The functional role of molecular forms of acetylcholinesterase in neuromuscular transmission.

Abstract

The severity of poisoning following acetylcholinesterase (AChE) inhibition correlates weakly with total AChE activity. This may be partly due to the existence of functional and non-functional pools of AChE. AChE consists of several molecular forms. The aim of the present study was to investigate which of these forms will correlate best with neuromuscular transmission (NMT) remaining after partial inhibition of this enzyme. Following sublethal intoxication of rats with the irreversible AChE inhibitor soman, diaphragms were isolated after 0.5 or 3 h. It appeared that at 3 h after soman poisoning the percentage of G1 increased, while those of G4 and A12 decreased. NMT was inhibited more strongly than in preparations obtained from the 0.5 h rats with the same level of AChE inhibition, but with a normal ratio of molecular forms. NMT correlated positively with G4 as well as with A12, but inversely with G1. In vitro inhibition with the charged inhibitors DEMP and echothiophate resulted in higher levels of total AChE, relatively less G1 and more G4 and A12 than after incubation with soman, but led to less NMT. Treatment of soman-intoxicated rats with the reactivating compound HI-6 resulted in preferential reactivation of A12, persisting low levels of G1 and concurrent recovery of NMT as compared with saline-treated soman controls with equal total AChE activity. Apparently, in rat diaphragm G4 and A12 are the functional AChE forms.