Serotonin modulates a specific potassium current in the sensory neurons that show presynaptic facilitation in Aplysia.

Serotonin exerts a long-lasting excitatory action on sensory neurons of Aplysia californica by decreasing outward K+ current. The depression of outward current delays repolarization of the action potential and extends the duration of Ca2+ influx into the presynaptic terminals, thereby contributing to the facilitation of transmitter release that underlies behavioral sensitization. We have extended the analysis of serotonin's action and find that it acts on a specific serotonin-sensitive K+ current (S current), which is different from the early K+ current (IA), the delayed K+ current (IK), the Ca2+-dependent K+ current (IC), and the muscarine-sensitive M current. The serotonin-sensitive current in these cells persists when IA and IK are reduced by conditioning depolarization or channel-blocking agents. The S current is not activated by intracellular injection of Ca2+, nor is it affected by substitution of Ba2+ for Ca2+, a treatment that reduces IC. Moreover, intracellular injection of cyclic AMP exerts an effect indistinguishable from that of serotonin. This observation and the insensitivity of the current to Ba2+ distinguishes the S current from M current. S current is activated at the resting potential and does not inactivate with steady-state depolarization. It is active sufficiently early during an action potential to contribute to the repolarization of the action potential and therefore accounts for the physiological effects of serotonin.     

Additional component in the cellular mechanism of presynaptic facilitation contributes to behavioral dishabituation in Aplysia.

Sensitization of defensive gill and siphon withdrawal reflexes in Aplysia results, in part, from presynaptic facilitation of transmitter release from mechanoreceptor sensory neurons that innervate the siphon skin and synapse with interneurons and motor neurons. Presynaptic facilitation also can be elicited by application of serotonin. This facilitation is associated with two phenomena, a prolongation of the presynaptic action potential resulting from a decrease in a specific K+ current and an enhancement of the Ca2+ transients elicited by depolarization. Previous work has shown that prolongation of the action potential enhances synaptic transmission at normal levels of release. Here we report that an additional set of processes also contributes to facilitation. When repeated activation of the sensory neurons induces profound homosynaptic depression, prolonging the duration of action potentials (or of depolarizing commands under voltage clamp) has little effect on transmitter release. Nonetheless, serotonin is still capable of enhancing release. Since homosynaptic depression underlies the behavioral process of habituation, the second set of processes, by counteracting the consequences of the depression, seems to mediate the effects of dishabituation in the sensory neuron. Prolongation of the action potential by closure of the K+ channel seems to mediate the effects of sensitization.     

Serotonin increases intracellular Ca2+ transients in voltage-clamped sensory neurons of Aplysia californica.

Noxious stimulation of the tail of Aplysia californica produces behavioral sensitization; it enhances several related defensive reflexes. This reflex enhancement involves heterosynaptic facilitation of transmitter release from sensory neurons of the reflex. The facilitation is stimulated by serotonin (5-HT) and involves suppression of a 5-HT-sensitive K+ current (the S current). Suppression of the S current broadens the action potential of the sensory neurons and is thought to enhance transmitter release by prolonging entry of Ca2+ in the presynaptic terminals. We now report a component of enhanced Ca2+ accumulation that is independent of changes in spike shape. We have measured intracellular free Ca2+ transients during long depolarizing steps in voltage-clamped sensory neuron cell bodies injected with the Ca2+-sensitive dye arsenazo III. The free Ca2+ transients elicited by a range of depolarizing voltage-clamp steps increase in amplitude by 75% following application of 5-HT. Since it is observed under voltage-clamp conditions, this increase in the free Ca2+ transients is not merely secondary to the changes in K+ current but must reflect an additional mechanism, an intrinsic change in the handling of Ca2+ by the cell. We have not yet determined whether this change in Ca2+ handling reflects an increase in Ca2+ influx, a reduction in intracellular Ca2+ uptake, or a release of Ca2+ from intracellular stores. Regardless of the underlying mechanism, however, it seems possible that the enhancement of Ca2+ accumulation and the reduction in K+ current act synergistically in producing short-term presynaptic facilitation. Alternatively, this additional modulation of Ca2+ by 5-HT might contribute to processes such as classical conditioning or long-term sensitization that may depend on Ca2+.     

Intracellular injection of t he catalytic subunit of cyclic AMP-dependent protein kinase simulates facilitation of transmitter release underlying behavioral sensitization in Aplysia.

It has been difficult to establish whether cyclic AMP-mediated protein phosphorylation in nerve cells plays a specific role in synaptic transmission. This difficulty can be overcome in higher invertebrates because their large neurons allow the injection of protein molecules into the cell. We have used intracellular injection to study whether protein phosphorylation is involved in the mechanism of sensitization, a simple form of learning. Sensitization of the gill-withdrawal reflex in Aplysia involves enhancement of transmitter release by presynaptic facilitation at a particular set of synaptic connections between identified sensory neurons and their follower cells. We have found that injection of the catalytic subunit of cyclic AMP-dependent protein kinase (ATP:protein phosphotransferase, EC 2.7.1.37) purified from bovine heart mimics the action of the natural transmitter and of serotonin, the putative transmitter, by simulating the physiological changes that accompany presynaptic facilitation. Intracellular injection of the kinase into a sensory cell (i) broadens the action potential in the presence of tetraethylammonium, indicating an increase in Ca2+ current, (ii) decreases the input conductance of the cell, presumably as a result of a decrease in the K+ current, and (iii) increases the amount of transmitter released by terminals of the sensory cell onto follower neurons.     

Presynaptic modulation of voltage-dependent Ca2+ current: Mechanism for behavioral sensitization in Aplysia californica

Behavioral sensitization of the gill-withdrawal reflex of Aplysia is the result of a prolonged increase in transmitter release from the presynaptic terminals of sensory neurons. Earlier work suggested that this presynaptic facilitation might be mediated by a serotonin-sensitive adenylate cyclase in the sensory neuron terminals. Here we present evidence that presynaptic facilitation results from a cyclic AMP-dependent increase in the calcium current that underlies action potentials in the sensory neurons. The action potentials of sensory neuron cell bodies have, in addition to a sodium current, a calcium current that is enhanced by blocking the opposing potassium current with tetraethylammonium. Under these conditions, the action potentials show a slowly repolarizing plateau that follows the Nernst potential for a calcium electrode and serves as a sensitive assay for changes in calcium current. Stimulation of the pathway that mediates sensitization, incubation with serotonin or phosphodiesterase inhibitors, or intracellular injection of cyclic AMP produces an increase in the calcium plateau in the presence of tetraethylammonium. In addition, both before and after sensitizing stimulation, the duration of the plateau potential parallels transmitter release as measured by the amplitude of monosynaptic excitatory postsynaptic potentials evoked in the motor neurons by intracellular stimulation of single sensory neurons. These results are consistent with the idea that presynaptic facilitation is caused by a cyclic AMP-mediated increase in a voltage-sensitive calcium current in sensory neuron presynaptic terminals. This synaptic action is novel in that it can produce little or no change in the resting potential, is of long duration, and exerts its influence directly on a conductance triggered by the action potential, rather than on non-voltage-sensitive conductances, as is typical of conventional synaptic actions.     

Two endogenous neuropeptides modulate the gill and siphon withdrawal reflex in Aplysia by presynaptic facilitation involving cAMP-dependent closure of a serotonin-sensitive potassium channel.

We have found that two endogenous neuropeptides in Aplysia, the small cardioactive peptides SCPA and SCPB, facilitate synaptic transmission from siphon mechano-sensory neurons and enhance the defensive withdrawal reflex that these sensory neurons mediate. Single-channel recording revealed that these peptides close a specific K+ channel, the S channel, which is sensitive to cAMP. Moreover, the peptides increase cAMP levels in these sensory neurons. This reduction in K+ current slows the repolarization of the action potential in these cells, which increases transmitter release. In these actions, the SCPs resemble both noxious sensitizing stimuli, which enhance the reflex, and serotonin. Bioassay of HPLC fractions of abdominal ganglion extracts and immunocytochemistry indicate that both the SCPs and serotonin are present in the ganglion and are found in processes close to the siphon sensory neurons, suggesting that these transmitters may be involved in behavioral sensitization. Recent evidence suggests that one group of identified facilitatory interneurons, the L29 cells, does not appear to contain either the SCPs or serotonin but may use yet another facilitatory transmitter. Thus, it appears that several transmitters can converge to produce presynaptic facilitation in the sensory neurons of the defensive withdrawal reflex. All of the transmitters studied here, the SCPs and serotonin, act via an identical molecular cascade: cAMP-dependent closure of the S-K+ channel, broadening of the presynaptic action potential, and facilitation of transmitter release.     

Presynaptic membrane potential affects transmitter release in an identified neuron in Aplysia by modulating the Ca2+ and K+ currents

We have examined the relationships between the modulation of transmitter release and of specific ionic currents by membrane potential in the cholinergic interneuron L10 of the abdominal ganglion of Aplysia californica. The presynaptic cell body was voltage-clamped under various pharmacological conditions and transmitter release from the terminals was assayed simultaneously by recording the synaptic potentials in the postsynaptic cell. When cell L10 was voltage-clamped from a holding potential of -60 mV in the presence of tetrodotoxin, graded transmitter release was evoked by depolarizing command pulses in the membrane voltage range (-35 mV to + 10 mV) in which the Ca(2+) current was also increasing. Depolarizing the holding potential of L10 results in increased transmitter output. Two ionic mechanisms contribute to this form of plasticity. First, depolarization inactivates some K(+) channels so that depolarizing command pulses recruit a smaller K(+) current. In unclamped cells the decreased K(+) conductance causes spike-broadening and increased influx of Ca(2+) during each spike. Second, small depolarizations around resting potential (-55 mV to -35 mV) activate a steady-state Ca(2+) current that also contributes to the modulation of transmitter release, because, even with most presynaptic K(+) currents blocked pharmacologically, depolarizing the holding potential still increases transmitter release. In contrast to the steady-state Ca(2+) current, the transient inward Ca(2+) current evoked by depolarizing clamp steps is relatively unchanged from various holding potentials.     

Action-potential duration and the modulation of transmitter release from the sensory neurons of Aplysia in presynaptic facilitation and behavioral sensitization

Presynaptic facilitation of transmitter release from Aplysia sensory neurons is an important contributor to behavioral sensitization of the gill and siphon withdrawal reflex. The enhanced release is accompanied by reduction of the serotonin-sensitive S current in the sensory neurons and a consequent increase in duration of the presynaptic action potential (ranging from 10% to 30%). We find that changes of similar magnitude in the duration of depolarizing voltage-clamp steps in sensory neurons in intact abdominal ganglia yield increases in synaptic potentials of 45-120%. In dissociated cell culture, these changes lead to increases of 25-60% in the synaptic potential. Prolongation of presynaptic depolarization using voltage clamp or prolongation of the duration of the action potential by K⁺-channel blockers leads to prolongation of the time-to-peak of the synaptic potentials; similar changes in time-to-peak occur during presynaptic facilitation. The time-to-peak is not changed by homosynaptic depression or by changing the Ca²⁺ concentration, procedures that alter release without changing the duration of the action potential. Preventing the spike from broadening by voltage clamping the presynaptic neuron substantially reduces or blocks the facilitation. These results suggest that broadening of the action potential during facilitation is a causal factor in the enhancement of transmitter release.     

Transient outward currents and action potential alterations in rabbit ventricular myocytes

To clarify ionic mechanisms underlying successive changes in action potential repolarization upon sudden increase in driving rate or initiation of rapid drive after a rest, membrane potentials and currents were recorded from isolated rabbit ventricular myocytes using the suction-pipette whole-cell clamp method. When 20 action potentials were elicited with a stimulus frequency of 2.0 Hz after a rest period of 20 s, the plateau and action potential duration showed complex changes in successive beats, whereas they were nearly constant with stimulation at 0.1 Hz. There were only weak correlations between changes in action potential parameters and preceding diastolic intervals. The changes were prominent in the first 10 beats but subsided gradually thereafter, attaining nearly steady configurations of action potentials. When depolarizing pulses were applied at a fast rate, under the voltage clamp, the amplitudes of the initial inward current in the presence of tetrodotoxin changed greatly depending on the pulse numbers and diastolic intervals, whereas the delayed outward K+ current changed little. Variations of the initial inward current in successive pulses were caused by different degrees of activation and recovery from inactivation in the Ca2+ current, the Ca(2+)-sensitive and -insensitive transient outward current. While inhibition of either one or two current components decreased the action potential alterations, blocking the three components completely abolished them. These results indicate that alterations of the Ca(2+)-sensitive and -insensitive transient outward current together with the Ca2+ current contribute to the action potential alterations after initiation of rapid drive or an increase in driving rates.     

Dependence of hormone secretion on activation-inactivation kinetics of voltage-sensitive Ca2+ channels in pituitary gonadotrophs.

The relationships between the activation status of voltage-sensitive Ca2+ channels and secretory responses were analyzed in perfused rat gonadotrophs during stimulation by high extracellular K+ concentration ([K+]e) or the physiological agonist, gonadotropin-releasing hormone (GnRH). Increase of [K+]e to 50 mM evokes an on-off secretory response, with a rapid rise in luteinizing hormone (LH) secretion to a peak at 35 sec (on response) followed by an exponential decrease to the steady-state level. Cessation of K+ stimulation elicits a transient (off) response followed by an exponential decrease to the basal level. The LH response to high [K+]e is nifedipine-sensitive and its amplitude depends on membrane potential. There is a close relationship between the LH secretory response to high [K+]e and the amplitude of the inward Ca2+ current measured at 100 msec in whole-cell patch clamp experiments. In addition, the profile of the LH secretory response is similar to that of the response of intracellular Ca2+ concentration ([Ca2+]i) in K(+)-stimulated cells. In Ca2(+)-deficient medium, the effect of high [K+]e is abolished; subsequent elevation of [Ca2+]e during the K+ pulse is followed by restoration of the on response, but with reduced magnitude. Agonist stimulation during the steady-state phase of the [K+]e pulse or after repetitive stimulation by high [K+]e elicited biphasic [Ca2+]i and secretory responses with a significantly reduced plateau phase; conversely, K(+)-induced LH release was reduced in cells treated with desensitizing doses of GnRH. These findings indicate that depolarization-induced changes in the status of voltage-sensitive Ca2+ channels determine the profiles of [Ca2+]i and LH responses to stimulation by high [K+]e; the initial activation of dihydropyridine-sensitive Ca2+ channels is clearly dependent on membrane potential, whereas their subsequent inactivation depends on increased [Ca2+]i. Such inactivation of voltage-sensitive Ca2+ channels also occurs during GnRH action and may represent an additional regulatory mechanism to limit the entry of extracellular Ca2+ during prolonged or frequent agonist stimulation.     

cAMP modulates multiple K+ currents, increasing spike duration and excitability in Aplysia sensory neurons.

Enhancement of the defensive withdrawal reflex of Aplysia involves a prolongation of the action potentials of mechanosensory neurons, which contributes to facilitation of transmitter release from these cells. Recent reports have suggested that whereas cAMP-dependent modulation of K+ current increases sensory neuron excitability, a cAMP-independent decrease in K+ current may increase the action potential duration and, thus, facilitate transmitter release. We have tested this proposal using Walsh cAMP-dependent protein kinase inhibitor or activators of the cAMP cascade and found that cAMP plays a major role in the spike-broadening effects of facilitatory transmitter; however, broadening requires higher levels of activation of the cAMP-dependent kinase than does increasing excitability. A steeply voltage-dependent transient K+ current, termed IKV,early, and the slowly activating S-type K+ (S-K+) current are both reduced by activation of the cAMP cascade, although with different sensitivities to the second messenger, enabling excitability and spike duration to be regulated independently. Differences in cAMP sensitivity also suggested that the originally described S-K+ current actually consists of two independent components, a slowly activating component and a time-independent, "steady-state" current that is activated at rest.     

Calcium currents in GH3 cultured pituitary cells under whole-cell voltage-clamp: inhibition by voltage-dependent potassium currents.

To isolate inward Ca2+ currents in GH3 rat pituitary cells, an inward Na+ current as well as two outward K+ currents, a transient voltage-dependent current (IKV) and a slowly rising Ca2+-activated current (IKCa), must be suppressed. Blockage of these outward currents, usually achieved by replacement of intracellular K+ with Cs+, reveals sustained inward currents. Selective blockage of either K+ current can be accomplished in the presence of intracellular K+ by use of quaternary ammonium ions. When IKCa and Na+ currents are blocked, the net current elicited by stepping the membrane potential (Vm) from -60 to 0 mV is inward first, becomes outward and peaks in 10-30 msec, and finally becomes inward again. Under this condition, in which both IKV and Ca2+ currents should be present throughout the duration of the voltage step, the Ca2+ current was not detected at the time of peak outward current. That is, plots of peak outward current vs. Vm are monotonic and are not modified by nisoldipine or low external Ca2+ as would be expected if Ca2+ currents were present. However, similar plots at times other than at peak current are not monotonic and are altered by nisoldipine or low Ca2+ (i.e., inward currents decrease and plots become monotonic). When K+ channels are first inactivated by holding Vm at -30 mV, a sustained Ca2+ current is always observed upon stepping Vm to 0 mV. Furthermore, substitution of Ba2+ for Ca2+ causes blockage of IKV and inhibition of this current results in inward Ba2+ currents with square wave kinetics. These data indicate that the Ca2+ current is completely inhibited at peak outward IKV and that Ca2+ conductance is progressively disinhibited as the transient K+ current declines due to channel inactivation. This suggests that in GH3 cells Ca2+ channels are regulated by IKV.     

Early afterdepolarizations: mechanism of induction and block. A role for L-type Ca2+ current

Early afterdepolarizations (EADs) are a type of triggered activity found in heart muscle. We used voltage-clamped sheep cardiac Purkinje fibers to examine the mechanism underlying EADs induced near action potential plateau voltages with the Ca2+ current agonist Bay K 8644 and the effect of several interventions known to suppress or enhance these EADs. Bay K 8644 produced an inward shift of the steady-state current-voltage relation near plateau voltages. Tetrodotoxin, lidocaine, verapamil, nitrendipine, and raising [K]o abolish EADs and shift the steady-state current-voltage relations outwardly. Using a two-pulse voltage-clamp protocol, an inward current transient was present at voltages where EADs were induced. The voltage-dependence of availability of the inward current transient and of EAD induction were similar. The time-dependence of recovery from inactivation of the inward current transient and of EAD amplitude were nearly identical. Without recovery of the inward current transient, EADs could not be elicited. The inward current transient was enhanced with Bay K 8644 and blocked by nitrendipine, but was not abolished by tetrodotoxin or replacement of [Na]o with an impermeant cation. These results support a hypothesis that the induction of EADs near action potential plateau voltages requires 1) a conditioning phase controlled by the sum of membrane currents present near the action potential plateau and characterized by lengthening and flattening of the plateau within a voltage range where, 2) recovery from inactivation and reactivation of L-type Ca2+ channels to carry the depolarizing charge can occur. Our results suggest an essential role for the L-type Ca2+ "window" current and provide a framework for understanding the role of several membrane currents in the induction and block of EADs.     

Presynaptic inhibition in Aplysia involves a decrease in the Ca2+ current of the presynaptic neuron.

By voltage clamping presynaptic cell L10 and using pharmacologic separation techniques, we have analyzed the specific ionic currents in the presynaptic cell that correlate with presynaptic inhibition while assaying transmitter release with intracellular recordings from postsynaptic cells. We have found that presynaptic inhibition can be elicited in conditions in which the Na+ and the various K+ channels are pharmacologically blocked and depolarizing current pulses produce only an inward Ca2+ current. Both inward currents and tail currents at and above the K+ reversal potential were always less inward during presynaptic inhibition. The changes in conductance associated with presynaptic inhibition were voltage sensitive and paralleled the voltage sensitivity of the Ca2+ channel. We therefore conclude that presynaptic inhibition is caused by a direct transmitter-mediated decreased of presynaptic Ca2+-channel conductance.     

Changes in left ventricular repolarization and ion channel currents following a transient rate increase superimposed on bradycardia in anesthetized dogs

INTRODUCTION: We previously demonstrated in dogs that a transient rate increase superimposed on bradycardia causes prolongation of ventricular refractoriness that persists for hours after resumption of bradycardia. In this study, we examined changes in membrane currents that are associated with this phenomenon. METHODS AND RESULTS: The whole cell, patch clamp technique was used to record transmembrane voltages and currents, respectively, in single mid-myocardial left ventricular myocytes from dogs with 1 week of complete AV block; dogs either underwent 1 hour of left ventricular pacing at 120 beats/min or did not undergo pacing. Pacing significantly heightened mean phase 1 and peak plateau amplitudes by approximately 6 and approximately 3 mV, respectively (P < 0.02), and prolonged action potential duration at 90% repolarization from 235+/-8 msec to 278+/-8 msec (1 Hz; P = 0.02). Rapid pacing-induced changes in transmembrane ionic currents included (1) a more pronounced cumulative inactivation of the 4-aminopyridine-sensitive transient outward K+ current, Ito, over the range of physiologic frequencies, resulting from a approximately 30% decrease in the population of quickly reactivating channels; (2) increases in peak density of L-type Ca2+ currents, I(Ca.L), by 15% to 35 % between +10 and +60 mV; and (3) increases in peak density of the Ca2+-activated chloride current, I(Cl.Ca), by 30% to 120% between +30 and +50 mV. CONCLUSION: Frequency-dependent reduction in Ito combined with enhanced I(Ca.L) causes an increase in net inward current that may be responsible for the observed changes in ventricular repolarization. This augmentation of net cation influx is partially antagonized by an increase in outward I(Ca.Cl).     

Mechanism of increased amplitude and duration of the plateau with sudden shortening of diastolic intervals in rabbit ventricular cells

Action potentials and membrane currents were recorded from isolated single ventricular cells from rabbit hearts using the suction pipette whole-cell clamp method. Action potentials elicited after short diastolic intervals of less than 2 seconds showed an increase and prolongation of the plateau compared to those elicited after a 10-second rest period. The recovery of the tetrodotoxin-insensitive secondary inward current revealed a transient increase at short diastolic intervals above the level of full recovery (after 10 seconds). The increased secondary inward current recovery, however, was voltage-dependent, and the period of its increase did not cover the entire diastolic intervals of the action potential overshoots, suggesting the contribution of another ionic current to the changes in potential. During depolarizing voltage steps, from + to -20 mV, a rapid activating and then inactivating outward current was elicited, which overlapped the calcium current. This outward current exhibited time- and voltage-dependent properties similar to those of the transient outward current in Purkinje and other cardiac preparations. The recovery of the transient outward current was slow, achieving only 75% of its full level at 2 seconds, whereas the same level of calcium current recovery was achieved at 200 milliseconds. The application of 4-aminopyridine suppressed most of the transient outward current, and the rest of the current was abolished by caffeine or Co2+. The 4-aminopyridine sensitive transient outward current exhibited slow recovery kinetics compared to those of the other or calcium current, and its inhibition caused elimination of the augmented plateau during electrical restitution. The application of verapamil or Co2+ for inhibition of secondary inward current also abolished the action potential overshoot. These results indicate that an increase and prolongation of the plateau at short diastolic intervals are produced by the slower recovery from inactivation in the 4-aminopyridine-sensitive transient outward current than that in the calcium current.     

Post-tetanic potentiation at an identified synapse in Aplysia is correlated with a Ca2+-activated K+ current in the presynaptic neuron: evidence for Ca2+ accumulation.

We have examined the presynaptic changes underlying post-tetanic potentiation (PTP) in Aplysia by using voltage-clamp techniques combined with specific pharmacological blocking agents. The amplitude and time course of PTP parallel a slow outward clamp current that we have identified as a Ca2+-activated K+ current. Because this current is proportional to intracellular Ca2+ concentration our findings provide evidence for the "residual Ca2+ hypothesis," according to which PTP is caused by the accumulation of intracellular Ca2+ after tetanus. To obtain further evidence for this mechanism we injected EGTA intracellularly and found that it decreased the duration of both PTP and the Ca2+ -activated K+ current.     

Tail shock produces inhibition as well as sensitization of the siphon-withdrawal reflex of Aplysia: possible behavioral role for presynaptic inhibition mediated by the peptide Phe-Met-Arg-Phe-NH2.

Recent studies have shown that, in addition to being modulated by presynaptic facilitation, the sensory neurons of the gill- and siphon-withdrawal reflex of Aplysia are also capable of being modulated by transient presynaptic inhibition produced by the peptide Phe-Met-Arg-Phe-NH2. These two modulatory effects involve different second-messenger systems: the facilitation is mediated through cAMP-dependent protein phosphorylation, and the inhibition is mediated through the lipoxygenase pathway of arachidonic acid. To explore the behavioral function of this inhibition, we have carried out a parametric analysis of the effect of tail shock on the siphon-withdrawal reflex. In addition to producing sensitization of the withdrawal reflex, tail shock also transiently inhibits the reflex. The inhibition is produced by relatively weak shock, whereas sensitization is more prominent and may mask the inhibition with stronger shock. Furthermore, inhibition is not observed after habituation training. Cellular studies suggest that the behavioral inhibition is mediated, at least in part, by presynaptic inhibition of transmitter release from the siphon sensory neurons. Moreover, we have identified an interneuron within the left pleural ganglion (LPL16) that shows Phe-Met-Arg-Phe-NH2 immunoreactivity, is activated by tail shock, and simulates the presynaptic inhibitory actions produced by tail shock. Therefore, our results suggest that presynaptic inhibition mediated by Phe-Met-Arg-Phe-NH2 and its lipoxygenase second messenger contributes to behavioral inhibition of the siphon-withdrawal reflex.     

Biochemical correlates of short-term sensitization in Aplysia: temporal analysis of adenylate cyclase stimulation in a perfused-membrane preparation.

During short-term sensitization, a simple form of nonassociative learning in Aplysia, the presentation of a single brief noxious stimulus results in enhancement of the defensive withdrawal reflex lasting minutes to tens of minutes. This behavioral plasticity involves presynaptic facilitation of synaptic transmission from the mechanosensory neurons that mediate the reflex to their central target cells. This facilitation is due to cAMP-dependent protein phosphorylation. To determine whether the time course of presynaptic facilitation might be due to a persistent increase in activity of adenylate cyclase (EC 4.6.1.1) itself, persistence of the transmitter, or yet other processes, we developed a perfused-membrane method to analyze the time course of activation of adenylate cyclase by transient stimuli. After stimulation by a pulse of stimulatory transmitter, activation of adenylate cyclase decayed within 60 sec. This finding indicates that the enzyme does not remain persistently active in the absence of transmitter and suggests that short-term retention is likely to be due to other mechanisms. Possible additional mechanisms include continued activation of the cyclase by transmitter, cellular factors extrinsic to the cyclase that prolong the time course of its activation, and persistence of processes downstream from the cyclase.     

Mutant analysis shows that the Ca2+-induced K+ current shuts off one type of excitation in Paramecium.

Two mutants of Paramecium tetraurelia, called "pantophobiacs," were found to lack most of the slow Ca2+-induced K+ outward current. Passive properties, the transient Ca2+ inward current, and the fast depolarization-induced K+ outward current remain normal. The mutant defect reduces the ability to shut off a normal, excited state of the membrane and results in repeated, long backward swimming instead of the wild-type jerks in response to a variety of ions, to heat, and to touch.