Home  About us  Contact
 

Slope Conductance (slope + conductance)

Distribution by Scientific Domains
Life Sciences100%
Distribution within Life Sciences
Anatomy & Physiology57%
Neuroscience42%

Selected Abstracts

NCS-1 differentially regulates growth cone and somata calcium channels in Lymnaea neurons

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 3 2008
Kwokyin Hui
Abstract Local voltage-gated calcium channels, which regulate intracellular Ca2+ levels by allowing Ca2+ influx, play an important role in guiding and shaping growth cones, and in regulating the outgrowth and branching of neurites. Therefore, elucidating the mechanisms that regulate the biophysical properties of whole-cell calcium currents in the growth cones and somata of growing neurons is important to improving our understanding of neuronal development and regeneration. In this study, taking advantage of the large size of the pedal A (PeA) neurons in Lymnaea stagnalis, we compared the biophysical properties of somata and growth cone whole-cell calcium channel currents using Ba2+ and Ca2+ as current carriers. We found that somata and growth cone currents exhibit similar high-voltage activation properties. However, Ba2+ and Ca2+ currents in growth cones and somata are differentially affected by a dominant-negative peptide containing the C-terminal amino acid sequence of neuronal calcium sensor-1 (NCS-1). The peptide selectively reduces the peak and sustained components of current densities and the slope conductance in growth cones, and shifts the reversal potential of the growth cone currents to more hyperpolarized voltages. In contrast, the peptide had no significant effect on the somata calcium channels. Thus, we conclude that NCS-1 differentially modulates Ca2+ currents in the somata and growth cones of regenerating neurons, and may serve as a key regulator to facilitate the growth cone calcium channel activity. [source]

Ionic currents underlying rhythmic bursting of ventral mossy cells in the developing mouse dentate gyrus

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 7 2003
Shozo Jinno
Abstract The electrophysiological properties of mossy cells were examined in developing mouse hippocampal slices using whole-cell patch-clamp techniques, with particular reference to the dorsoventral difference. Dorsal mossy cells exhibited a higher spontaneous excitatory postsynaptic potential (EPSP) frequency and larger maximal EPSP amplitude than ventral mossy cells. On the other hand, the blockade of synaptic inputs with glutamatergic and GABAergic antagonists disclosed a remarkable dorsoventral difference in the intrinsic activity: none (0/27) of the dorsal mossy cells showed intrinsic bursting, whereas the majority (35/47) of the ventral mossy cells exhibited intrinsic rhythmic bursting. To characterize the ionic currents underlying the rhythmic bursting of mossy cells, we used somatic voltage-clamp recordings in the subthreshold voltage range. Ventral bursting cells possessed both hyperpolarization-activated current (Ih) and persistent sodium current (INaP), whereas dorsal and ventral nonbursting cells possessed Ih but no INaP. Blockade of Ih with cesium did not affect the intrinsic bursting of ventral mossy cells. In contrast, the blockade of INaP with tetrodotoxin or phenytoin established a stable subthreshold membrane potential in ventral bursting cells. The current,voltage curve of ventral bursting cells showed a region of tetrodotoxin-sensitive negative slope conductance between ,55 mV and a spike threshold (, ,45 mV). On the other hand, no subthreshold calcium conductances played a significant role in the intrinsic bursting of ventral mossy cells. These observations demonstrate the heterogeneous electrophysiological properties of hilar mossy cells, and suggest that the subthreshold INaP plays a major role in the intrinsic rhythmic bursting of ventral mossy cells. [source]

A Novel Background Potassium Channel in Rat Atrial Cells

EXPERIMENTAL PHYSIOLOGY, Issue 4 2000
Z. Shui
A K+ channel activated by intracellular ATP has been observed in inside-out patches from rat atrial cells. The channel has a slope conductance of 130 ± 5 pS in symmetrical 140 mM K+ solution, and is almost independent of voltage over the range from -80 to +80 mV. There is no detectable inactivation during application of ATP over a few minutes. In the presence of 3 mM intracellular ATP, channel openings occur as bursts with a mean open time of 1.7 ms, a mean closed time of 0.4 ms, a mean burst duration of 18 ms and a mean burst interval of 41 ms. Kinetic analysis suggests that ATP mainly affects the burst duration and the burst interval of the channel. Based on the properties above, the channel differs from other known K+ channels in cardiac cells and may contribute to background K+ current. [source]

BK channels in human glioma cells have enhanced calcium sensitivity,

GLIA, Issue 4 2002
Christopher B. Ransom
Abstract We have previously demonstrated the expression of large-conductance, calcium-activated potassium (BK) channels in human glioma cells. In the present study, we characterized the calcium sensitivity of glioma BK channels in excised membrane patches. Channels in inside-out patches were activated at ,60 mV by 2.1 × 10,6 M cytosolic Ca2+, were highly K+ -selective, and had a slope conductance of ,210 pS. We characterized the Ca2+ sensitivity of these channels in detail by isolating BK currents in outside-out patches with different free [Ca2+]i. The half-maximal voltage for channel activation, V0.5, of glioma BK currents in outside-out patches was +138 mV with 0 Ca2+/10 EGTA. V0.5 was shifted to +81 mV and ,14 mV with free [Ca2+]i of 1.5 × 10,7 M and 2.1 × 10,6 M, respectively. These results suggest that glioma BK channels have a higher Ca2+ sensitivity than that described in many other human preparations. Data obtained from a cloned BK channel (hbr5) expressed in HEK cells support the conclusion that glioma BK channels have an unusually high sensitivity to calcium. In addition, the sensitivity of glioma BK channels to the BK inhibitor tetrandrine suggests the expression of BK channel auxiliary ,-subunits by glioma cells. Expression of the auxiliary ,-subunit of BK channels by glioma cells may relate to the high Ca2+ sensitivity of glioma BK channels. GLIA 38:281,291, 2002. © 2002 Wiley-Liss, Inc. [source]

Changes in extracellular K+ concentration modulate contractility of rat and rabbit cardiac myocytes via the inward rectifier K+ current IK1

THE JOURNAL OF PHYSIOLOGY, Issue 3 2004
Ron Bouchard
The mechanisms underlying the inotropic effect of reductions in [K+]o were studied using recordings of membrane potential, membrane current, cell shortening and [Ca2+]i in single, isolated cardiac myocytes. Three types of mammalian myocytes were chosen, based on differences in the current density and intrinsic voltage dependence of the inwardly rectifying background K+ current IK1 in each cell type. Rabbit ventricular myocytes had a relatively large IK1 with a prominent negative slope conductance whereas rabbit atrial cells expressed much smaller IK1, with little or no negative slope conductance. IK1 in rat ventricle was intermediate in both current density and slope conductance. Action potential duration is relatively short in both rabbit atrial and rat ventricular myocytes, and consequently both cell types spend much of the duty cycle at or near the resting membrane potential. Rapid increases or decreases of [K+]o elicited significantly different inotropic effects in rat and rabbit atrial and ventricular myocytes. Voltage-clamp and current-clamp experiments showed that the effects on cell shortening and [Ca2+]i following changes in [K+]o were primarily the result of the effects of alterations in IK1, which changed resting membrane potential and action potential waveform. This in turn differentially altered the balance of Ca2+ efflux via the sarcolemmal Na+,Ca2+ exchanger, Ca2+ influx via voltage-dependant Ca2+ channels and sarcoplasmic reticulum (SR) Ca2+ release in each cell type. These results support the hypothesis that the inotropic effect of alterations of [K+]o in the heart is due to significant non-linear changes in the current,voltage relation for IK1 and the resulting modulation of the resting membrane potential and action potential waveform. [source]

Functional expression of the hyperpolarization-activated, non-selective cation current If in immortalized HL-1 cardiomyocytes

THE JOURNAL OF PHYSIOLOGY, Issue 1 2002
Laura Sartiani
HL-1 cells are adult mouse atrial myocytes induced to proliferate indefinitely by SV40 large T antigen. These cells beat spontaneously when confluent and express several adult cardiac cell markers including the outward delayed rectifier K+ channel. Here, we examined the presence of a hyperpolarization-activated If current in HL-1 cells using the whole-cell patch-clamp technique on isolated cells enzymatically dissociated from the culture at confluence. Cell membrane capacitance (Cm) ranged from 5 to 53 pF. If was detected in about 30 % of the cells and its occurrence was independent of the stage of the culture. If maximal slope conductance was 89.7 ± 0.4 pS pF,1 (n= 10). If current in HL-1 cells showed typical characteristics of native cardiac If current: activation threshold between ,50 and ,60 mV, half-maximal activation potential of ,83.1 ± 0.7 mV (n= 50), reversal potential at ,20.8 ± 1.5 mV (n= 10), time-dependent activation by hyperpolarization and blockade by 4 mm Cs+. In half of the cells tested, activation of adenylyl cyclase by the forskolin analogue L858051 (20 ,m) induced both a ,6 mV positive shift of the half-activation potential and a ,37 % increase in the fully activated If current. RT-PCR analysis of the hyperpolarization-activated, cyclic nucleotide-gated channels (HCN) expressed in HL-1 cells demonstrated major contributions of HCN1 and HCN2 channel isoforms to If current. Cytosolic Ca2+ oscillations in spontaneously beating HL-1 cells were measured in Fluo-3 AM-loaded cells using a fast-scanning confocal microscope. The oscillation frequency ranged from 1.3 to 5 Hz and the spontaneous activity was stopped in the presence of 4 mm Cs+. Action potentials from HL-1 cells had a triangular shape, with an overshoot at +15 mV and a maximal diastolic potential of ,69 mV, i.e. more negative than the threshold potential for If activation. In conclusion, HL-1 cells display a hyperpolarization-activated If current which might contribute to the spontaneous contractile activity of these cells. [source]