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Control of locomotion in marine mollusc — Clione limacina. V. Photoinactivation of efferent neurons (1985)

Arshavsky, Yu. I. ; Orlovsky, G. N. ; Panchin, Yu. V.

Springer

Experimental brain research 59 (1985), S. 203-205

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Pedal ganglia ; Locomotion ; Lucifer yellow

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary Efferent neurons in isolated pedal ganglia of the pteropodial mollusc Clione limacina were filled with Lucifer Yellow through the wing nerves. Then the ganglia were illuminated with intense blue light which resulted in the complete inactivation of these neurons. After inactivation of efferent neurons, interneurons of the pedal ganglia continued to generate the locomotor rhythm.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00237680

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Vestibular control of swimming in lamprey (1992)

Orlovsky, G. N. ; Deliagina, T. G. ; Wallén, P.

Springer

Experimental brain research 90 (1992), S. 479-488

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ISSN: 1432-1106

Keywords: Reticulospinal neurons ; Vestibular reactions ; Locomotion ; Lamprey

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary A method has been developed for recording the response of single neurons in the lamprey brainstem in vitro to natural stimulation of vestibular receptors. The brainstem dissected together with the intact vestibular apparatus could be rotated in space, in two perpendicular planes (transverse, the roll tilt, and sagittal, the pitch tilt), in one of them up to 360°, and in the other one up to ± 30°. The responses of single reticulospinal (RS) neurons, in all four reticular nuclei of the brainstem, to roll and pitch were recorded extracellularly and, with small inclinations (up to ±45°) also intracellularly. Two types of preparations were used, with and without the rostral part of the spinal cord. In the brainstem preparations, most RS neurons responded both to a definite brain orientation in space and to a change of the orientation (static and dynamic reactions). Responses to roll tilt were similar in all reticular nuclei: all cells were excited with roll tilt towards the contralateral side, this reaction was qualitatively preserved when the roll was performed in combination with different pitch inclinations. Responses to pitch tilt were less clearcut; some neurons were activated with noseup deflection while others responded to nose-down tilt. In preparations including the spinal cord, responses of RS neurons to roll and pitch tilt differed from those in the isolated brainstem in that they were much less specific and sfable. Roll and pitch tilts could trigger the spinal locomotor CPG, which, by sending “efference copy” signals back to the brainstem, produced modulation of RS neurons in relation to the locomotor rhythm.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00230930

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Control of locomotion in marine mollusc Clione limacina IV. Role of type 12 interneurons (1985)

Arshavsky, Yu. I. ; Beloozerova, I. N. ; Orlovsky, G. N. ; [et al.]

Springer

Experimental brain research 58 (1985), S. 285-293

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Pedal ganglia ; Locomotion ; Central pattern generator ; Plateau potentials

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1. Type 12 interneurons in pedal ganglia of Clione limacina exerted a strong influence upon the locomotor generator during “intense” swimming. These neurons generated “plateau” potentials, i.e. their membrane potential had two stable states: the “upper” one when a neuron was depolarized, and the “down” one, separated by 30–40 mV. The interneurons could remain in each state for a long time. Short depolarizing and hyperpolarizing current pulses, as well as excitatory and inhibitory postsynaptic potentials, could transfer the interneurons from one state to another. 2. When the pedal ganglia generated the locomotory rhythm, type 12 neurons received an EPSP and passed to the “upper” state in the V2-phase of a locomotor cycle. They remained at this state until the beginning of the D1-phase when they received an IPSP and passed to the “down” state. The EPSP in type 12 neurons was produced by type 8d neurons, and the IPSP by type 7 neurons. 3. Type 12 neurons exerted inhibitory influences upon many neurons active in the V1 and V2 phases, and excitatory influences upon the D-phase interneurons (type 7). 4. The functional role of type 12 neurons was to limit the activity of neurons discharging in the V-phase of a locomotory cycle. In addition, they enhanced the excitation of the D-phase neurons and promoted, thus, the transition from the V-phase to the D-phase.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235310

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Control of locomotion in marine mollusc Clione limacina (1989)

Arshavsky, Yu. I. ; Orlovsky, G. N. ; Panchin, Yu. V. ; [et al.]

Springer

Experimental brain research 78 (1989), S. 398-406

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ISSN: 1432-1106

Keywords: Pteropod mollusc ; Locomotion ; Central pattern generator ; Interneurons ; Plateau potential

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary In previous work carried out on the isolated pedal ganglia of the pteropod mollusc Clione limacina we described the activity of a neuronal element (type 12 neuron) and looked into its role in the locomotor rhythm generation (Arshavasky et al. 1985d). As we learned subsequently, the activity was recorded from the neuron axon passing in the pedal ganglia, while the neuron soma was located in the pleural ganglia and consequently was cut off in the course of pedal ganglia isolation. It thus became necessary to reinvestigate the properties of this neuron and its role in locomotory rhythm generation by using less reduced preparation of the central nervous system. The following results were obtained. (1) Each pleural ganglion contains only one neuron of this type, this cell is thus to be considered as the identified neuron. The neuron's axon reaches into the pedal ganglion via the pleuro-pedal connective. Then the axon divides into two branches terminating in the lateral regions of both pedal ganglia. The neurons 12 from the left and right pleural ganglia have no direct connections with one another; their synchronous operation in the locomotor cycle is determined by common inputs. (2) The electrical properties of an intact neuron 12 and one without a soma are about the same. In either case the neuron generates “plateau” potentials, i.e., it may persist for a long time in the depolarized state. Plateau potentials can be induced by a depolarizing current pulse or by an EPSP, and terminated by hyperpolarizing current or by an IPSP. The neuron input resistance drops about twofold during generation of the plateau potential. (3) Recording of the neuron 12 in the pleural ganglia showed that its activity during “fictive swimming” does not differ from that of somadeprived axon recorded in the isolated pedal ganglia. The neuron generates a plateau potential in the V-phase of the locomotor cycle (definitions for the phases of the cycle were given in Arshavsky et al. 1985b). This potential is triggered by an EPSP evoked by subgroup 8d pedal neurons. The plateau potential terminates in the D-phase under the influence of an IPSP evoked by group 7 neurons. The effects of the neuron 12 on other neuronal elements of the locomotor generator in pedal ganglia do not depend on the presence of the cell soma either. (4) The pedal ganglia locomotor generator sometimes generates an “anomalous rhythm” when normal cycles alternate with reduced ones in which the activity of some groups of neurons is inhibited. Simultaneous recording from two neurons 12 demonstrated that the alternating rhythm generation was caused by the anomalous behaviour of one of the neurons 12: the neuron persisted in the depolarized state for one cycle and a half and not for half a cycle, as during the normal operation of the locomotor generator.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00228912

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Vestibular control of swimming in lamprey (1992)

Deliagina, T. G. ; Orlovsky, G. N. ; Grillner, S. ; [et al.]

Springer

Experimental brain research 90 (1992), S. 489-498

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ISSN: 1432-1106

Keywords: Reticulospinal neurons ; Vestibular reactions ; Space orientation ; Locomotion ; Lamprey

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1. Experiments were carried out on an in vitro preparation of the lamprey brainstem isolated together with intact labyrinths. Responses of reticulospinal neurons from different brainstem reticular nuclei (mesencephalic, MRN; anterior rhombencephalic, ARRN; middle rhombencephalic, MRRN; and posterior rhombencephalic, PRRN) to rotation of the preparation (0°–360°) either in the sagittal plane (pitch tilt, or nose up-down movement) or in the transverse plane (roll tilt, or left-right inclination) were recorded. 2. Responses to roll tilt were qualitatively similar in all nuclei: contralateral side down tilt (in relation to the location of the neuron in the brain) caused an activation of reticulospinal neurons. The angular thresholds for activation differed, however, between nuclei as well as the angle at which the maximal activity occurred. The maximal response for MRN was at 45°, for MRRN and PRRN at 90°, for ARRN at 180°. Thus, the zones of spatial sensitivity differed in different nuclei, and they covered the whole range of possible inclinations in the transverse plane. 3. Responses to pitch tilt were not uniform in the different nuclei. MRN neurons responded preferentially in the range of 45°–90° nose-up inclinations, but a proportion of the cells responded in the range of 45°–90° nose-down inclinations. The ARRN neurons had their maximal response when the brain was turned to a dorsal side-down position (180°). In the MRRN, three subgroups of neurons could be distinguished, the first responding at around 90° nose-down, the second responding at around 90° nose-up and the third responding in both zones. However, the activation in the nose-up zone was less robust: responses in this zone were present only in approximately one half of the experiments. Finally, the PRRN neurons were found to be very heterogeneous, with their zones of sensitivity being distributed throughout the whole space (0°–360°). Thus, also in the sagittal plane, the zones of spatial sensitivity in the different nuclei covered the whole range of possible inclinations. 4. Long-term recording of MRRN neurons having the zone of sensitivity around 90° nose-up showed that this response was rather unstable. Its amplitude varied considerably and could disappear with time to reappear later. These results, together with the fact that in a part of the experiments the MRRN neurons responded only in the 90° nose-down zone (see above), leads us to suggest that the system of spatial orientation can dynamically re-organize. This would allow the animal to stabilize not only a horizontal orientation during swimming but also an orientation at different angles in relation to the horizontal.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00230931

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Control of locomotion in marine mollusc Clione limacina I. Efferent activity during actual and fictitious swimming (1985)

Arshavsky, Yu. I. ; Beloozerova, I. N. ; Orlovsky, G. N. ; [et al.]

Springer

Experimental brain research 58 (1985), S. 255-262

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Locomotion ; Pedal ganglion ; Central pattern generator ; Identified neurons ; Serotonin

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1.The marine mollusc Clione limacina swims by making rhythmic movements (with a frequency of 1–5 Hz) of its two wings. Filming demonstrated that the wings perform oscillatory movements in the frontal plane of the animal. During both the upward and downward movements of the wing, its posterior edge lagged behind the anterior one, i.e. the wing plane was inclined in relation to the longitudinal axis of an animal. As a result of this inclination, the wing oscillations in the frontal plane produce a force directed forwards. 2.In restrained animals with the body cavity opened (a whole-animal preparation), the wing position, electrical activity in the wing nerve and activity of two identified efferent neurons (1A and 2A) were recorded during locomotory wing movements. There were two bursts of activity in the wing nerve during the locomotory cycle, the first one corresponding to the excitation of efferent neurons controlling the wing elevation, and the second one, to the excitation of efferent neurons controlling the lowering of the wing. Neurons 1A and 2A fired reciprocally at the beginning of the phase of elevating and lowering the wing, respectively. During excitation of one of the neurons, an IPSP appeared in its antagonist. 3. A pair of isolated pedal ganglia of Clione was capable of generating the locomotory rhythm (“fictitious swimming”). In fictitious swimming, as in actual swimming, there were two bursts of activity in the wing nerve per locomotory cycle, and the 1A and 2A neurons fired reciprocally. Homologous neurons from the left and right ganglia fired inphase. A single pedal ganglion was also capable of generating the locomotory rhythm. 4.Serotonin (10-5–10-6 M) increased the locomotor activity both in the whole-animal preparation and in the isolated pedal ganglia.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235307

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Control of locomotion in marine mollusc Clione limacina II. Rhythmic neurons of pedal ganglia (1985)

Arshavsky, Yu. I. ; Beloozerova, I. N. ; Orlovsky, G. N. ; [et al.]

Springer

Experimental brain research 58 (1985), S. 263-272

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Locomotion ; Pedal ganglion ; Interneurons ; Efferent neurons

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1.Activity from neurons in isolated pedal ganglia of Clione limacina was recorded intracellularly during generation of rhythmic swimming. To map the distribution of cells in a ganglion, one of two microelectrodes was used to monitor activity of the identified neuron (1A or 2A), while the second electrode was used to penetrate successively all the visible neurons within a definite area of the ganglion. In addition, pairs of neurons of various types were recorded in different combinations with each other. Intracellular staining of neurons was also performed. 2.Each ganglion contained about 400 neurons, of which about 60 neurons exhibited rhythmic activity related to a swim cycle. These rhythmic neurons were divided into 9 groups (types) according to axonal projections, electrical properties and the phase of activity in a swim cycle. Three types of interneurons and six types of efferent neurons were distinguished. 3.Type 7 and 8 interneurons generated only one spike of long (50–150 ms) duration per swim cycle. Type 7 interneurons discharged in the phase of the cycle that corresponded (in actual swimming) to the dorsal movement of wings (D-phase). Type 8 interneurons discharged in the opposite phase corresponding to the ventral movement of wings (V-phase). With excitation of type 7 interneurons, an IPSP appeared in the type 8 interneurons, and vice versa. Neuropilar branching of these neurons was observed in the ipsilateral ganglion. In addition, they sent an axon to the contralateral ganglion across the pedal commissure. 4.Efferent neurons (i.e. the cell sending axons into the wing nerve) generated spikes of 1–5 ms duration. Type 1 and 3 neurons were excited in the D-phase of a swim cycle and were inhibited in the V-phase. Type 2 and 4 neurons were excited in the V-phase and inhibited in the D-phase. Type 10 neurons received only an excitatory input in the V-phase, while type 6 neurons received only an inhibitory input in the D-phase. 5. Type 12 interneurons were non-spiking cells, they generated a stable depolarization (“plateau”) throughout most of the V-phase. 6. Neurons of the same type from one ganglion (except for type 6) were electrically coupled to each other. There were also electrical connections between most neurons firing in the same phase of the cycle, i.e. between types 3 and 7, as well as between types 2, 4 and 8. Type 7 interneurons from the left and right ganglia were electrically coupled, the same was true for type 8 interneurons.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235308

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Control of locomotion in marine mollusc Clione limacina III. On the origin of locomotory rhythm (1985)

Arshavsky, Yu. I. ; Beloozerova, I. N. ; Orlovsky, G. N. ; [et al.]

Springer

Experimental brain research 58 (1985), S. 273-284

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Pedal ganglia ; Locomotion ; Central pattern generator ; Neuron polarization ; Tetrodotoxin ; Cobalt

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary 1. Neurons from the isolated pedal ganglia of the marine mollusc Clione limacina were recorded from intracellularly during generation of the locomotory rhythm. Polarization of single type 7 or type 8 interneurons (which discharge in the D-and V-phases of a swim cycle, respectively) strongly affected activity of the rhythm generator. Injection of depolarizing and hyperpolarizing current usually resulted in shortening and lengthening of a swim cycle, respectively. A short pulse of hyperpolarizing current shifted the phase of the rhythmic generator. The same effect could be evoked by polarization of efferent neurons of types 2, 3 and 4 which are electrically coupled to interneurons. On the contrary, polarization of types 1, 6 and 10 efferent neurons, having no electrical connections with interneurons, did not affect the locomotory rhythm. 2. A number of observations indicate that type 7 and 8 interneurons constitute the main source of postsynaptic potentials that were observed in all the “rhythmic” neurons of the pedal ganglia. Type 7 interneurons excited the D-phase neurons and inhibited the V-phase neurons; type 8 interneurons produced opposite effects. 3. Tetrodotoxin eliminated spike generation in all efferent neurons of the pedal ganglia, while in interneurons spike generation persisted. After blocking the spike discharges in all the efferent neurons, type 7 and 8 interneurons were capable of generating alternating activity. One may conclude that these interneurons determine the main features of the swim pattern, i.e., the rhythmic alternating activity of two (D and V) populations of neurons. 4. Both type 7 and type 8 interneurons were capable of endogenous rhythmic discharges with a period like that in normal swimming. This was demonstrated in experiments in which one of the two populations of “rhythmic” neurons (D or V) was inhibited by means of strong electrical hyperpolarization, as well as in experiments in which interaction between the two populations, mediated by chemical synapses, was blocked by Co2+ ions. 5. Type 7 and 8 interneurons were capable of “rebound”, i.e. they had a tendency to discharge after termination of inhibition. 6. V-phase neurons exerted not only inhibitory but also excitatory action upon D-phase neurons, the excitatory action being longer than the inhibitory one. 7. The main experimental findings correspond well to the model of rhythm generator consisting of two half centres possessing endogenous rhythmic activity. The half-centres exert strong, short duration inhibitory and weak long duration excitatory actions upon one another. The behaviour of such a model is considered and compared with that of the locomotor generator of Clione.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235309

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Control of locomotion in marine mollusc Clione limacina (1986)

Arshavsky, Yu. I. ; Deliagina, T. G. ; Orlovsky, G. N. ; [et al.]

Springer

Experimental brain research 63 (1986), S. 106-112

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ISSN: 1432-1106

Keywords: Pteropodial mollusc ; Pedal ganglia ; Locomotion ; Interneurons and efferent neurons ; Endogenous activity ; Isolated cells

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Summary In the pteropodial mollusc Clione limacina, the rhythmic locomotor wing movements are controlled by the pedal ganglia. The locomotor rhythm is generated by two groups of interneurons (groups 7 and 8) which drive efferent neurons. In the present paper, the activity of isolated neurons, which were extracted from the pedal ganglia by means of an intracellular electrode, is described. The following results have been obtained: 1. Isolated type 7 and 8 interneurons preserved the capability for generation of prolonged (100–200 ms) action potentials. The frequency of these spontaneous discharges was usually within the limit of locomotor frequencies (0.5–5 Hz). By de- or hyperpolarizing a cell, one could usually cover the whole range of locomotor frequencies. This finding demonstrates that the locomotor rhythm is indeed determined by the endogenous rhythmic activity of type 7 and 8 interneurons. 2. Type 1 and 2 efferent neurons, before isolation, could generate single spikes as well as high-frequency bursts of spikes. These two modes of activity were also observed after isolating the cells. Thus, the bursting activity of type 1 and 2 neurons, demonstrated during locomotion, is determined by their own properties. Type 3 and 4 efferent neurons generated only repeated single spikes both before and after isolation. 3. The activity of the isolated axons of type 1 and 2 neurons did not differ meaningfully from the activity of the whole cells. Furthermore, in the isolated pedal commissure, we found units whose activity (rhythmically repeating prolonged action potentials) resembled the activity of type 7 and 8 interneurons. These units seemed to be the axons of type 7 and 8 interneurons. Thus, different parts of the cell membrane (soma and axons) have similar electric properties.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00235652

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Control of locomotion in the marine mollusc Clione limacina (1996)

Panchin, Y. V. ; Arshavsky, Y. I. ; Deliagina, T. G. ; [et al.]

Springer

Experimental brain research 109 (1996), S. 361-365

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ISSN: 1432-1106

Keywords: Locomotion ; Central pattern generator ; Serotonin ; Modulation ; Pteropod mollusc

Source: Springer Online Journal Archives 1860-2000

Topics: Medicine

Notes: Abstract The locomotor activity in the marine mollusc Clione limacina has been found to be strongly excited by serotonergic mechanisms. In the present study putative serotonergic cerebropedal neurons were recorded simultaneously with pedal locomotor motoneurons and interneurons. Stimulation of serotonergic neurons produced acceleration of the locomotor rhythm and strengthening of motoneuron discharges. These effects were accompanied by depolarization of motoneurons, while depolarization of the generator interneurons was considerably lower (if it occurred at all). Effects of serotonin application on isolated locomotor and non-locomotor pedal neurons were studied. Serotonin (5×10-7 to 1×10-6 M) affected most pedal neurons. All locomotor neurons were excited by serotonin. This suggests that serotonergic command neurons exert direct influence on locomotor neurons. Effects of serotonin on nonlocomotor neurons were diverse, most neurons being inhibited by serotonin. Some effects of serotonin on locomotor neurons could not be reproduced by neuron depolarization. This suggests that, along with depolarization, serotonin modulates voltage-sensitive membrane properties of the neurons. As a result, serotonin promotes the endogenous rhythmical activity in neurons of the C. limacina locomotor central pattern generator.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00231794

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