Preferential stimulation of ventral tegmental area dopaminergic neurons by nicotine.

The effect of intravenous (i.v.) nicotine on the single unit activity of midbrain dopamine (DA) neurons was studied in rats under either local or general anesthesia. Nicotine (50-500 micrograms/kg) produced a dose-related increase in the firing rate of nigral pars compacta DA cells (A9), up to 25% above baseline, irrespective of the preparation. The same range of doses was more than three times as effective on ventral tegmental area DA cells (A10) in rats paralyzed and given a local anesthetic. By contrast, the majority of these cells were temporarily depressed in deeply anesthetized animals. All of the above effects were reversed and prevented by i.v. mecamylamine suggesting the involvement of nicotine cholinergic receptors. Moreover, after nicotine-induced stimulation, low doses of i.v. apomorphine inhibited the firing rate similar to controls indicating that dopamine receptors are not directly involved in the nicotinic action. The results suggest that acute nicotine shares with other drugs of abuse the characteristic of being more effective in stimulating A10 than A9 neurons.

Responsiveness to 'autoreceptor' doses of apomorphine inversely correlated with the firing rate of dopaminergic A9 neurons: action of baclofen.

Supersensitivity of dopamine (DA) autoreceptors develops soon after acute treatments with baclofen or gamma-butyrolactone, two drugs which suppress DA neuronal firing. We have hypothesized that this effect might reflect a condition associated with the low firing rate of DA cells induced by such treatments rather than a long-term adaptive modification of DA receptor sensitivity. In this study we show that the degree of the intravenous apomorphine-induced inhibition of A9-DA neurons is inversely correlated to the basal firing rate of these neurons. When administered after baclofen, apomorphine further reduced DA cell activities in a manner proportional to the predrug firing rate, as in control rats. Since the minute doses of apomorphine which were used are thought to selectively activate DA autoreceptors, our finding may indicate that DA autoreceptor stimulation is more effective when the activity of the DA neurons is low, or it is decreased by drugs such as baclofen.

Computational characterization for catalytic activities of human CD38's wild type, E226 and E146 mutants.

A series of the complexes of human CD38's wild type, E226 and E146 mutants as well have been simulated. The biosoftwares well simulate the penetration of nicotinamide-adenine-dinucleotide (NAD) into the active site. The nicotinamide end of NAD penetrates deep into the active site consistent with cleavage of the nicotinamide-glycosidic bond which is the first step of catalysis creating a Michaelis complex regarded as the intermediate product of NAD cyclase and hydrolysis reaction. The breaking down hydrogen bond between 2'-3' OH ribosyl and the residues replaced Glu(226) makes NAD to be less constrained in active site and nicotinamide (NA) becomes more difficult to be cleaved and eliminates the mutant catalytic activities. The large majority of the substrate NAD is hydrolyzed to ADPR while the conversion of NAD to cADPR is not the dominant reaction catalyzed by wild-type human CD38. The more strongly kept ribosyl group by hydrogen bonds the more NADase and the less cyclase activity. Breaking hydrogen bonds of ribosyl 2'- and 3'-OH by mutation will loosen it to promote the cyclase. The cyclic adenosine diphosphate-ribose (cADPR) could also penetrate deeply into active site to make some hydrogen bonds with Glu(146) and Glu(226); however, its docking poses are affected by a residue located at the entrance of the catalytic pocket (Lys(129)). These results are in good agreement with the previous crystallographic analysis and the experiments quantified the catalytic activities of human CD38 and its mutants.