A cellular analysis of inhibition in the siphon withdrawal reflex of Aplysia

Recent behavioral experiments examining the siphon withdrawal reflex of Aplysia have revealed inhibitory effects of strong tail shock, a stimulus commonly used as an unconditioned stimulus in studies of associative and nonassociative learning in Aplysia. We utilized a reduced preparation to perform a cellular analysis of tail shock-induced inhibition in the siphon withdrawal reflex. First, we carried out behavioral studies that showed that the reduced preparation exhibits a siphon withdrawal reflex to water jet stimuli, and that tail shock produces inhibitory behavioral effects comparable to those in the intact animal: (1) strong shock produces transient inhibition of nonhabituated responses, and (2) a habituated response is facilitated by weak shock, but not by strong shock, suggesting that increasing tail shock intensity recruits the inhibitory process that competes with facilitation of habituated reflexes. Next, we carried out cellular studies that showed that the amplitude of the complex EPSP in siphon motor neurons elicited by water jet stimuli to the siphon also exhibits the inhibitory patterns produced by tail shock: (1) the nondecremented complex EPSP (a neural correlate of a nonhabituated siphon withdrawal reflex) is significantly inhibited 90 sec after strong tail shock and recovers to preshock levels 10 min later, and (2) the decremented complex EPSP (a neural correlate of a habituated reflex) is significantly facilitated by weak shock, but is not facilitated by strong shock. In addition to the complex EPSP, we simultaneously examined the monosynaptic connection between siphon sensory neurons and siphon motor neurons. The monosynaptic EPSP does not show the pattern of inhibitory modulation by tail shock exhibited by the siphon withdrawal reflex and the complex EPSP: (1) the nondecremented monosynaptic EPSP is not inhibited 90 sec after strong shock, but tends to be above preshock levels; and (2) the decremented monosynaptic EPSP is facilitated by weak as well as strong tail shock. Our results suggest that an important component of the inhibitory process triggered by strong tail shock is mediated by neural elements presynaptic to the siphon motor neurons. Because modulation of the monosynaptic connection between identified siphon sensory and siphon motor neurons does not parallel the tail shock-induced inhibitory patterns observed in the siphon withdrawal reflex and in the complex EPSP, other synaptic connections are likely to play an important role in mediating tail shock-induced inhibition in the siphon withdrawal reflex.     

Depletion of serotonin in the nervous system of Aplysia reduces the behavioral enhancement of gill withdrawal as well as the heterosynaptic facilitation produced by tail shock

Noxious stimuli, such as electrical shocks to the animal's tail, enhance Aplysia's gill- and siphon-withdrawal reflex. Previous experimental work has indicated that this behavioral enhancement, known as dishabituation (if the reflex has been habituated) or sensitization (if it has not been habituated), might be mediated, at least in part, by the endogenous monoaminergic transmitter serotonin (5-HT). To assess 5-HT's role in dishabituation and sensitization of Aplysia withdrawal reflex, we treated Aplysia with the serotonergic neurotoxin 5,7-dihydroxytryptamine (5,7-DHT). We found that 5,7-DHT treatment significantly reduced the dishabituation of the withdrawal reflex produced by tail shock. Treatment with the neurotoxin also blocked the heterosynaptic facilitation of monosynaptic connections between siphon sensory neurons and their follower cells, which contributes to the behavioral enhancement. Analysis by high-performance liquid chromatography indicated that 5,7-DHT treatment significantly reduced 5-HT levels in the Aplysia CNS. Moreover, the neurotoxic effects of 5,7-DHT appeared to be relatively specific for serotonergic pathways. Thus, 5,7-DHT treatment did not disrupt the ability of nonserotonergic facilitatory interneurons, the L29 cells, to facilitate the connections of siphon sensory neurons. Also, 5,7-DHT reduced 5-HT-dependent, but not dopamine-dependent, histofluorescence in Aplysia central ganglia. Finally, 5,7-DHT does not reduce the levels of the facilitatory peptides SCPA and SCPB within the Aplysia CNS. Our results, together with those of Mackey et al. (1989), indicate that 5-HT plays a major role in mediating dishabituation and sensitization of Aplysia's withdrawal reflex.     

The contribution of facilitation of monosynaptic PSPs to dishabituation and sensitization of the Aplysia siphon withdrawal reflex.

To examine the relationship between synaptic plasticity and learning and memory as directly as possible, we have developed a new simplified preparation for studying the siphon-withdrawal reflex of Aplysia in which it is relatively easy to record synaptic connections between individual identified neurons during simple forms of learning. We estimated that monosynaptic EPSPs from LE siphon sensory neurons to LFS siphon motor neurons mediate approximately one-third of the reflex response measured in this preparation, which corresponds to siphon flaring in the intact animal. To investigate cellular mechanisms contributing to dishabituation and sensitization, we recorded evoked firing of LFS neurons, the siphon withdrawal produced by stimulation of an LFS neuron, the complex PSP in an LFS neuron, and the monosynaptic PSP from an "on-field" or "off-field" LE neuron to an LFS neuron during behavioral training. Unlike the simplified gill-withdrawal preparation (Cohen et al., 1997; Frost et al., 1997), in the siphon-withdrawal preparation we found no qualitative differences between the major cellular mechanisms contributing to dishabituation and sensitization, suggesting that dissociations that have been observed previously may be attributable to transient inhibition that does not occur for this component of the reflex. Furthermore, in the siphon-withdrawal preparation, all of the various cellular measures, including monosynaptic PSPs from either on-field or off-field LE neurons, changed approximately in parallel with changes in the behavior. These results provide the most direct evidence so far available that both dishabituation and sensitization involve multiple mechanisms, including heterosynaptic facilitation of sensory neuron-motor neuron PSPs.     

Identified serotonergic neurons LCB1 and RCB1 in the cerebral ganglia of Aplysia produce presynaptic facilitation of siphon sensory neurons

Several lines of evidence suggest that 5-HT plays a significant role in presynaptic facilitation of the siphon sensory cells contributing to dishabituation and sensitization of the gill- and siphon-withdrawal reflex in Aplysia. Most recently, Glanzman et al. (1989) found that treatment with the 5-HT neurotoxin, 5,7-DHT markedly reduced both synaptic facilitation and behavioral dishabituation. To provide more direct evidence for a role of 5-HT, we have attempted to identify individual serotonergic facilitator neurons. Hawkins (1989) used histological techniques to locate several serotonergic neurons in the ring ganglia that send axons to the abdominal ganglion and are therefore possible serotonergic facilitators. These include one neuron in the B cluster of each cerebral ganglion, which we have identified electrophysiologically and named the CB1 cells. Both glyoxylic acid histofluorescence and 5-HT immunofluorescence indicate that the CB1 neurons are serotonergic. In a semiintact preparation, the CB1 neurons respond to cutaneous stimulation which produces dishabituation and sensitization (such as tail shock) with an increase in firing, which may outlast the stimulation by 15 min. Intracellular stimulation of a CB1 neuron in a manner similar to its response to tail shock produces facilitation of the EPSPs from siphon sensory neurons to motor neurons, as well as broadening of the action potential in the sensory neurons in tetraethylammonium solution. These results strongly suggest that the identified serotonergic CB1 neurons participate in mediating presynaptic facilitation contributing to dishabituation and sensitization of the gill- and siphon-withdrawal reflex in Aplysia.     

Contribution of polysynaptic pathways in the mediation and plasticity of Aplysia gill and siphon withdrawal reflex: evidence for differential modulation.

The gill and siphon withdrawal (GSW) reflex of Aplysia is centrally mediated by a monosynaptic and a polysynaptic pathway between sensory and motor neurons. The first objective of this article was to evaluate quantitatively the relative importance of these two components in the mediation of the GSW reflex. We have used an artificial sea water (ASW) solution containing a high concentration of divalent cations to raise the action potential threshold of the interneurons without affecting the monosynaptic component of the reflex (2:1 ASW). Compound EPSPs induced in gill or siphon motor neurons by direct stimulation of the siphon nerve or by tactile stimulation of the siphon skin were reduced by more than 75% in 2:1 ASW. These results indicate that interneurons intercalated between sensory and motor neurons are responsible for a considerable proportion of the afferent input to the motor neurons of the reflex. The second objective of this article was to compare the modulation of the monosynaptic and polysynaptic pathways. We have evaluated their respective contribution in sensitization of the GSW reflex by testing the effects of two neuromodulators of the reflex, 5-HT and small cardioactive peptide B (SCPB). We found that these two neuromodulators have a differential action on the two components of the GSW neuronal network. The polysynaptic pathway was more facilitated than the monosynaptic pathway by the neuropeptide SCPB. By contrast, 5-HT displayed an opposite selectivity. These results suggest that the polysynaptic component of the neuronal network underlying the GSW reflex is very important for its mediation. The data also indicate that the monosynaptic and polysynaptic components of the reflex can be differentially modulated. The diversity of modulatory actions at various sites of the GSW network should be relevant for learning-associated modifications in the intact animal.     

Identified FMRFamide-immunoreactive neuron LPL16 in the left pleural ganglion of Aplysia produces presynaptic inhibition of siphon sensory neurons.

The gill- and siphon-withdrawal reflex of Aplysia undergoes transient inhibition following noxious stimuli such as tail shock. This behavioral inhibition appears to be due in part to transient presynaptic inhibition of the siphon sensory cells, which can be mimicked by application of the peptide FMRFamide. Although FMRFamide is widespread in the Aplysia nervous system, an FMRFamide-containing inhibitory neuron has not previously been identified. We have searched for such a neuron by combining FMRFamide immunofluorescence with fluorescent dye backfilling from the abdominal ganglion, the location of the siphon sensory cells. These methods localized a neuron in the left pleural ganglion, which we have named LPL16. LPL16 is FMRFamide immunoreactive; it is excited by tail shock; and stimulation of LPL16 produces inhibition of siphon sensory cell-to-motor cell postsynaptic potentials and narrowing of action potentials in the sensory cells in tetraethylammonium solution. These results indicate that LPL16 participates in the inhibitory effects of tail shock, and support the idea that FMRFamide plays a physiological role in the inhibition.     

Localization of potential serotonergic facilitator neurons in Aplysia by glyoxylic acid histofluorescence combined with retrograde fluorescent labeling

A variety of evidence suggests that 5-HT participates in presynaptic facilitation of the siphon sensory cells contributing to dishabituation and sensitization of the gill- and siphon-withdrawal reflex in Aplysia. Most recently, Glanzman et al. (1989) have shown that the 5-HT neurotoxin 5,7-DHT markedly reduces both the synaptic facilitation and behavioral dishabituation produced by tail shock. To provide more direct evidence for a role of 5-HT, I have used histological techniques to try to locate individual serotonergic facilitator neurons. I first used a modification of the glyoxylic acid histofluorescence technique to map serotonergic and dopaminergic neurons in the CNS of Aplysia. Intracellular fluorescent labeling combined with histofluorescence indicates that the previously identified L29 facilitator neurons are not serotonergic. Nerve transection experiments suggest that most of the perisomatic 5-HT histofluorescence in the abdominal ganglion (the location of the siphon sensory cells) comes from neurons whose cell bodies are located in the pedal or cerebral ganglia. As there are at least 500 serotonergic neurons in those ganglia, I combined retrograde fluorescent labeling with histofluorescence to identify a small subset of those neurons which send processes to the abdominal ganglion and are therefore potential serotonergic facilitators. In the following paper, Mackey et al. (1989) show that stimulation of 2 of those neurons in the cerebral ganglia (the CB1 cells) produces presynaptic facilitation of the siphon sensory cells contributing to dishabituation and sensitization of the withdrawal reflex.     

Stimuli that produce sensitization lead to elevation of cyclic AMP levels in tail sensory neurons ofAplysia

Facilitation of synaptic connections between sensory neurons and motor neurons mediating the tail withdrawal reflex in Aplysia is produced by the modulatory effects of sensitizing stimuli. Facilitation can be mimicked by perfusing these neurons with serotonin (5-HT) in a semi-intact preparation. Consequently, 5-HT has been presumed to be acting as an agonist of the modulatory transmitter that mediates sensitizing input in vivo. While the 5-HT effects appear to be mediated by increased cyclic adenosine monophosphate (cAMP) levels in the sensory neurons, a critical issue that has not been examined is whether sensitizing stimuli also increase cAMP levels in these cells. We now report that such sensitizing stimuli delivered to the tail of a semi-intact preparation lead to elevation of cAMP levels in the tail sensory neurons.     

Serotonin and cyclic adenosine 3':5'-monophosphate modulate the potassium current in tail sensory neurons in the pleural ganglion of Aplysia

Tail sensory neurons in the pleural ganglion that mediate the afferent portion of the tail withdrawal reflex in Aplysia californica undergo heterosynaptic facilitation of transmitter release during sensitization. As in the siphon sensory neurons, the transmitter serotonin produces facilitation and also elicits a slow, decreased conductance excitatory postsynaptic potential (EPSP) in these neurons. Using voltage clamp and biochemical analyses, we have found that the slow EPSP in the pleural sensory neurons is due to a decrease in a potassium conductance identical to the S potassium current characterized in siphon sensory neurons. Like the S current, the current modulated by serotonin in the pleural sensory neurons is a non-inactivating potassium current, and it contributes to both the resting and action potentials. The current reverses in 120 mM external K+ at -20 mV, close to the predicted Nernst equilibrium potential. Intracellular cesium blocks the serotonin response, but the current is not blocked by equimolar substitution of barium for calcium, nor by 50 mM tetraethylammonium chloride. The effect of serotonin is cAMP dependent, since serotonin elevates cAMP and both cAMP injection and forskolin mimic the serotonin response. These results indicate that the mechanism associated with sensitization of the siphon-gill withdrawal reflex, a slow decreased potassium conductance, is also a component of the neuronal circuitry underlying modulation of another reflex, the tail withdrawal reflex. Therefore, two distinct populations of neurons subserving similar behavioral functions have related biophysical and biochemical properties.     

Intracellular responses of raphe magnus neurons during the jaw-opening reflex evoked by tooth pulp stimulation

Neurons in the nucleus raphe magnus (RM) may play an important role in the modulation of nociception. To determine how RM neurons are activated during a nociceptive reflex, the intracellular responses of raphe neurons were studied during the jaw-opening reflex (JOR) elicited by tooth pulp shock in lightly anesthetized cats. Tooth pulp stimulation produces reflex EMG activation of the digastric muscle at a latency of 7-11 ms, resulting in jaw opening. Tooth pulp shock that elicits the JOR also produces an EPSP in a subset of raphe neurons. This EPSP consists of an early small depolarization that occurs at a latency of 10-15 ms followed by a larger depolarization at a latency of 20-60 ms. In all cases the latency to EPSP is longer than the latency to digastric EMG onset. Electrical stimulation of the 4 paws elicits oligosynaptic EPSPs in the same cells at a latency of 16-20 ms. Electrical train stimulation of the midbrain periaqueductal gray region (PAG) suppresses the JOR. Single shock stimulation at the same PAG sites that suppress the JOR evokes monosynaptic EPSPs in the large majority of raphe neurons recorded. In all cases, the threshold for EPSP is below the threshold for suppression of the JOR. The EPSP amplitude is a direct function of PAG stimulus intensity and there is temporal summation of EPSPs evoked by paired PAG shocks. At condition-test intervals of 40-90 ms, train stimulation of PAG suppresses the tooth pulp-evoked EPSP in raphe neurons. The threshold for EPSP suppression occurs at a PAG stimulation intensity below that required for suppression of the JOR. The present findings provide evidence that RM neurons may play an important role in the modulation of the tooth pulp-evoked JOR, but only after the initial withdrawal reflex has occurred.     

Development of learning and memory in Aplysia. III. Central neuronal correlates

The defensive withdrawal reflex of the mantle organs of Aplysia californica has 2 major components, siphon withdrawal and gill withdrawal. In the previous paper of this series (Rankin and Carew, 1987), the development of 2 forms of nonassociative learning, habituation and dishabituation, was examined in the siphon withdrawal component of the reflex. In the present study we examined these same forms of learning in the gill withdrawal component of the reflex. The purpose of these experiments was 2-fold: to examine the development of learning in the other major component of the reflex; and to establish preparations in which it is possible to carry out a cellular analysis of the development of learning in the CNS. We first established that the gill withdrawal reflex in intact animals exhibited significant habituation in response to repeated tactile stimulation of the siphon and significant dishabituation in response to tail shock. We next determined the contribution of the CNS to the gill withdrawal reflex by surgically removing the abdominal ganglion from intact animals. Using the same stimulus intensity (4 mg) that produced habituation in the previous experiments, we found that the CNS accounted for approximately 95% of the reflex. Finally, we developed 2 preparations that allowed us to relate behavioral observations of learning directly to neural plasticity exhibited in the CNS. In a semi-intact preparation gill withdrawal was behaviorally measured as in the intact animal, but tactile stimulation of the siphon (to produce habituation) and shock to the tail (to produce dishabituation) were replaced by electrical stimulation of the siphon nerve and left connective, respectively. Stimulation parameters were matched to produce behavioral responses comparable with those in the intact animal. In an isolated CNS preparation the same nerve stimuli were used as in the semi-intact preparation, but the response measure used was the evoked neural discharge recorded in an efferent nerve innervating the gill. Both preparations exhibited response decrement and facilitation that was quantitatively as well as qualitatively similar to that observed in intact animals, indicating that 2 simple forms of learning exhibited by the gill withdrawal reflex in juvenile Aplysia can be localized to neural circuits within the abdominal ganglion.     

Heterosynaptic facilitation and behavioral sensitization are inhibited by lowering endogenous cAMP in Aplysia

An adenylate cyclase inhibitor, RMI 12330A, is able to depress cAMP synthesis stimulated by serotonin in the abdominal ganglion of Aplysia depilans and punctata. This substance reversibly blocked the heterosynaptic facilitation, induced by activation of serotonergic pathways, of the EPSP recorded from L7 motoneuron in abdominal ganglion after electrical stimulation of the siphon nerve. RMI 12330A, injected into whole unrestrained animals, inhibited the short-term dishabituation of the siphon withdrawal reflex. These findings demonstrate that the increase of endogenous cAMP in the sensory neurons mediating the gill and siphon withdrawal reflex is an essential step in the mechanism of potentiation of the transmitter output underlying heterosynaptic facilitation and short-term behavioral sensitization.     

Inhibitory neuron produces heterosynaptic inhibition of the sensory-to-motor neuron synapse in Aplysia.

We have identified an inhibitory neuron (RPL4) in the right pleural ganglion of Aplysia, which produced hyperpolarization of the sensory and motor neurons involved in the tail withdrawal reflex. Activation of RPL4 significantly reduced the amplitude of excitatory postsynaptic potentials produced in tail motor neurons by action potentials triggered in sensory neurons. This example of heterosynaptic inhibition was due, at least in part, to an increase in membrane input conductance in the motor neuron. Since the synaptic strength of the sensory-to-motor neuron connection has been associated with the strength of the tail withdrawal reflex, RPL4 may contribute to modulation of that reflex.     

Multiple sensory neuronal correlates of site-specific sensitization in Aplysia

Noxious stimulation of a restricted site on the skin of Aplysia (training) causes site-specific sensitization of the tail-withdrawal reflex that is associated with several sensory correlates that are evident both 10 min and 2 hr after training. First, extracellularly recorded afferent activity evoked by test stimulation of the trained site increases, indicating peripheral sensory changes. Second, central sensory alterations are manifested by tail sensory neurons within the pleural VC cluster that innervate the trained site and are activated during training. These mechanosensory/nociceptive cells display a number of differences from unactivated tail sensory neurons innervating other sites: slow depolarization of the soma observed immediately after training, decrease in soma action potential threshold, and enhancement of monosynaptic EPSPs to identified motor neurons. Noxious stimulation of a more extensive region also produces site-specific sensitization of the tail-withdrawal reflex and site-specific enhancement of EPSP amplitude measured 1 d after training. This training produced a novel cellular correlate of behavioral enhancement in Aplysia--regenerative bursting responses (2-35 spikes) in response to brief depolarization of the sensory neuron soma. The changes in peripheral and central excitability appear similar to changes associated with mammalian models of primary hyperalgesia. Site-specific enhancement of nociceptive signaling also occurs during aversive associative conditioning in a noxious unconditioned stimulus (US) pathway. These site-specific changes involve activity-dependent extrinsic modulation (ADEM) of the VC sensory neurons, suggesting a close relationship to changes underlying associative conditioning in conditioned stimulus (CS) pathways in Aplysia.     

The cellular analog of sensitization in Aplysia emerges at the same time in development as behavioral sensitization

Recent studies examining the development of learning and memory in the gill and siphon withdrawal reflex of Aplysia have shown that different forms of learning emerge according to very different developmental timetables. For example, in the previous paper, Rankin and Carew (1988) showed that, whereas habituation and dishabituation emerge early in juvenile development (in stages 9 and 10, respectively), sensitization emerges at least 60 d later (in late stage 12). This developmental separation of different learning processes provides the opportunity to examine the unique contribution of specific cellular mechanisms to each form of learning. As a first step in this cellular analysis, in the present paper we have examined the development of the cellular analog of sensitization (facilitation of nondecremented EPSPs) in the identified giant neuron R2, which can serve as a monitor of the afferent input in the gill and siphon withdrawal reflex (Rayport and Camardo, 1984). We have found 2 striking parallels between the development of behavioral sensitization and the development of its cellular analog: (1) Behavioral sensitization, produced by tail shock, emerges very late in juvenile development (stage 12), and the cellular analog of sensitization (produced by activation of the tail pathway) emerges by exactly the same late juvenile stage; (2) prior to the emergence of behavioral sensitization, tail shock unexpectedly was found to produce significant reflex depression (Rankin and Carew, 1988), and prior to the emergence of the cellular analog of sensitization, activation of the tail pathway was found to produce significant depression of the synaptic input in the reflex pathway. Thus, the cellular analog of sensitization in the CNS develops and matures in close temporal register with the development of behavioral sensitization in juvenile Aplysia.     

Acute modulation of synaptic transmission to motoneurons by BDNF in the neonatal rat spinal cord

We investigated the acute effects of bath applied BDNF on synaptic input to motoneurons in the hemisected spinal cord of the neonatal rat. Motoneurons were recorded intracellularly, and BDNF-induced modulation of the synaptic response to stimulation of the homologous dorsal root (DR) and the ventrolateral funiculus (VLF) was examined. All motoneurons exhibited long-lasting (up to several hours) depression of the DR-activated monosynaptic AMPA/kainate-receptor mediated EPSP in response to BDNF but in about half of the motoneurons this was preceded by facilitation. VLF-evoked AMPA/kainate EPSPs in the same motoneurons were unaffected. BDNF effects were blocked by K252a and were not observed in neonates older than 1 week. Bath applied NMDA antagonists APV and MK-801 abolished both facilitatory and inhibitory actions of BDNF on the AMPA/kainate responses indicating the requirement for functional NMDA receptors. The pharmacologically isolated, DR-evoked, NMDA receptor-mediated response exhibited the same pattern of changes after BDNF superfusion. When introduced into the motoneuron through the recording microelectrode, MK-801 selectively blocked the facilitatory action of BDNF. Furthermore, BDNF enhanced NMDA-induced depolarization of the motoneuron in the presence of tetrodotoxin (TTX), thus, confirming its facilitatory effect on motoneuron NMDA receptors. Bath application of either BDNF or NMDA depressed the monosynaptic EPSP after selective blockade of postsynaptic NMDA receptors indicating a role for presynaptic NMDA receptors in BDNF-induced inhibitory action. Thus, BDNF-induced facilitation of monosynaptic EPSPs in neonatal rats is mediated by direct effects on postsynaptic NMDA receptors, while its inhibitory action occurs presynaptically.     

Dishabituation and sensitization emerge as separate processes during development in Aplysia

Until recently, dishabituation and sensitization have commonly been considered to reflect a unitary process: Sensitization refers to a general facilitation produced by strong or noxious stimuli that enhances subsequent responding; dishabituation has been thought to represent a special instance of sensitization in which the facilitation is simply superimposed on a habituated response level. The unitary process hypothesis was based on the observation that both decremented and nondecremented responses are facilitated by a common noxious or strong stimulus. However, this observation does not rule out the possibility that dishabituation and sensitization could reflect separate processes that are activated in parallel by a strong stimulus. Recent cellular experiments by Hochner et al. (1986) suggest that this, in fact, occurs in the sensory neurons of the gill withdrawal reflex in Aplysia. A developmental analysis of learning in the marine mollusc Aplysia permits a direct behavioral test of this hypothesis. If dishabituation and sensitization reflect a unitary process then they should emerge at the same time ontogenetically. On the other hand, if they reflect different processes, then they might emerge according to different ontogenetic timetables. In the present study we examined the temporal emergence of dishabituation and sensitization in the defensive siphon withdrawal reflex in 3 stages of juvenile Aplysia: stage 11, early stage 12, and late stage 12. Animals received one of 2 kinds of training: Dishabituation training, in which the effect of strong tail shock on habituated responses were observed, and Sensitization training, in which the effect of strong tail shock on nondecremented responses was observed. We found that, while dishabituation was present in all stages examined, sensitization did not emerge until several weeks later, in late stage 12. These results were confirmed and extended in a group of animals that were tested twice: first in stage 11, when they showed no sensitization, and again 13 weeks later, in late stage 12, when they then showed significant sensitization. Our analysis of nondecremented responses prior to the emergence of sensitization also revealed an unexpected inhibitory component of tail shock that produces reflex depression. Moreover, there was a clear progression in the net effects of tail shock during development: reflex depression was produced in stages 11 and early stage 12, followed by a transition to reflex facilitation (sensitization) in late stage 12. Finally, when sensitization emerged in late stage 12, the process of dishabituation showed a significant increase compared with previous developmental stages.(ABSTRACT TRUNCATED AT 400 WORDS)     

A short duration GABAergic inhibition in identified neostriatal medium spiny neurons: in vitro slice study

Inhibition in the neostriatum was investigated in rat in vitro slice preparation using intracellular recording and labeling technique. The initial response recorded following local stimulation is a monosynaptically activated EPSP. In 17% of the neurons tested, IPSPs were observed following EPSPs evoked by local stimulation. In paired shock experiments reduction of test EPSP amplitude or action potentials occurred over interstimulus intervals (ISIs) of 3-38 msec. In some neurons, a pulse injection of depolarizing current was used to trigger an action potential which was in a paired shock, used to condition a test monosynaptically induced EPSP. Test EPSPs were shunted over ISIs less than 45 msec. Paired shock performed on the slices perfused with the medium containing GABA antagonists (e.g., bicuculline methiodide, picrotoxin, or penicillin-G) resulted invariably in potentiation of test EPSPs. Inhibition in the neostriatum in vitro is demonstrated as reduction in test amplitude in paired shock tests, by the presence of IPSPs and by the shunting of EPSPs conditioned by an action potential triggered by direct depolarization. Neurons exhibiting these forms of inhibition were intracellularly labelled with HRP and identified as medium spiny neurons. These results indicate that striatal GABAergic medium spiny neurons which are known to have an extensive axon collateral plexus play in a role in a short lasting inhibition observed in the striatum.     

Corticofugal influences on the reticulospinal neurons of gigantocellular nucleus in cats]

Stimulation of the motor cortex evoked excitatory and inhibitory PSP in reticulospinal neurons of the cat gigantocellular nucleus. EPSP were recorded in 94.3% of the investigated neurons and IPSP in 5.7%. Analysis of the presynaptic pathways showed that 77.4% of EPSPs appeared through monosynaptic and 22.6% through polysynaptic corticoreticular connections. According to latency, duration and rise time all monosynaptic EPSP were divided into two groups (fast and slow). Obviously, fast EPSPs are generated by fast corticobulbar fibres and slow ones by slow fibres. IPSP were recorded in neurons which were also inhibited by stimulation of the ventral funiculi of the spinal cord. It is suggested that motor cortical signals can be transmitted to the spinal cord through both mono- and polysynaptic connections of the fast and slow pyramidal neurons with reticulospinal neurons.     

Selective modulation of spike duration by serotonin and the neuropeptides, FMRFamide, SCPB, buccalin and myomodulin in different classes of mechanoafferent neurons in the cerebral ganglion of Aplysia

An examination of the cellular properties and synaptic outputs of mechanoafferent neurons found on the ventrocaudal surface of the cerebral ganglion of Aplysia indicated that the cerebral mechanoafferent (CM) neurons are a heterogeneous population of cells. Based on changes in action potential duration in response to bath applications of 5-HT in the presence of TEA, CM neurons could be divided into 2 broad classes: mechanoafferents whose spikes broaden in response to 5-HT (CM-SB neurons) and mechanoafferents whose spikes narrow in response to 5-HT (CM-SN neurons). Morphological and electrophysiological studies of the CM-SN neurons indicated that they were comprised of previously identified interganglionic cerebral-buccal mechanoafferent (ICBM) neurons and a novel set of sensory neurons that send an axon into the LLAB cerebral nerve and have perioral zone receptive fields that are similar to those of ICBM neurons. Changes in spike width due to 5-HT were correlated with changes in synaptic output as indicated by the magnitudes of EPSPs evoked in postsynaptic neurons. Electrical stimulation of cerebral nerves and connectives also produced spike narrowing or broadening, and the sign of the effect was a function of the parameters of stimulation. Both heterosynaptic facilitation and heterosynaptic depression of EPSPs evoked in follower cells could be demonstrated. A variety of putative neuromodulators other than 5-HT were also found to affect the duration of action potentials in both classes of CM neurons. FMRFamide had effects opposite to that of 5-HT. SCPB and a recently characterized Aplysia neuropeptide, buccalin, broadened the spikes of both CM classes. Another neuropeptide, myomodulin, decreased the duration of CM-SB neuron spikes but had no effect on CM-SN spikes. Since the CM neurons appear to mediate a variety of competing behaviors, including feeding, locomotion, and defensive withdrawal, the various neuromodulator actions may contribute to the mechanisms whereby behaviors are selected and modified.