Transducer properties of the rapidly adapting stretch receptor neurone in the crayfish (Pacifastacus leniusculus).

Rydqvist, B.; Puralı, Nuhan

doi:10.1113/jphysiol.1993.sp019811

Cited by 28 publications

(25 citation statements)

References 23 publications

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“…Primary transduction of receptor neurons is generally believed to be linked to the opening of ionic channels (Edwards, 1983). It has been shown in abdominal stretch receptors in crayfish that the stretch-activated channel has low cation selectivity, including sodium, potassium, calcium and magnesium (Nakajima and Onodera, 1969a,b;Brown et al, 1978;Erxleben, 1989;Rydqvist and Purali, 1993). Our data showed that the tension-induced responses of the CG neuron were in the hyperpolarizing direction (Figs 5-7), and the responses became more apparent when the CG neuron was depolarized (Fig.…”

Section: Membrane Potential Response Of the Cg Neurons To Tension Ofsupporting

confidence: 54%

Tension sensitivity of the heart pacemaker neurons in the isopod crustaceanLigia pallasii

Sakurai

Wilkens

2003

Journal of Experimental Biology

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SUMMARYIn the crustacean neurogenic heart, the cardiac ganglion (CG) acts as a peripherally located central pattern generator (CPG) by producing rhythmic motor output that initiates the heartbeat. In the isopod Ligia, the CG consists of six electrically coupled neurons that all function both as endogenous oscillators and as glutamatergic motoneurons innervating heart muscle. In the present study, we present several lines of evidence to suggest that the CG neurons are sensitive to passive stretch and active tension of the heart muscle. Stretching the heart wall caused a sustained decrease in the burst frequency of the CG neuron. Releasing from the stretch caused a rebound increase in burst frequency above the control rate. A brief stretch (200-300 ms duration) caused either phase advance or phase delay of the following CG bursts, depending on the timing at which the stretch was applied. Repeated brief stretches could entrain the CG bursts to either higher or lower frequencies than the free-run burst frequency. Intracellular recording from one of the CG neurons revealed that it exhibited hyperpolarization during the stretch. The stretch-induced hyperpolarization was followed by a burst discharge upon release from the stretch. With increased stretch amplitude, the amplitude of hyperpolarizing response increased and the timing of the following burst was advanced. When the myogenic activity of the heart muscle was pharmacologically isolated from the ganglionic drive by applying a glutamatergic antagonist, Joro spider toxin (JSTX), the spontaneous muscle contraction caused a hyperpolarizing deflection in the CG neuron. Under specific conditions made by JSTX and tetrodotoxin, the CG burst became entrained to the myogenic rhythm. These results suggest that the Ligia CG neurons have tension sensitivity in addition to their pacemaker and motoneuronal functions. Such multifunctional neurons may form a single neuron reflex arc inside the heart.

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Section: Membrane Potential Response Of the Cg Neurons To Tension Ofsupporting

confidence: 54%

Tension sensitivity of the heart pacemaker neurons in the isopod crustaceanLigia pallasii

Sakurai

Wilkens

2003

Journal of Experimental Biology

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“…Changes in dendritic membrane potential would spread passively along the dendritic tree to the axon hillock. For a sub-threshold stimulation, the event could be observed by inserting a microelectrode into the cell soma [18]. However, a suprathreshold stimulation evokes action potentials which could propagate in both directions.…”

Section: Discussionmentioning

confidence: 99%

Antidromic potential spread modulates the receptor responses in the stretch receptor neurons of the crayfish

Puralı

2011

Pflugers Arch - Eur J Physiol

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The effects of antidromic potential spread were investigated in the stretch receptor neurons of the crayfish. Current and potential responses to conductance changes were recorded in the dynamic clamp condition and compared to those obtained by using some conventional clamp methods and a compartmental neuron model. An analogue circuit was used for dynamic calculation of the injected receptor current as a function of the membrane potential and the given conductance change. Alternatively, receptor current responses to a mechanical stimulus were recorded and compared when the cell was voltage clamped to a previously recorded impulse wave form and the resting potential, respectively. Under dynamic clamp, the receptor current had an oscillating waveform which contrasts with the conventional recordings. Frequency, amplitude and sign of the oscillations were dependent on the applied conductance level, reversal potential and electrotonic attenuation. Mean current amplitude and frequency of the evoked impulse responses were smaller under dynamic clamp, especially for large conductance increases. However, firing frequency was larger if plotted against the mean current response. Recorded responses were similar to those calculated in the model. It was not possible to evoke any adaptation in the slowly adapting neuron by using the dynamic clamp. Evoked potential change served as a self limiting response, preventing the depolarization block. However, impulse duration was significantly shorter in the rapidly adapting neuron when the dynamic clamp was used. It was concluded that, in the stretch receptor neurons during a conductance increase, antidromic potential spread modulates the receptor responses and contributes to adaptation.

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“…The remaining factor contributing to the adaptation of MRO firing rate, and the differences in their time course of adaptation, was therefore attributed to unidentified intrinsic membrane properties affecting action potential encoding. Stimulation of the crayfish RA MRO mechanically, or directly by intracellular current injection, showed that the duration and time course of action potential firing was essentially independent of the mode of stimulation (Rydqvist and Purali 1993). Similarly, the differences in adaptation of spider slit-sense organ afferents can be partially explained by differences in the dynamics of mechanotransduction from mechanical stimulus to receptor potential.…”

Section: Prior Work On Mechanoreceptor Adaptationmentioning

confidence: 96%

Activity-Dependent Sensitivity of Proprioceptive Sensory Neurons in the Stick Insect Femoral Chordotonal Organ

DiCaprio

Wolf

Büschges

2002

Journal of Neurophysiology

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schges. Activitydependent sensitivity of proprioceptive sensory neurons in the stick insect femoral chordotonal organ. J Neurophysiol 88: 2387-2398, 2002; 10.1152/jn.00339.2002. Mechanosensory neurons exhibit a wide range of dynamic changes in response, including rapid and slow adaptation. In addition to mechanical factors, electrical processes may also contribute to sensory adaptation. We have investigated adaptation of afferent neurons in the stick insect femoral chordotonal organ (fCO). The fCO contains sensory neurons that respond to position, velocity, and acceleration of the tibia. We describe the influence of random mechanical stimulation of the fCO on the response of fCO afferent neurons. The activity of individual sensory neurons was recorded intracellularly from their axons in the main leg nerve. Most fCO afferents (93%) exhibited a marked decrease in response to trapezoidal stimuli following sustained white noise stimulation (bandwidth ϭ 60 Hz, amplitudes from Ϯ5 to Ϯ30°). Concurrent decreases in the synaptic drive to leg motoneurons and interneurons were also observed. Electrical stimulation of spike activity in individual fCO afferents in the absence of mechanical stimulation also led to a dramatic decrease in response in 15 of 19 afferents tested. This indicated that electrical processes are involved in the regulation of the generator potential or encoding of action potentials and partially responsible for the decreased response of the afferents. Replacing Ca 2ϩ with Ba 2ϩ in the saline surrounding the fCO greatly reduced or blocked the decrease in response elicited by electrically induced activity or mechanical stimulation when compared with control responses. Our results indicate that activity of fCO sensory neurons strongly affects their sensitivity, most likely via Ca 2ϩ -dependent processes.

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Transducer properties of the rapidly adapting stretch receptor neurone in the crayfish (Pacifastacus leniusculus).

Cited by 28 publications

References 23 publications

Tension sensitivity of the heart pacemaker neurons in the isopod crustaceanLigia pallasii

Tension sensitivity of the heart pacemaker neurons in the isopod crustaceanLigia pallasii

Antidromic potential spread modulates the receptor responses in the stretch receptor neurons of the crayfish

Activity-Dependent Sensitivity of Proprioceptive Sensory Neurons in the Stick Insect Femoral Chordotonal Organ

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