Anatomical analysis of contacts between identified neurons that control heartbeat in the leech Hirudo medicinalis

Summary The rhythmic constriction of the heart tubes in the leech Hirudo medicinalis is controlled by an identified set of motor neurons (HE cells) and interneurons (HN cells) (reviewed by Calabrese and Peterson 1983). Electrophysiological recordings have indicated particular synaptic relationships among HE and HN cells. In the present study, the synaptic framework mediating the interactions among HE cells and HN cells was examined anatomically. Using light and electron microscopy of physiologically identified, HRP-injected cells, we have examined the zones of interaction and types of contacts between specific cells. HE cells, which have very fine, threadlike processes, interact with their contralateral homologues throughout most of the middle third of the ganglionic neuropil. When HE-cell neuntes come together, the apposed plasma membranes are rigidly parallel, separated by an intercellular gap of 6 nm, for up to 6 m. These specializations must form the structural basis for the strong electrical coupling observed (Peterson 1983) between HE-cell pairs. HE cells also emit from the main neurite a series of extremely fine processes that extend dorsally. These appear in the light microscope to contact processes of the ipsilateral HN cell of the same ganglion, and are also in a position to make contact with the axons of more anterior HN cells. The intraganglionic processes of HN cells, which are studded with large varicosities, ramify in part of the region of neuropil occupied by HE-cell processes, as well as more posteriorly. Contacts between HE and HN cells, which are known to be mostly inhibitory synaptic contacts, are seen in the electron microscope to be formed between medium-diameter HN processes, which are filled with clear round synaptic vesicles, and multiple fine tendrils of the HE cell that surround the HN process. Certain HN cells form reciprocal inhibitory synapses with their contralateral homologues. These contacts occur near the midline, sometimes in the major mass of neuropil and sometimes embedded in the extracellular material that ensheathes the neuropil. The contacts are between medium-and small-diameter profiles that are both filled with synaptic vesicles. Our findings indicate that various classes of physiological interactions among HE and HN cells are mediated by anatomically distinct types of contacts and, at least in some cases, are segregated from each other on the neuritic trees of the cells.     

Temporal correlation between neuronal tail ganglion activity and locomotion in the leech,Hirudo medicinalis

Intracellular and extracellular recordings were performed in the posterior ventral nerve cord of restrained crawling preparations of the medicinal leech,Hirudo medicinalis. Short-latency neuronal activities in the tail ganglion nerves correlated with different phases of crawling behavior. Eight neurons with characteristic activation patterns during crawling were identified morphologically and physiologically in the tail ganglia of 23 preparations. The axons of four of these neurons projected through posterior tail brain nerves; four ascending interneurons had projections in the connectives or in Faivre's nerve. These interneurons are suitable candidates for carrying information between the front end and the tail end of the animal to coordinate the behavioral components during a crawling step.     

Apparent intracellular Mg2+ buffering in neurons of the leech Hirudo medicinalis

The apparent intracellular Mg2+ buffering, or muffling (sum of processes that damp changes in the free intracellular Mg2+ concentration, [Mg2+](i), e.g., buffering, extrusion, and sequestration), was investigated in Retzius neurons of the leech Hirudo medicinalis by iontophoretic injection of H+, OH-, or Mg2+. Simultaneously, changes in intracellular pH and the intracellular Mg2+, Na+, or K+ concentration were recorded with triple-barreled ion-selective microelectrodes. Cell volume changes were monitored measuring the tetramethylammonium (TMA) concentration in TMA-loaded neurons. Control measurements were carried out in electrolyte droplets (diameter 100-200 microm) placed on a silver wire under paraffin oil. Droplets with or without ATP, the presumed major intracellular Mg2+ buffer, were used to quantify the pH dependence of Mg2+ buffering and to determine the transport index of Mg2+ during iontophoretic injection. The observed pH dependence of [Mg2+](i) corresponded to what would be expected from Mg2+ buffering through ATP. The quantity of Mg2+ muffling, however, was considerably larger than what would be expected if ATP were the sole Mg2+ buffer. From the decrease in Mg2+ muffling in the nominal absence of extracellular Na+ it was estimated that almost 50% of the ATP-independent muffling is due to the action of Na+/Mg2+ antiport.     

On nuclear structure in the ventral nerve cord of the leech Hirudo medicinalis

Summary A fibrous lamina that lines the inner surface of the nuclear envelope and has openings opposite the nuclear pores is described in the central nervous system of the leech.     

Parallel pathways coordinate crawling in the medicinal leech,Hirudo medicinalis

Changes in the behavior of crawling leeches were investigated after various kinds of manipulations, including selective transection or inactivation of body parts, as well as partial or complete transection of the central nerve cord, using a frame-by-frame analysis of video tapes of the crawling animals. From these studies, we found that: 1. Leeches made rhythmic crawling cycles even after their suckers were prevented from contacting the substrate by covering them over with glue. Hence, engagement and disengagement of the suckers are not necessary links in the crawling cycle. 2. Cutting the small, medial connective (Faivre's nerve) had no influence on crawling, but contraction during the whole-body shortening reflex was interrupted. Thus two behaviors which use the same motor output (i.e., whole-body shortening and the contraction phase of crawling) are mediated by two different pathways. 3. Cutting all the connectives between two ganglia in the middle of the leech resulted in a loss of coordination between the parts of the animal on either side of the cut. Therefore, temporally coordinated sucker activity must be mediated through these connectives. 4. Pieces of leech bodies produced by complete transection produced rhythmic crawling cycles as long as the pieces included the head or tail plus 2–4 adjacent midbody segments. In all cases, the crawling movements progressed without delays as the movements reached the cut ends. Pieces of animals that included only midbody segments did not produce crawling movements. 5. These results can be explained by a model composed of intersegmental pathways for both elongation and contraction, circuits in the head and tail brains that switch between elongation and contraction, and both ascending and descending inhibitory influences that determine when the cycle switches from elongation to contraction and back again.Abbreviations C1-C7 caudal segments 1 through 7 (comprise the tail sucker) - Circ. circular muscle(s) - CD circular element driver - CPG central pattern generator - ED elongation element driver - El elongation - El _init initiation of elongation - FN Faivre's nerve - fs + front sucker attachment - s— front sucker release - Long longitudinal muscle(s) - M1-M21 midbody segments 1 through 21 - R1-R4 rostral segments 1 through 4 (comprise the head) - rs + rear sucker attachment - rs rear sucker release - Sens sensory input - SR stretch receptors(s) - ti tonic inhibition     

A kinematic study of crawling behavior in the leech,Hirudo medicinalis

The medicinal leech crawls along a solid substrate by repeated alternating extensions and shortenings of the body. Extension occurs with the posterior sucker attached and the head sucker free. The head sucker then attaches, followed by shortening and release of the tail sucker. The tail sucker is then pulled toward the head, where it reattaches to the substrate. The head sucker then releases, and another crawling cycle begins (Figs. 1, 5). There are two crawling variants: inchworm crawling, in which the head and tail suckers are closely apposed at the end of a cycle and the body forms a loop above the substrate, and vermiform crawling, in which the suckers are placed farther apart and the body remains fairly close to the substrate (Fig. 1). The cycle period and the distance traveled during a cycle are greater in inchworm than in vermiform crawling; however, the velocity of travel is the same for both (Fig. 2). For both variants, the interval between head sucker attachment and tail sucker release is similar at all cycle periods and has a value consistent with direct interneuronal conduction of a signal from head sucker sensory neurons to tail sucker motor neurons. The interval between tail sucker attachment and head sucker release, however, is longer and varies with the cycle period, suggesting a more complex interneuronal circuit in the pathway from tail sucker sensory neurons to head sucker motor neurons (Fig. 4). The onsets of the components of the crawling cycle (extension, post-extension pause, shortening, and post-shortening pause) show an anteroposterior lag (Figs. 5, 7). For both variants, the travel time between segments varies directly with the period (Fig. 8). For both crawl types, the durations of the cycle components vary directly with the period, with several exceptions (Figs. 9, 10). A model is presented that summarizes the coordination of the various motor events in a cycle of leech crawling (Figs. 11 and 12).     

Action of FMRFamide on longitudinal muscle of the leech,Hirudo medicinalis

1. Nerve terminals associated with longitudinal muscle in the leech show FMRFamide-like immunoreactivity. 2. Structure-activity studies using FMRFamide analogs show that the C-terminal RFamide portion of the molecule is crucial for biological activity on leech longitudinal muscle. 3. The putative protease inhibitor FA (Phe-Ala) increases the peak tension produced by longitudinal muscle in response to superfused FMRFamide and the majority of its analogs, suggesting the presence of peripheral proteases capable of degrading RFamide peptides. 4. FMRFamide decreases the relaxation rate of neurally evoked contractions of longitudinal muscle. FA also decreases the relaxation rate of neurally evoked contractions. 5. Intact and isolated muscle cells respond to superfused FMRFamide with a conductance increase, that leads to depolarization and often with a delayed conductance decrease as the membrane potential is restored to resting levels. 6. The depolarizing response of isolated muscle cells to FMRFamide is dependent on external calcium.     

The role of the sexual organs in the generation of postembryonic neurons in the leech Hirudo medicinalis

In adult Hirudo medicinalis, the segmental ganglia (SG) of the fifth and sixth body segments contain a few hundred more cells than the other segmental ganglia of the body (Macagno, 1980). These ganglia innervate the sex organs and are known as the sex SG. As shown here, these cells are stained by neuron-specific antibodies. Cell counts at several developmental stages reveal that the extra cells are added exclusively to the sex SG, and that this addition occurs gradually and almost entirely postembryonically (embryogenesis ends at 30 days of development). Hence, we refer to them as PE cells. Until 16 days of development, deleting the male genitalia or disconnecting them from the sex ganglia results in a complete absence of the PE cells. From 16 days onward, the generation of the PE cells is independent of the male genitalia. No PE cells appear in non-sex SG that innervate male genitalia transplanted to ectopic locations at 10 days or later, indicating that as early as about 10 days of development sex SG are different from other SG in their ability to acquire PE cells. These data suggest that the PE cells are generated within the sex SG, in a process that is triggered by an interaction with the male genitalia and mediated through the innervation of the organs by these ganglia.     

Neural control of somatic muscle function in the earthworm, Allobophora longa, and in the leech, Hirudo medicinalis

Studies have been made on the electrical activity of the segmentary nerves and connectives of the abdominal nervous chain in the earthworm and leech. It was shown that the electrical activity of the isolated piece of the abdominal chain of the leech is manifested of periodic outbursts of impulsation. Presumably this central periodicity accounts for the discharge-like pattern of muscle rhythmic activity which was revealed in our earlier investigations. The electrical activity in the central nervous system of the earthworm depends on afferent influences which pass to the ganglia from the peripheral sensory nervous cells. Stimulation of the abdominal nervous chain did not result in extra discharges of muscle activity, but only affected some of the parameters of the latter.     

Phenology of the medicinal leech, Hirudo medicinalis L., in north-western Turkey

The seasonal occurrence of medicinal leeches was studied at two lakes in the Black Sea coastland of north-western Turkey. The number of leeches attracted by a collector per hour was taken as an indicator for population density. Leeches were most abundant in May/June, and were almost absent during the cold season (November – March). Leeches with a weight of less than 1 g occurred principally between July and October with a peak in July. It is thought that these individuals represent newly hatched leeches. Although both study areas are close to each other, significant differences were found in respect to mean leech size and the seasonal frequency of leeches (both total number and certain age classes). It is suggested that leech biology is greatly dependent on factors such as microclimate and the availability of hosts, and no general conclusions on phenology can be drawn. There is therefore no scientific basis for restricting commercial leech collecting to certain months of the year.     

Molecular characterization and embryonic expression of innexins in the leech Hirudo medicinalis

Gap junctions are direct intercellular channels that permit the passage of ions and small signaling molecules. The temporal and spatial regulation of gap junctional communication is, thus, one mechanism by which cell interactions, and hence cell properties and cell fate, may be regulated during development. The nervous system of the leech, Hirudo medicinalis, is a particularly advantageous system in which to study developmental mechanisms involving gap junctions because interactions between identified cells may be studied in vivo in both the embryo and the adult. As in most invertebrates, gap junctions in the leech are composed of innexin proteins, which are distantly related to the vertebrate pannexins and are encoded by a multi-gene family. We have cloned ten novel leech innexins and describe the expression of these, plus two other previously reported members of this gene family, in the leech embryo between embryonic days 6 and 12, a period during which the main features of the central nervous system are established. Four innexins are expressed in neurons and two in glia, while several innexins are expressed in the excretory, circulatory, and reproductive organs. Of particular interest is Hm-inx6, whose expression appears to be restricted to the characterized S cell and two other neurons putatively identified as presynaptic to this cell. Two other innexins also show highly restricted expressions in neurons and may be developmentally regulated. Electronic Supplementary Material Supplementary material is available for this article at .     

Activity-dependent suppression of spontaneous spike generation in the Retzius neurons of the leech Hirudo medicinalis L.

We report on factors affecting the spontaneous firing pattern of the identified serotonin-containing Retzius neurons of the medicinal leech. Increased firing activity induced by intracellular current injection is followed by a ‘post-stimulus-depression’ (PSD) without spiking for up to 23 s. PSD duration depends both on the duration and the amplitude of the injected current and correlates inversely with the spontaneous spiking activity. In contrast to serotonin-containing neurons in mammals, serotonin release from the Retzius cells presumably does not mediate the observed spike suppression in a self-inhibitory manner since robust PSD persists after synaptic isolation. Moreover, single additional spikes elicited at specific delays after spontaneously occurring action potentials are sufficient to significantly alter the firing pattern. Since sub-threshold current injections do not affect the ongoing spiking pattern and PSD persists in synaptically isolated preparations our data suggest that PSD reflects an endogenous and ‘spike-dependent’ mechanism controlling the spiking activity of Retzius cells in a use-dependent way.     

The structure of a natural population of the medicinal leech, Hirudo medicinalis, at Dungeness, Kent

SUMMARY 1. A hot branding method was used to mark medicinal leeches ( Hirudo medicinalis L.) from five samples (four in 1984, one in 1985) at agravel pit at Dungeness in Kent. Analysis of capture-recapture data by the Fisher-Ford and Jolly methods gave similar results and indicated a population in excess of 10000 (0.112 leeches per m²) in 1984 and 1985. Successive estimates were each higher than the last suggesting a thriving community.
2. The population structure was skewed towards the lower weight classes. This may indicate good recruitment of hatchlings, as also indicated by the presence of cocoons, or the failure to capture heavier satiated or gravid leeches because of their relative unresponsiveness to the sampling method involving water disturbance, or their complete absence from the water during cocoon laying. Gravid leeches were always above 2 g in weight. Recaptured marked leeches revealed that they migrated throughout the site, indicating active foraging for hosts.     

The ganglion-connective junction in the central nervous system of the leech,Hirudo medicinalis

Classical studies of the nervous system of the leech revealed that there were specific types of very large glial cells associated with various parts of the neuron. Recent microelectrode studies demonstrated that there was a low resistance to the flow charge from any one of these large glial cells to another. The present study describes a previously unreported type of glial cell, the glial cell of the fascicles. These cells, which resemble the glial cells of the connectives but are smaller, are found in the fascicles of axons that unite the connectives to the neuropil. Thus, these cells are located between the glial cells of the connectives on the one hand and the glial cells of the neuropil and packets on the other and must be taken into account in considerations of the low resistance to the transfer of charge from one glial cell to another.