Determination of Glutathione and ATP in Ganglia and Individual Neurons of Aplysia californica

The levels of two gamma-glutamyl cycle substrates, glutathione and ATP, were determined in single identified nerve cell bodies from the CNS of Aplysia californica. The glutathione content of single cells averaged 30 +/- 4.9 mumol/g protein. Glutathione levels were similar in identified cholinergic, serotonergic, and histaminergic cells, as well as in neurons whose transmitters are not yet identified. The abdominal rostral white cells, which are enriched in glycine, a component amino acid of glutathione, did not possess distinctively higher glutathione concentrations. The ATP content of single Aplysia nerve cell bodies averaged 15.0 +/- 1.5 mumol/g protein. Despite the vast chemical, anatomical, and functional heterogeneity between Aplysia central neurons, no cells were found that contained unusually high or low ATP levels.     

Ganglionic circulation and its effects on neurons controlling cardiovascular functions in Aplysia californica

The abdominal ganglion of the mollusk Aplysia californica receives most of its blood supply through a small caudal artery that branches off the anterior aorta near its junction with the heart. Injection of an ink/gelatin mixture into the caudal artery revealed a consistent pattern of arterial branching within the ganglion and a general proximity of larger vessels to identified neurons controlling circulation in this animal. This morphological arrangement was particularly evident for the heart excitor interneuron, cell L10, which lies next to the caudal artery near its entry into the ganglion. In electrophysiological experiments, L10 was excited when blood flow or oxygen tension within the ganglion was reduced. This effect was expressed as a gradual increase in impulse frequency of L10 and conversion from tonic to bursting mode of spike discharge. L10 follower cells in the RB and LD neuron clusters were affected synaptically by the changes in L10 activity, while other follower cells (L3 and RD neurons) responded independently of L10's synaptic influence. The neurosecretory white cells (R3 to R14) that innervate the major arteries and pericardial tissues were also excited when ganglionic circulation was interrupted. In innervated preparations of the heart and respiratory organs, decreased circulation through the abdominal ganglion stimulated a transient increase in the rate and amplitude of respiratory (gill) pumping and pericardial contractions and caused a sustained increase in activity of the heart. Both responses increase cardiac output and both appear to involve a direct influence of ganglionic circulation on interneurons controlling the gill and heart. These results indicate that the cell-specific patterns of excitation and inhibition caused by fluctuations in ganglionic circulation may be important factors for maintaining circulatory homeostasis in this animal.     

Alteration of calcium conductances and outward current by cyclic adenosine monophosphate (cAMP) in neurons ofLimax maximus

Membrane responses to cyclic adenosine monophosphate (cAMP) injections have been studied by means of voltage clamp, Ca-indicator dye, and ion substitution techniques in identified neurons from the abdominal ganglion of Limax maximus. The ventral abdominal giant cell (AGC) displayed a response consisting of a decrease in outward current usually accompanied by a smaller enhancement of voltage-gated Ca2+ influx. Both responses were eliminated by external Cd2+ or Mn2+ and required membrane voltages more positive than -40 mV for expression. The enhanced influx persisted in Ba2+-substituted saline, while the decrease in outward current was blocked. A group of dorsal neurons (RD1-3, LD1) showed a mixed Na-Ca influx induced by cAMP that could be activated over a wide range of membrane potentials (less than -100 to greater than -20 mV). This flux caused a measurable increase in internal Ca2+. The influx was insensitive to Cd2+ and Mn2+ but was reduced by prolonged exposure to Co2+. The relative magnitude of the Na-Ca flux ratio showed considerable variation between specimens. In immature animals the Ca component was absent. The results demonstrated that elevation of intracellular cAMP can cause cell-specific changes of membrane conductance within closely associated neurons.     

Electrophysiological studies of the gill ganglion inAplysia californica

1. An electrophysiological analysis was made of gill ganglion neurons in Aplysia californica. 2. Gill ganglion neurons behave similarly to neurons in the abdominal ganglion (the central nervous systems; CNS) that are involved with gill withdrawal behaviors. 3. Some gill ganglion neurons are motor neurons much like those in the CNS. 4. Neurons in the gill ganglion are electronically and dye-coupled. In addition, they receive common chemical synaptic inputs from the Int-II network in the CNS. 5. Tactile stimulation of the gill or siphon evokes synaptic activity in gill ganglion neurons whether or not the CNS is present. 6. Pedal nerve stimulation results in synaptic activity in gill ganglion neurons and facilitates synaptic input evoked by tactile stimulation of the gill or siphon. 7. Antibody staining reveals serotonin-like fibers in the branchial nerve close to the gill ganglion but no cell bodies in the ganglion. 8. The gill ganglion may play a role in the mediation of adaptive gill reflex behaviors. It may be one of the loci where the CNS and peripheral nervous system (PNS) interact and form an integrated circuit to mediate gill withdrawal reflex (GWR) behaviors.     

Reorganization of the ventral nerve cord in the moth Manduca sexta (L.) (Lepidoptera : Sphingidae)

Morphology of the ventral nerve cord of the hawkmoth, Manduca sexta (Lepidoptera : Sphingidae), changes at the larval-pupal transition as several separate larval ganglia fuse to form single ganglia characteristic of the adult. We examined in detail the time course of ganglionic fusion. Changes in the relative positions of the ganglia were studied by staining the tissue with methylene or toluidine blue. Alterations in the positions and structure of individual neurons were studied by filling neurons with a cobalt-lysine complex. The first gross morphological change, anterior movement of the first abdominal ganglion, is visible within the first 24 hr after pupal ecdysis. Adult ventral nerve cord morphology is recognizable 6 days later, approximately 12 days before the adult will emerge. The sequence in which the individual ganglia fuse is invariant. During ganglionic fusion, the neuronal cell bodies and associated neuropil move out of their former ganglionic sheath and through the sheath covering the connectives. Axons between the fusing ganglia form loops in the shortening connectives. The presence of looping axons is a morphological feature that identifies the boundaries between ganglia during intermediate stages of fusion. Some individual adult neurons also show looped axons at the boundaries of fused ganglia. These axonal loops may be a valuable morphological marker by which neurons can be characterized as conserved neurons.     

Differential expression of neuropeptide gene mRNA within the LUQ cells of Aplysia californica.

Two neuropeptide precursor cDNAs (LUQ-1 and L5-67) have been recently isolated from the Left Upper Quadrant (LUQ) neurons of the abdominal ganglion of Aplysia californica (Shyamala, Fisher, and Scheller, 1986; Wickham and DesGroseillers, 1991). Using in situ hybridization techniques as well as dot blot and polymerase chain reaction (PCR) assays, we have studied the expression of these genes in the central nervous system (CNS) of Aplysia californica. The LUQ-1 gene was found to be expressed in neuron L5 in the abdominal ganglion, whereas the expression of the L5-67 gene was observed in the other four LUQ cells (L2-4 and L6). When in situ hybridization was performed on paraffin sections of the abdominal ganglion, clusters of smaller cells located in the left hemiganglion, were also found to express either the LUQ-1 or the L5-67 gene, never both. In many sections, the mRNAs coding for the two neuropeptides were found not only in cell bodies but also in the axon of individual LUQ neurons and even as far as the pericardial nerve. The presence of neuropeptide mRNA in axons, pericardial nerve, and kidney has been confirmed by polymerase chain reaction. A specific, although diffuse hybridization in the left upper quadrant also suggests that mRNA is present in the neuritic field. Taken together these results indicate that neuron L5 is the only giant neuron expressing the LUQ-1 gene and might therefore have a physiological function different from the other four LUQ cells. Neuropeptide mRNAs were also found in the axon and/or the neuritic field of giant neurons and could play important roles related to cell signalling in axons and nerve termini.     

Enkephalin-like substance in aplysia nervous tissue and actions of leu-enkephalin on single neurons

Extract from the abdominal ganglia of Aplysia was fractionated by high performance liquid chromatography. Several large uv absorbing peaks were found. One of these peaks from the ganglionic extract was analyzed by displacement assay with the use of Mytilus edulis membranes. The results revealed the substance in this peak was able to displace 3H-D-Ala2, met5-enkephalinamide. In electrophysiological studies of abdominal and cerebral neurons, depolarizing and hyperpolarizing responses were obtained from some neurons, including neurons in the identified cerebral B cell cluster. A smaller population of cells exhibited biphasic responses. Some of the responses could be depressed by prior naloxone treatment. In conclusion, an endogenous opioid system, using substance related to but distinct from the enkephalins, may exist in Aplysia.     

The abdominal ganglion of Aplysia brasiliana: a comparative morphological and electrophysiological study, with notes on A. dactylomela.

The ultrastructure and electrophysiological properties of neurons in the abdominal (visceral) ganglion of the marine opisthobranch gastropod Aplysia brasiliana have been investigated to determine whether this preparation compares favorably with the well studied A. californica for neurobiological research. In general, the topography, morphology and physiological characteristics, including synaptic connections, of neurons in this ganglion are quite similar to those of A. californica. There is close correspondence between the two animals in terms of each of the identified cells or neuronal clusters in the ganglion, including the presence of the cell L10 (interneuron I) in A. brasiliana which makes synaptic connections comparable with those in A. californica. New follower cells of this interneuron have been found in A. brasiliana. This species offers some advantages in that the connective tissue surrounding the ganglion is thinner and more transparent, making cell identification and penetration easier. A. brasiliana appears to exhibit the behaviors of A. californica that have been used in previous functional analyses of neural circuits. In addition, this species swims and exhibits a "burrowing" activity less commonly seen in A. californica. The rich repertoire of behaviors and accessibility of large identifiable and functionally interconnected neurons makes this species of Aplysia an excellent model preparation for future neurobiological studies. Similar, less thorough, investigations of the abdominal ganglion of A. dactylomela indicate that this species is also very similar to A. californica in terms of the identified cells in the abdominal ganglion.     

Dorsal unpaired median neurons, and ventral bilaterally paired neurons, project to a visceral muscle in an insect

Cobalt backfilling, Lucifer yellow injection and neurophysiological recordings have been used to identify the neurons, in particular dorsal unpaired median neurons, which contribute axons to the oviducal muscles of the locust Locusta migratoria. A total of eight neurons within the VIIth abdominal ganglion have axons passing to the oviducts. Three pairs of bilaterally symmetrical neurons have ventrally located cell bodies. One neuron from each pair projects to the left side of the oviducts and the other the right side of the oviducts. These cells lie ipsilateral to the nerve root through which they exit. The neuropilar branches are intraganglionic and lie mainly in the ipsilateral neuropile, however one of the neurons from each side possesses a giant process, reaching 10 micron in diameter, which passes dorsally to the contralateral side of the ganglion. The other two neurons are dorsal unpaired median neurons, and have large cell bodies which lie at the posterior end of the ganglion. Lucifer yellow injection into these two dorsal unpaired median neurons reveals a single neurite passing anteriorly from the cell body which bifurcates into two bilaterally symmetrical processes which exit to the oviducts through both the left and right sternal roots. Similar to other identified dorsal unpaired median neurons, the cell bodies stain with neutral red and can support overshooting action potentials. The possibility that these two cells contain octopamine is discussed.     

Distribution of the Aplysia cardioexcitatory peptide,NdWFamide, in the central and peripheral nervous systems of Aplysia

NdWFamide is an Aplysia cardioexcitatory tri-peptide containing D-tryptophan. To investigate the roles of this peptide, we examined the immunohistochemical distribution of NdWFamide-positive neurons in Aplysia tissues. All the ganglia of the central nervous system (CNS) contained NdWFamide-positive neurons. In particular, two left upper quadrant cells in the abdominal ganglion, and the anterior cells in the pleural ganglion showed extensive positive signals. NdWFamide-positive processes were observed in peripheral tissues, such as those of the cardio-vascular system, digestive tract, and sex-accessory organs, and in the connectives or neuropils in the CNS. NdWFamide-positive neurons were abundant in peripheral plexuses, such as the stomatogastric ring. To examine the NdWFamide contents of tissues, we fractionated peptidic extracts from the respective tissues by reversed-phase high-pressure liquid chromatography and then assayed the fractions by competitive enzyme-linked immunosorbent assay. A fraction corresponding to the retention time of synthetic NdWFamide contained the most immunoreactivity, indicating that the tissues contained NdWFamide. The prevalence of the NdWFamide content was roughly in the order: abdominal ganglion >heart >gill >blood vessels >digestive tract. In most of the tissues containing NdWFamide-positive nerves, NdWFamide modulated the motile activities of the tissues. Thus, NdWFamide seems to be a versatile neurotransmitter/modulator of Aplysia and probably regulates the physiological activities of this animal.     

Cyclic AMP enhances calcium-dependent potassium current inAplysia neurons

The effect on the Ca-dependent potassium current, IK(Ca), of procedures that increase intracellular cAMP levels was studied in Aplysia neurons using three different pharmacological approaches. Exposure to cAMP analogues which were either resistant to or protected from phosphodiesterase hydrolysis caused an increase in IK(Ca) from 30 to 50% in 10 min. The degree of reversibility of this effect varied from complete with db cAMP to very little with pcpt cAMP. Exposure to cholera toxin, which stimulates the synthesis of endogenous cAMP, increased IK(Ca) 25% in 10 min and the effect was not reversible. Both approaches were effective in all seven neuron types studied. Application of serotonin plus phosphodiesterase inhibitor caused an increase in IK(Ca) in neuron R15 but not in the other neuron types. Application of pentylene tetrazole (PTZ) led to a decrease in IK(Ca). It is proposed that elevation of cyclic AMP mediates an increased sensitivity of the IK(Ca) channel to Ca ions.     

Differential expression of neuropeptide gene mRNA within the LUQ cells of Aplysia californica

Two neuropeptide precursor cDNAs (LUQ-1 and L5-67) have been recently isolated from the Left Upper Quadrant (LUQ) neurons of the abdominal ganglion of Aplysia californica (Shyamala, Fisher, and Scheller, 1986; Wickham and DesGroseillers, 1991). Using in situ hybridization techniques as well as dot blot and polymerase chain reaction (PCR) assays, we have studied the expression of these genes in the central nervous system (CNS) of Aplysia californica. The LUQ-1 gene was found to be expressed in neuron L5 in the abdominal ganglion, whereas the expression of the L5-67 gene was observed in the other four LUQ cells (L2-4 and L6). When in situ hybridization was performed on paraffin sections of the abdominal ganglion, clusters of smaller cells located in the left hemiganglion, were also found to express either the LUQ-1 on the L5-67 gene, never both. In many sections, the mRNAs coding for the two neuropeptides were found not only in cell bodies but also in the axon of individual LUQ neurons and even as far as the pericardial nerve. The presence of neuropeptide mRNA in axons, pericardial nerve, and kidney has been confirmed by polymerase chain reaction. A specific, although diffuse hybridization in the left upper quadrant also suggests that mRNA is present in the neuritic field. Taken together these results indicate that neuron L5 is the only giant neuron expressing the LUQ-1 gene and might therefore have a physiological function different from the other four LUQ cells. Neuropeptide mRNAs were also found in the axon and/or the neuritic field of giant neurons and could play important roles related to cell signalling in axons and nerve termini.     

The bag cell neurons ofAplysia

Egg laying in Aplysia involves a well-characterized series of behaviors that can last for several hours. The behaviors are controlled by two bilateral clusters of peptidergic neurons in the abdominal ganglion. Following brief stimulation, these neurons, which have been termed the bag cell neurons, undergo a sequence of changes in their excitability lasting many hours. The bag cell neurons have served as a model system for studying the molecular mechanisms involved in the synthesis, processing, and release of neuroactive peptides and in the regulation of prolonged changes in neuronal excitability.     

Alternative splicing in individual Aplysia neurons generates neuropeptide diversity

The neuron R15 is a peptidergic cell within the abdominal ganglion of Aplysia that participates in two neural circuits governing physiological and behavioral programs. We have cloned and characterized the major gene product expressed in this neuron. The R15 cDNA encodes a polyprotein precursor that is cleaved to yield a set of small neuropeptides. One peptide, R15 alpha 1, may act on different target cells to generate distinct but complementary physiological alterations that contribute to a program of cardiovascular changes in Aplysia. We have found that the RNA encoding the R15 polyprotein is spliced differently in different neurons. Our results suggest that alternative splicing of RNAs encoding polyproteins may provide a mechanism to generate distinct but overlapping sets of peptides that govern distinct but related physiological or behavioral programs.     

An autoradiographic analysis of neurogenesis in juvenile Aplysia californica

In developing Aplysia californica, a dramatic proliferation of new neurons occurs throughout the central nervous system (CNS) surprisingly late in juvenile development (Cash and Carew, 1989). In the present study, we investigated the source of these new neurons. Using tritiated thymidine autoradiography, we examined two different juvenile stages: stage 11 (before the large-scale proliferation) and stage 12 (at the peak of proliferation). Previous results implicated the body wall as a source for neurons in developing Aplysia (McAllister, Scheller, Kandel, and Axel, 1983; Jacob, 1984). Thus, we focused our attention on the body wall adjacent to a specific central ganglion, the abdominal ganglion. We found that in stage 11 there was uniform labelling of cells across the entire body wall. However, in stage 12 there was significantly more labelling in the body wall region immediately adjacent to the abdominal ganglion compared to flanking regions. Thus, at the time of neuronal proliferation, specific and highly localized regions of the body wall immediately opposite their target in the CNS show a significant increase in cell division. We also examined the distribution of labelled cells in the abdominal ganglion at survival times of 1 and 7 days after thymidine injection. In both stage 11 and stage 12, the fraction of labelled cells on the surface of the ganglion decreased over time, with a corresponding significant increase in the fraction observed on the inside. Our results support the hypothesis that specific regions of body wall are significantly up-regulated in juvenile Aplysia development, giving rise to widespread neuronal proliferation. These neurons then migrate from the body wall to their target ganglion, and from there continue migrating into the ganglion to achieve their final position.     

AMINO ACID CONCENTRATIONS IN THE APLYSIA NERVOUS SYSTEM: NEURONS WITH HIGH GLYCINE CONCENTRATIONS

Abstract— The levels of the amino acids glycine, aspartic acid and glutamic acid were determined in the ganglia and in identified neurons of A. californica. All of the determinations were done by gas chromatography–mass spectrometry–selected ion monitoring using deuterium-labelled amino acids as internal standards. Aspartate and glutamate concentrations vary 2- to 3-fold among the ganglia and individual neurons. Glycine levels are 3–10 times higher in the abdominal ganglion than in the other ganglia. This is in large part due to the glycine concentrations in the abdominal ganglion neurons R3–R14 being about 20 times higher than in the somata of most other Aplysia neurons. The concentrations of all three amino acids are several times lower in the muscle than in ganglia, and orders of magnitude lower in the hemolymph than in tissue.     

Serotonin immunoreactivity of neurons in the gastropod Aplysia californica

Serotonergic neurons and axons were mapped in the central ganglia of Aplysia californica using antiserotonin antibody on intact ganglia and on serial sections. Immunoreactive axons and processes were present in all ganglia and nerves, and distinct somata were detected in all ganglia except the buccal and pleural ganglia. The cells stained included known serotonergic neurons: the giant cerebral neurons and the RB cells of the abdominal ganglion. The area of the abdominal ganglion where interneurons are located which produce facilitation during the gill withdrawal reflex was carefully examined for antiserotonin immunoreactive neurons. None were found, but two bilaterally symmetric pairs of immunoreactive axons were identified which descend from the contralateral cerebral or pedal ganglion to abdominal ganglion. Because of the continuous proximity of this pair of axons, they could be recognized and traced into the abdominal ganglion neuropil in each preparation. If serotonin is a facilitating transmitter in the abdominal ganglion, these and other antiserotonin immunoreactive axons in the pleuroabdominal connectives may be implicated in this facilitation.     

Localization of GABA- and glutamate-like immunoreactivity in the cardiac ganglion of the lobster Panulirus argus

Wholemount immunohistochemical methods were used to examine the localization of γ-aminobutyric acid (GABA) and glutamate within the cardiac system of the Caribbean spiny lobster Panulirus argus. All of the GABA-like immunoreactivity (GABAi) in the cardiac ganglion originated from a single bilateral pair of fibers that entered the heart via the two dorsal nerves. Each GABAi axon bifurcated upon entering the ganglion and gave rise to varicose fibers that surrounded the somata and initial segments of the five large motor neurons. The four small posterior cells did not appear to receive somatic contacts. Double-labeling experiments in which individual motor neurons were injected with Neurobiotin showed that their dendritic processes, which project to muscle bundles adjacent to the ganglion and are thought to respond to stretch, were also accompanied by branches of the GABAi fibers. Glutamate-like immunoreactivity (GLUi) was present in each of the motor neuron cell bodies. In some preparations, GLUi was also detected in large caliber fibers in the major ganglionic nerves. These fibers gave rise to more slender branches that innervated the cardiac muscle bundles. GLUi was also found in the small cell bodies and in fibers surrounding motor neuron somata. Taken together, these findings support previous electrophysiological, pharmacological and anatomical studies indicating that GABA mediates extrinsic inhibition and that glutamate acts as a neuromuscular and intraganglionic transmitter in this system. While axosomatic contacts may play a major role in both transmitter systems, the GABAergic inhibition also appears to involve substantial axodendritic synaptic signaling.     

The morphology of the fourth abdominal ganglion of the hermit crab: A light microscope study

The hermit crab, Pagurus pollicarus, has the same organization in its fourth abdominal ganglion as its macruran relatives in spite of the reduction in abdominal muscles, sensory receptors, and appendages. Connective axons are grouped into discrete bundles between which five groups of commissural fibers run to connect left and right sides. The neurites of ventral cell bodies run dorsally in characteristic groups between the connective bundles. The hermit crab fourth ganglion has two thirds as many cells as the crayfish and is laterally compressed. This reduction appears related to the reduction in the sizes of the ganglionic roots. The ventral fine fibered neuropil is larger on the left than the right side reflecting the loss of pleopods on the right side. The basic organization of decapod abdominal ganglia appears to permit considerable integrative flexibility within a relatively conservative morphological framework.     

Identification and molecular cloning of a neuropeptide Y homolog that produces prolonged inhibition in Aplysia neurons.

The neuroendocrine bag cell neurons of the marine mollusk Aplysia produce prolonged inhibition that lasts for more than 2 hr. We purified a peptide from the abdominal ganglion that mimics this inhibition. Mass spectrometry and microsequence analysis indicate that the peptide is 40 aa long and is amidated at its carboxyl terminus. It is highly homologous to vertebrate neuropeptide Y (NPY) and other members of the pancreatic polypeptide family. As determined from cloned cDNA, the gene coding for the precursor protein shares a common structural organization with genes encoding precursors of the vertebrate family. The peptides may therefore have arisen from a common ancestral gene. Bag cell neurons are immunoreactive for Aplysia NPY, and Northern blot analysis indicates that as with its vertebrate counterparts, the peptide is abundantly expressed in the CNS. This suggests that peptides related to NPY may have important functions in the nervous system of Aplysia as well as in other invertebrates.