Cyclic-AMP-dependent phosphorylation modulates the stereospecific activation of cardiac Ca channels by Bay K 8644

Voltage-gated Ca channels have been reported to be regulated by membrane potential, phosphorylation and binding of specific agonists or antagonists such as dihydropyridines. We report here evidence that cyclic AMP (cAMP) modulates the activation of Ca-channel current by the dihydropyridine agonist Bay K 8644. Bay K 8644 (racemate) alone induces a primary voltage-dependent, potentiating effect on peak current amplitude and accelerates the current decay. In contrast, in the presence of cAMP activators, we observed a striking slowing of the decay in addition to the increase in peak current. The agonist (–)-Bay K 8644, but not the antagonist (+)-Bay K 8644, when applied in combination with cAMP, forskolin or isoproterenol, mimics the effect of the racemate. We have interpreted the results presented here in respect of a cAMP-dependent modulation of Bay K 8644 effects on cardiac Ca-channel currents. It may open the new perspective that dephosphorylated and phosphorylated Ca channels have distinct pharmacology.A preliminary account of this work appeared in abstract form (Lory et al. 1989)     

Different action of ethosuximide on low- and high-threshold calcium currents in rat sensory neurons.

The effects of ethosuximide on calcium channels were studied on dorsal root ganglion neurons from one-day-old rats using the patch-clamp technique. Bath application of ethosuximide induced dose-dependent and reversible suppression of calcium currents without affecting their time-course. Substantial differences between the effects of ethosuximide on the low-threshold and high-threshold (T- and L-) currents were observed. Ethosuximide reduced the T-current with greater potency than the L-current (Kd for T-current is 7 microM vs 15 microM for L-current). This relative specificity of its action still remained if applied at concentrations up to 1 mM. These data support the hypothesis according to which the anti-epileptic action of ethosuximide is related to reduction of the low-threshold calcium currents in sensory neurons.     

Inhibitory action of acetylcholine, baclofen and GTP-gamma-S on calcium channels in adult rat sensory neurons.

High- and low-voltage activated calcium channel currents (HVA and LVA) were inhibited by acetylcholine (10-100 microM) and baclofen (10 microM) in adult rat sensory neurons. This modulatory effect was present on dihydropyridine (nifedipine 1 microM) and/or omega-conotoxin (3.2 microM, 2-5 h incubation) insensitive components and was insensitive to holding potentials (Vh -50 to -90 mV). GTP-gamma-S (100 microM) prolonged calcium channel current activation in a time- and voltage-dependent manner. On the other hand, the current amplitude reduction induced by muscarinic and GABAB receptor activation, was not relieved by a 50-ms conditioning prepulse to +50 mV. This suggests the possibility of an alternative voltage-independent modulation mechanism.     

Mechanosensitive potassium channels in rat colon sensory neurons

Single-channel recording techniques were used to characterize mechanosensitive channels in identified (1.1'-dioctadecyl-3,3,3', 3'-tetramethylindocarbocyanine methanesulfonate labeled) colon sensory neurons dissociated from adult S1 dorsal root ganglia. Channels were found in 30% (7/23) of patches in a cell-attached configuration and in 43% (48/111) of excised inside-out patches. Channels were highly selective for K(+), had a slope conductance of 54 pS in symmetrical solutions, and were blocked by tetraethylammonium, amiloride, and benzamil. Channels were also seen under Ca(2+)-free conditions. Gadolinium (Gd(3+)), a known blocker of mechanosensitive ion channels, did not block channel activity. Tetrodotoxin and 4-aminopyridine were also ineffective. The cytoskeletal disrupters colchicine and cytochalasin D reduced the percentage of patches containing mechanosensitive channels. These results indicate that rat colon sensory neurons contain K(+)-selective mechanosensitive channels that may modulate the membrane excitability induced by colonic distension.     

An inward calcium current underlying regenerative calcium potentials in rat striatal neurons in vitro enhanced by Bay K 8644

The single electrode voltage clamp technique was used to characterize the currents underlying the calcium potentials in rat caudate neurons in vitro. In current clamp experiments, long depolarizing current pulses evoked repetitive firing of fast somatic action potentials. These were abolished by tetrodotoxin (1 microM) and replaced by slow graded depolarizing potentials. These were preceded by a transient hyperpolarizing notch. Addition of 4-aminopyridine (100 microM) abolished the hyperpolarizing notch, enhanced the slow graded depolarizing response and induced the appearance of a slow all-or-nothing action potential. Both the slow graded response and the all-or-nothing action potential were abolished by cobalt (2 mM), suggesting the involvement of voltage-dependent calcium conductances. When the neurons were loaded intracellularly with caesium the action potential duration increased. Substitution of the extracellular calcium by barium (1-3 mM) or external addition of tetraethylammonium (5 mM) further prolonged spike duration and induced the appearance of long-lasting plateau potentials. These were insensitive to tetrodotoxin and were reversibly blocked by the calcium antagonists cobalt (2 mM), manganese (2 mM) or cadmium (500 microM). The calcium potentials were enhanced by the calcium 'agonist' BAY K 8644 (1-5 microM). In voltage clamp experiments when intracellular caesium was used to reduce outward currents and tetrodotoxin to block fast regenerative sodium currents, depolarizing voltage steps from a holding potential of -50, -40 mV activated an inward current. This current peaked in 50-80 ms and inactivated in two phases: an initial one at 150-200 ms followed by a second one after several hundred ms.(ABSTRACT TRUNCATED AT 250 WORDS)     

Axotomy-induced apoptosis in adult rat primary sensory neurons

Neuronal death following unilateral axotomy of a sensory nerve has long been inferred from neuronal counts of dorsal root ganglion neurons, using the contralateral ganglia as a control. The counting methods used usually involved the counting of neuronal nucleoli and made assumptions about them which could conceivably be flawed. Very few studies have used direct observations of dying or degenerating neurons to address questions concerning the duration of the period of neuronal death or the mechanisms involved in this process. Here we describe a morphological, morphometric and histochemical study into the nature and duration of sensory neuron death following transection and ligation of the sciatic nerve at mid-thigh level in the adult rat. We show that at least some of this neuronal loss occurs by apoptosis as defined by morphological criteria and in situ end-labelling of damaged DNA. Absolute numbers of apoptotic neurons were counted from serial paraffin sections of ganglia and estimates of neuronal numbers obtained by disector analysis at 1, 2, 3 and 6 months after axotomy. Using this approach we show that axotomy-induced apoptosis begins at around 1 week and continues up to at least 6 months after axotomy.     

Functional role of low-voltage-activated dihydropyridine-sensitive Ca channels during the action potential in adult rat sensory neurones

Neuronal cell firing is crucial to nerve-nerve communication. The ability to produce consecutive action potentials is related to the activation of inward currents after each upstroke. If fast Na current is indeed responsible for the overshoot, it is still unclear which current drives membrane voltage to the Na threshold. In this study we present evidence that in adult rat sensory neurones a dihydropyridine-sensitive Ca channel exists in addition to the well characterized L-type, or high-threshold Ca channel. During stimulated action potential trains, L-type Ca channels open during the excitation wave, whereas activity of the other dihydropyridine-sensitive Ca channel was observed primarily between action potentials. This second Ca pathway shows remarkably long openings at negative potentials after a series of positive prepulses. The nerve action potential and the repetitive firing work as a physiological Ca channel facilitation mechanism. Therefore, we suggest that this novel Ca conductance provides inward current, between two consecutive action potentials, able to modulate the frequency of neuronal bursts. Received: 3 August 1995/Received after revision: 9 October 1995/Accepted: 10 October 1995     

Multiple neuropeptide Y receptors regulate K+ and Ca2+ channels in acutely isolated neurons from the rat arcuate nucleus

We examined the effects of neuropeptide Y (NPY) and related peptides on Ca2+ and K+ currents in acutely isolated neurons from the arcuate nucleus of the rat. NPY analogues that activated all of the known NPY receptors (Y1-Y5), produced voltage-dependent inhibition of Ca2+ currents and activation of inwardly rectifying K+ currents in arcuate neurons. Both of these effects could occur simultaneously in the same cells. In some cells, activation of Y4 NPY receptors also caused oscillations in [Ca2+]i. NPY hyperpolarized arcuate neurons through the activation of a K+ conductance and increased the spike threshold. Molecular biological studies indicated that arcuate neurons possessed all of the previously cloned NPY receptor types (Y1, Y2, Y4, and Y5). Thus activation of multiple types NPY receptors on arcuate neurons can regulate both Ca2+ and K+ conductances leading to a reduction in neuronal excitability and a suppression of neurotransmitter release.     

Cationic channels activated by extracellular ATP in rat sensory neurons

Single channels activated by externally applied ATP were investigated in cultured sensory neurons from nodosal and spinal ganglia of rat using patch clamp and concentration clamp methods. Mean conductance of single ATP-activated channels was 17 pS when measured at a holding potential of -75 mV in saline containing 3 mM Ca2+ and 1 mM Mg2+. Sublevels of conductance were detected in some cases. The current-voltage relationship for a single channel is highly non-linear and demonstrates inwardly directed rectification. The I-V curve obtained for single channels was identical to that for macroscopic current. ATP activated the channels in the absence of divalent cations (in ethylenediaminetetra-acetate-containing medium) as well as in their presence. This indicates that ATP as a free anion can activate the receptor. Ca2+ ions decreased both macro- and microscopic ATP-activated currents. The concentration dependence of this Ca2+ effect does not fit a single site binding isotherm. The single channel current demonstrated prominent fluctuations. When measured in the 0-4 kHz frequency band the amplitude of fluctuations evaluated as a double r.m.s. was about 30% of the mean amplitude of current. The autocorrelation function for the current fluctuations in an open channel could be approximated by a single exponential with the time constant of 0.4 ms. These fluctuations did not depend on the presence of divalent cations in the external medium. The open time distribution for the investigated channels could be described by a sum of two exponentials. Presumably this reflects the existence of two subtypes of ATP-activated channels.     

Analysis of the variation in use-dependent inactivation of high-threshold tetrodotoxin-resistant sodium currents recorded from rat sensory neurons

This study addressed variation in the use-dependent inactivation (UDI) of high-threshold tetrodotoxin-resistant Na+ currents (TTX-R currents) and action potential firing behavior among acutely isolated rat dorsal root ganglion (DRG) cells. UDI was quantified as the percent decrease in current amplitude caused by increasing the current activation rate from 0.1-1.0 Hz for 20 s. TTX-R current UDI varied from 6% to 66% among 122 DRG cells examined, suggesting the existence of two or more levels of UDI. The voltage-dependency of the TTX-R currents was consistent with Na(V)1.8, regardless of UDI. However, TTX-R currents with more UDI had a more negative voltage-dependency of inactivation, a greater tendency to enter slow inactivation, and a slower recovery rate from slow inactivation, compared with those with less UDI. TTX-R currents with more UDI ran down faster than those with less UDI. However, UDI itself changed little over time, regardless of the initial UDI level observed in a particular DRG cell. Together, these two observations suggest that individual DRG cells did not express mixtures of TTX-R channels that varied regarding UDI. TTX-R current UDI was correlated with expression of a low-threshold A-current and whole-cell capacitance, suggesting that it varied among different nociceptor types. Whole-cell inward currents (WCI-currents), recorded without channel blockers, also exhibited UDI. WCI-current UDI varied similarly to TTX-R current UDI in magnitude, and relative to whole-cell capacitance and A-current expression, suggesting that the WCI-currents were carried predominantly by TTX-R channels. DRG cells with more WCI-current UDI exhibited a greater decrease in action potential amplitude and number, and a greater increase in action potential threshold over seven ramp depolarizations, compared with DRG cells with less WCI-current UDI. Variation in UDI of Na(V)1.8 channels expressed by different nociceptor types could contribute to shaping their individual firing patterns in response to noxious stimuli.     

The mechanism of GABAB-mediated slowing of the activation phase of high voltage-activated Ca2+ channels in rat sensory neurons.

The mechanism underlying the slowed activation of the high voltage-activated Ca2+ current (HVA-ICa) in the presence of (-)-baclofen was studied in cultured neurons of rat dorsal root ganglia. The decay phase of the baclofen-sensitive component of HVA-ICa was described by a sum of two exponential functions. Although the inhibited portion in the amplitude of the baclofen-sensitive component of HVA-ICa was increased in a concentration-dependent manner, the two decay time constants remained unaffected regardless of the concentration of baclofen. Furthermore, the baclofen-sensitive component of HVA-ICa was largely inactivated by a depolarizing prepulse (-30 mV for 0.5 s). These results support the notion that the slowed activation of the HVA-ICa in the presence of baclofen is due to a preferential inhibition of the inactivating component of HVA-ICa rather than due to voltage-dependent unblocking of a single population of HVA-ICa.     

Voltage-gated calcium channels in adult rat inferior colliculus neurons

The inferior colliculus (IC) plays a key role in the processing of auditory information and is thought to be an important site for genesis of wild running seizures that evolve into tonic-clonic seizures. IC neurons are known to have Ca(2+) channels but neither their types nor their pharmacological properties have been as yet characterized. Here, we report on biophysical and pharmacological properties of Ca(2+) channel currents in acutely dissociated neurons of adult rat IC, using electrophysiological and molecular techniques. Ca(2+) channels were activated by depolarizing pulses from a holding potential of -90 mV in 10 mV increments using 5 mM barium (Ba(2+)) as the charge carrier. Both low (T-type, VA) and high (HVA) threshold Ca(2+) channel currents that could be blocked by 50 microM cadmium, were recorded. Pharmacological dissection of HVA currents showed that nifedipine (10 microM, L-type channel blocker), omega-conotoxin GVIA (1 microM, N-type channel blocker), and omega-agatoxin TK (30 nM, P-type channel blocker) partially suppressed the current by 21%, 29% and 22%, respectively. Since at higher concentration (200 nM) omega-agatoxin TK also blocks Q-type channels, the data suggest that Q-type Ca(2+) channels carry approximately 16% of HVA current. The fraction of current (approximately 12%) resistant to the above blockers, which was blocked by 30 microM nickel and inactivated with tau of 15-50 ms, was considered as R-type Ca(2+) channel current. Consistent with the pharmacological evidences, Western blot analysis using selective Ca(2+) channel antibodies showed that IC neurons express Ca(2+) channel alpha(1A), alpha(1B), alpha(1C), alpha(1D), and alpha(1E) subunits. We conclude that IC neurons express functionally all members of HVA Ca(2+) channels, but only a subset of these neurons appear to have developed functional LVA channels.     

Ethanol modulates the ionic permeability of sodium channels in rat sensory neurons

The effects of ethanol on tetrodotoxin-sensitive (TTX_s) and tetrodotoxin-resistant (TTX_r) sodium channels in rat spinal ganglia were studied using a patch-clamp method. Application of ethanol (10 and 100 mM) to both sides of membranes resulted in decreases in the reversion potentials of both types of sodium channels. In the case of TTX_r channels, ethanol decreased their selectivity in relation to Na ions and altered the sequence of ion selectivity of these channels for different cations from row X to row XI of the Eisenman selectivity classification. It is suggested that this change in ion selectivity is associated with ethanol-induced disruption of hydrogen bonds which stabilize the spatial structure of ion channel macromolecules, whith may lead to changes in the steric parameters of the pores formed by these channels. Translated from Rossiskii Fiziologisheskii Zhurnal imeni I. M. Sechenova, Vol. 85, No. 1, pp. 110–118, January, 1999.     

Modulation of N-type Ca2+ channels by intracellular pH in chick sensory neurons

Both physiological and pathological neuronal events, many of which elevate intracellular [Ca2+], can produce changes in intracellular pH of between 0.15 and 0.5 U, between pH 7.4 and 6.8. N-type Ca2+ channels, which are intimately involved in exocytosis and other excitable cell processes, are sensitive to intracellular pH changes. However, the pH range over which N-type Ca2+ channels are sensitive, and the sensitivity of N-type Ca2+ channels to small changes in intracellular pH, are unknown. We studied the influence of intracellular pH changes on N-type calcium channel currents in dorsal root ganglion neurons, acutely isolated from 14-day-old chick embryos. Intracellular pH was monitored in patch-clamp recordings with the fluorescent dye, BCECF, and manipulated in both the acidic and basic direction by extracellular application of NH4+ in the presence and absence of intracellular NH4+. Changes in intracellular pH between 6.6 and 7.5 produced a graded change in Ca2+ current magnitude with no apparent shift in activation potential. Intracellular acidification from pH 7.3 to 7.0 reversibly inhibited Ca2+ currents by 40%. Acidification from pH 7.3 to pH 6.6 reversibly inhibited Ca2+ currents by 65%. Alkalinization from pH 7.3 to 7.5 potentiated Ca2+ currents by approximately 40%. Channels were sensitive to pHi changes with high intracellular concentrations of the Ca2+ chelator, bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid, which indicates that the effects of pHi did not involve a Ca2+-dependent mechanism. These data indicate that N-type Ca2+ channel currents are extremely sensitive to small changes in pHi in the range produced by both physiological and pathological events. Furthermore, these data suggest that modulation of N-type Ca2+ channels by pHi may play an important role in physiological processes that produce small changes in pHi and a protective role in pathological mechanisms that produce larger changes in pHi.     

Mitochondrial modulation of Ca2+ -induced Ca2+ -release in rat sensory neurons

Ca2+ -induced Ca2+ -release (CICR) from ryanodine-sensitive Ca2+ stores provides a mechanism to amplify and propagate a transient increase in intracellular calcium concentration ([Ca2+]i). A subset of rat dorsal root ganglion neurons in culture exhibited regenerative CICR when sensitized by caffeine. [Ca2+]i oscillated in the maintained presence of 5 mM caffeine and 25 mM K+. Here, CICR oscillations were used to study the complex interplay between Ca2+ regulatory mechanisms at the cellular level. Oscillations depended on Ca2+ uptake and release from the endoplasmic reticulum (ER) and Ca2+ influx across the plasma membrane because cyclopiazonic acid, ryanodine, and removal of extracellular Ca2+ terminated oscillations. Increasing caffeine concentration decreased the threshold for action potential-evoked CICR and increased oscillation frequency. Mitochondria regulated CICR by providing ATP and buffering [Ca2+]i. Treatment with the ATP synthase inhibitor, oligomycin B, decreased oscillation frequency. When ATP concentration was held constant by recording in the whole cell patch-clamp configuration, oligomycin no longer affected oscillation frequency. Aerobically derived ATP modulated CICR by regulating the rate of Ca2+ sequestration by the ER Ca2+ pump. Neither CICR threshold nor Ca2+ clearance by the plasma membrane Ca2+ pump were affected by inhibition of aerobic metabolism. Uncoupling electron transport with carbonyl cyanide p-trifluoromethoxy-phenyl-hydrazone or inhibiting mitochondrial Na+/Ca2+ exchange with CGP37157 revealed that mitochondrial buffering of [Ca2+]i slowed oscillation frequency, decreased spike amplitude, and increased spike width. These findings illustrate the interdependence of energy metabolism and Ca2+ signaling that results from the complex interaction between the mitochondrion and the ER in sensory neurons.