L-type calcium channels and calcium/calmodulin-dependent kinase II differentially mediate behaviors associated with nicotine withdrawal in mice.

Smoking is a widespread health problem. Because the nicotine withdrawal syndrome is a major contributor to continued smoking and relapse, it is important to understand the molecular and behavioral mechanisms of nicotine withdrawal to generate more effective smoking cessation therapies. Studies suggest a role for calcium-dependent mechanisms, such as L-type calcium channels and calcium/calmodulin-dependent protein kinase II (CaMKII), in the effects of nicotine dependence; however, the role of these mechanisms in nicotine-mediated behaviors is unclear. Thus, the goal of this study was to elucidate the role of L-type calcium channels and CaMKII in nicotine withdrawal behaviors. Using both pharmacological and genetic methods, our results show that L-type calcium channels are involved in physical, but not affective, nicotine withdrawal behaviors. Although our data do provide evidence of a role for CaMKII in nicotine withdrawal behaviors, our pharmacological and genetic assessments yielded different results concerning the specific role of the kinase. Pharmacological data suggest that CaMKII is involved in somatic signs and affective nicotine withdrawal, and activity level is decreased after nicotine withdrawal, whereas the genetic assessments yielded results suggesting that CaMKII is involved only in the anxiety-related response, yet the kinase activity may be increased after nicotine withdrawal; thus, future studies are necessary to clarify the precise behavioral specifics of the relevance of CaMKII in nicotine withdrawal behaviors. Overall, our data show that L-type calcium channels and CaMKII are relevant in nicotine withdrawal and differentially mediate nicotine withdrawal behaviors.

Cotinine inhibits catecholamine release evoked by cholinergic stimulation from the rat adrenal medulla.

The aim of the present study was to clarify whether cotinine affects the release of catecholamines (CA) from the isolated perfused rat adrenal gland, and to establish the mechanism of its action, in comparison with the response of nicotine. Cotinine (0.3-3 mM), when perfused into an adrenal vein for 60 min, inhibited CA secretory responses evoked by ACh (5.32 mM), DMPP (a selective neuronal nicotinic agonist, 100 microM for 2 min) and McN-A-343 (a selective muscarinic M1-agonist, 100 microM for 2 min) in dose- and time-dependent manners. However, cotinine did not affect CA secretion by high K+ (56 mM). Cotinine itself also failed to affect basal CA output. Furthermore, in the presence of cotinine (1 mM), CA secretory responses evoked by Bay-K-8644 (an activator of L-type Ca2+ channels, 10 microM) and cyclopiazonic acid (an inhibitor of cytoplasmic Ca2+-ATPase, 10 microM) were relative time-dependently attenuated. However, nicotine (30 microM), given into the adrenal gland for 60 min, initially rather enhanced CA secretory responses evoked by ACh and high K+, followed by the inhibition later, while it time-dependently depressed the CA release evoked by McN-A-343 and DMPP. Taken together, these results suggest that cotinine inhibits greatly CA secretion evoked by stimulation of cholinergic (both nicotinic and muscarinic) receptors, but does fail to affect that by the direct membrane-depolarization. It seems that this inhibitory effect of cotinine may be exerted by the cholinergic blockade, which is associated with blocking both the calcium influx into the rat adrenal medullary chromaffin cells and Ca2+ release from the cytoplasmic calcium store. It also seems that there is a big difference in the mode of action between cotinine and nicotine in the rat adrenomedullary CA secretion.

Gonadotropin subunit transcriptional responses to calcium signals in the rat: evidence for regulation by pulse frequency.

Alterations in the frequency of calcium influx signals to rat pituitary cells can regulate the expression of gonadotropin subunit mRNAs in a differential manner, producing effects that are similar to those previously found for GnRH. The present study was conducted to investigate whether this reflects a transcriptional response to calcium pulse frequency, as determined by alterations in primary transcript (PT) expression. Perifused rat pituitary cells were given pulses of the calcium channel-activator Bay K 8644 (BK; with 10 mM KCl in the injectate) for 6 h. The response to alterations in pulse dose was examined by giving pulses of 1, 3, or 10 microM BK at 60-min intervals. Maximal increases in LHbeta and FSHbeta PTs were obtained with the 3-microM BK pulse dose and with the 10-microM dose for alpha. To investigate the effect of calcium pulse frequency, 3-microM BK pulses were given at intervals of 15, 60, or 180 min. Alpha PT was selectively stimulated by 15-min pulses and LHbeta by 15- and 60-min pulses of BK. In contrast, FSHbeta PT was maximally stimulated by the slower, 180-min pulse interval. These findings reveal that pulsatile increases in intracellular calcium stimulate alpha, LHbeta, and FSHbeta transcription in a differential manner. Thus, intermittent changes in intracellular calcium appear to be important in the transmission of GnRH pulse signals from the plasma membrane to the gene, and they may mediate the differential actions of pulse frequency on gonadotropin subunit gene expression.

Bay K-8644 in different solvents acts as a transient calcium channel antagonist and a long-lasting calcium channel agonist.

This report describes the effect of Bay K-8644 dissolved in various solvents on two types of calcium channel currents in neuroblastoma cells. Transient calcium channel (T channel) currents were not affected by Bay K-8644 dissolved in ethanol (EtOH) or polyethylene glycol (PEG). However, at the same concentration of 0.6 microM, Bay K-8644 dissolved in dimethylsulfoxide (DMSO) (Bay K-8644/DMSO) decreased the T channel current by 50%. The concentration of all three solvents in the bath was fixed at 0.3% to reach different final concentrations of Bay K-8644. At this fixed solvent concentration, the inhibitory effect of Bay K-8644/DMSO on T channel currents was dose-dependent; the solvents alone did not have any effect on T channel currents; and DMSO pretreatment of cells did not render the T channel current sensitive to Bay K-8644 dissolved in EtOH or PEG. Bay K-8644/DMSO was dried using a flash evaporator and redissolved in EtOH or PEG. Dried Bay K-8644 that was redissolved in EtOH or PEG to achieve a final concentration of 0.6 microM inhibited T channel currents by 39 or 35%, respectively. Furthermore, Bay K-8644 (10 nM) increased L channel currents by 80% with DMSO, but only 30% with EtOH as the solvent. These results show that in neuroblastoma cells Bay K-8644/DMSO, within the concentration range examined, is a T channel antagonist and more effective L channel agonist than Bay K-8644 dissolved in the two other solvents.

Ethanol exposure alters K+- but not bradykinin-induced dopamine release in PC12 cells.

The effects of ethanol on [3H]dopamine release were investigated in cultured PC12 cells using two methods to stimulate dopamine release: exposure to depolarizing concentrations of extracellular K+ and incubation with the highly active secretagogue, bradykinin. Both K+ and bradykinin dose-dependently increased [3H]dopamine release. The mean +/- S.E.M. EC50 for K+ was 35.8 +/- 1.2 mM; for bradykinin it was 1.07 +/- 0.23 x 10(-7) M. The characteristics of the bradykinin-stimulated dopamine release showed it to be dependent on extracellular Ca2+ and was attenuated by 1 mM Co2+ or 1 mM Ni2+. However, release was unaffected by either the voltage-dependent Ca2+ channel antagonist, verapamil, or the dihydropyridine (DHP) Ca2+ channel agonist, BAY K 8644. In contrast, 1 mM Co2+ completely blocked, verapamil inhibited and BAY K 8644 augmented K+-stimulated [3H]dopamine release. PC12 cells acutely exposed to ethanol (100 and 200 mM) showed diminished K+-stimulated [3H]dopamine release but an unaltered bradykinin-stimulated response. Cells exposed to 200 mM ethanol for 6 days showed significantly enhanced [3H]dopamine release in response to high concentrations of K+ but no changes were observed in their response to bradykinin. These data provide evidence that ethanol, within the same cell, can differentially affect neurotransmitter release, dependent upon the secretagogue used.