Altered modulation by excitatory amino acids of cortical phosphatidylinositol system stimulated by carbachol in rats poisoned by an anti-cholinesterase compound, diisopropyl fluorophosphate.

The effects of glutamate and N-methyl aspartate (NMDA) on carbachol-induced inositol phosphate (IP) accumulation were evaluated in slices of the cerebral cortex of rats treated with diisopropyl fluorophosphate (DFP) for 2 weeks. This induced an about 75% inhibition of cholinesterases. The IP accumulation induced by carbachol (expressed as ratio stimulated/basal IP content) was lower in DFP rats than in controls when incorporation of [3H]-myoinositol into membrane phospholipids and their hydrolysis were measured (no washing step between labeling and hydrolytic incubation). There were no differences in carbachol induced IP accumulation between control and DFP rats when only phosphoinositide hydrolysis was determined (hydrolytic incubation of prelabeled washed slices). When both incorporation of [3H]-myoinositol and the hydrolysis were measured, 0.5 mM glutamate and 0.1 mM NMDA caused a significant, about 40%, decrease of carbachol-induced IP accumulation in control rats; the inhibitory effects of glutamate and NMDA were not significant in DFP rats. When only hydrolytic IP accumulation by carbachol was studied, the inhibitory effects of glutamate and NMDA were very similar in control and DFP rats. Additional experiments on inositol phospholipid synthesis showed a significantly lesser [3H]-myoinositol incorporation (by about 30%) in DFP rats. This may explain the differences between the results obtained by the two methods. The overall data suggest that the attenuation of glutamate and NMDA effects in DFP-rats depends on a decrease of carbachol-induced IP accumulation or phosphoinositide synthesis rather than on the EAA specific action.