The neural changes accompanying sensitization of the gill-withdrawal reflex in Aplysia are associated with presynaptic facilitation at monosynaptic connections between sensory neurons and motor cells. To analyze the molecular mechanisms underlying the facilitation, the pharmacological actions of serotonin, octopamine, and dopamine were examined. Only serotonin enhanced synaptic transmission between the sensory and the motor neurons. A serotonin antagonist, cinanserin, reversibly blocked the synaptic facilitation. The action of serotonin may be mediated by adenosime 3',5'-monophosphate (cyclic AMP). Exposing the ganglion to dibutyryl cyclic AMP or injecting cyclic AMP into the cell body enhances the synaptic action of a sensory neuron. The mechanism of presynaptic facilitation, therefore, may include activation of one or more serotonergic neurons, which enhance the release of a neurotransmitter by increasing the intracellular concentration of cyclic AMP in the terminals of the sensory neurons.
In order to ascertain whether there are hippocampal electrophysiological modifications specifically related to memory, exploratory activity and emotional stress, extracellular electrical activity was recorded in hippocampal slices prepared from the brains of male adult rats. Several groups of animals were employed: (i) rats which had freely explored the experimental apparatus (8 min exposure); (ii) rats which had been subjected, in the same apparatus, to a fear conditioning paradigm training entailing the administration of aversive electrical footshocks (8 min exposure); (iii) rats to which the same number of aversive shocks had been administered in the same apparatus, but temporally compressed so as to make difficult the association between painful stimuli and the apparatus (30 s exposure); (iv) naïve rats never placed in the apparatus. Half of the rats from each treatment group were used for retrieval testing and the other half for hippocampal excitability testing. The conditioned freezing response was exhibited for no less than 4 weeks. Hippocampal excitability was measured by means of input-output curves (IOC) and paired-pulse facilitation curves (PPF). Retrieval testing or brain slices preparation were performed at increasing delays after the training sessions: immediately afterwards or after 1, 7 or 28 days. Only the rats subjected to the fear conditioning training exhibited freezing when placed again in the apparatus (retrieval testing). It was found that IOCs, with respect to naïve rats, increased in the conditioned animals up to the 7-day delay. In free exploration animals the IOCs increased only immediately after the training session. In all other rats no modification of the curves was observed. IOC increases do not appear to imply presynaptic transmitter release modifications, because they were not accompanied by PPF modifications. In conclusion, a clear-cut correlation was found between the increase in excitability of the Schaffer collateral-CA1 dendrite synapses and freezing response consolidation.
The effects of contextual fear-learning on hippocampal synaptic excitability were investigated by means of high frequency tetanic stimulation (HFS) in rat brain slices (hippocampal CA1 region), prepared at different intervals (immediately, 24 h or 7 days) after a one-trial contextual fear conditioning paradigm session. In the latter, rats that had previously received aversive electrical footshocks in the experimental apparatus exhibited freezing (the conditioned response) when placed again in the same apparatus (retrieval test). It was shown that contextual fear-learning affects the hippocampal synaptic response. In fact, the HFS produced a decrease in the amplitude of short-term (STP) and long-term potentiation (LTP) when compared to control "naïve" subject values. This decrease in STP amplitude could be observed only in slices prepared immediately after the training session. A decrease in the amplitude of long-term but not short-term potentiation was also observed at 24 h. At 7 days, no decreases in amplitude were observed. These modifications may be thought of as specifically associated with the learning process as they were not recorded in brain preparations from "shock-only" rats (i.e. those that received the same number of aversive stimuli of equal intensity as the conditioned group but with the shocks compressed temporally so that the shocked subjects could not associate nociceptive stimulation and surroundings - no conditioned freezing during retention testing). In "exploration" preparations (brain slices from rats having only freely explored the experimental apparatus without receiving any adverse stimulation) a decrease in LTP amplitude was recorded only immediately after the training session, and STP was never modified. The synaptic response modifications do not appear to be due to presynaptic events, as they are not associated with paired-pulse facilitation curve (PPF) modifications. The present results show that contextual fear conditioning and exploration of a novel environment (i) reduce the ability to induce synaptic plasticity; (ii) differentially influence STP and LTP and that (iii) the persistence of synaptic modifications depends on an animal's prior experience.
Using electrophysiological and biochemical approaches, we investigated the effects of chronic, intermittent ethanol (CIE) treatment on activation of the mitogen activated protein kinase (MAPK), also known as extracellular signal regulated protein kinase 1 and 2. In hippocampal slices taken from control rats, brief high-frequency stimulation to Schaffer collateral fibers induced a large post-tetanic potentiation (PTP) in the CA1 region that decayed to stable long-term potentiation (LTP) of field extracellular postsynaptic potentials. Western blot analyses showed that phosphorylation of MAPK was increased during PTP and returned to baseline levels during LTP. In slices from the rats removed immediately from CIE treatment, PTP and MAPK activation during the PTP was significantly less than that observed in control slices and LTP was absent. In slices from rats subjected to 1 day withdrawal from CIE treatment, both the reduction in MAPK phosphorylation during PTP and the impairment of PTP and LTP were still evident. Recovery of PTP and partial recovery of LTP was observed in slices obtained from 5-day withdrawn rats. However, MAPK activation during PTP was still attenuated significantly. Interestingly, MAPK activation was enhanced significantly during LTP in 5-day withdrawn rats as well as the sensitivity to MAPK inhibitor PD 098059. In addition to these changes in HFS-induced MAPK activation, we also observed a significant reduction in the basal phosphorylation of MAPK in slices removed from rats immediately after CIE treatment. These results implicate the MAPK signal transduction pathway as a potential cellular target of ethanol. Alterations in MAPKs could play an important role in the alcohol-induced changes in synaptic plasticity associated with the effects of alcohol abuse on learning and memory processes.
We identified a new form of activity-dependent modulation of the afterhyperpolarization (AHP) in tactile (T) sensory neurons of the leech Hirudo medicinalis. Repetitive intracellular stimulation with 30 trains of depolarizing impulses at 15-s inter-stimulus interval (ISI) led to an increase of the AHP amplitude (~60% of the control). The enhancement of AHP lasted for >/=15 min. The AHP increase was also elicited when a T neuron was activated by repetitive stimulation of its receptive field. The ISI was a critical parameter for the induction and maintenance of AHP enhancement. ISI duration had to fit within a time window with the upper limit of 20 s to make the training effective to induce an enhancement of the AHP amplitude. After recovery from potentiation, AHP amplitude could be enhanced once again by delivering another training session. The increase of AHP amplitude persisted in high Mg(2+) saline, suggesting an intrinsic cellular mechanism for its induction. Previous investigations reported that AHP of leech T neurons was mainly due to the activity of the Na(+)/K(+) ATPase and to a Ca(2+)-dependent K(+) current (I(K/Ca)). In addition, it has been demonstrated that serotonin (5HT) reduces AHP amplitude through the inhibition of the Na(+)/K(+) ATPase. By blocking the I(K/Ca) with pharmacological agents, such as cadmium and apamin, we still observed an increase of the AHP amplitude after repetitive stimulation, whereas 5HT application completely inhibited the AHP increment. These data indicate that the Na(+)/K(+) ATPase is involved in the induction and maintenance of the AHP increase after repetitive stimulation. Moreover, the AHP increase was affected by the level of serotonin in the CNS. Finally, the increase of the AHP amplitude produced a lasting depression of the synaptic connection between two T neurons, suggesting that this activity-dependent phenomenon might be involved in short-term plasticity associated with learning processes.
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