Ingestive sensory inputs excite serotonin effector neurones and promote serotonin depletion from the leech central nervous system and periphery.

Thermal and chemical stimuli known to promote ingestive behaviours in the medicinal leech Hirudo medicinalis were tested for their physiological effects on Retzius neurones and for their biochemical effects on serotonin levels in the central nervous system, pharynx and body wall. Retzius neurones throughout the leech nerve cord receive excitatory synaptic input during thermal or chemical stimulation of the prostomial lip. These neurones respond to the rate of change of temperature as well as to absolute temperature at the lip. Exposure of the lip to sodium chloride excites Retzius neurones, whereas exposure to arginine has little effect. Thermal stimulation of the lip elicits a more rapid but less prolonged excitation of Retzius neurones than does chemical stimulation. Stimulation of the prostomial lip is associated with afferent activities in the cephalic nerves D1, D2 and V1-2. Thermal stimulation of the prostomial lip results in depletion of serotonin from midbody ganglia, whereas chemical stimulation has no effect. Conversely, chemical stimulation of the lip results in depletion of serotonin from the body wall, whereas thermal stimulation does not. Pharyngeal serotonin content is decreased with either modality. These data distinguish two important feeding-related sensory input pathways to central serotonergic effector neurones in Hirudo medicinalis.

Inhibitory actions of dopamine on Limulus visceral muscle involve a cyclic AMP-dependent mechanism.

1. The catecholamines dopamine, epinephrine and norepinephrine were detected in alumina extracts of Limulus midgut tissue using high performance liquid chromatography with electrochemical detection. Moderate levels of norepinephrine (28.2 +/- 2.1 ng/g) and dopamine (24.0 +/- 5.2 ng/g) were detected in the midgut, while epinephrine levels (7.4 +/- 0.9 ng/g) were less. Catecholamines were present in all regions along the longitudinal axis of the midgut, and norepinephrine and dopamine levels were highest in posterior regions. 2. Catecholamines decreased muscle tonus and inhibited spontaneous contractions of the Limulus midgut. Dopamine typically decreased spontaneous midgut activity at doses of 10(-8) M or greater, and produced inhibitory actions on all regions of the Limulus midgut. In some preparations epinephrine and norepinephrine elicited a secondary rhythmicity. The actions of dopamine opposed the excitatory effects produced by either proctolin or octopamine. 3. Catecholamines significantly elevated levels of cyclic AMP in Limulus midgut muscle rings. Dopamine (10(-5) M) increased cyclic AMP with a time course consistent with its physiological effects. Forskolin and several methyl xanthines increased Limulus midgut cyclic AMP levels and mimicked the inhibitory effects of dopamine on the isolated midgut preparation. Cyclic nucleotide analogues also produced dopamine-like effects on the isolated midgut preparation. Inhibition of cyclic nucleotide phosphodiesterase prior to addition of dopamine enhanced the effect of this amine to decrease baseline muscle tension. 4. The inhibitory effects of 10(-5) M dopamine on the midgut persisted in solutions of zero sodium and in the presence of tetrodotoxin. Zero calcium solutions gradually reduced spontaneous midgut activity and the effects of dopamine. Calcium channel blockers did not prohibit dopamine-induced relaxation.(ABSTRACT TRUNCATED AT 250 WORDS)

Serotonin in the leech central nervous system: anatomical correlates and behavioral effects.

1. Serotonin is sequestered by a limited population of identified neurons in the 32 ganglia of the leech nervous system. A major fraction of the serotonin in each ganglion is contained in the paired Retzius cells, colossal effector neurons whose size varies longitudinally. The 5 other classes of identified serotonin-containing neurons, one effector cell and 4 interneurons, are approximately twice as numerous in anterior as in posterior ganglia. 2. We dissected 6 longitudinal samples from the ventral nerve cords of hungry Hirudo medicinalis, and measured their serotonin content using high pressure liquid chromatography with electrochemical detection. A consistent neurochemical pattern emerged in which segmental ganglia 2-4 had the highest quantity of serotonin: 18.51 pmol per ganglion. The anterior cerebral ganglion contained 14.78 pmol, and the content of the 4 posterior samples, segmental ganglia 7-10, 12-15, 17-20 and the caudal ganglion, decreased continuously from 16.35, 15.08, 10.75 to 2.51 pmol per ganglion, respectively. Morphometric analyses indicated that this pattern of ganglionic serotonin correlated primarily with longitudinal variations in the number of serotonin neurons per ganglion and secondarily with volume of the Retzius cells. Retzius cell volume correlated highly with the mass of their innervated body segments both of which are largest in mid-body domains. 3. Serotonin expresses leech feeding, and its ganglionic levels are a potentially useful index of behavioral state. We measured serotonin in the ganglionic samples from hungry and satiated leeches. The samples from recently fed animals contained 28% less serotonin than those from hungry ones. The amounts of serotonin in the cerebral and all the segmental samples from satiated leeches were significantly lower than equivalent samples of hungry animals. A similar pattern of depletion was seen in leeches which fed for a prolonged period (90 to 120 min) rather than the normal period of 30 min. 4. The effects of ingestion on serotonin-containing neurons was examined with the glyoxylic acid-induced histochemical fluorescence. The levels of fluorescence in all serotonin neurons in fed leeches were consistently lower than those in equivalent neurons in hungry animals, corroborating the ganglionic decrease in serotonin in satiated leeches. 5. To examine effects of body wall distension on serotonin levels, hungry leeches were fed to satiation, and half of them were relaxed by removing their distending blood meals. After 6 weeks, ganglionic serotonin in leeches with relaxed bodies was 21% higher than in those with distended bodies. 6. Ingestive behavior depletes serotonin from leech neurons and body wall distension appears to interfere with its synthesis.(ABSTRACT TRUNCATED AT 400 WORDS)

Serotonin is released from isolated leech ganglia by potassium-induced depolarization.

1. The quantities of serotonin that are released from isolated leech ganglia in vitro were measured with the sensitive neurochemical techniques of HPLC-EC. 2. Segmental ganglia were exposed to elevated concentrations of potassium that depolarize leech serotonin-containing neurons by approximately 35 mV per decade. 3. Each segmental ganglion released on average 0.20 pmol of serotonin during 10 min of incubation in a solution containing 64 mM K+. 4. The rate of serotonin release increased nearly four-fold to 0.74 pmol/10 min when ganglia were incubated in 120 mM K+. 5. The rates of ganglionic serotonin release in 120 mM K+ were quantitatively similar in these three, experimentally important species of leeches: Hirudo medicinalis, Macrobdella decora and Haementeria ghilianii. 6. Ionic substitution experiments with the divalent cations Mg2+ and Co2+ indicated that the release of serotonin from leech ganglia is mediated by a Ca2+ dependent process. 7. The serotonin-uptake blockers, imipramine and chlorimipramine, did not increase the amount of serotonin released in elevated potassium. 8. Vitally staining the identified serotonin-containing neurons with Neutral Red dye did not reduce the quantity of serotonin that was released from the ganglia in elevated potassium. 9. This study demonstrates the capacity of leech ganglia to release the neurochemical serotonin, and the rates of transmitter release increase with the degree of depolarization of serotonin-containing neurons.

Ingestive behaviour and physiology of the medicinal leech.

Ingestion lasts 25 min in Hirudo medicinalis and is characterized by pharyngeal peristalsis which fills the crop. This peristalsis has an initial rate of 2.4 Hz which decays smoothly to 1.2 Hz at termination of ingestion. During ingestion, the leech body wall undergoes peristalsis which appears to aid in filling the crop diverticula. Body peristalsis begins at a rate of 10 min-1 and decreases linearly to 2 min-1 at termination. The body also undergoes dorsoventral flexions when blood flow is occluded. Blood meal size increases slightly with leech size: 8.4 g for 1-g leeches and 9.7 g for 2-g leeches. However, relative meal size decreases markedly with increasing animal size; from 8.15 times body mass for 1-g to 4.80 times for 2-g leeches. When intact leeches were exposed to micromolar concentrations of serotonin, there was an increase in the rate of pharyngeal peristalsis and the size of the blood meals. Leeches excrete the plasma from their ingested blood meals. Excretion is activated during ingestion, which increases feeding efficiency by increasing the proportion of blood cells in the ingestate. Excretion continues for 4-6 days following ingestion, removing all the remaining plasma from the ingestate. Leech ingestion comprises stereotyped muscular movements, secretion of saliva and excretion of plasma. A strikingly similar feeding physiology is seen in the blood-sucking insect Rhodnius, and we suggest that efficient sanguivory may require the convergent evolution of similar ingestive mechanisms.

Excitability and secretory activity in the salivary gland cells of jawed leeches (Hirudinea: Gnathobdellida).

Thousands of salivary cells fill the interstices throughout the anterior ends of jawed leeches. The somata are large (30-200 micron in diameter). They project single processes (ductules) into the three jaws, and were found to fire overshooting action potentials of 50-85 mV amplitude and 100-200 ms duration at low spontaneous rates. The action potentials were not detected in the presence of cobalt (10 mmol l-1), but could be recorded when sodium was absent from the Ringer, so they appear to be calcium-dependent. Salivary material is transported by the long processes of these unicellular glands and secreted into ducts which alternate with paired teeth on the jaws. Secretion is activated reliably by 10(-6) mol l-1 serotonin, but not by other neurotransmitters found in the leech nervous system. Each jaw secretes at an average rate of 230 nl min-1 in the presence of serotonin, and secretion is completely abolished by cobalt. Perfusion with serotonin excites the salivary gland cells into impulse activity, and often evokes bursting. Impulse activity of the peripherally projecting, serotonergic Retzius cells evokes both depolarizations and action potentials in the salivary gland cells. In jawed leeches, central neurones appear to control salivation by a peripheral release of serotonin. This neurotransmitter evokes calcium-dependent action potentials and calcium, in turn, stimulates secretion.

The neurobiology of feeding in leeches.

How does a simple nervous system control a behavior? In the bloodsucking medicinal leech a single neurotransmitter, serotonin, has been found to orchestrate the animal's search for a target, the movements of its jaws, the filling of its crop and even the distension of its body that eventually tells the leech enough is enough.

On the termination of ingestive behaviour by the medicinal leech.

Hungry leeches, Hirudo medicinalis, ingest blood meals averaging 890% of their mass in 29 min. Ingestion is terminated as a result of distension of the body: experimentally distending leeches as they feed causes an immediate cessation of ingestion and inhibits any subsequent biting behaviour; if distension is circumvented by various experimental procedures, leech ingestive periods are prolonged significantly. Ingestion is not terminated as a result of fatigue, chemical cues or mass change. Distension also underlies satiation, for removing blood from the crops of recently fed leeches qualitatively alters their satiated behaviour to biting. Biting is not a defensive reaction to injury. In rostral ganglia, impulses of the serotonergic Retzius (RZ) and LL neurones evoke the physiological components of ingestion. Localized warming of the prostomial lip induces impulses in these large effector neurones. Distending the body wall tonically hyperpolarizes the RZ and LL cells. This inhibitory response to distension is conducted from the mid-body to the anterior neurones via the ventral nerve cord. Distensive inhibition antagonizes the synaptic excitation evoked in RZ and LL neurones by thermal stimulation. Thus, a stimulus which evokes feeding synaptically excites 5-HT neurones and a stimulus which terminates ingestion inhibits them. The integration of these inputs controls the expression of leech feeding behaviour and these connections match precisely a model proposed to regulate the ingestive behaviour of blowflies.

Serotonergic modulation of the feeding behavior of the medicinal leech.

Hungry medicinal leeches, Hirudo medicinalis, bite warm surfaces and ingest blood meals averaging 890% of their weight. Satiation lasts 12-18 months during which leeches avoid warm surfaces and will not bite. The segmental nervous system of the leech is distinguished by a population of neurons which contain serotonin (5-Hydroxytryptamine, 5-HT) at high concentrations. Some of these identified 5-HT neurons directly activate the effectors responsible for three physiological components of feeding: salivary secretion, bite-like movements and pharyngeal peristalsis. A localized warming of the lip is sufficient to initiate ingestion and synaptically excites anterior 5-HT cells into high frequency impulses or bursts. Distension of the body wall terminates ingestion and also hyperpolarizes these 5-HT neurons. Serotonin treatment produces hyperphagic behavior by the leech, while a specific pharmacological lesion of its 5-HT cell produces the anorexic behavior of satiation. This anorexia is transiently reversed by 5-HT treatment. Serotonin plays an obligatory role in the initiation and expression of leech feeding behavior by its differential modulation of central neuronal networks and peripheral glands and muscles.

6-Hydroxydopamine produces lesions of serotonin-containing Retzius cells in the leech nervous system.

The neurotoxin 6-hydroxydopamine (6-OHDA) is reported to selectively ablate neurons which contain catecholamines. Leeches were injected with 6-OHDA over a 4-month period in an attempt to destroy their identified dopamine neurons. Ganglionic Retzius cells (RZ), which contain serotonin, were the first to be rendered brown, misshapen, and non-fluorescent. Continued injections of 6-OHDA had similar, but less substantial, morphological and histochemical effects on the dopamine-containing neurosomata within the anterior roots. Toxin treatment reduced RZ serotonin by 75-90%, but these depleted cells retained normal electrophysiological properties. Serotonin and dopamine within ganglia, as well as dopamine within anterior roots, were reduced significantly by 6-OHDA.

Calcium-dependent action potentials in leech giant salivary cells.

Two pairs of discrete salivary glands are located at the base of the muscular proboscis of the sanguivorous Glossiphoniid leeches Haementeria ghilianii and Haementeria officinalis. Each anterior gland is 0.8 cm to 2 cm in length, and comprises over 200 giant salivary cell bodies ranging from 150 microns to over 1000 microns in diameter, depending on the size of the animal. The salivary cells are neither electrically nor dye coupled, and there is no acinar structure or common duct, but instead each cell extends an individual ductule. The cells fire action potentials of 100-200 ms duration and 70-100 mV amplitude in response to depolarizing pulses, or at the cessation of a hyperpolarizing pulse. The impulse is abolished by procedures known to antagonize calcium currents, and persists in sodium-free solution, or when calcium is replaced with strontium or barium. Our results support the hypothesis of a purely calcium-dependent impulse.

Quantitative effects of a neurotoxin upon serotonin levels within tissue compartments of the medicinal leech.

The serotonin (5-hydroxytryptamine, 5-HT) content of tissue compartments in the medicinal leech, Hirudo medicinalis, was measured by means of high-pressure liquid chromatography coupled with electrochemical detection (HPLC-EC). Each segmental ganglion contains 21.3 +/- 2.9 (9) pmol 5-HT [X +/- SEM (N)]. The pharynx contains 7.1 +/- 1.1 (9) pmol 5-HT/mg wet weight; the salivary glands 3.2 +/- 0.9 (10), ventral body wall 2.0 +/- 0.2 (11), and vasofibrous tissue 1.2 +/- 0.2 (11). The blood of hungry leeches contains 8.7 +/- 1.9 (7) nM 5-HT while that of well-fed leeches is 2.2 +/- 0.4 (6) nM. Leeches were injected with the cytotoxic analog of serotonin, 5,7-dihydroxytryptamine (5,7-DHT) producing selective lesions of the peripherally projecting serotonin-containing neurons, and which in turn abolished their feeding behavior. The serotonin content of the pharynx and ganglia of these toxin-treated leeches were lowered significantly. The serotonin levels within the body wall and salivary glands were not altered significantly by the toxin treatment, but the levels within the vasofibrous tissue and blood were elevated substantially.

Relationship of muscle growth in vitro to sodium pump activity and transmembrane potential.

Serum stimulates embryonic avian skeletal muscle growth in vitro and the growth-related processes of amino acid transport and protein synthesis. Serum also stimulates myotube Na pump activity (measured as ouabain-sensitive rubidium-86 uptake) for at least 2 h after serum addition. Serum-stimulated growth depends on this Na pump activity since ouabain added at the same time as serum totally inhibits the growth responses. The relationship of myotube growth, Na pump activity, and transmembrane potential was studied to determine whether serum-stimulated Na pump activation and growth are coupled by long-term membrane hyperpolarization. When myotube amino acid transport and protein synthesis are prestimulated by serum, ouabain was found to have little inhibitory effect, indicating that the already stimulated growth-related processes are not tightly coupled to continued Na pump activity. Serum-stimulated protein synthesis is tightly coupled to Na pump activity, but only during the first 5-10 min after serum addition. When myotube transmembrane potentials were measured using the lipophilic cation tetraphenylphosphonium, serum at concentrations that stimulate myotube growth and Na pump activity was found to have little effect on the cell's transmembrane potential. Furthermore, partial depolarization of the myotubes with 12- to 55-mM extracellular potassium does not prevent serum stimulation of myotube growth. Monensin was found to hyperpolarize the myotubes, but causes myotube atrophy. These results indicate that although Na pump activity is associated with initiation of serum-stimulated myotube growth, continued Na pump activity is not essential, and there is little relationship between myotube growth and the myotube's transmembrane potential.

Retzius cells retain functional membrane properties following 'ablation' by the neurotoxin 5,7-DHT.

The neurotoxin 5,7-dihydroxytryptamine (5,7-DHT) is generally believed to selectively ablate serotonergic neurons. Serotonin-containing Retzius cells (RZ) in the leech appear ablated by 5,7-DHT treatment. However, these brown, mis shapen , non-fluorescent neurons retain their synaptic inputs, action potentials, electronic outputs, a membrane receptor, and axonal projections.

Action potential prolongation: an effect of physostigmine (eserine) upon Retzius cells in the leech C.N.S.

Physostigmine (PHY; eserine) prolongs the action potentials in the Retzius cells within leech ganglia to about 800 ms. The effect was reversible and occurred at concentrations of 1-10 mM which are several orders of magnitude greater than those required to inhibit cholinesterase. The prolonged action potentials showed an early, spike-like depolarization followed by a plateau. The initial depolarization exhibited a strong dependence on external Na+ while the amplitude of the plateau had somewhat less Na+ dependence: 52 and 24 mV/decade, respectively. The duration of the plateau was increased by elevating Na+ and decreased by elevating Ca2+. Increasing the action potential frequency, by intracellular stimulation, decreased both the duration and amplitude of the plateau. Neostigmine, di-isopropylphosphofluoridate, and acetylcholine did not prolong RZ action potentials. Thus, the membrane effects of physostigmine appear to be independent of any inhibition of cholinesterase or accumulation of acetylcholine.

Chromatographic and histochemical identification of dopamine within an identified neuron in the leech nervous system.

Each segmental ganglion of the leech nervous system has two pairs of lateral roots extending to the body wall and viscera. A cluster of about eight neuron cell bodies is located proximal to the first major branch of each anterior root and is termed the anterior root ganglion (ARG). Only one of these eight cells is vitally-stained by Neutral Red dye and fluoresces an intense blue-green following the glyoxylic acid histochemical condensation. The emission spectrum of this anterior root cell (AR) is stable under continuous UV illumination and is bimodal, with peaks at about 480 and 515 nm. This spectrum is indistinguishable from that of millimolar solutions of dopamine (DA) in gelatin droplets following glyoxylic acid histochemistry. We utilized high performance liquid chromatography and an amperometric detector to measure DA within the AR neurosomata at 1.01 pmol/cell. The AR cells in this study had an average diameter of 23 micron and therefore, the minimum intrasomatal concentration of DA is 160 mM, an unusually high level for any neurotransmitter. We measured DA in anterior axons at 0.83 pmol, in segmental ganglia at 1.07 pmol, and in longitudinal connectives at 0.16 pmol. Control neurosomata (Retzius cells) and axonal tracts which lack blue-green fluorescence (posterior and distal anterior roots), had no detectable DA (less than 0.06 pmol/sample). These data establish that the catecholamine DA is responsible for the fluorescence of the AR cell.

Fluorescent properties of monoamine neurons following glyoxylic acid treatment of intact leech ganglia.

The SPG modification (de la Torre and Surgeon 1976) of the glyoxylic acid method for amine condensation is a straightforward procedure which can be used upon intact ganglia from the leech. Intense fluorescence of the neurosomata of identified neurons which contain either indoleamine (serotonin, 5-HT) or catecholamine (CA) is obtained in less than 30 min. The fluorescence of the 5-HT containing neurons is yellow (518-526 nm) and decays more rapidly than the dominant blue emission (478-480 nm) of the CA neurons. Most importantly, the SPG technique greatly enhances the visibility of the axonal processes of neurons which contain both classes of amines over the fluorescence produced by formaldehyde condensation techniques. Both blue and yellow fluorescent varicosities are easily distinguished in the longitudinal connectives and lateral roots of the leech C.N.S. Because of its simplicity and high fluorescence yields, the SPG method for histochemical fluorescence should contribute to investigations of amine functions in invertebrate nervous systems.