Cerebral interneurons controlling fictive feeding in Limax maximus

Summary Initiation and modulation of fictive feeding by cerebral to buccal interneurons (CBs) was examined in an isolated CNS preparation of Limax maximus. Three CBs which are phasically active during fictive feeding, CB₁, CB₃ and CB₄, will reliably trigger bouts of fictive feeding when activated alone or in pairs. Another phasic CB, CB_EC, is not effective for triggering feeding. One CB which is tonically active during fictive feeding, CB_ST, drives fictive feeding in 50% of preparations when activated alone and enhances triggering of feeding when co-activated with phasic CBs. The metacerebral giant cell (MGC) was found to be capable of triggering fictive feeding in preparations with an intact subcerebral commissure. The MGC was especially effective at increasing the effectiveness of other CBs for initiation of feeding. Short high-frequency bursts of phasic CB or MGC action potentials are capable of resetting ongoing fictive feeding. Resetting effects of CB action potentials are relatively independent of the phase of the bite-cycle in which they are activated. CB₄ phase-advances the bite-cycle while the other phasic CBs phase-delay the bite cycle. Moderate frequency stimulation of CB₄ speeds up the bite rate while moderate frequency stimulation of CB₃ slows biting. All CBs, except the tonic CB, CB_DL, increase the intensity of buccal motor neuron bursting during feeding. The excitatory effects of phasic CBs and the tonic CB, CB_EPSP, on fictive feeding persist for many seconds after the offset of stimulation. CBs form both monosynaptic excitatory and monosynaptic inhibitory connections with different BG motor neurons.Abbreviations BG buccal ganglion - BR buccal root - CB cerebral-buccal interneuron - CBC cerebral-buccal connective - CPG central pattern generator - FB fast burster neuron - FMP feeding motor program - IBI interbite interval - MGC metacerebral giant cell     

The molluscan neuropeptide, SCPB, increases the responsiveness of the feeding motor program of Limax maximus

Small cardioactive peptide B (SCPB) has an excitatory effect on both buccal neurons and musculature in numerous molluscan species. The present study reports the effects of SCPB on the activity of specified buccal neurons and the expression of the feeding motor program of the terrestrial slug, Limax maximus. Superfusion of an isolated CNS preparation with 10(-6)M SCPB results in a 3-4-fold increase in the burst frequency of the fast salivary burster neuron (FSB), while having no effect on the activity of another endogenous burster, the bilateral salivary neuron (BSN). The response of the FSB to SCPB is dose dependent, with a threshold concentration of 2 X 10(-8)M. The response of the FSB to SCPB showed no indication of desensitization, even after long-term exposure (20 min). The feeding motor program (FMP) in Limax is a discrete pattern of cyclical motor activity that can be initiated by lip nerve stimulation. In the presence of SCPB a previously subthreshold stimulus can initiate the full FMP. The pattern of the FMP, once initiated, appears unaffected by SCPB. Thus it is the responsiveness of the initiation process that is enhanced by SCPB. Histochemical studies revealed a number of buccal neuron somata and fibers that stain for SCPB-like immunoreactive material (SLIM).     

Naloxone-reversible stress-induced feeding and analgesia in the slug Limax maximus

Exposure to tail-pinch stress increased the thermal nociceptive thresholds and food intakes of the slug, Limax maximus. These stress-induced "analgesic" and feeding responses, which were similar to the behaviors observed after treatment with exogenous opiates, were blocked by the opiate antagonist, naloxone. These results indicate that exposure to stress increases endogenous opioid activity in slugs and induces various behavioral and physiological responses in a manner analogous to that reported in mammals.     

Autoactive molluscan neuron: Reflex function and synaptic modulation during feeding in the terrestrial slug,Limax maximus

Summary The salivary burster (SB) is an autoactive motoneuron to the salivary duct of the terrestrial slugLimax maximus. The SB is electrically coupled to protractor motoneurons and inhibited by the metacerebral giant cell. During feeding these synaptic inputs cause SB activity to be phase-locked to the protraction-retraction cycle. The SB can be used as a clear and reliable monitor of feeding motorprogram activation.We thank Dr. Joseph Jin Chang for invaluable assistance with some of this work. Support was provided by NSF grant BMS74-15217 to D.J.P., NSF grant BMS74-03572 to A.G., and a grant from the Spencer Foundation.     

Dietary choline augments associative memory function in Limax maximus

Previous clinical and experimental work has shown that increased dietary intake of choline elevates blood choline and brain acetylcholine levels. This change in neuronal acetylcholine concentration may augment learning and memory functions. We tested this prediction using the mollusc Limax maximus, an animal which can be readily conditioned to avoid food odors. In our experiments, initial learning of a food avoidance task was not augmented by the high choline diet. However, the duration of memory retention was prolonged. In previous studies, we have shown that intake of the choline enriched diet significantly increases blood choline and amplifies transmission at an identified cholinergic synapse in Limax. Together, these results support the involvement of cholinergic synapses in the memory retention mechanism.     

The effects of feeding on heart activity in the terrestrial slug,Limax maximus: central and peripheral control

Summary The role of the central nervous system (CNS) in the modulation of heart activity induced by feeding was investigated in the terrestrial slug,Limax maximus. Intact slugs and semi-intact preparations were used to examine the effects of food, non-nutritive bulk, digestive tract distension, and the concentration of hemolymph glucose on the control of heart activity. The heart rate of intact slugs increased following ingestion of food or nonnutritive bulk and in response to injections of glucose. The heart rate of semi-intact preparations increased in response to gradual crop inflation and to perfusion of the heart with a glucose solution for longer than 30 min. The present results indicate that the increase in heart rate observed in intact slugs following a meal is mediated in part by the CNS and in part is a direct response of the heart musculature. The CNS mediates an immediate response to proprioceptive input from stretch of the crop while the heart musculature responds directly to increased hemolymph glucose concentration following ingestion of food.     

Distribution of biogenic amines in the slug,Limax maximus

Summary The distribution of monoamines inLimax maximus was studied by the histochemical fluorescent method of Falck and Hillarp. The number of 5-HT-containing and catecholamine-containing perikarya in the central nervous system is small compared with the non-fluorescent perikarya. However, all the ganglia except the proto-cerebral ganglia have some amine-containing neurons. There are relatively larger numbers of fluorescent cells in the cerebral, visceral, pedal and right parietal ganglia than in the other ganglia. A single, giant 5-HT-containing neuron was observed in each meta-cerebral ganglion.Monoamine neurons are localised in a number of peripheral tissues (heart, integument, tentacles, penis retractor muscle, sole of foot, kidney, alimentary canal, reproductive organs and tentacular, pharyngeal and cephalic retractor muscles). Neurons containing catecholamine are mostly associated with sensory structures such as the statocysts, the retina of the eye and the integument of the tentacles, whereas 5-HT-containing nerve fibres are mainly observed in muscle tissues.We wish to thank the Wellcome Trust for financial support.     

Feeding motor program in Limax. I. Neuromuscular correlates and control by chemosensory input

The feeding motor program(FMP) of the terrestrial slug Limax maximus was examined in vivo and in vitro. The feeding pattern of intact animals shows an initial increase in bite frequency followed by a plateau phase. Recordings obtained from semi-intact preparations of the lips, brain, and buccal mass established the correlation of activity in buccal ganglion nerve roots with the protraction-retraction bite cycle. A preparation of the lips, cerebral ganglia, and buccal ganglia was developed, such that, repetitive chemostimulation of the lips yields reproducible bouts of FMP. Sources of proprioceptive feedback from buccal muscles were demonstrated. The feasibility of computer scoring of the FMP is documented. The results demonstrate that aspects of in vivo feeding behavior are retained and identifiable in highly dissected, in vivo preparations.     

Distribution of GABA-like immunoreactive neurons in the slug Limax maximus

Summary Immunohistochemical techniques were used to study the distribution of gamma-amino butyric acid (GABA)-like immunoreactive neurons in the nervous system of the slug Limax maximus. Approximately 170 GABA-like immunoreactive cell bodies were found in the central nervous system. These were located in the cerebral, buccal and pedal ganglia. Most GABA-like immunoreactive neurons had small cell bodies, which were aggregated into discrete clusters within the cerebral and pedal ganglia. Three pairs of longer, uniquely identifiable, GABA-like immunoreactive cells were found in the cerebral ganglion. GABA-like immunoreactive nerve fibres were also found in all of the central ganglia but were absent from peripheral nerves. These results suggest that GABA acts as a central neurotransmitter in the slug. The possible roles of GABA-ergic neurotransmission in the slug are discussed.     

Brain-gonad axis and photoperiodically-stimulated sexual maturation in the slug,Limax maximus

Summary Physiological and endocrine mechanisms mediating long-day (LD 168) triggered sexual maturation were studied in the terrestrial slug,Limax maximus. Our findings were: (1) Maturation was induced in immature slugs seeing only short days (LD 816) after implantation of whole brains from maturing donors, but no development was found in sham-operated control slugs or in animals receiving implants of muscle from mature donors (Table 1). (2) Removal of the optic tentacles did not block maturation in LD 168 or promote maturation in LD 816 (Fig. 1). (3) Gonadectomy (castration) abolished penis development in 9 of 11 slugs exposed to LD 168 for periods of up to 31 weeks (Table 2). The results are consistent with a model forLimax reproductive tract development in which the perception of long days by extraocular receptors results in the secretion of a maturation hormone by the brain followed by the production of a separate male-phase sex hormone by the developing gonad.Abbreviations ASO accessory sex organs - DB dorsal bodies - FPSH female-phase sex hormone - MH maturation hormone - MPSH male-phase sex hormone This work was supported in part by grants from NSF (BNS 78-01408) and NIH (MH 27948) to P.G.S. The assistance of Mr. T.M. Gordon, Mr. J.L. Broyles, and Mr. M. Bullock is gratefully acknowledged.     

Immunohistochemical demonstration of cholinergic structures in central ganglia of the slug (Limax maximus, Limax valentianus)

Immunohistochemical techniques were used to study the distribution of cholinergic neurons containing choline acetyltransferase of the common type (cChAT), the synthetic enzyme of acetylcholine, in the central nervous system of the slug Limax maximus and Limax valentianus. Because the antiserum applied here was raised against a recombinant protein encoded by exons 7 and 8 of the rat gene for ChAT, three methods were used in order to validate antibody specificity for the Limax counterpart enzyme. Western blot combined with ChAT activity assay following native gel electrophoresis and immunoprecipitation analysis both indicated that immunoreactive Limax brain molecules were capable of synthesizing acetylcholine. Western blot after denatured gel electrophoresis of Limax brain extracts revealed a single band of about 67kDa. All findings obtained with these three methods clearly indicated that the antiserum effectively recognized Limax cChAT. 1400 neuronal cell bodies positive for cChAT, mainly small to medium-sized, were found in various brain regions in the buccal, cerebral, pleural, parietal, visceral and pedal ganglia. cChAT immunoreactive nerve fibers were distributed extensively in the neuropil, connectives and commissures of these central ganglia. The map of cChAT-positive cells provided here are valuable for understanding the cholinergic mechanism in the slug brain, as well as giving an important hint to clarifying the mechanisms of learning and memory in higher vertebrates including humans.     

Repeatability of energy metabolism and resistance to dehydration in the invasive slug Limax maximus

Standard metabolic rate (SMR) and resistance to body dehydration (BD) are important physiological traits that have an effect on water balance and the amount of energy available for activity and production, and thus could contribute to variation in life history traits expressed across a range of environments. Few studies have tested whether SMR and BD show consistent between‐individual variation in molluscs. Significant repeatability of SMR and BD indicates that the traits might be heritable and therefore a possible target for natural selection, so describing the repeatability of SMR and BD is important in studies of phenotypic variability. Here, we studied energy metabolism (body mass‐corrected SMR) and the change in the scaling relationship of SMR and body mass in response to time between measurements in the giant garden slug Limax maximus. Limax maximus is one of the most invasive terrestrial molluscs, with a wide geographical distribution, and is considered an important pest of horticultural and agricultural crops. Our results show that L. maximus follows the expected relationship of increasing SMR with increasing mass, but the scaling exponent varies through time and is different from that described for other gastropods. We also found significant inter‐individual variation in VCO_{2 Mean}, VCO_{2 Min}, VCO_{2 Max}, and BD (τ=0.25, 0.29, 0.24, 0.22, p<0.05, respectively), and significant repeatability of body mass (τ=0.90). To our knowledge, this is the first comprehensive analysis of the repeatability of body mass‐corrected SMR and BD in terrestrial slugs. Our results suggest that energy metabolism and water balance could potentially respond to selection.     

Feeding and a serotonergic interneuron activate an identified autoactive salivary neuron in Limax maximus

• 1.1. A single neuron is found in each buccal ganglion of the giant garden slug, Limax maximus, which is autoactive and has an axon in both the ipsilateral and contralateral salivary nerve.
• 2.2. This neuron, the bilateral salivary neuron (BSN), is a slow bursting neuron and is presynaptic to some of the secretory acinar cells of the salivary gland.
• 3.3. Increases in BSN action potential frequency and saliva flow during the generation of feeding motor program are shown, as is the relationship of BSN activity to that of other salivary neurons.
• 4.4. BSN is affected synaptically by the serotonergic metacerebral giant cell.

     

Distribution of FMRFamide-like immunoreactivity in the nervous system of the slug Limax maximus

Summary The distribution of FMRFamide-like immunoreactive neurons in the nervous system of the slug Limax maximus was studied using immunohistochemical methods. Approximately one thousand FMRFamide-like immunoreactive cell bodies were found in the central nervous system. Ranging between 15 m and 200 m in diameter, they were found in all 11 ganglia of the central nervous system. FMRFamide-like immunoreactive cell bodies were also found at peripheral locations on buccal nerve roots. FMRFamide-like immunoreactive nerve fibres were present in peripheral nerve roots and were distributed extensively throughout the neuropil and cell body regions of the central ganglia. They were also present in the connective tissue of the perineurium, forming an extensive network of varicose fibres. The large number, extensive distribution and great range in size of FMRFamide-like immunoreactive cell bodies and the wide distribution of immunoreactive fibres suggest that FMRFamide-like peptides might serve several different functions in the nervous system of the slug.     

Modification of cardiac activity in response to dehydration in the terrestrial slug, Limax maximus

The level of body hydration in the terrestrial slug Limax maximus modifies several aspects of behavior such as pneumostome activity, feeding responsiveness, huddling, and contact-rehydration. The relationship between water balance and pneumostome activity and respiratory function suggested that cardiac activity might also be affected. To pursue this possibility, intact slugs and isolated heart-central nervous system (CNS) preparations were used to investigate cardiac responses to the increase in hemolymph osmolality which occurs during dehydration. In intact animals, heart rate increased in response to progressive air-dehydration and to increases in hemolymph osmolality resulting from injections of hyperosmotic solutions of mannitol or NaCl. In isolated preparations, the heart or CNS were separately exposed to hyperosmotic saline. Exposure of the heart alone to hyperosmotic saline resulted in decreased heart rate while exposure of only the CNS resulted in an increase in heart rate. These observations suggest that the increase in heart rate that is observed in intact air-dehydrated slugs is primarily mediated by the CNS.     

Neurosecretory cells in the central nervous system of the giant garden slug, Limax maximus

The neurosecretory system of the giant garden slug Limax maximus was studied using the alcian blue/alcian yellow (AB/AY) staining technique for neurosecretion. Stainable cells could be identified in the paired cerebral, pleural, parietal, and buccal ganglia, and in the visceral ganglion. The cells occur as single cells or in groups of up to 100, with diameters ranging between 10 and 70 mu m. Axon tracts could only be traced for a small number of cells; neurohemal areas were not conclusively identified. The morphological similarities of the neurosecretory system of L. maximus is compared with that of other investigated stylommatophoran slugs.     

Analysis of associative learning in the terrestrial mollusc Limax maximus. II. Appetitive learning

Summary The odor and taste processing systems of the terrestrial mollusc Limax maximus have been shown capable of a number of complex computations. Most of the complex higher-order features of Limax learning have been demonstrated using differential aversive conditioning. The present experiments probe the appetitive learning ability of Limax. In the first experiment a differential appetitive classical conditioning procedure was used. An aversive CS⁺ odor was paired with an attractive taste while a CS^– odor was explicitly unpaired with the attractive taste. This appetitive conditioning procedure dramatically increased the preference for the CS⁺ odor. Further experiments determined the time course of acquisition, the effect of an extinction procedure and long-term retention of the appetitive conditioning. Now that Limax has been shown capable of appetitive conditioning, the neural network simulation of Limax learning, called LIMAX, can be examined for its ability to display appetitive conditioning.Abbreviations AA amyl acetate - CS conditioned stimulus - ISI interstimulus interval - ITI intertrial interval - MCH methylcyclohexanol - US unconditioned stimulus     

Localization and synthesis of monoamines in regions of Limax CNS controlling feeding behavior

Localization and synthesis of dopamine and serotonin in the cerebral and buccal ganglia of Limax maximus were studied. A combination of fluorescence histochemistry, immunocytochemistry, and microchemical analysis showed that both amines were localized to particular cell groups and fiber tracts within and between the two sets of ganglia. Since these ganglia control feeding behavior, which is readily modified by associative learning, these studies have direct bearing on analysis of both motor control and learning mechanisms.     

Ultrastructure and histochemistry of the supportive structures associated with the radula of the slug,Limax maximus

The odontophore and connective tissue-filled portion of the radular sac (called the “collostyle”) of the slug, Limax maximus, were examined by light and electron microscopy. While both of these structures grossly resemble vertebrate cartilage, neither is composed of a type of tissue with the microscopic appearance and histochemical properties of cartilage. The roughly U-shaped odontophore possesses a thin capsule composed of connective tissue. The parenchyma of the odontophore consists of modified muscle cells which are organized into irregular groups by incomplete trabeculae composed of conventional muscle cells. The odontophoral cells are variable in size; they contain glycogen-filled “cores” as well as bundles of peripherally located filaments resembling myofilaments; and they are innervated like muscle cells. The nuclei of the cells are located eccentrically in the glycogen-filled portions of the cells and typically contain prominent nucleoli. The nuclei are surrounded by multiple small Golgi complexes and pleomorphic dense bodies resembling lysosomes. The extracellular matrix of the odontophore is very sparse and contains glycogen and fibrillar material but no histochemically demonstrable acidic mucosubstances. The collostyle consists of a gelatinous type of tissue somewhat like vertebrate mucoid connective tissue. The abundant extracellular matrix contains cross banded filaments, a flocculent material disposed in wavy indefinite strands, and small electron-dense particles. The matrix contains histochemically demonstrable neutral and weakly acidic mucosubstances. The cell population of the collostyle includes solitary muscle cells and fibrocytes containing large quantities of glycogen.