Identification of neurons contributing to presynaptic inhibition in Aplysia californica

Electrical stimulation of the connectives presynaptically inhibits the PSP from cell L10 to the left upper quadrant cells (LUQC)⁸. The present report decribes the properties of some of the individual neurons contributing to this response. Action potentials produced in a cluster of cells in the abdominal ganglion reduce the amplitude of the L10-LUQC PSP for periods greater than 30 sec. At least some of their inhibitory action is mediated by a slow hyperpolarization of L10 which results in a decreased transmitter release⁴. In other cases, however, the inhibition is produced with no significant alteration of L10 membrane potential, indicating that additional mechanisms may also be present. The neurons producing these effects are approximately 75 μm in diameter and are located on the left ventral surface of the ganglion. They have axons in the connectives and are thus activated by stimuli previously utilized to produce presynaptic inhibition. They appear to be some of the same cells that produce a slow inhibition of ink motoneuron L14; one of these has been identified as L32². The identification of these cells allows for the further biochemical, biophysical and morphological analysis of the events underlying presynaptic inhibition.     

Identified facilitator neurons L29 and L28 are excited by cutaneous stimuli used in dishabituation, sensitization, and classical conditioning of Aplysia

Tactile or electrical stimulation of the skin can be used to produce dishabituation, sensitization, and classical conditioning of the gill- and siphon-withdrawal reflex in Aplysia. These behavioral effects are thought to involve presynaptic facilitation at the synapses from siphon sensory neurons to gill and siphon motor neurons. Facilitation of PSPs onto the motor neurons can also be produced by intracellular stimulation of single identified neurons in the abdominal ganglion, including L29 and L28. In this paper, we further characterize L29 and L28. First, we show that they are excited by cutaneous stimuli similar to those used to produce dishabituation, sensitization, and classical conditioning and may therefore participate in mediating those behavioral effects. The results are also consistent with a possible role of L29 and L28 in higher-order features of conditioning. Second, we show that 5-HT does not mimic some of the PSPs of L29, in agreement with previous evidence that L29 is not serotonergic. Third, we present 2 types of evidence that L29 acts directly to produce facilitation of the sensory cells: (1) L29 comes into close contact with sensory cells in fluorescent double-labeling experiments, and (2) L29 produces facilitation of sensory cells in dissociated cell culture. Together with the results of the preceding paper (Mackey et al., 1989), these results indicate that facilitation of sensory cell synapses contributing to behavioral enhancement of the reflex can be produced by identified neurons that use 2 different transmitters: 5-HT (the transmitter of CB1) and the unknown transmitter of L29.     

Giant Aplysia neuron R2 reliably forms strong chemical connections in vitro

The giant cholinergic neuron R2 of Aplysia was cultured in combination with identified neurons L11 and R15 and members of a group of left upper quadrant (LUQ) cells L2 to L6 from the abdominal ganglion. All of these neurons receive cholinergic input from other cells in vivo, but not from R2. In vitro, R2 reliably formed unidirectional chemical connections with these cells. Single action potentials in R2 produced a dual fast and slow inhibitory response in LUQ cells (L2 to L6), a dual fast inhibitory-slow excitatory response in L11, and a slow inhibitory response in R15. The connections formed on LUQ cells were characteristic of their cholinergic input, but the R2-L11 and the R2-R15 connections also had noncholinergic properties. Thus, unlike L10 which forms connections only with its normal targets in vitro, R2 forms strong chemical connections with other neurons which are not found in vivo. The properties of the R2 connections also suggest that it may release another neurotransmitter besides acetylcholine.     

Respiratory pumping: Neuronal control of a centrally commanded behavior in aplysia

Respiratory pumping in Aplysia californica is a relatively stereotyped behavioral pattern with three components: (1) withdrawal of gill, siphon and mantle shelf; (2) closing of parapodia; (3) heart inhibition accompanied by a decrease in vasomotor tone. This phasic behavior is triggered by a central burst-generating network of interneurons in the abdominal ganglion. During respiratory pumping, motor neurons innervating the several effector organs receive a burst of either excitatory or inhibitory synaptic input which has previously been attributed to an unidentified central command cell called Interneuron II. Several of these motor cells are also concomitantly release from tonic synaptic input, which is opposite in sign to that which they receive from Interneuron II. This tonic input has been attributed to an unidentified cell called Interneuron XI. In this paper we identify and describe some of the neurons which contribute to the burst generating network; specifically, we focus on the neurons that produce the synaptic action attributed to Interneurons II and XI. The synaptic actions attributed to Interneuron XI are produced by a single, spontaneously active neuron, cell L24. This cell is a multi-action interneuron: it produces inhibitory synaptic potentials in some follower motor neurons, excitatory synaptic potentials in other follower cells, and a conjoint excitatory-inhibitory synaptic action onto gill motor neuron L7. At low frequency, L24 is excitatory to L7. With high frequency firing of L24, the synaptic potential produced in L7 converts from excitatory to inhibitory. In contrast to Interneuron XI, which is a single cell, the synaptic potentials previously attributed to Interneuron II are actually produced by a cluster of at least 3 respiratory command cells which we call L25, L26 and L27. Each of these cells accounts for only a limited portion of the synaptic input that drives the motor neurons during respiratory pumping. For most motor neurons innervated by both the respiratory command cells and Interneuron XI, the two synaptic inputs are opposite in sign. Mutually inhibitory connections between Interneuron XI and some of the central respiratory command cells ensure that the synaptic potentials from these two sources are constrained to occur at different times. Thus, centrally commanded synaptic inhibition or excitation of these motor neurons is made more effective by simultaneous disexcitation or disinhibition of Interneuron XI input. In addition to their role in generating respiratory pumping, L24 and L26 also contribute to the mediation of the defensive gill and siphon withdrawal reflex.     

Distribution of serotonin-immunoreactive cell bodies and processes in the abdominal ganglion of mature Aplysia

Sensitization of the gill withdrawal reflex in Aplysia californica is an elementary form of learning, in part resulting from presynaptic facilitation of the LE mechanoreceptor neurons of the abdominal ganglion. It has previously been established that either application of serotonin or direct stimulation of a group of facilitatory neurons, the L29 cells of the abdominal ganglion, can simulate the effect of physiological stimulation in producing presynaptic facilitation. Because the evidence that serotonin serves as a facilitatory transmitter was indirect, we examined the distribution of serotonin-immunoreactive fibers and cell bodies in the abdominal ganglion in order to answer two questions: (1) do the sensory neurons receive serotonergic innervation and (2) are the L29 cells serotonergic? We observed two distinctive patterns of serotonergic innervation within the ganglion, sparse and dense. The sparse pattern is correlated with a serotonin-stimulated increase in cAMP in identified target cells, while the dense innervation is not. We found a sparse distribution of serotonin-immunoreactive fibers with varicosities close to both cell bodies and processes of identified LE sensory cells. It therefore is likely that the sensory neurons do receive serotonergic innervation. We also mapped the population of serotonergic neuronal cell bodies in the ganglion, and found five clusters of neurons. Cells in one of these clusters, the identified RB neurons, had previously been shown to synthesize serotonin from tryptophan and to contain the neurotransmitter in high concentration. Identified L29 facilitator cells marked by injection with Lucifer Yellow do not contain serotonin immunoreactivity and therefore evidently are not a source of serotonergic input onto sensory cells.     

Unusual ultrastructural features in intrafascicular ganglion cells of the rat pelvic nerve

The incidental finding of four ectopic ganglion cells within the pelvic nerve of a normal rat prompted a thorough electron microscopic investigation of the ultrastructural features of these neurons. They were found to enwrap presynaptic terminals inside crater-like invaginations; the appositional surfaces were made more complex by the presence of slender dendritic appendages and sheet-like processes of glial cells. The presynaptic elements contained both clear and dense-cored vesicles, and appeared similar to those characterizing SIF (paraneuronal) cells. In addition, cilia were encountered in both the invaginated processes and most of the Schwann cells associated with the pre- and postsynaptic nerve cells and their processes. Overall, these features were deemed worth reporting because 1) of the unusual features of synaptic input from a SIF cell to a ganglion cell associated with the pelvic plexus, and 2) the ectopic ganglion cells possibly represent the sole example, other than ciliary neurones in the avian ciliary ganglion, of postsynaptic cells encasing presynaptic endings inside their perikarya.     

Substance P-mediated membrane currents in voltage-clamped guinea pig inferior mesenteric ganglion cells

Responses to substance P (SP) and to hypogastric nerve stimulation were recorded from voltage-clamped guinea pig inferior mesenteric ganglion (IMG) neurons, and compared with those to muscarine. Muscarine produced a voltage-dependent inward current accompanied by a reduced input conductance and inhibition of IM a time- and voltage-dependent K+-current (Brown and Adams: Nature 283:673-676, 1980). SP also produced an inward current, accompanied by a fall in input conductance (20 out of 31 cells) or a rise in input conductance (7 out of 31 cells). The fall in input conductance was not accompanied by an inhibition of M-current (unlike frog ganglia: Adams et al.: British Journal of Pharmacology 79:330-333, 1983) or an inhibition of the inward rectifier current (unlike globus pallidus neurons: Stanfield et al.: Nature 315:498-501, 1985). Repetitive hypogastric nerve stimulation (10-20 Hz, 2-10 s) produced a slow inward postsynaptic current lasting 1-3 min, with decreases or increases of input conductance matching those produced by SP. The postsynaptic current did not show a consistent or reproducible change in amplitude on varying the holding potential between -90 and -25 mV. It is concluded that SP and hypogastric stimulation produce complex and variable changes in ionic conductance in IMG neurons.     

Generation of new cerebral ganglion neurons in the snail Melampus: An ultrastructural study

Reports in the literature have established that reconnection of central neural tracts occurs following commissurotomy and cerebral ganglion excision in the primitive pulmonate snail Melampus bidentatus and have suggested the possibility that long-term regeneration might result in the appearance of new neurons in the ganglion bud. We have used electron microscopy to examine the ganglion buds that form by reconnection of cerebral nerves, commissure, and connectives following cerebral ganglion excision in adult Melampus. The buds were examined from 2.5 to 12 months postoperatively. By 2.5 months, ganglion buds consist of a mixture of axon tracts that travel through the bud region and some dendritic processes; a few synaptic contacts can be identified at this stage, scattered throughout the bud. By 5–6 months, some of the most advanced ganglia have undifferentiated cells that are distinct from glia. By 7 months, differentiated neurons with clear, small dense-core or neurosecretory vesicles are present, although these cells are not all concentrated in a rind on the ganglion surface. Another cell type, the pigment-sheath cell, is present by this stage. By 11–12 months, the most advanced regenerating ganglia have neurons which form a cell rind on the ganglion surface. The gross appearance of a regenerated ganglion at this stage is similar to that of the intact contralateral cerebral ganglion, although the regenerated ganglion is smaller. One 12-month ganglion was found to possess fairly normal intraganglionic morphology, with lobes and cell types that were recognizable. Hence, nerve cell regeneration can occur in the absence of body part regeneration in adult members of one species of pulmonate snail.     

Metabolites of arachidonic acid in the nervous system of Aplysia: possible mediators of synaptic modulation

Release of arachidonic acid from membrane phospholipids is receptor-mediated and might generate second messengers in neurons. We tested this idea using the simple nervous system of the marine mollusk, Aplysia californica. Aplysia neural components metabolize arachidonic acid through lipoxygenase and cyclo-oxygenase pathways. We identified 2 major lipoxygenase products, 12- and 5-hydroxyeicosatetraenoic acids (12-HETE and 5-HETE), and 2 cyclo-oxygenase products, PGE2 and PGF2 alpha. These metabolites of arachidonic acid are formed in synaptosomes, as well as in identified nerve cell bodies, indicating that both lipoxygenase and cyclo-oxygenase pathways are active within neurons. Application of the modulatory neurotransmitter histamine to cerebral ganglia that had been labeled with 3H-arachidonic acid induced the formation of 3H-12-HETE. This response was inhibited by the histamine antagonist cimetidine. Furthermore, release of radioactive 5-HETE and 12-HETE was observed after intracellular stimulation of the histaminergic cell C2 in cerebral ganglia labeled with 3H-arachidonic acid. Cimetidine also inhibited this response. Application of serotonin or stimulation of the giant serotonergic cell (GCN) in the cerebral ganglion did not cause detectable amounts of the labeled eicosanoids to be released. We found that intracellular stimulation of putative histaminergic neurons in the L32 cluster of the abdominal ganglion, which produces presynaptic inhibition in L10 neurons, also elicited the release of 3H-12-HETE and 3H-PGE2. Thus, for the first time we provide evidence that synaptic stimulation promotes turnover of arachidonic acid in neurons. We suggest that metabolites of arachidonic acid are likely to participate in some postsynaptic responses to histamine and may be second messengers for presynaptic inhibition.     

Antidromic inhibition of acetylcholine release from presynaptic nerve terminals in bullfrog's sympathetic ganglia

In isolated bullfrog's sympathetic ganglia it was examined if the release of acetylholine (ACh) from presynaptic nerve terminals was changed when postsynaptic ganglion cells were activated antidromically. The fast excitatory postsynaptic potential (fast EPSP) of ganglion cells was found to be depressed, whereas the nicotinic ACh potential of these cells was not depressed, immediately after these ganglion cells were activated by antidromic axonal or direct intracellular stimulations. This indicates that activation of ganglion cells results in inhibition of the release of ACh from their presynaptic nerve terminals. Such an antidromic inhibition of ACh release could not be clearly observed when preparations were perfused with Ca²⁺-deficient solution or when adrenaline (10⁻⁵ M) was added to the superfusion solution. Frequency of the spontaneous miniature EPSP was also found to be decreased after antidromic activation of ganglion cells. On the basis of these results it was concluded that some kind of transmitter was released from activated ganglion cells which inhibited ACh release by acting on preganglionic nerve terminals. This putative neurotransmitter was suggested to be adrenaline.     

Substance P depolarizes nerve terminals in an autonomic ganglion

The effect of substance P on presynaptic nerve terminals was examined by intracellular impalements of calyciform terminals within the chick ciliary ganglion. Substance P produced a slow depolarization of the nerve terminals which was associated with an increase in input resistance. The postsynaptic ciliary neurons were unaffected by exposure to substance P, indicating that at this synapse the physiological effects of substance P may be largely presynaptic in nature.     

Uptake of [3H]serotonin in the abdominal ganglion of Aplysia californica. Further studies on the morphological and biochemical basis of presynaptic facilitation

Sensitization of the gill-withdrawal reflex in Aplysia california is mediated, in part, by a group of identified neurons, the L29 cells, which produce presynaptic facilitation of transmitter release from siphon sensory neurons. Physiological and pharmacological studies have provided indirect evidence that the L29 cells are serotonergic. In the present study we have used the specific uptake [3H]serotonin ([3H]5-HT) and electron-microscopic autoradiography in combination with horseradish peroxidase-labeling of identified neurons to characterize the fine structure of Aplysia serotonergic terminals and to examine more directly the transmitter biochemistry of the L29 neurons. Abdominal ganglia were incubated for 2 h in 10(-6) M [3H]5-HT and thick and thin plastic sections examined with the light and electron microscope. L29 varicosities, identified by labeling with HRP, were found to accumulate [3H]5-HT. In addition, [3H]-5-HT was localized to unidentified varicosities within the neuropil as well as to vesicle-filled terminals that formed axosomatic contacts in the cortical regions of the ganglion. The processes that accumulated [3H]5-HT contained conspicuous dense core vesicles identical in morphology to those previously described for L29. Some processes were found to make contact with HRP-labeled varicosities of sensory neurons. Comparison with results obtained from ganglia exposed to [3H]5-HT in the presence of either non-radioactive 5-HT or non-radioactive dopamine indicate that the uptake process is transmitter-specific. These studies provide additional evidence that the L29 cells are serotonergic and are consistent with the notion that aminergic neurons may be preferentially involved in modulatory synaptic actions.     

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.     

Cholinergic function in cultures of mouse spinal cord neurons

Cholinergic synapses formed in cultures of fetal mouse spinal cord (SC) and superior cervical ganglion (SCG) were studied using intracellular and extracellular stimulation and recording as well as immunohistochemical staining for choline acetyltransferase (ChAT). Dissociated SC neurons and SC explants exhibited cholinergic terminals on SCG and SC neurons as demonstrated by ChAT immunoreactivity. Intracellular recordings showed that cholinergic inputs to SCG neurons were relatively common and that these synaptic inputs were blocked by the nicotinic acetylcholine (ACh) receptor blocker, tubocurarine. A comparison of three preparations indicated that the incidence of cholinergic activity recorded in SCG neurons was significantly higher in co-cultures of SCG with spinal cord ventral horn (VH) neurons grown on a substrate of non-neuronal cells from cerebral cortex, than in co-cultures with VH alone or with SC and dorsal root ganglion cells. Consistency between cholinergic physiology and staining for ChAT-positive terminals on SCG neuronal somata was obtained in cultures of SC explants grown with dissociated SCG. Application of acetylcholine, muscarine, and/or vasoactive intestinal polypeptide (VIP) produced slow excitation of SC neurons. Fast excitatory cholinergic interactions between SC neurons were not observed. Excitatory synaptic interactions between SC neurons were augmented by ACh or muscarine, while inhibitory synaptic interactions were diminished. Both types of synaptic modulation probably were produced by a presynaptic mechanism. Acetylcholine or muscarine affected synaptic interactions between SC neurons in only one-third of the synaptic connections tested, suggesting that the incidence of presynaptically cholinoceptive SC neurons is low in dissociated cell cultures. The experimental results show that a culture system incorporating dissociated fetal mouse SC neurons or explants of SC with sympathetic ganglion neurons expresses both nicotinic and muscarinic cholinergic function.     

Localization of GABA-like immunoreactivity in the central nervous system of Aplysia californica.

Gamma-aminobutyric acid (GABA) is present in the central nervous system of Aplysia californica (Gastropoda, Opisthobranchia) where its role as a neurotransmitter is supported by pharmacological, biochemical, and anatomical investigations. In this study, the distribution of GABA-immunoreactive (GABAi) neurons and fiber systems in Aplysia was examined by using wholemount immunohistochemistry and nerve backfill methods. GABAi neurons were located in the buccal, cerebral, and pedal ganglia. Major commissural fiber systems were present in each of these ganglia, whereas more limited fiber systems were observed in the ganglionic connectives. Some of the interganglionic fibers were found to originate from two unpaired GABAi neurons, one in the buccal ganglion and one in the right pedal ganglion, each of which exhibited bilateral projections. No GABAi fibers were found in the nerves that innervate peripheral sensory, motor, or visceral organs. Although GABAi cells were not observed in the pleural or abdominal ganglia, these ganglia did receive limited projections of GABAi fibers originating from neurons in the pedal ganglia. The distribution of GABAi neurons suggests that this transmitter system may be primarily involved in coordinating certain bilateral central pattern generator (CPG) systems related to feeding and locomotion. In addition, the presence of specific interganglionic GABAi projections also suggests a role in the regulation or coordination of circuits that produce components of complex behaviors.     

An inward rectifier is present in presynaptic nerve terminals in the chick ciliary ganglion

Inwardly rectifying voltage-sensitive channels have been detected in the cell bodies and axons of a number of excitable cells. The question of whether similar channels exist at axon terminals has been a matter of speculation for some time. We now report the first direct evidence for the existence of inward rectifiers in vertebrate presynaptic nerve terminals. Following impalement with intracellular electrodes, the large calyciform nerve terminals innervating chick ciliary ganglion neurons exhibit pronounced inward rectification upon hyperpolarization that increases with increasing current strength. The response is blocked by 2 mM Cs+, but is insensitive to Ba2+, tetraethylammonium and tetrodotoxin. The inward rectifier exhibits dependence on both Na+ and K+, but is unaffected by altering extracellular Ca2+. Ciliary neurons innervated by these nerve terminals display inward rectification with similar properties. We conclude that the inward rectifier present in these presynaptic nerve terminals resembles the H-current previously described in sensory ganglion neurons and the Q-current found in hippocampal pyramidal neurons. The presence of channels that are activated by hyperpolarization may serve to enhance the excitability of the calyciform nerve terminals, which are capable of relatively high frequencies (greater than 100 Hz) of discharge.     

Serotoninlike immunoreactivity in the central and peripheral nervous system of the scale worm Harmothoe imbricata (Polychaeta)

The distribution of serotoninergic neurons in the nervous system of the scale worm Harmothoe imbricata was visualized in the anterior half of the body by the peroxidase-antiperoxidase (PAP) immunohistochemical method with a specific antiserotonin antibody. Immunoreactive neuronal somata were localized in discrete ganglion cell masses of the dorsally situated cerebral ganglion and in segmental ganglia of the ventral nerve cord. They also make up the majority of neurons present in the parapodial ganglia. Large and small varicose fibers stained in the neuropile of all the above-mentioned ganglia but also in interganglionic connectives and segmental nerves. On the basis of soma size and location and of fiber distribution, the reactive neurons were identified as primarily interneuronal with a few motoneurons and presumptive afferent neurons. The presence of a motor component was substantiated by observations of several reactive varicose fibers spread over longitudinal muscle layers of the trunk. In addition, neurites of the subepidermal nerve plexus and enterochromaffinlike cells of the gut epithelium reacted with the serotonin antibody. It is concluded that serotoninergic pathways are ubiquitous elements in the organization of the central and peripheral nervous system of this polychaete. The significance of these findings in relation to other annelid groups and to the physiological role of serotonin is discussed.     

Two neuronal populations in the head ganglia of Aplysia californiaa with egg-laying hormone-like immunoreactivity

The egg-laying hormone (ELH) is a polypeptide of known structure, which is synthesized and released by the neurosecretory bag cells in the abdominal ganglion of the mollusc, Aplysia californica. We have used immunohistochemical procedures to reveal organized groups of specific cells and fiber tracts within the pleural and cerebral ganglia in adult Aplysia which are immunopositive when reacted with antibodies generated against ELH. These antibodies are highly specific in that they only stain the bag cells within the abdominal ganglion. The ELH+ systems in the head ganglia persisted in two animals 43 days and 67 days after surgical removal of their abdominal ganglia and pleurovisceral connectives. It is therefore likely that these immunoreactive neurons and their processes are independent of the bag cell system.The pleural ganglia neurons, with ELH-like immunoreactivity, bear a striking resemblance to bag cells in somal and nuclear dimensions, neuritic morphology and association with the pleurovisceral connectives. This suggests that both populations of cells may have descended from a common precursor pool during embryogenesis. In the cerebral ganglion, a pair of bilateral clusters of 6–10 small immunopositive neurons are located on the dorsal surface in the vicinity of the C clusters, and send their processes into the neuropil. Intensely stained tracts of ELH+ fibers are prominent at all levels of section in the cerebral neuropil; stained fibers can also be traced into most of the nerves emanating from the cerebral ganglion.Although the functions of these systems, as well as the specific nature of the immunoreactive molecule(s) they contain, remain unknown, 5 ELH-like genes of Aplysia have now been cloned and 3 of these have been sequenced^26,27. Our results suggest that the immunoreactive molecules in the pleural and cerebral neurons are due to peptides controlled by one or more of these genes. ELH is known to markedly change the electrical activity of neurons in the head ganglia in vitro. This demonstration of the presence and distribution of ELH-like molecules endogenous to the head ganglia raises the possibility that ELH target neurons in the head ganglia may be activated by local sources of ELH-like neuroactive peptides in vivo.     

Identified Aplysia neurons form specific chemical synapses in culture

Identified neurons from the abdominal ganglion of the marine mollusc Aplysia californica make specific transmitter-mediated synapses in dissociated cell culture. The cholinergic interneuron L10 makes synapses in vitro with one group of its follower cells, the left upper quadrant cells, and these connections exhibit the features of these synapses in vivo when the postsynaptic cells are plated with their initial axon segments. Furthermore, L10 will avoid making synapses with right upper quadrant cells, which contain cholinergic receptors but do not synapse with L10 in vivo. This in vitro system can therefore be used as a model in which to study the development of specific neuronal connections.     

An identified histaminergic neuron can modulate the outputs of buccal-cerebral interneurons in Aplysia via presynaptic inhibition

We have identified 2 buccal-cerebral interneurons (BCIs), B17 and B18, that appear to be involved in the coordination of feeding behavior in Aplysia. The BCIs have their cell bodies in the buccal ganglion, but send axons to the cerebral ganglion via the cerebral-buccal connectives. The BCIs appear to make monosynaptic connections with neurons in the cerebral ganglion that modulate extrinsic muscles involved in feeding behavior. B17 and B18 are activated antiphasically during a motor program induced by stimulating the esophageal nerve and appear to "read out" different phases of the buccal program to different cells in the cerebral ganglion. B17 and B18 are not necessary, and probably not sufficient, to generate the buccal program. These BCIs, and other cells like them in the buccal ganglion, may be capable of coordinating the activity of the intrinsic muscles of the buccal mass with the activity of its extrinsic muscles, and perhaps with those of the lips, mouth, and tentacles. Identified histaminergic neuron, C2, can modulate the outputs of the BCIs onto their synaptic followers in the cerebral ganglion. Firing of C2 inhibits spiking of the BCIs, probably via cerebral-buccal interneurons. C2 also decreases the size of the EPSP that B17 and B18 evoke in cerebral neuron C4. C2 appears to do so monosynaptically, and it decreases the conductance of C4, ruling out one possible postsynaptic mechanism of action. Variance analysis of the EPSPs evoked by B18 supports the hypothesis that C2 acts presynaptically to decrease the release of transmitter. Applications of histamine to the solution bathing the neuron mimic the effect of firing C2 and reduce the size of the EPSPs B18 induces in C4. The bath-applied histamine appears to act directly on B18, since it elicits a voltage-dependent increased conductance hyperpolarization recorded in the soma of B18, and the hyperpolarization persists in a solution in which synaptic transmission has been blocked. Histamine did not produce any marked changes of the duration of a TEA-broadened somatic action potential of B18. To the extent that the soma of B18 reflects the membrane properties of its synaptic terminal region, the data suggest that histamine may produce presynaptic inhibition by hyperpolarizing the synaptic terminal region.