Stretch‐activated and background non‐selective cation channels in rat atrial myocytes

Zhang, Yin Hua; Youm, Jae Boum; Sung, Hwa Jung; Lee, Sang Hyun; Ryu, Shin Young; Lee, Suk Ho; Ho, Won Kyung; Earm, Yung E.

doi:10.1111/j.1469-7793.2000.00607.x

Cited by 110 publications

(77 citation statements)

References 50 publications

(73 reference statements)

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“…The channels carrying this current may account for the resting permeability to sodium in many cells. The current appears electrophysiologically similar to background nonselective cation currents of cardiac cells (Hagiwara et Manabe et al, 1995;Zhang et al, 2000). The existence of such a flux in cerebellar nuclear neurons is consistent with Jahnsen's (1986a) observation that the cells "always showed signs of having a steady inward current."…”

Section: Currents That Determine the Resting Potentialsupporting

confidence: 67%

Ionic Currents and Spontaneous Firing in Neurons Isolated from the Cerebellar Nuclei

2000

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Neurons of the cerebellar nuclei fire spontaneous action potentials both in vitro, with synaptic transmission blocked, and in vivo, in resting animals, despite ongoing inhibition from spontaneously active Purkinje neurons. We have studied the intrinsic currents of cerebellar nuclear neurons isolated from the mouse, with an interest in understanding how these currents generate spontaneous activity in the absence of synaptic input as well as how they allow firing to continue during basal levels of inhibition. Current-clamped isolated neurons fired regularly (ϳ20 Hz), with shallow interspike hyperpolarizations (approximately Ϫ60 mV), much like neurons in more intact preparations. The spontaneous firing frequency lay in the middle of the dynamic range of the neurons and could be modulated up or down with small current injections.During step or action potential waveform voltage-clamp commands, the primary current active at interspike potentials was a tetrodotoxin-insensitive (TTX), cesium-insensitive, voltageindependent, cationic flux carried mainly by sodium ions. Although small, this cation current could depolarize neurons above threshold voltages. Voltage-and current-clamp recordings suggested a high level of inactivation of the TTX-sensitive transient sodium currents that supported action potentials. Blocking calcium currents terminated firing by preventing repolarization to normal interspike potentials, suggesting a significant role for K(Ca) currents. Potassium currents that flowed during action potential waveform voltage commands had high activation thresholds and were sensitive to 1 mM TEA. We propose that, after the decay of high-threshold potassium currents, the tonic cation current contributes strongly to the depolarization of neurons above threshold, thus maintaining the cycle of firing.

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Section: Currents That Determine the Resting Potentialsupporting

confidence: 67%

Ionic Currents and Spontaneous Firing in Neurons Isolated from the Cerebellar Nuclei

2000

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“…The overall physiological action of these channels is depolarization of the membrane in response to stretch, as shown in the majority of experimental observations from isolated cardiac tissue and the whole heart. Experimental studies of the electrophysiological properties of stretch-activated channels show that they are activated instantly by mechanical stimulation, and the currentvoltage (I-V) relationship for the most important nonspecific cation channel is linear (18,19). On the basis of these observations, linear ionic models for I s have been proposed (20,21).…”

Section: Mathematical Modelmentioning

confidence: 99%

“…In our model, we used values close to E s ϳ 1 to provide the depolarizing effect. However, the exact value of the reversal potential may depend on the cell type (11,18,19); therefore, we performed simulations with lower values of E s to investigate the possible effects on the main results of this study.…”

Section: Mathematical Modelmentioning

confidence: 99%

Drift and breakup of spiral waves in reaction–diffusion–mechanics systems

Panfilov

Keldermann

Nash

2007

Proc. Natl. Acad. Sci. U.S.A.

101

130

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Rotating spiral waves organize excitation in various biological, physical, and chemical systems. They underpin a variety of important phenomena, such as cardiac arrhythmias, morphogenesis processes, and spatial patterns in chemical reactions. Important insights into spiral wave dynamics have been obtained from theoretical studies of the reaction–diffusion (RD) partial differential equations. However, most of these studies have ignored the fact that spiral wave rotation is often accompanied by substantial deformations of the medium. Here, we show that joint consideration of the RD equations with the equations of continuum mechanics for tissue deformations (RD–mechanics systems), yield important effects on spiral wave dynamics. We show that deformation can induce the breakup of spiral waves into complex spatiotemporal patterns. We also show that mechanics leads to spiral wave drift throughout the medium approaching dynamical attractors, which are determined by the parameters of the model and the size of the medium. We study mechanisms of these effects and discuss their applicability to the theory of cardiac arrhythmias. Overall, we demonstrate the importance of RD–mechanics systems for mathematics applied to life sciences.

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“…The SAC and/or SOC conductance (G m ) given in the results for any experimental conditions was evaluated from I m . In order to reveal the presence of SACs, the cells were stretched using two patch microelectrodes, as previously reported (Zhang et al, 2000). Briefly, one microelectrode was positioned by a hydraulic micromanipulator at the centre of the cell and used for electrophysiological measurements, while the other one was sealed 10-20 μm far, and moved by another hydraulic micromanipulator to stretch the cell.…”

Section: Electrophysiologymentioning

confidence: 99%

Regulation of transient receptor potential canonical channel 1 (TRPC1) by sphingosine 1-phosphate in C2C12 myoblasts and its relevance for a role of mechanotransduction in skeletal muscle differentiation

Formigli

Sassoli

Squecco

et al. 2009

Journal of Cell Science

101

106

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Transient receptor potential canonical (TRPC) channels provide cation and Ca2+ entry pathways, which have important regulatory roles in many physio-pathological processes, including muscle dystrophy. However, the mechanisms of activation of these channels remain poorly understood. Using siRNA, we provide the first experimental evidence that TRPC channel 1 (TRPC1), besides acting as a store-operated channel, represents an essential component of stretch-activated channels in C2C12 skeletal myoblasts, as assayed by whole-cell patch-clamp and atomic force microscopic pulling. The channel's activity and stretch-induced Ca2+ influx were modulated by sphingosine 1-phosphate (S1P), a bioactive lipid involved in satellite cell biology and tissue regeneration. We also found that TRPC1 was functionally assembled in lipid rafts, as shown by the fact that cholesterol depletion resulted in the reduction of transmembrane ion current and conductance. Association between TRPC1 and lipid rafts was increased by formation of stress fibres, which was elicited by S1P and abolished by treatment with the actin-disrupting dihydrocytochalasin B, suggesting a role for cytoskeleton in TRPC1 membrane recruitment. Moreover, TRPC1 expression was significantly upregulated during myogenesis, especially in the presence of S1P, implicating a crucial role for TRPC1 in myoblast differentiation. Collectively, these findings may offer new tools for understanding the role of TRPC1 and sphingolipid signalling in skeletal muscle regeneration and provide new therapeutic approaches for skeletal muscle disorders.

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Stretch‐activated and background non‐selective cation channels in rat atrial myocytes

Cited by 110 publications

References 50 publications

Ionic Currents and Spontaneous Firing in Neurons Isolated from the Cerebellar Nuclei

Ionic Currents and Spontaneous Firing in Neurons Isolated from the Cerebellar Nuclei

Drift and breakup of spiral waves in reaction–diffusion–mechanics systems

Regulation of transient receptor potential canonical channel 1 (TRPC1) by sphingosine 1-phosphate in C2C12 myoblasts and its relevance for a role of mechanotransduction in skeletal muscle differentiation

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