Taurine- and FMRFamide-dependent modulation of receptor- and voltage-gated currents by cerebrolysine in molluscan neurons

Abstract

The action of cerebrolysine, a biogenic stimulator, on the receptor- and voltage-gated ionic currents was studied in identifiedHelix pomatia neurons. Cerebrolysine reversibly suppressed the acetylcholine (ACh)- and glutamate (GLU)-induced chloride currents in some neurons (LP11, B4, E12) with a latency of 9±3 sec, while not affecting these currents in other neurons. The suppressing effect of cerebrolysine on the voltage-gated sodium and calcium currents was also selective. There were “fast” and “slow” phases, with latencies of 52±8 sec and 5±1 min, respectively, in the cerebrolysine effect on the voltage-gated sodium current. The effect of cerebrolysine on the sodium current during the “fast” suppression phase could be simulated with FMRFamide (10−5 M), while those exerted on the ACh- and GLU-induced currents could be simulated with taurine (10−6 M). The effects of cerebrolysine and the above substances were non-additive. These facts allow us to suggest that both taurine and FMRFamide (or its fragment) are involved in the mechanism of posttraumatic and postsurgical curative effects of cerebrolysine.