Adenosine modulates hypoxia-induced responses in rat PC12 cells via the A2A receptor

1. The present study was undertaken to determine the role of adenosine in mediating the cellular responses to hypoxia in rat phaeochromocytoma (PC12) cells, an oxygen-sensitive clonal cell line. 2. Reverse transcriptase polymerase chain reaction studies revealed that PC12 cells express adenosine deaminase (the first catalysing enzyme of adenosine degradation) and the A2A and A2B adenosine receptors, but not the A1 or A3 adenosine receptors. 3. Whole-cell current- and voltage-clamp experiments showed that adenosine attenuated the hypoxia-induced membrane depolarization. The hypoxia-induced suppression of the voltage-sensitive potassium current (IK(V)) was markedly reduced by adenosine. Furthermore, extracellularly applied adenosine increased the peak amplitudes of IK(V) in a concentration-dependent manner. This increase was blocked by pretreatment not only with a non-specific adenosine receptor antagonist, 8-phenyltheophylline (8-PT), but also with a selective A2A receptor antagonist, ZM241385. 4. Ca2+ imaging studies using fura-2 acetoxymethyl ester (fura-2 AM) revealed that the increase in intracellular free Ca2+ during hypoxic exposure was attenuated significantly by adenosine. Voltage-clamp studies showed that adenosine inhibited the voltage-dependent Ca2+ currents (ICa) in a concentration-dependent fashion. This inhibition was also abolished by both 8-PT and ZM241385. 5. The modulation of both IK(V) and ICa by adenosine was prevented by intracellular application of an inhibitor of protein kinase A (PKA), PKA inhibitor fragment (6-22) amide. In addition, the effect of adenosine on either IK(V) or ICa was absent in PKA-deficient PC12 cells. 6. These results indicate that the modulatory effects of adenosine on the hypoxia-induced membrane responses of PC12 cells are likely to be mediated via activation of the A2A receptor, and that the PKA pathway is required for these modulatory actions. We propose that this modulation serves to regulate membrane excitability in PC12 cells and possibly other oxygen-sensitive cells during hypoxia.

Defective endothelium-dependent relaxation of vascular smooth muscle and endothelial cell Ca2+ signaling in mice lacking sarco(endo)plasmic reticulum Ca2+-ATPase isoform 3

Sarco(endo)plasmic reticulum Ca2+ ATPase isoform 3 (SERCA3) is one of two Ca2+ pumps serving intracellular Ca2+ signaling pools in non-muscle tissues; however, unlike the ubiquitous SERCA2b, it exhibits a restricted cell-type distribution. Gene targeting was used to generate a mouse with a null mutation in the SERCA3 gene. Homozygous mutant mice were viable, fertile, and did not exhibit an overt disease phenotype. Because SERCA3 is expressed in arterial endothelial cells, aortic ring preparations were analyzed to determine whether it is involved in the regulation of vascular tone. Contraction-isometric force relations in response to phenylephrine or KCl, as well as relaxation produced by exposure to a nitric oxide donor, were similar in wild-type and null mutant aortas. Acetylcholine-induced endothelium-dependent relaxation of aortas after precontraction with phenylephrine was significantly reduced in homozygous mutants (61.3 +/- 5.6% in wild type, 35.4 +/- 7.3% in mutants). Ca2+ imaging of cultured aortic endothelial cells demonstrated that the acetylcholine-induced intracellular Ca2+ signal is sharply diminished in SERCA3-deficient cells and also indicated that replenishment of the acetylcholine-responsive Ca2+ stores is severely impaired. These results indicate that SERCA3 plays a critical role in endothelial cell Ca2+ signaling events involved in nitric oxide-mediated relaxation of vascular smooth muscle.

Loss of protein kinase C inhibition in the beta-T594M variant of the amiloride-sensitive Na+ channel

We previously reported the presence of a novel variant (beta-T594M) of the amiloride-sensitive Na+ channel (ASSC) in which the threonine residue at position 594 in the beta-subunit has been replaced by a methionine residue. Electrophysiological studies of the ASSC on Epstein-Barr virus (EBV)-transformed lymphocytes carrying this variant showed that the 8-(4-chlorophenylthio) adenosine 3':5'-cyclic monophosphate (8cpt-cAMP)-induced responses were enhanced when compared to wild-type EBV-transformed lymphocytes. Furthermore, in wild-type EBV-transformed cells, the 8cpt-cAMP-induced response was totally blocked by the phorbol ester, phorbol 12-myristate 13-acetate (PMA). This inhibitory effect of PMA was blocked by a protein kinase C inhibitor, chelerythrine. We now have identified individuals who are homozygous for this variant, and showed that PMA had no effect on the 8cpt-cAMP-induced responses in the EBV-transformed lymphocytes from such individuals. Cells heterozygous for this variant showed mixed responses to PMA, with the majority of cells partially inhibited by PMA. Our results demonstrate that an alteration in a single amino acid residue in the beta-subunit of the ASSC can lead to a total loss of inhibition to PMA, and establish the beta-subunit as having an important role in conferring a regulatory effect on the ASSC of lymphocytes.

Norepinephrine-mediated calcium signaling is altered in vascular smooth muscle of diabetic rat

We studied the influence of diabetes on norepinephrine (NE)-induced changes in intracellular free Ca2+ levels (receptor-mediated Ca2+ signaling) in single tail artery vascular smooth muscle (VSM) cells. VSM cells from 12-16 week streptozotocin-induced diabetic (SID) rats showed an increase in sensitivity to NE when compared to control VSM cells in that the concentration of NE needed to elicit half maximal response of the initial Ca2+ transient was reduced more than 4-fold though the maximal response attained was apparently reduced. In addition, the slope factor (steepness) of the dose-response relation was lowered 4-fold. Moreover, VSM cells of diabetic animals had a higher incidence of NE-induced Ca2+ oscillatory responses. The shift of the dose-response curve to the left, coupled with a higher incidence of oscillations, indicate that the noradrenergic receptor-mediated Ca2+ signaling pathways in tail artery VSM of diabetic rat may be altered.

A novel variant of the beta-subunit of the amiloride-sensitive sodium channel in African Americans

The amiloride-sensitive sodium channel is responsible for the rate-limiting step of sodium reabsorption in the distal renal tubule, and thus may play a key role in the maintenance of sodium balance and blood pressure. In this study, a genetic variant that results in a change of threonine to methionine at amino acid 594 (T594 M) in the carboxy-terminus of the beta-subunit of the amiloride-sensitive sodium channel has been identified. This variant was present in 6.1% of African-American subjects (N = 231) but was not seen in Caucasians (N = 192). Whole cell voltage clamp of B-lymphocytes from individuals with the T594 M variant showed similar basal membrane slope conductance, compared with the wild-type but increased response to cAMP analog.

Persistence of the olfactory receptor current in a wide variety of extracellular environments

We measured the current activated by cytoplasmic adenosine 3':5'-cyclic monophosphate (cAMP) in olfactory cilia from the frog Rana pipiens. The odorant-induced current in frog olfactory receptor neurons was also measured for comparison. In both cases, recordings were performed near the neuronal resting potential in a variety of extracellular bath solutions. 2. In Ca(2+)-free baths, cAMP activated an inward current in excised olfactory cilia that was carried entirely by cations. As extracellular Ca2+ was increased, the cationic current decreased while a second current, carried by C1-, increased. Total cAMP-activated current decreased with increasing extracellular CA2+. When external Na+ but not Ca2+ was eliminated, only the C1- component of the current persisted. When external Na+ and Ca2+ were both removed, there was no cAMP-activated current. 3. In receptor neurons, the total odorant-induced receptor current varied in a similar way with the extracellular ionic environment. Under conditions favoring the anionic receptor current, the response amplitude decreased and the latency increased. 4. It is known that olfactory receptor currents persist in a wide variety of extracellular environments. This persistence can be sufficiently explained by the balance between cationic and anionic currents demonstrated here.

Guanine nucleotides modulate steady-state inactivation of voltage-gated sodium channels in frog olfactory receptor neurons

The voltage for half-inactivation (V1/2) of Na+ currents in frog olfactory receptor neurons (ORNs) under whole-cell voltage clamp showed a shift to more negative potentials with time. Inclusion of guanosine triphosphate (GTP) or its nonhydrolyzable analogue, guanosine-5'-O-3-thiotriphosphate (GTP-gamma-S), which activates G proteins, in the recording pipette, not only gave a more positive V1/2, but also reduced and delayed the negative shift observed in the absence of nucleotides. Guanosine-5'-O-2-thiodiphosphate (GDP-beta-S), a nonhydrolyzable analogue that prevents the binding of GTP to G proteins, did not affect the V1/2 significantly by itself but blocked the positive shift induced by GTP. Since the steady-state activation was not affected, our results indicate that a G protein or a G-protein-dependent process may be important in regulating the steady-state inactivation of Na+ channels in ORNs of the frog.

G-protein activation mediates prepulse facilitation of Ca2+ channel currents in bovine chromaffin cells

The effects of G-protein activation were investigated on tonic, large depolarization-induced Ca2+ channel facilitation in cultured bovine adrenal chromaffin cells. Under whole-cell voltage clamp, activation of G proteins by intracellular dialysis with 200 microM GTP-gamma S did not significantly affect prepulse facilitation or whole-cell Ba2+ current (IBa) density. In contrast, inactivation of G proteins by intracellular GDP-beta S or pertussis toxin (PTX) pretreatment completely abolished or markedly attenuated facilitation of IBa, respectively. GDP-beta S dialysis resulted in nearly a threefold increase in peak IBa density, whereas PTX pretreatment resulted in a 50% increase. Our results indicate that under control recording conditions (200 microM intracellular GTP), G proteins are tonically activated and suppress high-voltage-activated (HVA) Ca2+ channels in a voltage-dependent and voltage-independent manner. Local superfusion of chromaffin cells with normal bath solution produced a rapid and reversible increase (approximately 50%) in IBa amplitudes that also abolished prepulse facilitation. Together, these results demonstrate that tonic facilitation of HVA Ca2+ channels in bovine chromaffin cells involves the voltage-dependent relief of a G-protein-mediated suppression, imposed by chromaffin cell secretory products that feedback and activate G-protein-coupled autoreceptors.

Angiotensin II suppresses Na+ currents in bovine adrenal chromaffin cells

We investigated the effects of angiotensin II (ANG II) on the voltage-dependent Na+ channel currents (INa) recorded from bovine adrenal medullary chromaffin cells (BCCs) under whole-cell voltage clamp. Angiotensin II reversibly reduced the peak INa in a dose-dependent fashion. Inhibition was observed at a concentration of 1 nM (6.3 +/- 1.4%, mean +/- SEM) and reached a maximum at 1 microM (35 +/- 3.8%), with a half-maximal effect at 11.6 nM. The ANG II-induced inhibition resulted from a reduction in peak conductance (control, 7.2 +/- 0.7 nS; ANG II 4.3 +/- 0.5 nS; p < 0.01). Angiotensin II had no effect on the reversal potential or the decay time of INa. In addition, the V1/2 and k values, two parameters that describe the voltage dependence of INa for both steady-state activation and inactivation, were not affected by ANG II. The response to ANG II (1 microM) had a delay and attained maximum inhibition in 0.9 +/- 0.2 min (n = 10). Recovery from the effect was slow and took 3.5 +/- 0.8 min (n = 10) after the application of ANG II had been terminated. The inhibitory effects of ANG II were effectively blocked by a specific ANG II receptor antagonist. [Sar1, Val5, Ala8]ANG II. The present study demonstrates that ANG II inhibits voltage-dependent INa+ channel currents in BCCs via a specific receptor-coupled mechanism. The prolonged time course of the ANG II response indicates a possible involvement of second messenger(s) mediating this inhibition.

Activation of serotonin1A receptors inhibits midbrain periaqueductal gray neurons of the rat

The midbrain periaqueductal gray (PAG) is involved in a variety of functions including pain modulation, vocalization, autonomic control, fear and anxiety. This area contains serotonin receptors, particularly 5-HT1A that are known to play a role in the above functions. The goals of this study were to characterize the effects of 8-OH-DPAT, a selective 5-HT1A agonist, on the firing characteristics and membrane properties of PAG neurons. Both in vivo and in vitro preparations were used. The effects of 8-OH-DPAT on baseline activity of 91 neurons were tested in the in vivo preparation. In 50/91 cells, 8-OH-DPAT produced a decrease in the firing rate that ranged between 21 and 98% (mean +/- S.E.M. decrease of 49 +/- 1.9%). This inhibitory effect was dose dependent and could be blocked by spiperone. In 10/91 cells, 8-OH-DPAT produced an increase in the firing rate that ranged between 13 and 290%, with mean increase of 83 +/- 7.4%. The baseline firing rate of the remaining 31 cells was not affected by 8-OH-DPAT. In the PAG slice preparation, the effects of 8-OH-DPAT on synaptic and membrane properties of 17 PAG neurons were tested using whole-cell voltage clamp-recording procedures. In 14 cells, application of 8-OH-DPAT produced hyperpolarization that ranged between 6 and 21 mV, with mean of 8.4 +/- 2.0 mV. This hyperpolarization was associated with a decrease in membrane impedance that ranged between 8 and 45%, with mean decrease of 21.6 +/- 4.5%. The remaining three neurons did not respond to 8-OH-DPAT.(ABSTRACT TRUNCATED AT 250 WORDS)

Cyclic AMP-dependent phosphorylation modifies the gating properties of L-type Ca2+ channels in bovine adrenal chromaffin cells

We investigated the effects of cAMP-dependent phosphorylation on the voltage- and time-dependent gating properties of Ca2+ channel currents recorded from bovine adrenal chromaffin cells under whole-cell voltage clamp. Extracellular perfusion with the membrane-permeant activator of cAMP-dependent protein kinase, 8-bromo(8-Br)-cAMP (1 mM), caused a 49%, 29%, and 21% increase in Ca2+ current (ICa) amplitudes evoked by voltage steps to 0, +10, and +20 mV respectively (mean values from eight cells, p less than or equal to 0.05). Analysis of voltage-dependent steady-state activation (m infinity) curves revealed a 0.70 +/- 0.27 charge increase in the activation-gate valency (zm) following 8-Br-cAMP perfusion. Similar responses were observed when Ba2+ was the charge carrier, where zm was increased by 1.33 +/- 0.34 charges (n = 8). The membrane potential for half activation (V1/2) was also significantly shifted 6 mV more negative for IBa (mean, n = 8). The time course for IBa (and ICa) activation was well described by second-order m2 kinetics. The derived time constant for activation (tau m) was voltage-dependent, and the tau m/V relation shifted negatively after 8-Br-cAMP treatment. Ca2+ channel gating rates were derived from the tau m and m infinity 2 values according to a Hodgkin-Huxley type m2 activation process. The forward rate (alpha m) for channel activation was increased by 8-Br-cAMP at membrane potentials greater than or equal to 0 mV, and the backward rate (beta m) decreased at potentials less than or equal to + 10 mV. Time-dependent inactivation of ICa consisted of a slowly decaying component (tau h approximately 300 ms) and a "non-inactivating" steady-state component. The currents contributed by the two inactivation processes displayed different voltage dependences, the effects of 8-Br-cAMP being exclusively on the slowly inactivating L-type component.

Long-term monitoring of depolarization-induced exocytosis from adrenal medullary chromaffin cells and pancreatic islet B cells using "perforated patch recording"

(1) Membrane capacitance measurements using perforated patch recording offer the possibility of studying the process of depolarization-secretion coupling (DSC) in single endocrine cells with unprecedented time resolution and stability. (2) Early results with catecholamine-secreting adrenal chromaffin cells and insulin-secreting pancreatic B cells support longstanding ideas that the Ca(2+)-dependent processes underlying DSC are fundamentally similar to those of nerve terminals. (3) Future experiments using these approaches should prove useful in sorting out those effects of humoral substances that have a predominant effect on excitability and Ca2+ entry from those that affect the secretory process itself.

Single cell assay of exocytosis from adrenal chromaffin cells using "perforated patch recording"

We have combined "perforated patch recording" with phase detection to examine depolarization-induced changes in membrane capacitance (delta Cm) in bovine adrenal chromaffin cells. With this technique, voltage dependent Ca2+ currents and resultant delta Cm's often show little rundown over 1-2 hours even when the free Ca2+ concentration of the pipette is in the millimolar range. By limiting washout of cytosolic components and by maintaining more intact cytosolic Ca2+ buffering, this approach should facilitate the study of stimulus-exocytosis coupling evoked by physiological stimuli which involve cell metabolism and/or membrane receptor triggered second messenger cascades.

Somatic sodium channels of frog olfactory receptor neurones are inactivated at rest

Membrane excitability of acutely isolated olfactory receptor neurones (ORNs) of the grass frog (R. pipiens) was studied with the use of the whole-cell "tight-seal" patch recording technique. ORNs of the frog had a mean resting membrane potential of -52 mV, a mean input resistance of 1-2 G omega, and a mean capacitance of 4.5 pF. In the majority of cells examined (over 70%), short duration (several milliseconds) action potentials were elicited at the end of a hyperpolarising pulse (off-spike) or following hyperpolarization of the membrane potential by injection of current. Under voltage-clamp conditions, a fast inward current followed by an outward current could be evoked upon depolarisation of the membrane. The fast inward current decayed with a time constant of 1-2 ms, with an e-fold decrease per 52 mV increase in voltage, and was blocked by the selective voltage-dependent sodium channel blocker tetrodotoxin (0.5-1 microM). Steady-state inactivation studies revealed that the mean voltage for half-inactivation (V1/2) was -82 mV (range -72 to -98 mV), which indicates that the voltage-dependent Na+ channels in the cell body or soma of frog ORNs are not available for conducting currents at the resting membrane potential. This finding raises the possibility that voltage-dependent Na+ channels may not play a significant role in sensory transduction at the soma. Our results indicate that ORNs of the frog are very efficient in transducing signals towards the brain since currents generated at the cilia will be directed towards depolarising the axons.(ABSTRACT TRUNCATED AT 250 WORDS)

Cultured rat olfactory neurons are excitable and respond to odors

Newborn rat nasal tissues containing olfactory epithelium were dissociated and maintained in a monolayer cell culture. Neurons were present, as determined by immunostaining with antibodies to 4 neuron-specific proteins: neuron-specific enolase, microtubule-associated protein 2, tau protein and synaptophysin. Immunostained neurons had a distinctive morphology resembling olfactory neurons. By patch-clamp analysis, these cells were electrically active. Responses of some neurons to physiological concentrations of an odorant mixture identified them as olfactory receptor cells.

Thyrotropin-releasing hormone has profound presynaptic action on cultured spinal cord neurons

Thyrotropin-releasing hormone (TRH) receptors are widely distributed throughout the nervous system. In particular, both the dorsal and the ventral horn (VH) neurons contain a rich distribution of TRH receptors, and TRH application to these sites has profound physiological effects. Currently the mechanism of action of TRH is not known. We examined the effect of TRH on ventral horn neurons using intracellular and patch-clamp techniques. Our results indicate that TRH application profoundly increases the firing rate of VH cells by decreasing membrane conductance. More importantly, TRH causes a significant increase in frequency and amplitude of postsynaptic potentials. Under voltage-clamp condition, TRH reduces holding current and causes a significant increase in the rate of occurrence and the amplitude of excitatory postsynaptic currents (EPSCs), an effect that lasts for more than 5 minutes. This effect of TRH is not observed in cultured neurons pretreated with tetanus toxin. TRH also fails to alter the characteristics of the EPSCs when it is applied to a region of the cell that is sparsely innervated. These results provide strong evidence that presynaptic mechanisms have a significant role in the excitatory effect of TRH on the VH neurons. Because there is evidence that trophic factors are released from presynaptic terminals, by increasing synaptic activity, TRH can have a trophic influence on the spinal cord neurons. In addition, because there are a significant number of TRH containing neurons within the spinal cord, it is likely that TRH has a major role in information processing within the spinal cord.

A rapidly inactivating Ca2(+)-dependent K+ current in pheochromocytoma cells (PC12) of the rat

The membrane electrical properties of undifferentiated pheochromocytoma cells of the rat (PC12) were studied using both current- and voltage-clamp techniques with the use of low-resistance blunt-tipped micropipettes (patch electrodes). In the presence of tetrodotoxin (TTX, 2-3 microM), a spike-like wave form with a prominent after-hyperpolarization (AHP) was recorded following brief (less than 10 ms) depolarizing current pulses. The inorganic divalent cations, Cd2+ (0.5 mM), Mn2+ (4 mM), and 0 mM Ca2+/4 mM Mg2+ solution prolonged the duration, attenuated the AHP, slowed the rate of repolarization, and slightly enhanced the amplitude of this wave form. A rapidly inactivating outward current was recorded in over 70% of the cells under voltage-clamp conditions. This transient current was elicited at about -30 mV, and was blocked by tetraethylammonium (5 mM), inorganic divalent cations (Cd2+, 0.5 mM; Mn2+, 4 mM; Ba2+, 3 mM), and removal of Ca2+ (0 mM Ca2+/4 mM Mg2+) from the local perfusion medium. In addition, 4-aminopyridine (5 mM), which blocks the transient outward K+ current IA in a variety of excitable cells, did not have any appreciable effect on this rapidly inactivating current. Moreover, it was possible to elicit the current at a holding potential of -40 mV. The reversal potential of this current was -90 mV, and shifted positively when extracellular K+ concentrations were elevated. It is concluded that PC12 cells have a rapidly inactivating Ca2(+)-dependent K+ current. A possible explanation for the transient nature of this current may be the presence of an effective intracellular Ca2+ buffering (uptake or extrusion) system.

Voltage clamping with single microelectrodes: comparison of the discontinuous mode and continuous mode using the Axoclamp 2A amplifier

The voltage clamp technique is a powerful method for studying the physiology of excitable membrane. This technique has made possible the determination of ionic responses generated by activation of either receptor-mediated or voltage-dependent processes. The development of the whole-cell, 'tight-seal' voltage clamp method has allowed the analysis and examination of membrane physiology at the single cell level. The method allows the characterization of voltage-dependent ionic conductances both at the macroscopic (whole-cell) and at the microscopic (unitary conductance or single channel) level in cells less than 10 micron in diameter, a feat difficult to achieve with 'conventional' fine-tipped micropipettes. In this paper, several methologies used for culturing neuronal and non-neuronal cells in the laboratory are described. A comparison between the two modes of voltage clamp using blunt-tipped 'patch'-microelectrodes, the switching (discontinuous) and the non-switching (continuous) modes, of the Axoclamp-2A amplifier is made. Some results on membrane currents obtained from neuronal and non-neuronal cells using the single electrode whole-cell 'tight-seal' voltage clamp is illustrated. The possible existence of two inactivating K+ currents, one dependent on Ca++ the other is not, is discussed.

Active and inactive central synapses in cell culture

Synaptic interactions between pairs of spinal cord (SC) neurons and between dorsal root ganglion neurons and SC neurons were studied in dissociated cell cultures prepared from fetal mouse. Combined injection of horseradish peroxidase into presynaptic neurons and Lucifer yellow into postsynaptic neurons allowed detailed correlation of morphological-physiological analyses of synaptically linked cells. Statistical analysis of trains of evoked EPSPs under conditions of high and of low transmitter output was used to determine the number of physiological release elements, n, involved in a given synaptic connection. When n was compared with the number of boutons subserving a synaptic connection, it was found that in 80% of cases the number of boutons was equal to or greater than the number of release elements. In some cases, the bouton count was more than fivefold greater than n. The simplest explanation is that, in general, one bouton can release no more than one quantum of transmitter and, in a significant proportion of synaptic connections, a large fraction of boutons do not participate in the release process. Theoretical consideration and analysis of the electrotonic structure of some of the neurons studied indicate that the dendritic location of synaptic inputs does not affect our results. Variations in the probability of release, p, may contribute to the apparent disparity between n and bouton number. If so, this variation must be large with many boutons having a very low p, difficult to distinguish experimentally from zero.

Synaptic excitation in cultures of mouse spinal cord neurones: receptor pharmacology and behaviour of synaptic currents

Fast monosynaptic excitatory post-synaptic potentials between spinal cord neurones in cell culture (s.c.-s.c. e.p.s.p.s) were studied with current-clamp and two-electrode voltage-clamp methods. The reversal potential, response to acidic amino acid antagonists, and behaviour of the synaptic current were examined. The amplitude of the e.p.s.p. increased with membrane potential hyperpolarization and decreased with depolarization. The reversal potential of the e.p.s.p. was +3.8 +/- 2.5 mV (mean +/- S.E. of mean). The reversal potential for responses to ionophoretically applied L-glutamate and L-aspartate was also near 0 mV. The acidic amino acid antagonist, cis-2,3-piperidine dicarboxylic acid (PDA, 0.25-1.0 mM) reversibly antagonized the monosynaptic e.p.s.p.s as well as responses to kainate (KA) or quisqualate (QA). The selective N-methyl-D-aspartate antagonist, (+/-) 2-amino-5-phosphonovaleric acid (APV), had little effect on either the monosynaptic e.p.s.p.s or responses to QA or KA at concentrations that abolished responses to L-aspartate. Under voltage clamp, the peak synaptic current (e.p.s.c.) was linearly related to the membrane potential, increasing in amplitude with hyperpolarization and decreasing with depolarization from the resting potential. The decay of a somatic e.p.s.c. was well fitted by a single exponential function with a time constant of 0.6 ms at 25 degrees C. E.p.s.c.s which had proximal dendritic locations had decay time constants of 1-2 ms. The decay time constant was voltage-insensitive between -80 and +10 mV. We suggest that an acidic amino acid receptor other than that for NMDA mediates excitatory transmission at the s.c.-s.c. synapse; and that the underlying conductance mechanism is voltage insensitive with an estimated mean channel lifetime of less than 1 ms.

Effects of nitrendipine on the voltage-sensitive calcium channel in mammalian sensory neurons

We examined the ability of nitrendipine, a calcium antagonist believed to block the voltage-sensitive calcium channels in a number of excitable membranes, to affect the calcium spike duration and rate of rise (Dv/Dt) in 4-week-old cultured mouse dorsal root ganglion neurons. Concentrations of 10 nM-1.0 microM nitrendipine reduced but did not eliminate calcium spike as measured by the rate of rise. These results were obtained at either 22 degrees or 37 degrees C in solutions containing 5 mM calcium. A similar lack of total block was seen with prolonged incubation in sodium-free recording media containing 1 microM tetrodotoxin (TTX), 1.8 mM calcium, and 1 microM nitrendipine. Calcium spike duration was affected in an inconsistent manner by nitrendipine and other 1,4 dihydropyridines. Cobalt (10 mM) totally blocked the voltage-dependent calcium mechanism as measured by either the spike duration or the rate of rise. We conclude that calcium influx through the voltage-sensitive calcium channel in mouse dorsal root ganglion neurons is not blocked by even high concentrations of nitrendipine.

Noradrenergic responses of spinal neurons in locus coeruleus-spinal cord co-cultures

Locus coeruleus (LC) explants were co-cultured with dissociated spinal neurons of mice. Nerve fibers exhibiting catecholamine fluorescence radiated from the explants and frequently invested spinal cord (SC) neurons close to the explants. Electrical stimulation of the explant and iontophoretic application of norepinephrine evoked a spectrum of slow depolarizing, hyperpolarizing, and biphasic responses in the SC cells. The responses to LC stimulation and to application of norepinephrine were usually similar in a given cell. The depolarizing responses were associated with an increase in apparent input resistance and pharmacologic tests indicated that the responses were mediated by alpha-receptors. Neurons in regions innervated by catecholamine-containing fibers usually gave depolarizing responses to LC stimulation and such neurons had a very high probability of exhibiting depolarizing responses to applied norepinephrine. It would appear that either locus coeruleus explants favored the survival of cells with alpha-receptors or expression of these receptors in SC neurons was induced by innervation of the neurons by locus coeruleus axons.

Synaptic interactions between mammalian central neurons in cell culture. I. Reversal potential for excitatory postsynaptic potentials

Intracellular recording and stimulation techniques were used to study the electrical properties of neurons in cell cultures from fetal mouse spinal cord (SC). The morphology of SC neurons and the distribution on SC neurons of boutons formed by synaptically connected SC or dorsal root ganglion (DRG) neurons were demonstrated with horseradish peroxidase (HRP) injection. Postsynaptic polarization in conjunction with synaptic activation of SC neurons was used to determine the reversal potential for excitatory postsynaptic potentials (EPSPs). Tetraethylammonium ions were injected postsynaptically in order to obtain reversal of the EPSPs. Both SC-SC and DRG-SC excitatory connections could be reversed by postsynaptic depolarization. The average reversal potential for the SC-SC EPSP was -4 +/- 12.2 (SD) mV and that for the DRG-SC EPSP was +8 +/- 7.9 (SD) mV, a statistically significant difference (Wilcoxon two-sample rank; P less than 0.05). Scatter was quite large, particularly for the SC-SC connection. While some neurons gave clear electrophysiological evidence of significant dendritic effects, the average total electrotonic length was small (0.58 +/- 0.65 (SD) of a length constant). The morphological extent of the dendrites of SC neurons was substantially less than that of mature motoneurons in vivo. We concluded that both SC-SC and DRG-SC EPSPs were mediated by a conventional conductance increase and that most synaptic input was not far removed electrically from the recording site in the neuron cell body.

Synaptic interactions between mammalian central neurons in cell culture. II. Quantal Analysis of EPSPs

The presynaptic release mechanism involved in excitatory synaptic connections between neurons in cell cultures of fetal mouse spinal cord were studied by statistical analysis of intracellularly recorded postsynaptic responses. Quantal parameters were determined for the EPSPs evoked in spinal cord (SC) neurons by stimulation of either other SC or dorsal root ganglion (DRG) neurons. Transmitter release was manipulated by varying the Ca2+ and Mg2+ content of the culture medium. The release process was represented better by binomial than by Poisson statistics. A method was derived for obtaining the probability of release and the number of release elements. The quantal content and the number of release elements were substantially higher for the SC-SC connection than for the DRG-SC connection. This was partially compensated for by a larger quantal amplitude for the DRG-SC connection. There was some indication that the probability of release was higher for the SC-SC connection. The relationship between transmitter output and effective external Ca2+ ion concentration was approximately linear.

A coeruleo-spinal system in culture

In combined cultures of dissociated spinal neurons and explants from the region of locus coeruleus, rich catecholamine-containing fiber projections from the explant to the surrounding regions of spinal neurons were demonstrated by fluorescence histochemistry. Electrical stimulation of the explant resulted in slow depolarizing responses in many of the spinal neurons. Cells exhibiting this type of response were also usually depolarized by local application of noradrenaline, whereas other, unresponsive neurons usually were not. The depolarizing responses to electrical stimulation and to noradrenaline were both increased by depolarizing current injection and decreased by hyperpolarizing current. These and other data suggest that the depolarizing responses of the spinal neurons to explant stimulation are mediated by noradrenaline released from axons of locus coeruleus neurons.

Comparison of the effects of methoxamine with those of noradrenaline and phenylephrine on single cerebral cortical neurones

1 The technique of microelectrophoresis was used to compare the actions of methoxamine, noradrenaline and phenylephrine on single neurones in the somatosensory cerebral cortex of the rat.2 Methoxamine evoked only excitatory responses on cortical neurones. The methoxamine-sensitive cells were also excited by phenylephrine; cells excited by methoxamine could either be excited or depressed by noradrenaline.3 Methoxamine appeared to be less potent than either noradrenaline or phenylephrine in evoking excitatory responses.4 Responses to methoxamine had a slower time course than responses to either noradrenaline or phenylephrine, both the latencies to onset and the recovery times being longer for responses to methoxamine than for responses to noradrenaline or phenylephrine.5 When the absolute mobilities of methoxamine, noradrenaline and phenylephrine were compared using an in vitro method, no significant differences were found between the mobilities of the three ionic species, suggesting that the three drugs have similar transport numbers. Thus the differences in potency between methoxamine and the other two drugs, and the difference between the time courses of responses to methoxamine and the other two drugs, are presumably of biological origin.6 The alpha-adrenoceptor antagonist, phenoxybenzamine, antagonized equally excitatory responses to methoxamine and noradrenaline, and responses to methoxamine and phenylephrine, without affecting responses to acetylcholine.7 When responses to methoxamine and noradrenaline and responses to methoxamine and acetylcholine were summated on the same cells, the net responses were smaller than those expected on the basis of additive effects; the deviation from additivity was greater in the case of the summation of responses to methoxamine and noradrenaline than in the case of summation of responses to methoxamine and acetylcholine. This observation is consistent with the hypothesis that the interaction between methoxamine and noradrenaline follows the model of competitive dualism, whereas the interaction between methoxamine and acetylcholine follows the model of functional synergism.8 The results suggest that methoxamine may act as a partial agonist at excitatory alpha-adrenoceptors on cerebral cortical neurones.

A procedure for comparing the mobilities of unlabeled drugs used in microelectrophoresis experiments

A novel method for comparing the absolute mobilities of unlabeled compounds released from micropipettes in microelectrophoresis experiments is described. The method is based on the principle that the introduction of a "foreign" ion into an electrolyte reduces the transport number of a "reference" ion present in the electrolyte. Using [14C]-noradrenaline as the "reference" ion, the mobilities of two "foreign" ions, methoxamine and phenylephrine, were compared. No significant difference was found between the mobilities of the two drugs. It was concluded that the two drugs probably have similar transport numbers when released from solutions of equal molarity in microelectrophoresis experiments in vivo, and thus the previously reported difference between the apparent potencies of the two drugs is presumably of biological origin. The method described here may be of use in comparing the mobilities of other compounds, the radiolabeled forms of which are either unavailable or prohibitively expensive.

The action of microelectrophoretically applied (3,4-dihydroxy-phenylamino)-2-imidazoline (DPI) on single cortical neurones

1. The technique of microelectrophoresis was used in order to compare the actions of the imidazoline derivative, (3,4-dihydroxy-phenylamino)-2-imidazoline (DPI), with those of dopamine and phenylephrine on single neurones in the cerebral cortex of the rat anaesthetized with halothane. 2. DPI and phenylephrine were almost exclusively excitatory, whereas dopamine could evoke both excitatory and depressant responses. 3. In the case of excitatory responses, DPI appeared to be more potent than dopamine, and was approximately equipotent with phenylephrine. 4. The dopamine antagonist, haloperidol, could discriminate between excitatory responses to DPI and dopamine: responses to dopamine were abolished, whereas responses to DPI, and to a control agonist, acetylcholine, were unaffected. 5. The alpha-adrenoceptor antagonist, phenoxybenzamine, antagonized equally excitatory responses to DPI and phenylephrine. Responses to acetylcholine were not affected. 6. It is concluded that DPI does not stimulate dopamine receptors on cortical neurones; the excitatory responses of these cells to DPI may be mediated by alpha-adrenoceptors.

Comparison of the responses of single cortical neurones to tyramine and noradrenaline: effects of desipramine

1 The technique of microelectrophoresis was used in order to compare the actions of tyramine and noradrenaline on single neurones in the cerebral cortex of the rat.2 Tyramine could both excite and depress cortical neurones. Each tyramine-sensitive cell was also sensitive to noradrenaline. There was a high correlation between the directions of responses to tyramine and noradrenaline, most cells excited by tyramine being excited by noradrenaline, and most cells depressed by tyramine being depressed by noradrenaline.3 In the case of both excitatory and depressant responses, tyramine appeared to be less potent than noradrenaline.4 Tyramine evoked ;slower' responses than noradrenaline, both the latencies to onset and the recovery times being longer for responses to tyramine than for responses to noradrenaline.5 When the rates of release of tyramine and noradrenaline from micropipettes were measured in vitro, no significant difference could be observed between the transport numbers of the two drugs. Thus the difference in potency between the two drugs, and the difference in the time courses of responses to the two drugs, are presumably of biological origin.6 Desipramine could discriminate between neuronal responses to tyramine and noradrenaline: responses to tyramine were antagonized, while responses to noradrenaline were either potentiated or unaffected. Responses to DL-homocysteic acid were not affected by desipramine.7 The results are consistent with the hypothesis that tyramine is an indirectly acting sympathomimetic amine in the brain, and desipramine acts by blocking the uptake of both tyramine and noradrenaline into presynaptic noradrenergic nerve terminals.