Morphofunctional effects of applications of glutamate and dopamine on the goldfish Mauthner neurons

In the goldfish, we studied the effects of intramedullar applications of glutamate (Glu), dopamine (DA), and of long-lasting rotational stimulation on the functional activity, dimensional characteristics, and ultrastructure of Mauthner neurons (MNs). Applications of Glu, especially when combined with rotational stimulation, were found to result in suppression of the function of MNs, in a decrease in their dimensions and lengths of desmosome-like contacts (DLCs, whose structure is determined by filamentous actin) in afferent mixed and chemical synapses, and in destruction of actin microfilaments in the cytoskeleton of MNs. Applications of DA, vice versa, induced an increase in the resistance to the effects of long-lasting stimulation and stabilized the dimensions of MNs; the length of DLCs increased in afferent synapses of both the above types, and the number of fibrillar actin bridges in the DLC cleft of mixed synapses also increased. Bundles of the actin filaments, which were preserved after stimulation, appeared in the cytoskeleton of MNs. Testing of the action of neurotransmitters on actin preparations in vitro showed that Glu entirely depolymerizes filamentous actin, while DA, vice versa, polymerizes monomeric actin. Thus, the Glu-and DA-induced reactions are similar in their types and are of a reciprocal nature both in the actin cytoskeleton of MNs in situ and in purified actin in vitro; these effects correlate with suppression of the functional state of MNs under the influence of Glu and with stabilization of this state under the influence of DA. These results agree with the concept on the roles of depolymerization and polymerization of actin in changes of the morphofunctional state of MNs and show that actin of the cytoskeleton of MNs is a cellular target for the actions of Glu and DA. The similarity between the effects of tested neurotransmitters on actin in MNs in situ and in cell-free preparations in vitro allows us to hypothesize that these transmitters can penetrate into the neuron.