Odor-stimulated phosphatidylinositol 3-kinase in lobster olfactory receptor cells

Two antagonists of phosphoinositide 3-OH kinases (PI3Ks), LY294002 and Wortmannin, reduced the magnitude of the receptor potential in lobster olfactory receptor neurons (ORNs) recorded by patch clamping the cells in vivo. An antibody directed against the c-terminus of human PI3K-P110 beta detected a molecule of predicted size in the outer dendrites of the ORNs. Two 3-phosphoinositides, PI(3,4)P(2) (1--4 microM) and PI(3,4,5)P(3) (1--4 microM) applied to the cytoplasmic side of inside-out patches taken from cultured lobster ORNs, reversibly activated a Na(+)-gated channel previously implicated in the transduction cascade in these cells. 3-Phosphoinositides were the most effective phosphoinositide (1 microM) in enhancing the open probability of the channel. Collectively, these results implicate 3-phosphoinositides in lobster olfactory transduction and raise the need to consider the 3-phosphoinositide pathway in olfactory transduction.     

Cyclic AMP cascade mediates the inhibitory odor response of isolated toad olfactory receptor neurons

Odor stimulation may excite or inhibit olfactory receptor neurons (ORNs). It is well established that the excitatory response involves a cyclic AMP (cAMP) transduction mechanism that activates a nonselective cationic cyclic nucleotide-gated (CNG) conductance, accompanied by the activation of a Ca2+-dependent Cl(-) conductance, both causing a depolarizing receptor potential. In contrast, odor inhibition is attributed to a hyperpolarizing receptor potential. It has been proposed that a Ca2+-dependent K+ (K(Ca)) conductance plays a key role in odor inhibition, both in toad and rat isolated olfactory neurons. The mechanism underlying odor inhibition has remained elusive. We assessed its study using various pharmacological agents and caged compounds for cAMP, Ca2+, and inositol 1,4,5-triphosphate (InsP3) on isolated toad ORNs. The odor-triggered K(Ca) current was reduced on exposing the cell either to the CNG channel blocker LY83583 (20 microM) or to the adenylyl cyclase inhibitor SQ22536 (100 microM). Photorelease of caged Ca2+ activated a Cl- current sensitive to niflumic acid (10 microM) and a K+ current blockable by charybdotoxin (20 nM) and iberiotoxin (20 nM). In contrast, photoreleased Ca2+ had no effect on cells missing their cilia, indicating that these conductances are confined to the cilia. Photorelease of cAMP induced a charybdotoxin-sensitive K+ current in intact ORNs. Photorelease of InsP3 did not increase the membrane conductance of olfactory neurons, arguing against a direct role of InsP3 in chemotransduction. We conclude that a cAMP cascade mediates the activation of the ciliary Ca2+-dependent K+ current and that the Ca2+ ions that activate the inhibitory current enter the cilia through CNG channels.     

Ion permeation properties of the glutamate receptor channel in cultured embryonic Drosophila myotubes.

Ion permeation properties of the glutamate receptor channel in cultured myotubes of Drosophila embryos were studied using the inside-out configuration of the patch-clamp technique. Lowering the NaCl concentration in the bath (intracellular solution), while maintaining that of the external solution constant, caused a shift of the reversal potential in the positive direction, thus indicating a higher permeability of the channel to Na+ than to Cl- (PCl/PNa < 0.04), and suggesting that the channel is cation selective. With 145 mM Na+ on both sides of the membrane, the single-channel current-voltage relation was almost linear in the voltage range between -80 and +80 mV, the conductance showing some variability in the range between 140 and 170 pS. All monovalent alkali cations tested, as well as NH4+, permeated the channel effectively. Using the Goldman-Hodgkin-Katz equation for the reversal potential, the permeability ratios with respect to Na+ were estimated to be: 1.32 for K+, 1.18 for NH4+, 1.15 for Rb+, 1.09 for Cs+, and 0.57 for Li+. Divalent cations, i.e. Mg2+ and Ca2+, in the external solution depressed not only the inward but also the outward Na+ currents, although reversal potential measurements indicated that both ions have considerably higher permeabilities than Na+ (PMg/PNa = 2.31; PCa/PNa = 9.55). The conductance-activity relation for Na+ was described by a hyperbolic curve. The maximal conductance was about 195 pS and the half-saturating activity 45 mM. This result suggests that Na+ ions bind to sites in the channel. All data were fitted by a model based on the Eyring's reaction rate theory, in which the receptor channel is a one-ion pore with three energy barriers and two internal sites.     

Suppression by extracellular K+ of N-methyl-D-aspartate responses in cultured rat hippocampal neurons

1. The effects of increasing K+ concentration in Mg2(+)-free extracellular solution on N-methyl-D-aspartate (NMDA)-induced current were studied in cultured rat hippocampal neurons with the use of the whole-cell and outside-out configurations of the patch-clamp technique. 2. When the K+ concentration in the external solution was increased by replacement of Na+ with isomolar K+, the amplitude of the NMDA-induced current decreased in a concentration-dependent manner. The effect of K+ was almost saturated at 100 mM, when the NMDA response was reduced to 12% of that in K(+)-free, 150 mM Na+ solution. Increasing the external K+ concentration did not affect either the kainate- or quisqualate-induced current in these experimental conditions. 3. Increase in the external K+ concentration reduced the NMDA-induced current almost equally over the whole range of membrane potential tested (-60-30 mV). The reversal potential of the NMDA-induced current was not significantly shifted by the replacement of Na+ with K+. 4. A rise in the external K+ concentration to 100 mM did not reduce the single-channel conductance of the NMDA channel, whereas it reduced the mean open time to about two-thirds of that in the control external solution. 5. The suppressed activation of the NMDA receptor channel in high-K+ environments may have a functional significance to alleviate entry of toxic Ca2+ into neurons of the CNS in pathological conditions such as hypoxia and ischemia.     

A brief history of trp: commentary and personal perspective

The history of the discovery of the transient receptor potential (TRP) cation channel superfamily began in 1969 with Cosens and Manning's isolation of the Drosophila transient receptor potential mutant, in which the photoreceptor response decays during continuous illumination. Early studies from Minke found that the elementary light response was unaffected in trp mutants, and he attributed the defect to an intermediate stage of phototransduction. Montell and Rubin cloned the trp gene in 1989: they recognised it as a transmembrane protein, but also concluded that it did not encode the light-sensitive channels. In 1991, Minke and Selinger proposed that TRP represented a Ca2+ transporter required for refilling intracellular InsP3-sensitive Ca2+ stores, in turn required for activation of the light-sensitive channels. Also in 1991, after developing a photoreceptor patch clamp preparation, I showed that the light-sensitive channels themselves were highly permeable to Ca2+, questioning the need for such a dedicated Ca2+ transporter. In 1992, in collaboration with Minke, I resolved this paradox by showing there were two classes of light-sensitive channels, one highly Ca2+ permeable and eliminated in trp mutants. This represented the first and compelling evidence that TRP represented a light-sensitive channel and was supported by the cloning of the second light-sensitive channel, TRPL, by Kelly's lab. Three years later, in 1995, the labs of Montell and Birnbaumer independently cloned TRPC1, the first of 29 vertebrate TRP isoforms distributed amongst seven subfamilies.     

Calcium sensitivity of a sodium-activated nonselective cation channel in lobster olfactory receptor neurons

We report that a Na+-activated nonselective cation channel described previously in lobster olfactory neurons, in which phosphoinositide signaling mediates olfactory transduction, can also be activated by Ca2+. Ca2+ activates the channel in the presence of Na+, increasing the open probability of the channel with a K1/2 of 490 nM and a Hill coefficient of 1.3. Ca2+ also increases the sensitivity of the channel to Na+. In some cells, the same channel is Ca2+ insensitive in a cell-specific manner. The nonspecific activator of protein phosphatases, protamine, applied to the intracellular face of patches containing the channel irreversibly eliminates the sensitivity to Ca2+. This effect can be blocked by okadaic acid, a nonspecific blocker of protein phosphatases, and restored by the catalytic subunit of protein kinase A in the presence of MgATP. The Ca2+-sensitive form of the channel is predominantly expressed in the transduction zone of the cells in situ. These findings imply that the Ca2+ sensitivity of the channel, and possibly its regulation by phosphorylation, play a role in olfactory transduction and help tie activation of the channel to the canonical phosphoinositide turnover pathway.     

T-type Ca2+ channels mediate propagation of odor-induced Ca2+ transients in rat olfactory receptor neurons

Propagation of odor-induced Ca(2+) transients from the cilia/knob to the soma in mammalian olfactory receptor neurons (ORNs) is thought to be mediated exclusively by high-voltage-activated Ca(2+) channels. However, using confocal Ca(2+) imaging and immunocytochemistry we identified functional T-type Ca(2+) channels in rat ORNs. Here we show that T-type Ca(2+) channels in ORNs also mediate propagation of odor-induced Ca(2+) transients from the knob to the soma. In the presence of the selective inhibitor of T-type Ca(2+) channels mibefradil (10-15 microM) or Ni(2+) (100 microM), odor- and forskolin/3-isobutyl-1-methyl-xanthine (IBMX)-induced Ca(2+) transients in the soma and dendrite were either strongly inhibited or abolished. The percentage of inhibition of the Ca(2+) transients in the knob, however, was 40-50% less than that in the soma. Ca(2+) transients induced by 30 mM K(+) were partially inhibited by mibefradil, but without a significant difference in the extent of inhibition between the knob and soma. Furthermore, an increase of as little as 2.5 mM in the extracellular K(+) concentration (7.5 mM K(+)) was found to induce Ca(2+) transients in ORNs, and such responses were completely inhibited by mibefradil or Ni(2+). Total replacement of extracellular Na(+) with N-methyl-d-glutamate inhibited none of the odor-, forskolin/IBMX- or 7.5 mM K(+)-induced Ca(2+) transients. Positive immunoreactivity to the Ca(v)3.1, Ca(v)3.2 and Ca(v)3.3 subunits of the T-type Ca(2+) channel was observed throughout the soma, dendrite and knob. These data suggest that involvement of T-type Ca(2+) channels in the propagation of odor-induced Ca(2+) transients in ORNs may contribute to signal transduction and odor sensitivity.     

Catecholamine release from bovine chromaffin cells: the role of sodium-calcium exchange in ouabain-evoked release

Spontaneous catecholamine (CA) release from bovine chromaffin cells maintained in primary tissue culture has been measured after pre-loading the cells with [3H]noradrenaline. Ouabain inhibited 86Rb+ uptake and increased 3H release in a concentration-dependent manner during a 60 min incubation period. Low external Na+ (5 mM: Li+ substitution) also increased 3H release. Whereas the 3H-releasing action of ouabain was maintained, the Li(+)-evoked release decreased with time. The effects of both ouabain and low Na+ solution on 3H release were completely inhibited by removal of Ca2+ from the external medium even though in Ca2(+)-free solution ouabain further inhibited 86Rb+ uptake into the cells. Readmission of Ca2+ to Na(+)-loaded cells (10-4 M-ouabain in Ca2(+)-free-1 mM-EGTA solution for 60 min) markedly increased the release of 3H. In the additional presence of diphenylhydantoin (DPH, 10-4 M) 3H release was significantly less on Ca2+ readmission. The 3H release from Na(+)-loaded cells was proportional to the concentration of Ca2+ readmitted. The 3H release was further increased from Na(+)-loaded cells in response to Ca2+ readmission when [Na+]o was lowered from 149 to 5 mM (Li+, choline+, Tris+ or sucrose substitution) though Li+ was less effective than the other Na+ substitutes. Potassium removal from the external medium significantly inhibited the 3H release evoked by Ca2+ readmission to Na(+)-loaded cells, even when [Ca2+]o was greater than normal (7.5 mM) or if Ca2+ was readmitted in low [Na+]o solution. Rb+, Cs+ or Li+ could substitute for K+ with the order of potency: Rb+ greater than or equal to K+ greater than Cs+ greater than Li+. A slight increase of external K+ (10.8 mM) potentiated the 3H release from Na(+)-loaded cells on Ca2+ readmission, but a higher concentration of K+ (149.4 mM) had the opposite action. The data is consistent with the hypothesis that ouabain-evoked CA release from bovine chromaffin cells is, in part, a consequence of an internal Na(+)-dependent Ca2+ influx. The evidence also suggests that there is Na(+)-Ca2+ competition at the external arm of the exchanger together with a monovalent cation activation site.     

Effect of a temperature increase in the non-noxious range on proton-evoked ASIC and TRPV1 activity

Acid-sensing ion channels (ASICs) are neuronal H(+)-gated cation channels, and the transient receptor potential vanilloid 1 channel (TRPV1) is a multimodal cation channel activated by low pH, noxious heat, capsaicin, and voltage. ASICs and TRPV1 are present in sensory neurons. It has been shown that raising the temperature increases TRPV1 and decreases ASIC H(+)-gated current amplitudes. To understand the underlying mechanisms, we have analyzed ASIC and TRPV1 function in a recombinant expression system and in dorsal root ganglion (DRG) neurons at room and physiological temperature. We show that temperature in the range studied does not affect the pH dependence of ASIC and TRPV1 activation. A temperature increase induces, however, a small alkaline shift of the pH dependence of steady-state inactivation of ASIC1a, ASIC1b, and ASIC2a. The decrease in ASIC peak current amplitudes at higher temperatures is likely in part due to the observed accelerated open channel inactivation kinetics and for some ASIC types to the changed pH dependence of steady-state inactivation. The increase in H(+)-activated TRPV1 current at the higher temperature is at least in part due to a hyperpolarizing shift in its voltage dependence. The contribution of TRPV1 relative to ASICs to H(+)-gated currents in DRG neurons increases with higher temperature and acidity. Still, ASICs remain the principal pH sensors of DRG neurons at 35°C in the pH range ≥6.     

Role of oxidative stress in ischemia-reperfusion-induced changes in Na+,K(+)-ATPase isoform expression in rat heart

The aim of this study was to assess whether depression of cardiac Na+,K(+)-ATPase activity during ischemia/reperfusion (I/R) is associated with alterations in Na+,K(+)-ATPase isoforms, and if oxidative stress participates in these I/R-induced changes. Na+,K(+)-ATPase alpha1, alpha2, alpha3, beta1, beta2, and beta3 isoform contents were measured in isolated rat hearts subjected to I/R (30 min of global ischemia followed by 60 min of reperfusion) in the presence or absence of superoxide dismutase plus catalase (SOD+CAT). Effects of oxidative stress on Na+,K(+)-ATPase isoforms were also examined by perfusing the hearts for 20 min with 300 microM hydrogen peroxide or 2 mM xanthine plus 0.03 U/ml xanthine oxidase (XXO). I/R significantly reduced the protein levels of all alpha and beta isoforms. Treatment of I/R hearts with SOD+CAT preserved the levels of alpha2, alpha3, beta1, beta2, and beta3 isoforms, but not that of the alpha1 isoform. Perfusion of hearts with hydrogen peroxide and XXO depressed all Na+,K(+)-ATPase alpha and beta isoforms, except for alpha1. These results indicate that the I/R-induced decrease in Na+,K(+)-ATPase may be due to changes in Na+,K(+)-ATPase isoform expression and that oxidative stress plays a role in this alteration. Antioxidant treatment attenuated the I/R-induced changes in expression of all isoforms except alpha1, which appears to be more resistant to oxidative stress.     

Effects of ouabain on intracellular ion activities of sensory neurons of the leech central nervous system.

1. The intracellular K+, Na+, and Ca2+ of mechanosensory neurons in the central nervous system of the leech Hirudo medicinalis was measured using double-barreled ion-sensitive microelectrodes. 2. After inhibition of the Na(+)-K+ pump with 5 x 10(-4) M ouabain, the intracellular K+ activity (aKi) decreased, while the intracellular Na+ activity (aNai) increased. The input resistance decreased in the presence of ouabain. The intracellular Ca2+ increased more than one order of magnitude after ouabain addition. All changes in intracellular ion activities and membrane resistance were fully reversible. 3. When extracellular Na+ concentration ([Na+]o) was removed [replaced by tris(hydroxymethyl)aminomethane (Tris)], aNai decreased. In the absence of [Na+]o, aKi and aNai remained unchanged after inhibition of the Na(+)-K+ pump by reducing the extracellular K+ concentration ([K+]o) to 0.2 mM. The membrane resistance increased under these conditions. 4. The intracellular Ca2+ decreased or remained constant after removal of [Na+]o. Addition of ouabain in the absence of [Na+]o did not change intracellular Ca2+, which only increased after readdition of [Na+]o. 5. The relative K+ permeability (PK) measured as membrane potential change during a brief increase of the [K+]o from 4 to 10 mM, increased manyfold after addition of ouabain but only little if [Na+]o had been removed before adding ouabain. 6. The results suggest that the intracellular Na+ increase after inhibition of the Na(+)-K+ pump affects the intracellular Ca2+ level by stimulating a Nai(+)-Ca2+ exchange mechanism. The subsequent intracellular Ca2+ activity (aCai) rise may result in an increase of the membrane permeability to K+ ions.     

Computer simulations of N-methyl-D-aspartate receptor-induced membrane properties in a neuron model.

1. To evaluate the role of N-methyl-D-aspartate (NMDA) receptors in simulations of the lamprey spinal locomotor network, we developed a computer-simulated electrical model of a neuron that contains NMDA channels in addition to voltage-gated Na+, K+, and Ca2+ channels and Ca(2+)-activated K+ channels [K(Ca) channels]. 2. The voltage dependence of the Mg2+ block of the Na(+)-K+ current flow through the NMDA channel was modeled according to a scheme of open-channel block. To account for the regulation of K(Ca) channels by NMDA and membrane voltage, we modeled two separate Ca2+ pools that had different voltage dependencies and dynamics. 3. Pacemaker-like membrane potential oscillations could be elicited in the model neuron, which resembled those observed experimentally in the presence of bath-applied NMDA and tetrodotoxin. The effect of changing different channel parameters were tested to determine under which conditions such membrane potential oscillations could occur. 4. The oscillation amplitude was determined by the potential levels at which the NMDA channels and voltage-dependent K+ channels, respectively, were activated. The oscillation frequency and the relative durations of the de- and hyperpolarized phases of the oscillations were determined by the balance between the depolarizing (NMDA channels) and hyperpolarizing [K(Ca) channels] currents. 5. Simulated alterations of the Mg2+ concentration and the K+ conductance as well as injection of constant current caused changes of the oscillations corresponding to those observed experimentally. The de- and hyperpolarizing phases could be reset by brief current pulses. 6. We conclude that the present model can account for the effects of bath-applied NMDA on spinal neurons. This permits an incorporation of NMDA-receptor-mediated properties in simulation models of the lamprey locomotor network.     

Molecular determinants of two neurotoxins that regulate sodium current inactivation in rat hippocampal neurons

We studied functional and structural differences between the two neurotoxins, wasp toxin pompilidotoxin (PMTX) and sea anemone toxin (ATXII). Although PMTX and ATXII inhibited inactivation of sodium currents both toxins had distinct actions on the lobster axon and on the rat hippocampal cells. To determine structural basis of the difference we compared arrangement of polar and non-polar amino acids of the two toxins and found that similar sequence of PMTX exist in a discrete position of three-dimensional structure of ATXII. The sequence may be responsible for the binding site in the neuronal Na(+) channel molecule because PMTX is insensitive to cardiac Na(+) channel. Differential actions of ATXII from PMTX may come from other regions than the overlapped sequence. PMTX has diverse actions in the central neurons and is useful to classify Na(+) channel subtypes.     

Sodium/calcium exchange: its physiological implications.

The Na+/Ca2+ exchanger, an ion transport protein, is expressed in the plasma membrane (PM) of virtually all animal cells. It extrudes Ca2+ in parallel with the PM ATP-driven Ca2+ pump. As a reversible transporter, it also mediates Ca2+ entry in parallel with various ion channels. The energy for net Ca2+ transport by the Na+/Ca2+ exchanger and its direction depend on the Na+, Ca2+, and K+ gradients across the PM, the membrane potential, and the transport stoichiometry. In most cells, three Na+ are exchanged for one Ca2+. In vertebrate photoreceptors, some neurons, and certain other cells, K+ is transported in the same direction as Ca2+, with a coupling ratio of four Na+ to one Ca2+ plus one K+. The exchanger kinetics are affected by nontransported Ca2+, Na+, protons, ATP, and diverse other modulators. Five genes that code for the exchangers have been identified in mammals: three in the Na+/Ca2+ exchanger family (NCX1, NCX2, and NCX3) and two in the Na+/Ca2+ plus K+ family (NCKX1 and NCKX2). Genes homologous to NCX1 have been identified in frog, squid, lobster, and Drosophila. In mammals, alternatively spliced variants of NCX1 have been identified; dominant expression of these variants is cell type specific, which suggests that the variations are involved in targeting and/or functional differences. In cardiac myocytes, and probably other cell types, the exchanger serves a housekeeping role by maintaining a low intracellular Ca2+ concentration; its possible role in cardiac excitation-contraction coupling is controversial. Cellular increases in Na+ concentration lead to increases in Ca2+ concentration mediated by the Na+/Ca2+ exchanger; this is important in the therapeutic action of cardiotonic steroids like digitalis. Similarly, alterations of Na+ and Ca2+ apparently modulate basolateral K+ conductance in some epithelia, signaling in some special sense organs (e.g., photoreceptors and olfactory receptors) and Ca2+-dependent secretion in neurons and in many secretory cells. The juxtaposition of PM and sarco(endo)plasmic reticulum membranes may permit the PM Na+/Ca2+ exchanger to regulate sarco(endo)plasmic reticulum Ca2+ stores and influence cellular Ca2+ signaling.     

Sodium-bicarbonate cotransport current in identified leech glial cells.

1. The membrane current associated with the cotransport of Na+ and HCO3- was investigated in neuropil glial cells in isolated ganglia of the leech Hirudo medicinalis L. using the two-electrode voltage-clamp technique. 2. The addition of 5% CO2-24 mM HCO3- evoked an outward current, which slowly decayed, and which was dependent upon the presence of external Na+. Removal of CO2-HCO3- elicited a transient inward current. Re-addition of Na+ to Na(+)-free saline in the presence of CO2-HCO3- also produced an outward current. Under these conditions an intracellular alkalinization and a rise in intracellular [Na+] were recorded using triple-barrelled, ion-sensitive microelectrodes. Addition or removal of HCO3-, in the absence of external Na+, caused little or no change in membrane voltage, membrane current and intracellular pH, indicating that the glial membrane has a very low HCO3- conductance. 3. Voltage steps revealed nearly linear current-voltage relationships both in the absence and presence of CO2-HCO3-, with an intersection at the assumed reversal potential of the HCO(3-)-dependent current. These results suggest a cotransport stoichiometry of 2HCO3-: 1 Na+. The HCO(3-)-dependent current could be inhibited by diisothiocyanatostilbene-2,2'-disulphonic acid (DIDS). 4. Simultaneous recording of current and intracellular pH showed a correlation of the maximal acid-base flux with the transient HCO(3-)-dependent current during voltage steps in the presence of CO2-HCO3-. The maximum rate of acid-base flux and the HCO(3-)-dependent peak current showed a similar dependence on membrane voltage. Lowering the external pH from 7.4 to 7.0 produced an inward current, which increased twofold in the presence of CO2-HCO3-. This current was largely inhibited by DIDS, indicating outward-going electrogenic Na(+)-HCO3- cotransport during external acidification. 5. When external Na+ was replaced by Li+, a similar outward current and intracellular alkalinization were observed in the presence of CO2-HCO3-. The Li(+)-induced intracellular alkalinization was not inhibited by amiloride, a blocker of Na+(Li+)-H+ exchange, but was sensitive to DIDS. These results suggest that Li+ could, at least partly, substitute for Na+ at the cotransporter site. 6. Our results indicate that the Na(+)-HCO3- cotransport produces a current across the glial cell membrane in both directions with a reversal potential near the membrane resting potential, rendering pHi a function of the glial membrane potential.     

A calcium-dependent slow afterdepolarization recorded in rat dorsolateral septal nucleus neurons in vitro

1. Conventional intracellular and single-electrode voltage-clamp recordings were obtained from rat brain slices containing dorsolateral septal nucleus (DLSN) neurons in vitro. 2. We observed a slow afterdepolarizing potential (slow-ADP) that lasted up to several seconds (half-decay time was in the range of 0.7-1.4 s) in almost 15% of DLSN neurons; these same neurons could exhibit burst firing activity. The amplitude of this slow-ADP was not affected by hyperpolarization of the membrane potential. 3. The slow-ADP was associated with an increased membrane conductance. Hybrid voltage clamping of the slow-ADP revealed a transient slow inward current (slow-ADC). The current-voltage relationship of the slow-ADC was linear between -40 and -100 mV and generated an extrapolated reversal potential of -30 mV. 4. We investigated the ionic mechanism of the slow-ADP in the rat DLSN. Slow-ADPs were not blocked by 1 microM tetrodotoxin (TTX) but were markedly depressed by 200 microM Cd2+, Ca2(+)-free, low-Na+ solutions, and the intracellular injection of ethylene glycol-bis(B-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA). Neither diltiazam (10 microM), an L-type Ca2+ channel blocker nor omega-conatoxin (0.2-2.5 microM), an N-type Ca2+ channel blocker affected the slow-ADP. Similarly, the slow-ADP was not affected in a low-Cl- solution. On the other hand, the slow-ADP was enhanced in a K(+)-free solution. In addition, the slow-ADP was not affected by 1 mM kynurenic acid, a broad-spectrum excitatory amino acid antagonist. 5. We conclude that the slow-ADP in the rat DLSN is mediated by a novel Ca2(+)-dependent, Na(+)-dependent, and nonsynaptic inward current that may be similar to the Ca2(+)-activated nonspecific cation channel currents (i.e., CAN-currents) described in various tissues. This current appears to underlie some forms of spontaneous bursting activity recorded from rat DLSN neurons. It may also be responsible for some types of bursting activity recorded in other CNS neurons.     

Palytoxin: a potent stimulator of catecholamine release from cultured bovine adrenal chromaffin cells.

The effect of palytoxin (PTX), a potent marine toxin, on catecholamine release from cultured bovine adrenal chromaffin cells was examined. PTX at concentrations of over 10(-9) M induced catecholamine release dose-dependently. About 40-50% of the total cellular catecholamine was released during 20-min incubation with 3 x 10(-8) M PTX. PTX-induced catecholamine release was dependent on both extracellular Na+ and Ca2+, and was inhibited by organic and inorganic Ca2+ channel blockers, but not by tetrodotoxin. PTX-induced increase in 45Ca2+ influx into the cells, which was associated with catecholamine release, was also inhibited by these Ca2+ channel blockers. These results indicated that PTX-induced catecholamine release was mediated by activation of Na(+)-dependent, tetrodotoxin (TTX) insensitive voltage-dependent Ca2+ channels.     

Synchronized oscillatory activity in leech neurons induced by calcium channel blockers.

1. Leech ganglia were superfused with salines in which Ca2+ was replaced with equimolar concentrations of Co2+, Ni2+, or Mn2+. These salines elicited rhythmic membrane potential oscillations with cycle periods ranging from 8 to 25 s in all neurons examined within the ventral nerve cord. 2. Rhythmic activity consisted of a rapid depolarization to a prolonged (3-6 s) plateau level, followed by a rapid repolarization. Each depolarization elicited a burst of action potentials. Peak-to-trough amplitudes of the plateau depolarizations were up to 40 mV in some cells. The plateau depolarizations were separated by slowly depolarizing ramp potentials. 3. Oscillations in all neurons were synchronized (in phase) both within individual ganglia and between ganglia linked by connective nerves. Rhythmic activity in isolated ganglia persisted after the interposed connective nerves were cut. 4. The occurrence of oscillatory activity was strongly correlated with the block of chemical synaptic transmission. 5. Electrotonic interactions persisted during oscillatory activity and may be one mechanism by which oscillations are synchronized. 6. The phase of rhythmic impulse bursts monitored with extracellular electrodes could be reset by electrical stimulation of connective nerves but not by injection of current pulses into individual neurons. Phase reset appeared to occur within one cycle and to a fixed phase point (plateau termination). 7. Oscillatory activity was eliminated by 75-100% reductions of [Na+]o (Na+ replaced with N-methyl-D-glucamine). Smaller reductions of Na+ (by 25-50%) increased the cycle period of oscillations. 8. The Na(+)-K+ pump inhibitors ouabain and strophanthidin disrupted oscillations. Cells were depolarized by approximately 20 mV and fired tonically. After the initial washout of the inhibitors, cells repolarized and became quiescent. After several minutes of continued washing, oscillatory activity resumed. 9. A conceptual model is proposed to explain the mechanisms underlying oscillatory activity induced by Ca2+ channel blockers. According to this model, depolarizing plateaus are generated by a noninactivating Na+ conductance. Na+ influx during the plateau leads to an increase in [Na+]i, which activates an electrogenic Na(+)-K+ pump that contributes to plateau termination. 10. A quantitative computer simulation incorporating six types of currents (capacity, outward rectifying potassium, inward rectifying potassium, sodium, leakage, and an electrogenic sodium pump) demonstrates the plausibility of the conceptual model. 11. These data suggest that a novel Na(+)-based mechanism for membrane potential oscillation is revealed by blockade of Ca2+ channels in leech ganglia.     

Relaxation in ferret ventricular myocytes: unusual interplay among calcium transport systems.

Transport systems responsible for removing Ca2+ from the myoplasm during relaxation in isolated ferret ventricular myocytes were studied using caffeine-induced contractures. Internal calcium concentration ([Ca2+]i) was measured with the fluorescent calcium indicator indo-1, and the results were compared with our recent detailed characterizations in rabbit and rat myocytes. Relaxation and [Ca2+]i decline during a twitch in ferret myocytes were fast and similar to that in rat myocytes (i.e. half-time, t 1/2 approximately 100-160 ms). During a caffeine-induced contracture (SR Ca2+ accumulation prevented), relaxation was still relatively fast (t 1/2 = 0.57 s) and similar to relaxation in rabbit supported mainly by a strong Na(+)-Ca2+ exchange. When both the SR Ca2+ uptake and Na(+)-Ca2+ exchange are blocked (by caffeine and 0 Na+, 0 Ca2+ solution) relaxation in the ferret myocyte is remarkably fast (approximately 5-fold) compared with rabbit and rat myocytes. The decline of the Cai2+ transient was also fast under these conditions. These values were similar to those in rat under conditions where relaxation is due primarily to Na(+)-Ca2+ exchange. Additional inhibition of either the sarcolemmal Ca(2+)-ATPase or mitochondrial Ca2+ uptake caused only modest slowing of the relaxation of caffeine-induced contracture in 0 Na+, 0 Ca2+ (t 1/2 increased to approximately 3 s). In rabbit myocytes the relaxation t 1/2 is slowed to 20-30 s by these procedures. Even when the systems responsible for slow relaxation in rabbit ventricular myocytes are inhibited (i.e. sarcolemmal Ca(2+)-ATPase and mitochondrial Ca2+ uptake) along with the SR Ca(2+)-ATPase and Na(+)-Ca2+ exchange, relaxation and [Ca2+]i decline in ferret myocytes remain rapid compared with rabbit myocytes. Ca2+ taken up by mitochondria in rabbit myocytes during a caffeine contracture in 0 Na+, 0 Ca2+ solution gradually returns to the SR after caffeine removal, but this component appears to be much smaller in ferret myocytes under the same conditions. We tested for possible residual Ca2+ transport by each of the four systems which suffice to explain Ca2+ removal from the cytoplasm in rabbit (SR Ca(2+)-ATPase, Na(+)-Ca2+ exchange, sarcolemmal Ca(2+)-ATPase and mitochondrial Ca2+ uptake). We conclude that there is an additional calcium transport system at work in ferret myocytes. For this additional system, our results are most compatible with a trans-sarcolemmal Ca2+ transport, but neither a cation exchanger nor a Ca(2+)-ATPase with characteristics like that in other cardiac cells. This additional system appears able to transport Ca2+ nearly as fast as the Na(+)-Ca2+ exchange in rat ventricular myocytes.