Measurement and dissociation of joint influence of action potentials in concurrently active parallel channels on motor neuron activity in crayfish.

1982 ◽  
Vol 47 (6) ◽  
pp. 1160-1173 ◽  
Author(s):  
B G Lindsey
Keyword(s):  
Motor Neuron ◽  
Action Potentials ◽  
Neuron Activity ◽  
Joint Influence ◽  
Parallel Channels

scholarly journals Kinesin Mutations Cause Motor Neuron Disease Phenotypes by Disrupting Fast Axonal Transport in Drosophila

Genetics ◽  
1996 ◽  
Vol 144 (3) ◽  
pp. 1075-1085 ◽  
Author(s):  
Daryl D Hurd ◽  
William M Saxton
Keyword(s):  
Motor Neuron ◽  
Axonal Transport ◽  
Action Potentials ◽  
Light And Electron Microscopy ◽  
Synaptic Membrane ◽  
Slow Axonal Transport ◽  
Fast Axonal Transport ◽  
Motor Neuron Diseases ◽  
Transmitter Secretion ◽  
Axon Terminals

Abstract Previous work has shown that mutation of the gene that encodes the microtubule motor subunit kinesin heavy chain (Khc) in Drosophila inhibits neuronal sodium channel activity, action potentials and neurotransmitter secretion. These physiological defects cause progressive distal paralysis in larvae. To identify the cellular defects that cause these phenotypes, larval nerves were studied by light and electron microscopy. The axons of Khc mutants develop dramatic focal swellings along their lengths. The swellings are packed with fast axonal transport cargoes including vesicles, synaptic membrane proteins, mitochondria and prelysosomal organelles, but not with slow axonal transport cargoes such as cytoskeletal elements. Khc mutations also impair the development of larval motor axon terminals, causing dystrophic morphology and marked reductions in synaptic bouton numbers. These observations suggest that as the concentration of maternally provided wild-type KHC decreases, axonal organelles transported by kinesin periodically stall. This causes organelle jams that disrupt retrograde as well as anterograde fast axonal transport, leading to defective action potentials, dystrophic terminals, reduced transmitter secretion and progressive distal paralysis. These phenotypes parallel the pathologies of some vertebrate motor neuron diseases, including some forms of amyotrophic lateral sclerosis (ALS), and suggest that impaired fast axonal transport is a key element in those diseases.

Aplysia ink release: central locus for selective sensitivity to long-duration stimuli

1979 ◽  
Vol 42 (5) ◽  
pp. 1223-1232 ◽  
Author(s):  
E. Shapiro ◽  
J. Koester ◽  
J. H. Byrne
Keyword(s):  
Motor Neuron ◽  
Spike Train ◽  
Motor Neurons ◽  
Neural Circuit ◽  
Reversal Potential ◽  
Secretory Process ◽  
Neuron Activity ◽  
Long Duration ◽  
Noxious Stimuli ◽  
Selective Sensitivity

1. A behavioral and electrophysiological analysis of defensive ink release in Aplysia californica was performed to examine the response of this behavior and its underlying neural circuit to various-duration noxious stimuli. 2. Three separate behavioral protocols were employed using electrical shocks to the head as noxious stimuli to elicit ink release. Ink release was found to be selectively responsive to longer duration stimuli, and to increase in a steeply graded fashion as duration is increased. 3. Intracellular stimulation of ink motor neurons revealed that ink release is a linear function of motor neuron spike train duration, indicating that the selective sensitivity of the behavior to long-duration stimuli is not due to a nonlinearity in the glandular secretory process. 4. In contrast, electrophysiological examination of ink motor neuron activity in response to sustained head shock revealed an accelerating spike train. During the later part of the spike train, compound excitatory synaptic potentials show a positive shift in reversal potential. 5. Our results suggest a central locus for the mechanisms that determine sensitivity of inking behavior to stimulus duration. 6. In contrast to ink release, defensive gill withdrawal was found to be extremely sensitive to short-duration stimuli.

Spinal Cord Coordination of Hindlimb Movements in the Turtle: Intralimb Temporal Relationships During Scratching and Swimming

1997 ◽  
Vol 78 (3) ◽  
pp. 1394-1403 ◽  
Author(s):  
Edelle C. Field ◽  
Paul S. G. Stein
Keyword(s):  
Spinal Cord ◽  
Motor Neuron ◽  
Activity Patterns ◽  
Angular Position ◽  
Knee Extension ◽  
Neuron Activity ◽  
Spinal Circuitry ◽  
Temporal Relationships ◽  
Kinematic Analyses ◽  
Behavioral Event

Field, Edelle C. and Paul S. G. Stein. Spinal cord coordination of hindlimb movements in the turtle: intralimb temporal relationships during scratching and swimming. J. Neurophysiol. 78: 1394–1403, 1997. Spinal cord neuronal circuits generate motor neuron activity patterns responsible for rhythmic hindlimb behaviors such as scratching and swimming. Kinematic analyses of limb movements generated by this motor neuron output reveal important characteristics of these behaviors. Intralimb kinematics of the turtle hindlimb were characterized during five distinct rhythmic forms of behavior: three forms of scratching and two forms of swimming. In each movement cycle for each form, the angles of the hip and knee joints were measured as well as the timing of a behavioral event, e.g., rub onset in scratching or powerstroke onset in swimming. There were distinct differences between the kinematics of different forms of the same behavior, e.g., rostral scratch versus pocket scratch. In contrast, there were striking similarities between forms of different behaviors, e.g., rostral scratch versus forward swimming. For each form of behavior there was a characteristic angular position of the hip at the onset of each behavioral event (rub or powerstroke). The phase of the onset of knee extension within the hip position cycle occurred while the hip was flexing in the rostral scratch and forward swim and while the hip was extending in the pocket scratch, caudal scratch, and back-paddling form of swimming. The phase of the onset of the behavioral event was not statistically different between rostral scratch and forward swim; nor was it different between pocket scratch and caudal scratch. These observations of similarities at the movement level support the suggestion that further similarities, such as shared spinal circuitry, may be present at the neural circuitry level as well.

scholarly journals Activity-Driven Synaptic and Axonal Degeneration in Canine Motor Neuron Disease

2004 ◽  
Vol 92 (2) ◽  
pp. 1175-1181 ◽  
Author(s):  
Dario I. Carrasco ◽  
Mark M. Rich ◽  
Qingbo Wang ◽  
Timothy C. Cope ◽  
Martin J. Pinter
Keyword(s):  
Motor Neuron ◽  
Motor Neuron Disease ◽  
Motor Unit ◽  
Neuromuscular Junctions ◽  
Muscular Atrophy ◽  
Motor Axon ◽  
Medial Gastrocnemius ◽  
Neuron Activity ◽  
Functional Changes ◽  
Unit Function

The role of neuronal activity in the pathogenesis of neurodegenerative disease is largely unknown. In this study, we examined the effects of increasing motor neuron activity on the pathogenesis of a canine version of inherited motor neuron disease (hereditary canine spinal muscular atrophy). Activity of motor neurons innervating the ankle extensor muscle medial gastrocnemius (MG) was increased by denervating close synergist muscles. In affected animals, 4 wk of synergist denervation accelerated loss of motor-unit function relative to control muscles and decreased motor axon conduction velocities. Slowing of axon conduction was greatest in the most distal portions of motor axons. Morphological analysis of neuromuscular junctions (NMJs) showed that these functional changes were associated with increased loss of intact innervation and with the appearance of significant motor axon and motor terminal sprouting. These effects were not observed in the MG muscles of age-matched, normal animals with synergist denervation for 5 wk. The results indicate that motor neuron action potential activity is a major contributing factor to the loss of motor-unit function and degeneration in inherited canine motor neuron disease.

Slow Temporal Filtering May Largely Explain the Transformation of Stick Insect (Carausius morosus) Extensor Motor Neuron Activity Into Muscle Movement

2007 ◽  
Vol 98 (3) ◽  
pp. 1718-1732 ◽  
Author(s):  
Scott L. Hooper ◽  
Christoph Guschlbauer ◽  
Géraldine von Uckermann ◽  
Ansgar Büschges
Keyword(s):  
Motor Neuron ◽  
Time Constant ◽  
Time Scale ◽  
Stick Insect ◽  
Neuron Activity ◽  
Temporal Filtering ◽  
Time Constants ◽  
Neural Input ◽  
Spike Number ◽  
Contraction And Relaxation

Understanding how nervous systems generate behavior requires understanding how muscles transform neural input into movement. The stick insect extensor tibiae muscle is an excellent system in which to study this issue because extensor motor neuron activity is highly variable during single leg walking and extensor muscles driven with this activity produce highly variable movements. We showed earlier that spike number, not frequency, codes for extensor amplitude during contraction rises, which implies the muscle acts as a slow filter on the time scale of burst interspike intervals (5–10 ms). We examine here muscle response to spiking variation over entire bursts, a time scale of hundreds of milliseconds, and directly measure muscle time constants. Muscle time constants differ during contraction and relaxation, and contraction time constants, although variable, are always extremely slow (200–700 ms). Models using these data show that extremely slow temporal filtering alone can explain much of the observed transform properties. This work also revealed an unexpected (to us) ability of slow filtering to transform steadily declining inputs into constant amplitude outputs. Examination of the effects of time constant variability on model output showed that variation within an SD primarily altered output amplitude, but variation across the entire range also altered contraction shape. These substantial changes suggest that understanding the basis of this variation is central to predicting extensor activity and that the animal could theoretically vary muscle time constant to match extensor response to changing behavioral need.

scholarly journals TRPM8-mediated cutaneous stimulation modulates motor neuron activity during treadmill stepping in mice

2019 ◽  
Vol 69 (6) ◽  
pp. 931-938 ◽  
Author(s):  
Kotaro Tamura ◽  
Satoshi Sugita ◽  
Tadayuki Tokunaga ◽  
Yoshihiko Minegishi ◽  
Noriyasu Ota
Keyword(s):  
Motor Neuron ◽  
Neuron Activity ◽  
Cutaneous Stimulation ◽  
Treadmill Stepping

Dopamine Modulates Two Potassium Currents and Inhibits the Intrinsic Firing Properties of an Identified Motor Neuron in a Central Pattern Generator Network

1999 ◽  
Vol 81 (1) ◽  
pp. 29-38 ◽  
Author(s):  
Peter Kloppenburg ◽  
Robert M. Levini ◽  
Ronald M. Harris-Warrick
Keyword(s):  
Action Potential ◽  
Motor Neuron ◽  
Central Pattern Generator ◽  
Action Potentials ◽  
Potassium Current ◽  
Potassium Currents ◽  
Pattern Generator ◽  
Pyloric Network ◽  
Firing Properties ◽  
Intrinsic Firing

Kloppenburg, Peter, Robert M. Levini, and Ronald M. Harris-Warrick. Dopamine modulates two potassium currents and inhibits the intrinsic firing properties of an identified motor neuron in a central pattern generator network. J. Neurophysiol. 81: 29–38, 1999. The two pyloric dilator (PD) neurons are components [along with the anterior burster (AB) neuron] of the pacemaker group of the pyloric network in the stomatogastric ganglion of the spiny lobster Panulirus interruptus. Dopamine (DA) modifies the motor pattern generated by the pyloric network, in part by exciting or inhibiting different neurons. DA inhibits the PD neuron by hyperpolarizing it and reducing its rate of firing action potentials, which leads to a phase delay of PD relative to the electrically coupled AB and a reduction in the pyloric cycle frequency. In synaptically isolated PD neurons, DA slows the rate of recovery to spike after hyperpolarization. The latency from a hyperpolarizing prestep to the first action potential is increased, and the action potential frequency as well as the total number of action potentials are decreased. When a brief (1 s) puff of DA is applied to a synaptically isolated, voltage-clamped PD neuron, a small voltage-dependent outward current is evoked, accompanied by an increase in membrane conductance. These responses are occluded by the combined presence of the potassium channel blockers 4-aminopyridine and tetraethylammonium. In voltage-clamped PD neurons, DA enhances the maximal conductance of a voltage-sensitive transient potassium current ( I A) and shifts its V act to more negative potentials without affecting its V inact. This enlarges the “window current” between the voltage activation and inactivation curves, increasing the tonically active I A near the resting potential and causing the cell to hyperpolarize. Thus DA's effect is to enhance both the transient and resting K+ currents by modulating the same channels. In addition, DA enhances the amplitude of a calcium-dependent potassium current ( I O(Ca)), but has no effect on a sustained potassium current ( I K( V)). These results suggest that DA hyperpolarizes and phase delays the activity of the PD neurons at least in part by modulating their intrinsic postinhibitory recovery properties. This modulation appears to be mediated in part by an increase of I A and I O(Ca). I A appears to be a common target of DA action in the pyloric network, but it can be enhanced or decreased in different ways by DA in different neurons.

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