'S' current, and a similar response to acetylcholine. 2. Ionophoretic or pressure injection of GTP-gamma-S into the cell triggered the slow and irreversible development of a large K+ current, rendered the K+ current responses to FMRFamide and acetylcholine irreversible, and finally, once the GTP-gamma-S-induced current had fully developed, occluded the neurotransmitter responses altogether. 3. The K+ currents activated by GTP-gamma-S and acetylcholine had properties identical to those previously found for the FMRFamide-induced 'S'-like K+ current: they were Ca2+ and voltage independent, relatively insensitive to block by extracellular tetraethylammonium (TEA) and 4-aminopyridine (when high concentrations of acetylcholine were used to overcome an additional block by these agents of the receptor), and suppressed in Ba2+-containing solution, by injection of TEA+ or Cs+ into the cell, and by serotonin and elevation of the intracellular concentration of cyclic AMP. 4. The K+ current responses to FMRFamide and acetylcholine were not additive when the agonist concentrations used were high enough to activate most of the available current. 5. Desensitization of either response did not affect the other, and the effect of acetylcholine, but not that of FMRFamide, could be blocked by the known acetylcholine-receptor blockers phenyltrimethylammonium and TEA. 6. These results suggest that FMRFamide and acetylcholine, acting through different receptors, activate the same 'S'-like K+ current by a mechanism involving a G protein. 7. In addition to activating the slow K+ current, FMRFamide and acetylcholine each activate a faster current in these cells, carried by Na+ in the case of FMRFamide, and by Cl- in the case of acetylcholine. Neither fast response was affected by GTP-gamma-S.

An investigation into the development of calcium-dependent neurotransmitter release from isolated growth cones.

The neuronal growth cone is a motile, expanded region at the tip of the growing axon or dendrite that is responsible for guiding neurites to their correct targets (Ramon y Cajal, 1890). This structure has received great attention in studies attempting to understand the mechanisms by which growing neuronal processes locate and recognize the appropriate sites with which they are to form synapses (Lockerbie, 1987). Once the correct target has been reached, the growth cone plays a central role in synaptogenesis, transforming into either the preor post-synaptic element (Rees, 1978). In this respect, neuronal growth cones are important structures in which to study the development of the mechanisms involved in neurotransmission. It is now clear that in culture, neurotransmitters are present in growing neurites and that the growth cones of these neurites are able to release their neurotransmitters both spontaneously and in response to electrical stimulation (Hume et al., 1983; Young & Poo, 1983). In this laboratory, we have shown that growth cones isolated from developing rat forebrain are able to take up exogenous y['Hlaminobutyric acid (['HIGABA) by a transport mechanism that appears to be identical to that found at mature, GABAergic synapses. Furthermore, growth cones can release this accumulated neurotransmitter in response to high K + stimulation. However, unlike the high K+ stimulated release of ['HIGABA from synaptosomes, the release from growth cones is largely independent of extracellular Ca2 +

Roles of protein kinases in neurotransmitter responses in Xenopus oocytes injected with rat brain mRNA.

Microinjection of rat brain mRNA in Xenopus oocytes induced acetylcholine, neurotensin, serotonin, and glutamate receptors in the cells. These receptors stimulate an intracellular reaction pathway, including G-protein activation, inositol trisphosphate (IP3) formation, and Ca2+-dependent Cl- channels. In the present study, we examined the roles of several protein kinases in these responses by means of inhibitors and activators of these kinases. Isoquinolinesulfonamides, inhibitors of protein kinases, caused no current responses and affected no receptor-mediated responses when injected into the oocytes at low doses (30-50 pmol), which inhibit cyclic nucleotide-dependent kinases or kinase C specifically, but abolished the receptor-mediated responses at a higher dose (300 pmol), which inhibit most protein kinases nonspecifically. Calmodulin inhibitors blocked the receptor-mediated responses strongly. Activation of cyclic nucleotide-dependent kinases or kinase C by injection of cAMP (or cGMP) or perfusion with phorbol esters caused no direct current responses but suppressed receptor-mediated responses. Current responses triggered by IP3 injection were not suppressed by these treatments. These results suggest that cAMP- (or cGMP-)dependent kinases or kinase C may not be involved in the pathway directly but may modulate it by inhibiting the initial part of the pathway (receptors, G-proteins, and/or phospholipase C), and they suggest that calmodulin may most likely be involved in the activation of Ca2+-dependent Cl- channels.

Isolated hippocampal neurons in cryopreserved long-term cultures: Development of neuroarchitecture and sensitivity to NMDA

Isolated neurons in long-term culture provide a unique opportunity to address important problems in neuronal development. In the present study we established conditions for cryopreservation and long-term primary culture of isolated embryonic hippocampal neurons. This culture system was then used for initial characterizations of the development of neuroarchitecture and neurotransmitter response systems. Cryoprotection with 8% dimethylsulfoxide, slow freezing, and rapid thawing provided high-yield cultures which appeared normal in terms of cell types, mitotic ability, axonal and dendritic outgrowth, and sensitivity to glutamate neurotoxicity. A reduced medium volume and moderate elevation in extracellular K+ to 20 mM promoted survival of isolated neurons through 3 weeks of culture. The outgrowth of axons and dendrites in pyramidal-like neurons was found to differ over a 3-week culture period such that axons continued to grow at a relatively constant rate while dendritic outgrowth slowed during the second week and ceased by the end of week 3. Developmental changes were also observed in the sensitivity of pyramidal neurons to glutamate neurotoxicity; functional kainate/ quisqualate receptors were present during the first week of culture, while responses to N-methyl-d-aspartic acid (NMDA) did not appear until the second week. The technologies for cryopreservation and long-term culture of isolated hippocampal neurons reported here provide a useful system in which to address a variety of problems in developmental neuroscience.

Genotypic differences in central neurotransmitter responses to aging in mice

Dopamine, serotonin, cholinergic and somatostatin responses to aging have been followed in striatum and hippocampus of two inbred strains of mice (C57BL and BALB/c). A striking strain dependency is noted. Dopaminergic mechanisms in BALB/c mice become particularly defective in striatum where both dopamine release and dopamine turnover are affected. Also, striatal cholinergic activity and somatostatin levels are more disturbed in BALB/c than in C57BL mice. For cholinergic neurotransmission and somatostatin levels, similar results are noted in hippocampus. Conversely, C57BL mice react to aging by increased serotonin turnover in hippocampus and decreased 5HIAA levels in both structures studied, whereas the BALB/c strain remains unaffected. Also, structure dependency is observed: in C57BL mice serotonin turnover appears to be unchanged in striatum and increased in hippocampus; in the BALB/c the slowing down of dopamine activity in striatum is not observed in hippocampus. This unequal capacity of central neurotransmitters and neuromodulators to adapt to aging processes, depending upon the genotype, the nervous structure and the neurotransmitter considered may be involved in man in specific pathologies in aged individuals.

Regulation of neuronal adenylate cyclase.

It appears that several components function in a spirit of integrated cooperation toward the intracellular regulation of neurotransmitter responsiveness. We have demonstrated that cytoskeletal proteins might interact with GNs and that GNs and GNi might interact with one another. At this juncture, it appears that both of these phenomena might occur only in cells of neural origin. Calmodulin and antidepressants may also affect adenylate cyclase in nervous tissue alone. The effects of AAGTP are different in nervous tissue from other tissues, and experiments with that nucleotide have led to the discovery of a new, 32 kDa GTP-binding protein which appears only in neural crest cells. Appreciation of the intricacies of signal transduction through the adenylate cyclase system are developing along with our understanding of that system. When combined with the complexity of neurotransmitter responsiveness, comprehension of the combined systems remains in its infancy, destined to grow as well as to surprise and delight all who are interested.