The role of motor neuron intrinsic properties in leech heartbeat fictive motor pattern generation

The cercal system of crickets detects low-frequency air currents produced by approaching predators and self-generated air currents during singing, which may provide sensory feedback to the singing motor network. We analyzed the effect of cercal stimulation on singing motor pattern generation to reveal the response of a singing interneuron to predator-like signals and to elucidate the possible role of self-generated air currents during singing. In fictive singing males, we recorded an interneuron of the singing network while applying air currents to the cerci; additionally, we analyzed the effect of abolishing the cercal system in freely singing males. In fictively singing crickets, the effect of short air stimuli is either to terminate prematurely or to lengthen the interchirp interval, depending on their phase in the chirp cycle. Within our stimulation paradigm, air stimuli of different velocities and durations always elicited an inhibitory postsynaptic potential in the singing interneuron. Current injection in the singing interneuron elicited singing motor activity, even during the air current-evoked inhibitory input from the cercal pathway. The disruptive effects of air stimuli on the fictive singing pattern and the inhibitory response of the singing interneuron point toward the cercal system being involved in initiating avoidance responses in singing crickets, according to the established role of cerci in a predator escape pathway. After abolishing the activity of the cercal system, the timing of natural singing activity was not significantly altered. Our study provides no evidence that self-generated cercal sensory activity has a feedback function for singing motor pattern generation.

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The role of sensory inputs in insect flight motor pattern generation

Trends in Neurosciences ◽

10.1016/0166-2236(82)90164-3 ◽

1982 ◽

Vol 5 ◽

pp. 257-258 ◽

Cited By ~ 11

Author(s):

Jennifer Altman

Keyword(s):

Insect Flight ◽

Motor Pattern ◽

Pattern Generation ◽

Sensory Inputs ◽

Flight Motor ◽

Motor Pattern Generation

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The role of neuronal excitation and inhibition in the pre-Bötzinger complex on the cough reflex in the cat

Journal of Neurophysiology ◽

10.1152/jn.00108.2021 ◽

2021 ◽

Author(s):

Tabitha Y Shen ◽

Ivan Poliacek ◽

Melanie J. Rose ◽

Matthew Nicholas Musselwhite ◽

Zuzana Kotmanova ◽

...

Keyword(s):

Blood Pressure ◽

Respiratory Rate ◽

Receptor Antagonist ◽

Gabaa Receptor ◽

Motor Pattern ◽

Pattern Generation ◽

Neuronal Excitation ◽

Bötzinger Complex ◽

Motor Pattern Generation

Brainstem respiratory neuronal network significantly contributes to cough motor pattern generation. Neuronal populations in the pre-Bötzinger complex (PreBötC) represent a substantial component for respiratory rhythmogenesis. We studied the role of PreBötC neuronal excitation and inhibition on mechanically induced tracheobronchial cough in 15 spontaneously breathing, pentobarbital anesthetized adult cats (35 mg/kg i.v. initially). Neuronal excitation by unilateral microinjection of glutamate analog D,L-homocysteic acid resulted in mild reduction of cough abdominal electromyogram (EMG) amplitudes and very limited temporal changes of cough compared to effects on breathing (very high respiratory rate, high amplitude inspiratory bursts with a short inspiratory phase and tonic inspiratory motor component). Mean arterial blood pressure temporarily decreased. Blocking glutamate related neuronal excitation by bilateral microinjections of non-specific glutamate receptor antagonist kynurenic acid reduced cough inspiratory and expiratory EMG amplitude and shortened most cough temporal characteristics similarly to breathing temporal characteristics. Respiratory rate decreased and blood pressure temporarily increased. Limiting active neuronal inhibition by unilateral and bilateral microinjections of GABAA receptor antagonist gabazine resulted in lower cough number, reduced expiratory cough efforts, and prolongation of cough temporal features and breathing phases (with lower respiratory rate). The PreBötC is important for cough motor pattern generation. Excitatory glutamatergic neurotransmission in the PreBötC is involved in control of cough intensity and patterning. GABAA receptor related inhibition in the PreBötC strongly affects breathing and coughing phase durations in the same manner, as well as cough expiratory efforts. In conclusion, differences in effects on cough and breathing are consistent with separate control of these behaviors.

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Contribution of motoneuron intrinsic properties to fictive motor pattern generation

Journal of Neurophysiology ◽

10.1152/jn.00101.2011 ◽

2011 ◽

Vol 106 (2) ◽

pp. 538-553 ◽

Cited By ~ 17

Author(s):

Terrence M. Wright ◽

Ronald L. Calabrese

Keyword(s):

Canonical Ensemble ◽

Motor Pattern ◽

Electrical Coupling ◽

Living System ◽

Input Pattern ◽

Pattern Generation ◽

Intrinsic Properties ◽

Minimal Set ◽

Motor Patterns ◽

Motor Pattern Generation

Previously, we reported a canonical ensemble model of the heart motoneurons that underlie heartbeat in the medicinal leech. The model motoneurons contained a minimal set of electrical intrinsic properties and received a synaptic input pattern based on measurements performed in the living system. Although the model captured the synchronous and peristaltic motor patterns observed in the living system, it did not match quantitatively the motor output observed. Because the model motoneurons had minimal intrinsic electrical properties, the mismatch between model and living system suggests a role for additional intrinsic properties in generating the motor pattern. We used the dynamic clamp to test this hypothesis. We introduced the same segmental input pattern used in the model to motoneurons isolated pharmacologically from their endogenous input in the living system. We show that, although the segmental input pattern determines the segmental phasing differences observed in motoneurons, the intrinsic properties of the motoneurons play an important role in determining their phasing, particularly when receiving the synchronous input pattern. We then used trapezoidal input waveforms to show that the intrinsic properties present in the living system promote phase advances compared with our model motoneurons. Electrical coupling between heart motoneurons also plays a role in shaping motoneuron output by synchronizing the activity of the motoneurons within a segment. These experiments provide a direct assessment of how motoneuron intrinsic properties interact with their premotor pattern of synaptic drive to produce rhythmic output.

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Principles of rhythmic motor pattern generation

Physiological Reviews ◽

10.1152/physrev.1996.76.3.687 ◽

1996 ◽

Vol 76 (3) ◽

pp. 687-717 ◽

Cited By ~ 765

Author(s):

E. Marder ◽

R. L. Calabrese

Keyword(s):

Motor Pattern ◽

Pattern Generation ◽

Rhythmic Movements ◽

Motor Patterns ◽

Nervous Systems ◽

Cellular Processes ◽

Rhythmic Motor ◽

Computational Analyses ◽

Motor Pattern Generation ◽

Rhythmic Motor Pattern

Rhythmic movements are produced by central pattern-generating networks whose output is shaped by sensory and neuromodulatory inputs to allow the animal to adapt its movements to changing needs. This review discusses cellular, circuit, and computational analyses of the mechanisms underlying the generation of rhythmic movements in both invertebrate and vertebrate nervous systems. Attention is paid to exploring the mechanisms by which synaptic and cellular processes interact to play specific roles in shaping motor patterns and, consequently, movement.

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