Neural Generation of the Peristaltic and Non-Peristaltic Heartbeat Coordination Modes in the Leech, Hirudo Medicinalis

The bilateral paired heart tubes of the leech Hirudo medicinalisare controlled, via excitatory synapses, by a set of bilaterallypaired segmental heart motor neurons (HE cells) which are inturn controlled, via inhibitory synapses, by a set of bilaterallypaired segmental heart interneurons (HN cells). The HE cellsproduce rhythmic impulse bursts because their inherent steadydischarge is periodically inhibited by the HN cells, most ofwhich produce impulse bursts endogenously. The known synapticinteractions among the HN cells and HE cells can account wellfor the observed behavior of the hearts. The HE cells are coordinatedby the HN cells such that the segmental heart tube sectionson one side constrict in a caudorostral sequence (peristalsis),while the segmental heart tube sections on the other side constrictnearly synchronously (non-peristalsis). This difference in thecoordination modes of the two hearts is not permanent; reciprocalcoordination mode transitions occur every 10–50 heartbeatcycles. Only one member of HN(5) cell pair (the HN cells ofthe fifth segmental ganglion) is rhythmically active at a time,the other being completely inactive. By coordinating the frontand rear HN cells the active HN(5) cell produces non-peristalsisipsilaterally and peristalsis contralaterally. Reciprocal changesin the activity-inactivity pattern of the HN(5) cell pair areresponsible for the reciprocal changes in the coordination mode.     

Rhythmic swimming activity in neurones of the isolated nerve cord of the leech.

1. Repeating bursts of motor neurone impulses have been recorded from the nerves of completely isolated nerve cords of the medicinal leech. The salient features of this burst rhythm are similar to those obtained in the semi-intact preparation during swimming. Hence the basic swimming rhythm is generated by a central oscillator. 2. Quantitative comparisons between the impulse patterns obtained from the isolated nerve cord and those obtained from a semi-intact preparation show that the variation in both dorsal to ventral motor neurone phasing and burst duration with swim cycle period differ in these two preparations. 3. The increase of intersegmental delay with period, which is a prominent feature of swimming behaviour of the intact animal, is not seen in either the semi-intact or isolated cord preparations. 4. In the semi-intact preparation, stretching the body wall or depolarizing an inhibitory motor neurone changes the burst duration of excitatory motor neurones in the same segment. In the isolated nerve cord, these manipulations also change the period of the swim cycle in the entire cord. 5. These comparisons suggest that sensory input stabilizes the centrally generated swimming rhythm, determines the phasing of the bursts of impulses from dorsal and ventral motor neurones, and matches the intersegmental delay to the cycle period so as to maintain a constant body shape at all rates of swimming.     

Neuronal control of swimming in the medicinal leech

Summary The cell bodies and function of twelve neurons whose impulse pattern is clearly related to that of the swimming rhythm were identified in the segmental ganglion of the leech. These include excitatory and inhibitory motor neurons of the dorsal and ventral longitudinal muscles and the excitatory flattener motor neuron of the dorsoventral muscles. During swimming the membrane potential of these cells oscillates between a depolarized and a hyperpolarized phase. The activity of this ensemble of cells is sufficient to account for the contractile rhythm of the swimming animal. The following connections were found between these motor neurons. Electrotonic junctions link: (1) bilaterally homologous cells; (2) excitors of the dorsal longitudinal muscles; (3) excitors of the ventral longitudinal muscles; (4) inhibitors of both dorsal and ventral longitudinal muscles. The dorsal inhibitors project via an inhibitory pathway to the dorsal excitors, and the ventral inhibitor projects via an inhibitory pathway to the ventral excitors. The membrane potential oscillation of the excitors is at least partly attributable to the phasic inhibitory synaptic input which they receive from the inhibitors. The excitatory shortener motor neuron of the entire longitudinal musculature is maintained in an inactive state during swimming. This control is achieved by rectifying electrotonic junctions linking this neuron to the dorsal and ventral excitors. These junctions allow passage of only depolarizing current from the shortener to the dorsal and ventral excitors and of only hyperpolarizing current in the reverse direction. Furthermore, both dorsal and ventral inhibitors project via inhibitory pathways to the shortener neuron.We are greatly indebted to Ann Stuart for advice and help in this study, and for communicating to us some unpublished findings. We thank Elizabeth Mullenbach for excellent technical assistance.This research was supported by grant GB 31933 X from the National Science Foundation, and by Public Health Service Research grant GM 17866 and Training Grant GM 01389 from the Institute for General Medical Sciences.     

Sprouting and connectivity of embryonic leech heart excitor (HE) motor neurons in the absence of their peripheral target

The rhythmic pumping of the hearts in the medicinal leech,Hirudo medicinalis, is neurogenic and mediated by a defined circuit involving identified interneurons in a central pattern generator (CPG) and segmentally iterated motor neurons that drive the heart muscle. During early embryogenesis, presumptive heart excitor (HE) motor neurons extend many axon branches into the body wall; they later innervate the heart while retracting the supernumerary peripheral axons, and only much later in development receive synaptic input from the central pattern generator (Jellies, Kopp and Bledsoe (1992)J. Exp. Biol., 170, 71–92.)- In this study, HE motor neurons were deprived of an early interaction with the heart by surgical ablation of a circumscribed portion of body wall including the heart primordium. Anatomical and electrophysiological data were obtained using intracellular techniques to examine the hypothesis that peripheral interactions with the developing heart provide instructive cues for the final differentiation of these neurons. Target-deprived HE motor neurons continued to extend multiple axons in ventral, lateral and dorsal body wall throughout late embryonic and into postembryonic stages and they extended anomalous axons within the CNS. This resembles the early embryonic growth of HE motor neurons before heart tube differentiation. Furthermore, HE motor neurons deprived of heart contact exhibited tonic activity similar to the situation during early development before they are contacted by the CPG interneurons. In contrast, sham-operated and contralateral HE motor neurons oscillated normally. These results suggest that heart tube contact is specifically required for at least some aspects of HE development and provide a framework in which to identify cell-cell interactions that are involved in matching neurons and targets to generate behaviorally relevant neural circuits.     

Photosensory input pathways in the medicinal leech

Summary The medicinal leech,Hirudo medicinalis possesses two types of photosensory organs: five bilateral pairs of eyes embedded in two longitudinal rows in the dorsal surface of the head, and seven bilateral pairs of sensilla situated in both the dorsal and the ventral surface of each of the 21 body segments. The photoreceptor cells of each eye or sensillum project their axons centrally via a characteristic cephalic or segmental nerve which carries the photosensory input to the brain or to the segmental ganglion. In response to a pulse of light the photoreceptors produce a train of impulses whose frequency first rises to anearly peak and then declines to asteady state plateau at which it remains until the end of the pulse. The amplitude of the early peak response and the level of the steady state plateau rise linearly with the log of the light pulse intensity, but the dynamic range of the early peak response is much narrower than that of the plateau. Both ocular and sensillar photoreceptors adapt to the intensity of interpulse background illumination; the ocular receptors adapt so completely that their level of background activity is nearly independent of the background light intensity, whereas the ventral sensillar photoreceptors adapt incompletely, so that their background activity rises with the background light intensity. Ocular and sensillar photoreceptors make their maximal response to green light at a wavelength of about 540 nm. They are almost insensitive to red and violet light at both extremes of the visible spectrum. The photosensory response of a single eye is directionally selective, whereas that of a single sensillum has much less directional selectivity. Several higher order sensory neurons were identified in the segmental ganglion that receive photosensory input from the sensilla. One of these neurons has the sensillum in the ipsilateral dorso-medial body wall of the same segment as its receptive field and another neuron the bilateral set of ventral sensilla in the body wall of the next posterior segment.We are indebted to Frank S. Werblin for valuable advice and discussions. We thank Kenneth L. Carlock for designing and constructing much of the special electronic equipment used in this study. We also thank Alexander Petruncola for his helpful suggestions regarding the computational analysis of the experimental results and for writing the computer programs used in the processing of the data.This research was supported by Grant No. GB 31933X from the National Science Foundation, and NIH research grant No. GM 17866 and Training Grant No. GM 00829 from the Institute for General Medical Sciences.     

Flexibility in the patterning and control of axial locomotor networks in lamprey

In lower vertebrates, locomotor burst generators for axial muscles generally produce unitary bursts that alternate between the two sides of the body. In lamprey, a lower vertebrate, locomotor activity in the axial ventral roots of the isolated spinal cord can exhibit flexibility in the timings of bursts to dorsally-located myotomal muscle fibers versus ventrally-located myotomal muscle fibers. These episodes of decreased synchrony can occur spontaneously, especially in the rostral spinal cord where the propagating body waves of swimming originate. Application of serotonin, an endogenous spinal neurotransmitter known to presynaptically inhibit excitatory synapses in lamprey, can promote decreased synchrony of dorsal-ventral bursting. These observations suggest the possible existence of dorsal and ventral locomotor networks with modifiable coupling strength between them. Intracellular recordings of motoneurons during locomotor activity provide some support for this model. Pairs of motoneurons innervating myotomal muscle fibers of similar ipsilateral dorsoventral location tend to have higher correlations of fast synaptic activity during fictive locomotion than do pairs of motoneurons innervating myotomes of different ipsilateral dorsoventral locations, suggesting their control by different populations of premotor interneurons. Further, these different motoneuron pools receive different patterns of excitatory and inhibitory inputs from individual reticulospinal neurons, conveyed in part by different sets of premotor interneurons. Perhaps, then, the locomotor network of the lamprey is not simply a unitary burst generator on each side of the spinal cord that activates all ipsilateral body muscles simultaneously. Instead, the burst generator on each side may comprise at least two coupled burst generators, one controlling motoneurons innervating dorsal body muscles and one controlling motoneurons innervating ventral body muscles. The coupling strength between these two ipsilateral burst generators may be modifiable and weakening when greater swimming maneuverability is required. Variable coupling of intrasegmental burst generators in the lamprey may be a precursor to the variable coupling of burst generators observed in the control of locomotion in the joints of limbed vertebrates.     

Mechanical aspects of heartbeat reversal in pupae of Manduca sexta

Pulsations of the dorsal vessel were investigated with new optocardiographic techniques based on the transmission and reflection of pulse-light through optic fibers. This noninvasive technique enabled simultaneous, in vivo multisensor recordings of the heartbeat without touching the pupal integument. There was a very regular heartbeat reversal with 3 distinctive phases: (a) a backward-oriented (retrograde) cardiac pulsation; (b) a forward-oriented (anterograde) pulsation with faster frequency; and (c) shorter or longer periods of temporary cardiac standstill that usually occurred after the termination of the anterograde phase. Occasionally, there were localized series of systolic cardiac contractions during the retrograde phase. Simultaneous recordings from the base and the tail of the abdomen revealed a reciprocal, "mirror image-like", quantitative relationship. The most intensive anterograde hemolymph flow occurred at the base while the most intensive retrograde flow occurred at the tail of the abdomen. The bi-directional switchovers of heartbeat (reversal) were occasionally associated with modifications during each of the unidirectional cardiac phases. Anterograde peristalsis showed a 2-fold higher frequency of pulsation in the thoracic aorta in comparison with the posterior parts of the heart. Thus, in addition to the "odd" peristaltic waves originating at the tail, there were intercallated "even" peristaltic waves originating in the middle of the abdomen. Both of them propagated hemolymph through the thoracic aorta into the head; the first waves took the hemolymph in from the distal end, while the second sucked it from the middle of the abdomen. The use of multiple optocardiographic sensors also enabled detection of cardiac pulsations on the opposite, ventral side of the body, within the ventral perineural sinus. The ventral side of the head showed only the presence of an anterograde pulse, whereas the ventral side of the tail exhibited a strong reciprocal retrograde phase and a very weak anterograde phase. These results explain why the existence of a periodic heartbeat reversal should be essential for circulatory functions at both extremities of the cylindrical insect body. In diapausing pupae, regular cycles of heartbeat reversal were substituted by prolonged periods of anterograde pulsation during the entire duration of bursts of CO2 release (average duration of the burst was 18-20 min, periodicity 5 to 18 h). The physiological nature of such feed-back correlation between heartbeat and metabolic CO2 production is not yet clear, because the anterograde heartbeat could be also induced by a number of nonspecific factors unrelated to CO2 (mechanical irritation, injury, injections, elevated temperature). During the postdiapause, developing pharate-adult stage, the correlation between CO2 and anterograde heartbeat completely disappeared. It has been concluded that regulation of insect heartbeat represents a highly coordinated, myogenic stereotype with inherent rhythmicity, which can be modified by a number of external and internal factors.     

Afferent connections to the fast conduction pathway in the central nervous system of the leech Hirudo medicinalis

A burst of all-or-none action potentials, identical in size and shape, can be recorded from the ventral cord of H. medicinalis following both photic and mechanical stimulation of the skin. This response propagates both anteriorly and posteriorly from its point of origin at the same conduction velocity of about 1.3 m/sec. The action potential elicited by electrical stimulation of the cord collides by refractoriness with the action potentials elicited in response to photic and mechanical stimulation. The cord response to photic and mechanical stimulation is reversibly suppressed by perfusion with high Mg++ solutions, whereas the afferent discharges recorded from the segmental nerves remain unaffected. Lesion experiments show that the cord responses to mechanical and photic stimuli, travel along the median connective (Faivre's nerve). It is concluded that afferent impulses originating from mechanoreceptors and photoreceptors converge with chemical excitatory synapses onto a fast conducting pathway in the ventral cord. This fast conducting pathway is coextensive with the one which is excited by electrical stimulation of the ventral cord (1, 3).     

Chaetae and mechanical function: tools no Metazoan class should be without

To address the functional contributions of capillary chaetae in the maldanid polychaete Clymenella torquata, we compared irrigation efficiency and tube structure for animals with intact and trimmed capillary chaetae. We measured pumping rates for worms before and after they were anaesthetized and subjected either to capillary trimming or mock trimming, i.e. handling without trimming. Worms with trimmed chaetae were significantly less effective at moving water through their tubes than those with intact chaetae. There were no significant differences in the ability of control worms to move water within their tubes. No significant changes in rates of peristalsis were observed among experimental or control groups. These data strongly suggest that body musculature and capillary chaetae work in concert to hold worms in position within tubes during peristaltic pumping. When chaetae are shortened, the body musculature must contract to a greater degree, increasing the functional diameter of the worm to achieve the necessary traction with the tube wall, resulting in less efficient irrigation. We also compared the inner diameters of original field tubes to tubes built by control worms or worms after capillary trimming. The inner diameters of new tubes built by worms with shortened chaetae were larger than their original tubes, while those of both control groups were not. One possible explanation is that the chaetae have a sensory role and shortened chaetae send the false message that the nascent tube walls are farther away than they are, the body contracts in compensation and the tube is widened, however this idea has not been tested.     

Development of spinal cord bioelectric activity in spinal chick embryos and its behavioral implications

Embryonic behavior of the chick is the product of spontaneous multiunit burst discharges within the ventral spinal cord. The present study describes the ontogeny of spinal cord burst discharges in embryos which were deprived of brain input by removing several neural tube segments of 2-day embryos at cervical or mid-thoracic levels. Characteristics of bioelectric activity present in both intact and chronically transected cords are: (a) the appearance of spike discharges; (b) the organization of unit discharges into synchronized multiunit bursts; (c) the establishment of intracord synchronization of burst discharges over wide expanses of cord tissue; (d) an increase in burst duration and complexity at 7 days due to the appearance of the burst afterdischarge; (e) an increase in the amount of burst activity from 6 to 13 days followed by a decline until hatching at 21 days; (f) a shift from periodic to irregular patterns of burst activity at 13 days; and (g) the existence of the cord burst discharge as a correlate of embryonic movement. Several differences were found between burst activity from chronic spinal and intact embryos: (a) cervical spinal embryos were significantly less active than controls from 15 through 19 days; and (b) long sequences of unusual repetitive burst afterdischarges appeared in chronic spinal embryos by 13 days. The results indicate that the transected embryonic spinal cord is remarkably autogenous in function, although patterns of activity unique to the transected cord appear and increase in prominence during later stages of incubation.     

Finite Element Study of the Mechanical Response in Spinal Cord during the Thoracolumbar Burst Fracture

Background

The mechanical response of the spinal cord during burst fracture was seldom quantitatively addressed and only few studies look into the internal strain of the white and grey matters within the spinal cord during thoracolumbar burst fracture (TLBF). The aim of the study is to investigate the mechanical response of the spinal cord during TLBF and correlate the percent canal compromise (PCC) with the strain in the spinal cord.

Methodology/Principal Findings

A three-dimensional (3D) finite element (FE) model of human T12-L1 spinal cord with visco-elastic property was generated based on the transverse sections images of spinal cord, and the model was validated against published literatures under static uniaxial tension and compression. With the validated model, a TLBF simulation was performed to compute the mechanical strain in the spinal cord with the PCC. Linear regressions between PCC and strain in the spinal cord show that at the initial stage, with the PCC at 20%, and 45%, the corresponding mechanical strains in ventral grey, dorsal grey, ventral white, dorsal white matters were 0.06, 0.04, 0.12, 0.06, and increased to 0.14, 0.12, 0.23, and 0.13, respectively. At the recoiled stage, when the PCC was decreased from 45% to 20%, the corresponding strains were reduced to 0.03, 0.02, 0.04 and 0.03. The strain was correlated well with PCC.

Conclusions/Significance

The simulation shows that the strain in the spinal cord correlated well with the PCC, and the mechanical strains in the ventral regions are higher than those in the dorsal regions of spinal cord tissue during burst fracture, suggesting that the ventral regions of the spinal cord may susceptible to injury than the dorsal regions.     

Peptidergic control of the heart of the stick insect, Baculum extradentatum

The dorsal vessel of the Vietnamese stick insect, Baculum extradentatum, consists of a tubular heart and an aorta that extends anteriorly into the head. Alary muscles, associated with the heart, are anchored to the body wall with attachments to the dorsal diaphragm. Alary muscle contraction draws haemolymph into the heart through incurrent ostia. Excurrent ostia lie on the dorsal vessel in the last thoracic and in each of the first two abdominal segments. Muscle fibers are associated with these excurrent ostia. Crustacean cardioactive peptide (CCAP)- and proctolin-like immunoreactivity is present in axons of the segmental nerves that project to the dorsal vessel, and in processes extending over the heart and alary muscles. Proctolin-like immunoreactive processes are also localized to the valves of the incurrent ostia and to the excurrent ostia. Neither the link nerve neurons, nor the lateral cardiac neurons, stain positively for these peptides. Physiological assays reveal dose-dependent increases in heart beat frequency in response to CCAP and proctolin. Isolating the dorsal vessel from the ventral nerve cord led to a change in the pattern of heart contractions, from a tonic, stable heart beat, to one which was phasic. The tonic nature was restored by the application of CCAP.     

The central nervous system, its cellular organisation and development, in the tadpole larva of the ascidian Ciona intestinalis

From its numerical composition, the central nervous system (CNS) of the ascidian larva is one of the simplest known nervous systems having a chordate plan. Fewer than 350 cells together constitute a caudal nerve cord, an interposed visceral ganglion containing motor circuits for swimming and, rostrally, an expanded sensory vesicle containing major sensory and interneuron regions of the CNS. Some cells are ependymal, with ciliated surfaces lining the neural canal, while others are clearly either sensory receptors or motoneurons, but most are distinguishable only on cytological grounds. Although reassignments between categories are still being made, there is evidence for determinancy of total cell number. We have made three-dimensional cell maps either from serial semithin sections, or from confocal image stacks of whole-mounted embryos and larvae stained with nuclear markers. Comparisons between the maps of neural tubes in embryos of successive ages, that is, between cells in one map and their progeny in older maps, enable us to follow the line of mitotic descent through successive maps, at least for the caudal neural tube. Details are clear for the lateral cell rows in the neural tube, at least until the latter contains approximately 320 cells, and somewhat for the dorsal cell row, but the ventral row is more complex. In the hatched larva, serial-EM reconstructions of the visceral ganglion reveal two ventrolateral fibre bundles at the caudalmost end, each of 10-12 axons. These tracts include at least five pairs of presumed motor axons running into the caudal nerve cord. Two pairs of axons decussate. Complementing this vertebrate feature in the CNS of the larval form of Ciona, we confirm that synapses form upon the somata and dendrites of its neurons, and that its motor tracts are ventral.     

Embryonic and postembryonic neurogenesis in the ventral nerve cord of the freshwater crayfish Cherax destructor.

Previous studies of neurogenic activity in the thoracic neuromeres of indirect developing crustaceans indicated that the temporal patterns of neurogenesis can be correlated with the appearance of the thoracic appendages during larval and metamorphic development. To test further the idea that the temporal patterns of neurogenesis in crustaceans are related to their life histories, we examined neurogenesis in the ventral nerve cord of a direct developing crustacean, the freshwater crayfish Cherax destructor, whose life history contains neither larval stages nor metamorphoses. Neurogenesis was examined using the in vivo incorporation of bromodeoxyuridine into DNA. During late embryonic development the thoracic neuromeres of the crayfish contain arrays of mitotically active neuroblasts similar to those previously described in the spider crab and lobster. The arrays in the crayfish abdomen are, however, greatly reduced compared with those of the thorax. On hatching, both the thoracic and abdominal appendages of C. destructor are capable of movement. The pleopods, however, do not beat rhythmically until the second postembryonic stage whereas the pereiopods are not used in coordinated walking movements until the third stage. An examination of the time course of neurogenesis in the ventral nerve cord revealed that neurogenic activity in each neuromere ceases during or before the moult to the developmental stage in which its segmental appendage is first used in coordinated movements. These findings indicate that the patterns of neurogenesis in crustaceans are indeed related to the maturation of the segmental appendages and, in particular, to the maturation of motor behaviours.     

Pharmacology of ureter.

Ureter which performs the important function of transport of urine from kidney to the bladder is not a passive tube, but exhibits characteristic spontaneous (peristaltic) activity. This peristaltic activity is characterized by coordinated muscular contractions, which after originating from a spontaneously active primary pacemaker, situated in the vicinity of the pelvi ureteric junction, propagate downwards along the entire length of the ureter. In addition, the ureter, like the heart, possesses certain cells which become activated when the primary pacemaker is suppressed or there is an interruption of conduction, thereby, acting as latent pacemakers. (1) The peristaltic activity of the ureter is modified by several pharmacologically active substances. Moreover, some of these substances are occasionally able to initiate spontaneous activity even in quiescent ureters. This article briefly reviews the effects of catecholamines (adrenaline, noradrenaline and isoprenaline) and acetylcholine on the ureters of human beings and some domestic and laboratory animals.     

Pattern of body-wall muscle differentiation during embryonic development of Enchytraeus coronatus (Annelida: Oligochaeta; Enchytraeidae)

The plesiomorphic arrangement of body-wall musculature within the annelids is still under discussion. While polychaete groups show a great variety of patterns in their somatic muscles, the musculature of soil-living oligochaetes was thought to represent the characteristic pattern in annelids. Oligochaete body-wall muscles consist of an outer continuous layer of circular and an inner continuous layer of longitudinal muscles, forming a closed tube. Since designs of adult body musculature are influenced by evolutionary changes, additional patterns found during embryogenesis can give further information about possible plesiomorphic features. In oligochaetes, detailed cell-lineage analyses document the origin of the mesoderm and consequently the muscles, but later processes of muscle formation remain unclear. In the present work, body-wall muscle differentiation was monitored during embryogenesis of thesoil-living oligochaete Enchytraeus coronatus (Annelida) by phalloidin staining. Primary circular muscles form in a discrete anterior-to-posterior segmental pattern, whereas emerging longitudinal muscles are restricted to one ventral and one dorsal pair of primary strands, which continuously elongate towards posterior. These primary muscles establish an initial muscle-template. Secondary circular and longitudinal muscles subsequently differentiate in the previous spaces later in development. The prominent ventral primary longitudinal muscle strands on both sides eventually meet at the ventral midline due to neurulation, which moves the ventral nerve cord into a coelomic position, closing the muscle layers into a complete tube. This early embryonic pattern in E. coronatus resembles the adult body-wall muscle arrangements in several polychaete groups as well as muscle differentiation during embryonic development of the polychaete Capitella sp. I.     

Blockade of the central generator of locomotor rhythm by noncompetitive NMDA receptor antagonists in Drosophila larvae

The noncompetitive antagonists of the vertebrate N-methyl-D-aspartate (NMDA) receptor dizocilpine (MK 801) and phencyclidine (PCP), delivered in food, were found to induce a marked and reversible inhibition of locomotor activity in Drosophila melanogaster larvae. To determine the site of action of these antagonists, we used an in vitro preparation of the Drosophila third-instar larva, preserving the central nervous system and segmental nerves with their connections to muscle fibers of the body wall. Intracellular recordings were made from ventral muscle fibers 6 and 7 in the abdominal segments. In most larvae, long-lasting (>1 h) spontaneous rhythmic motor activities were recorded in the absence of pharmacological activation. After sectioning of the connections between the brain and abdominal ganglia, the rhythm disappeared, but it could be partially restored by perfusing the muscarinic agonist oxotremorine, indicating that the activity was generated in the ventral nerve cord. MK 801 and PCP rapidly and efficiently inhibited the locomotor rhythm in a dose-dependent manner, the rhythm being totally blocked in 2 min with doses over 0.1 mg/mL. In contrast, more hydrophilic competitive NMDA antagonists had no effect on the motor rhythm in this preparation. MK 801 did not affect neuromuscular glutamatergic transmission at similar doses, as demonstrated by monitoring the responses elicited by electrical stimulation of the motor nerve or pressure applied glutamate. The presence of oxotremorine did not prevent the blocking effect of MK 801. These results show that MK 801 and PCP specifically inhibit centrally generated rhythmic activity in Drosophila, and suggest a possible role for NMDA-like receptors in locomotor rhythm control in the insect CNS.     

Behavioral plasticity and central regeneration of locomotor reflexes in the freshwater oligochaete, Lumbriculus variegatus. I: Transection studies

Abstract. Access to the ventral nerve cord in living specimens of Lumbriculus variegatus , an aquatic oligochaete, is normally impossible because surgical invasion induces segmental autotomy (self-fragmentation). We show here that nicotine is a powerful paralytic agent that reversibly immobilizes worms, blocks segmental autotomy, and allows experimental access to the nerve cord. Using nicotine-treated worms, we transected the ventral nerve cord and used non-invasive electrophysiological recordings and behavioral analyses to characterize the functional recovery of giant nerve fibers and other reflex pathways. Initially, after transection, medial giant fiber (MGF) and lateral giant fiber (LGF) spikes conducted up to, but not across, the transection site. Reestablishment of MGF and LGF through-conduction across the transection site occurred as early as 10 h (usually by 20 h) after transection. Analyses of non-giant-mediated behavioral responses (i.e., helical swimming and body reversal) were also made following nerve cord transection. Immediately after transection, functional reorganization of touch-evoked locomotor reflexes occurred, so that the two portions of the worm anterior and posterior to the transection site were independently capable of helical swimming and body reversal responses. Similar reorganization of responses occurred in amputated body fragments. Reversion back to the original whole-body pattern of swimming and reversal occurred as early as 8 h after transection. Thus, functional restoration of the non-giant central pathways appeared slightly faster than giant fiber pathways. The results demonstrate the remarkable plasticity of locomotor reflex behaviors immediately after nerve cord transection or segment amputation. They also demonstrate the exceptional speed and specificity of regeneration of the central pathways that mediate locomotor reflexes.     

Commissure formation in the embryonic CNS of Drosophila.

In the ventral nerve cord of Drosophila most axons are organized in a simple, ladder-like pattern. Two segmental commissures connect the hemisegments along the mediolateral and two longitudinal connectives connect individual neuromeres along the anterior-posterior axis. Cells located at the midline of the developing CNS first guide commissural growth cones toward and across the midline. In later stages, midline glial cells are required to separate anterior and posterior commissures into distinct axon bundles. To unravel the genes underlying the formation of axon pattern in the embryonic ventral nerve cord, we conducted a saturating ethylmethane sulfonate mutagenesis, screening for mutations which disrupt this process. Subsequent genetic and phenotypic analyses support a sequential model of axon pattern formation in the embryonic ventral nerve cord. Specification of midline cell lineages is brought about by the action of segment polarity genes. Five genes are necessary for the establishment of the commissures. In addition to commissureless, the netrin genes, and the netrin receptor encoded by the frazzled gene, two gene functions are required for the initial formation of commissural tracts. Over 20 genes appear to be required for correct development of the midline glial cells which are necessary for the formation of distinct segmental commissures.