Termination of leech swimming activity by a previously identified swim trigger neuron B. A. O'Gara W. O. Friesen Original Paper DOI :
10.1007/BF00207191
Cite this article as: O'Gara, B.A. & Friesen, W.O. J Comp Physiol A (1995) 177: 627. doi:10.1007/BF00207191 Abstract Cell Tr2 is a neuron in the subesophageal ganglion of the leech that can trigger swim episodes. In this report, we describe the ability of Tr2 to terminate ongoing swim episodes as well as to trigger swimming. Stimulation of Tr2 terminated ongoing swim episodes in nearly every preparation tested, while Tr2 stimulation triggered swim episodes in only a minority of the preparations. We suggest that the primary role of Tr2 is in the termination rather than the initiation of swimming activity.
The swim trigger neuron Tr3 and a swim-gating neuron, cell 21, hyperpolarized during Tr2-induced swim termination. Another swim-gating neuron, cell 204 was sometimes slightly excited, but more often, hyperpolarized during Tr2-induced swim termination. In contrast to these cells, Tr2 stimulation excited another swim-gating neuron, cell 61. The responses of the swimgating cells were variable in amplitude and sometimes not evident during Tr2-induced swim termination. Hence, the effects of Tr2 stimulation on swim-gating neurons seem unlikely to be the direct cause of swim termination.
Oscillator cells examined during Tr2-induced swim termination include: 27, 28, 33, 60, 115, and 208. The largest effect seen in an oscillator neuron was in cell 208, which was repolarized by up to 10 mV during Tr2 stimulation. Tr2 stimulation did not produce any obvious synaptic effects in motor neurons DI-1, VI-1, and DE-3. Our findings indicate that other, yet undiscovered, connections are likely to be important in Tr2-induced swim termination. Therefore, we propose that cell Tr2 is probably a member of a distributed neural network involved in swim termination.
Key words Hirudo medicinalis Locomotion Oscillator Inhibition Central pattern generator Abbreviations DP dorsal posterior nerve
Mx midbody ganglion x
Rx neuromere x of the subsesophageal (rostral) ganglion
DE dorsal excitatory motor neuron
DI dorsal inhibitory motor neuron
VI ventral inhibitory motor neuron
References Arshavsky YI, Deliagina TG, Orlovsky GN, Panchin YV, Popova LB (1992) Interneurones mediating the escape reaction of the marine mollusc
Clione limacina . J Exp Biol 164: 307–314
Google Scholar Brodfuehrer PD (1986) Control of swimming activity in the medicinal leech by the head brain. Doctoral dissertation, University of Virginia
Brodfuehrer PD, Burns A (1995) Neuronal factors influencing the decision to swim in the medicinal leech. Neurobiol Learn Mem 63: 192–199
Google Scholar Brodfuehrer PD, Friesen WO (1986a) Initiation of swimming activity by trigger neurons in the leech subesophageal ganglion. I. Output connections of Tr1 and Tr2. J Comp Physiol A 159: 489–502
Google Scholar Brodfuehrer PD, Friesen WO (1986b) Initiation of swimming activity by trigger neurons in the leech subesophageal ganglion. II. Role of segmental swim-initiating interneurons. J Comp Physiol A 159: 503–510
Google Scholar Brodfuehrer PD, Friesen WO (1986c) Initiation of swimming activity by trigger neurons in the leech subesophageal ganglion. III. Sensory inputs to Tr1 and Tr2. J Comp Physiol A 159: 511–519
Google Scholar Brodfuehrer PD, Friesen WO (1986d) Control of leech swimming activity by the cephalic ganglia. J Neurobiol 17: 697–705
Google Scholar Brodfuehrer PD, Friesen WO (1986e) From stimulation to undulation: a neuronal pathway for the control of swimming in the leech. Science 234: 1002–1004
Google Scholar Brodfuehrer PD, Kogelnik, AM, Friesen WO, Cohen AV (1993) Effect of the tail ganglion on swimming activity in the leech. Behav Neural Biol 59: 162–166
Google Scholar Cazalets JR, Cournil I, Geffard M, Moulins M (1987) Suppression of oscillatory activity in crustacean pyloric neurons: implication of GABAergic inputs. J Neurosci 7: 2884–2893
Google Scholar Cazalets JR, Sqalli-Houssaini Y, Clarac F (1994) GABAergic inactivation of the central pattern generators for locomotion in isolated neonatal rat spinal cord. J Physiol Lond 474: 173–181
Google Scholar Friesen WO (1989a) Neuronal control of leech swimming movements. In: Jacklet JW (ed) Neuronal and cellular oscillators. Dekker New York Basel, pp 269–316
Google Scholar Friesen WO (1989b) Neuronal control of leech swimming movements. I. Inhibitory interactions between motor neurons. J Comp Physiol A 166: 195–203
Google Scholar Friesen WO (1989c) Neuronal control of leech swimming movements. II. Motor neuron feedback to oscillator cells 115 and 28. J Comp Physiol A 166: 205–215
Google Scholar Friesen WO, Brodfuehrer PD (1984) Identification of neurones in the leech through local ionic manipulations. J Exp Biol 113: 455–460
Google Scholar Glover JC, Kramer AP (1982) Serotonin analog selectively ablates identified neurons in the leech embryo. Science 216: 317–319
Google Scholar Kien J (1983) The initiation and maintenance of walking in the locust: an alternative to the command concept. Proc R Soc Lond B 219: 137–174
Google Scholar Kovac MP, Davis WS, Matera EM, Croll RP (1983) Organization of synaptic inputs to paracerebral feeding command interneurons of
Pleurobranchaea californica . I. Excitatory inputs. J Neurophysiol 49: 1517–1538
Google Scholar Kristan WB Jr, Nusbaum MP (1983) The dual role of serotonin in leech swimming. J Physiol (Paris) 78: 743–747
Google Scholar Kristan WB Jr, Ort CA, Stent GS (1974) Neuronal control of swimming in the medicinal leech. I. Dynamics of the swimming rhythm. J Comp Physiol 94: 97–119
Google Scholar Marsden CA, Kerkut GA (1969) Fluorescent microscopy of the 5HT- and catecholamine-containing cells in the central nervous system of the leech
Hirudo medicinalis . Comp Biochem Physiol 31: 851–862
Google Scholar McClellan AD (1983) Higher order neurons in the cerebral ganglia of
Pleurobranchaea have diverse effects on buccal motor patterns. J Comp Physiol 153: 533–541
Google Scholar McClellan AD (1988) Brainstem command systems for locomotion in the lamprey: localization of descending pathways in the spinal cord. Brain Res 457: 338–349
Google Scholar Moore D, Larimer JL (1987) Neural control of a cyclic postural behaviour in the crayfish,
Procambarus clarkii : the pattern-initiating interneurons. J Comp Physiol A 160: 169–179
Google Scholar Nemes Z, Dietz R, Luth JB, Gomba S, Hackenthal E, Gross F (1979) The pharmacological relevance of vital staining with neutral red. Experientia 35: 1475–1476
Google Scholar Nusbaum MP (1986) Synaptic basis of swim initiation in the leech, III. Synaptic effects of serotonin-containing interneurones (cells 21 and 61) on swim CPG neurons (cells 18 and 208). J Exp Biol 122: 303–321
Google Scholar Nusbaum MP, Kristanan B Jr (1986) Swim initiation in the leech by serotonin-containing interneurones, cells 21 and 61. J Exp Biol 122: 277–302
Google Scholar Nusbaum MP, Friesen WO, Kristan WB Jr, Pearce RA (1987) Neural mechanisms generating the leech swimming rhythm: swim-initiator neurons excite the network of swim oscillator neurons. J Comp Physiol A 161: 355–366
Google Scholar O'Gara BA, Friesen WO (1987) Termination of swimming activity by stimulation of a neuron in the subesophageal ganglion of the leech,
Hirudo medicinalis . Soc Neurosci Abstr 13: 1060
Google Scholar O'Gara BA, Chae H, Latham LB, Friesen WO (1991) Modification of leech behavior patterns by reserpine-induced amine depletion. J Neurosci 11: 96–110
Google Scholar Ramirez JM (1988) Interneurons in the suboesophageal ganglion of the locust associated with flight initiation. J Comp Physiol A 162: 669–685
Google Scholar Stein PGS (1978) Motor systems, with specific reference to control of locomotion. Annu Rev Neurosci 1: 61–81
Google Scholar Weeks JC (1981) Neuronal basis of leech swimming: separation of swim initiation, pattern generation, and intersegmental coordination by selective lesions. J Neurophysiol 45: 698–723
PubMed Google Scholar Weeks JC (1982a) Synaptic basis of swim initiation in the leech. I. Connections of a swim-initiating neuron (cell 204) with motor neurons and pattern-generating ‘oscillator’ neurons. J Comp Physiol 148: 253–263
Google Scholar Weeks JC (1982b) Synaptic basis of swim initiation in the leech. II. A pattern-generating neuron (cell 208) which mediates motor effects of swim-initiating neurons. J Comp Physiol 148: 265–279
Google Scholar Weeks JC (1982c) Segmental specialization of a leech swim-initiating interneuron, cell 205. J Neurosci 2: 972–985
Google Scholar Weeks JC, Kristan WB Jr (1978) Initiation, maintenance and modulation of swimming in the medicinal leech by the activity of a single neurone. J Exp Biol 77: 71–88
Google Scholar Willard AL (1981) Effects of serotonin on the generation of the motor program for swimming by the medicinal leech. J Neurosci 1: 936–944
PubMed Google Scholar Authors and Affiliations B. A. O'Gara W. O. Friesen 1. Department of Biological Sciences Barnard College of Columbia University New York USA 2. Department of Biology University of Virginia Charlottesville USA 3. NSF Center for Biological Timing, University of Virginia Charlottesville USA