Linkage of strain-specific nicotinic receptor alpha 7 subunit restriction fragment length polymorphisms with levels of alpha-bungarotoxin binding in brain.

Inbred mouse strains have been shown to differ in their levels of brain alpha-bungarotoxin binding. These differences in alpha-bungarotoxin receptors have been shown to correlate with an animal's sensitivity to nicotine-induced seizures. Recent studies have shown that the alpha 7 nicotinic acetylcholine receptor subunit is the major alpha-bungarotoxin binding site in rodent brain. In this report, we examined whether mouse strains that differ in levels of alpha-bungarotoxin binding and sensitivity to nicotine-induced convulsions also differ for the alpha 7 subunit. A full-length murine alpha 7 cDNA was cloned and sequenced and found to be identical to that of a mouse alpha 7 cDNA recently reported. Subsequently, a comparison of alpha 7 cDNA sequences and RNA species was performed between two strains (C3H/2 and DBA/2) that differ in levels of brain alpha-bungarotoxin binding and sensitivity to nicotine-induced seizures. The only difference observed was a single nucleotide difference in the open reading frame of alpha 7 that does not affect the primary amino acid sequence. Inbred strains were also surveyed for restriction fragment length polymorphisms at the alpha 7 locus. Strain-specific polymorphisms were identified, and F2 and backcross animals from a classic genetic cross between C3H/2 and DBA/2 mice were compared for the inheritance of alpha 7 genotype and alpha-bungarotoxin receptor levels. A significant association between genotype and receptor levels was observed in both, the F2 and backcross generations. These results indicate that alpha 7 genotype is an important determinant of alpha-bungarotoxin receptor levels.

Chronic corticosterone treatment elicits dose-dependent changes in mouse brain alpha-bungarotoxin binding.

Previous studies have shown that adrenalectomy results in a small increase in hippocampal alpha-bungarotoxin binding, whereas seven days of chronic treatment with high doses of corticosterone results in decreases in alpha-bungarotoxin binding in several brain regions. The studies reported here examined the effects of different doses of corticosterone on brain alpha-bungarotoxin binding. C3H mice were adrenalectomized and treated with corticosterone-containing pellets (0.5-60%) for four days. Alpha-Bungarotoxin binding was measured in eight brain regions. Chronic treatment with corticosterone resulted in plasma corticosterone levels ranging from the low levels observed in an unstressed mouse during the daytime to levels significantly above those observed in mice during the night or as a result of stress. Adrenalectomy resulted in small increases in binding in hippocampus which was reversed by low dose corticosterone treatment. Chronic high-dose corticosterone treatment resulted in significant decreases in binding in four of the eight brain regions examined. Similar, but not identical, results were obtained in two other mouse strains (C57BL and DBA/2). These results argue that corticosterone levels play an important role in modulating the level of the brain nicotinic receptors that bind alpha-bungarotoxin with high affinity.

Nicotinic receptor function determined by stimulation of rubidium efflux from mouse brain synaptosomes.

The ability of nicotinic agonists to activate ion channels resulting in Na+ and K+ fluxes has been used to develop a functional assay by using mouse brain synaptosomes. Synaptosomes prepared using Percoll gradients were enriched in binding sites for [3H]nicotine and were capable of accumulating the K+ analog, 86Rb+. The efflux of 86Rb+ from the synaptosomes was subsequently monitored using continuous superfusion at 21 degrees C. Ion flux was stimulated in a concentration-dependent manner by several nicotinic agonists, including L-nicotine, acetylcholine, N-methylcarbamylcholine and dimethylphenylpiperazinium. The process was stereoselective: L-nicotine was 30-fold more potent than D-nicotine. Cytisine stimulated ion flux at low concentrations, but this drug was less efficacious than most other agonists tested. Anabasine was also less efficacious than the other agonists. The EC50 values for agonist-stimulated efflux correlated closely to the IC50 values for inhibition of [3H]nicotine binding, but concentrations required to inhibit binding were lower than those required to stimulate ion flux. Nicotine-induced 86Rb+ efflux was blocked by several nicotinic antagonists including mecamylamine, D-tubocurarine, hexamethonium and decamethonium. Mecamylamine was approximately 50 times as potent as hexamethonium. Neither alpha-bungarotoxin nor atropine were effective antagonists and neuronal-bungarotoxin was a relatively ineffective inhibitor. The amount of nicotine-induced efflux varied among brain regions with midbrain (thalamus and mesencephalon) having the largest response and cerebellum the smallest. The magnitude of the ion flux correlated closely with the amount of [3H] nicotine binding in each brain region. The results indicate that a nicotinic-receptor-mediated ion flux can be measured in brain tissue and that the ion flux may serve as a useful functional assay for nicotinic receptors in the central nervous system. Furthermore, it is postulated that the nicotinic-agonist stimulated ion flux may be mediated by receptors measured by high affinity [3H]nicotine binding.