Calcium‐dependent inward current in Aplysia bursting pace‐maker neurones.

Krämer, Richard; Zucker, Robert S.

doi:10.1113/jphysiol.1985.sp015666

Cited by 124 publications

(100 citation statements)

References 52 publications

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“…The DAPs last for hundreds of milliseconds to seconds and have amplitudes up to 10 mV, depending on the number of preceding spikes and membrane potential levels at which they are evoked (Andrew & Dudek, 1984;Andrew, 1987). Resembling those identified in invertebrate bursting pacemaker neurones (Thompson & Smith, 1976;Kramer & Zucker, 1985a) and other mammalian CNS neurones (Llin as, 1988;White, Lovinger & Weight, 1989), DAPs as well as phasic firing in SON neurones are abolished by depleting extracellular Ca¥, blocking membrane Ca¥ channels or chelating cytosolic free Ca¥ (Inenaga, Akamatsu, Nagatomo, Ueta & Yamashita, 1992;Li et al 1995). Our recent study has further demonstrated that interference with Ca¥-induced Ca¥ release from internal stores, with either blockade of intracellular ryanodine receptors or depletion of internal Ca¥ pools, reduces DAPs and eliminates phasic firing in SON cells (Li & Hatton, 1997).…”

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confidence: 54%

Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Hatton²

1997

The Journal of Physiology

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Whole‐cell patch clamp recordings were obtained from sixty‐five rat supraoptic nucleus (SON) neurones in brain slices to investigate ionic mechanisms underlying depolarizing after‐potentials (DAPs). When cells were voltage clamped around ‐58 mV, slow inward currents mediating DAPs (Idap), evoked by three brief depolarizing pulses, had a peak of 17 ± 1 pA (mean ± s.e.m.) and lasted for 2.8 ± 0.1 s. No significant differences in the amplitude and duration were observed when one to three preceding depolarizing pulses were applied, although there was a tendency for twin pulses to evoke larger Idap than a single pulse. The Idap was absent when membrane potentials were more negative than ‐70 mV. In the range ‐70 to ‐50 mV, Idap amplitudes and durations increased as the membrane became more depolarized, with an activation threshold of ‐65.7 ± 0.7 mV. I dap with normal amplitude and duration could be evoked during the decay of a preceding Idap. As frequencies of depolarizing pulses rose from 2 to 20 Hz, the times to peak Idap amplitude were reduced but the amplitudes and durations did not change. A consistent reduction in membrane conductance during the Idap was observed in all SON neurones tested, and averaged 34.6 ± 3.3%. Small hyperpolarizing pulses used to measure membrane conductances appeared not to disturb major ionic mechanisms underlying Idap, since the slope and duration of Idap with and without test pulses were similar. The Idap had an averaged reversal potential of ‐87.4 ± 1.6 mV, which was close to the K+ equilibrium potential. An elevation in [K+]O reduced or abolished the Idap, and shifted its reversal potential toward more positive levels. Perifusion of slices with 7.5–10 mm TEA, a K+ channel blocker, reversibly suppressed the Idap. Both Na+ and Ca2+ currents failed to induce an Idap‐like current during perifusion of slices with media containing high [K+]o or TEA. However, the Idap was abolished by replacing external Ca2+ with Co2+, or replacing 82% of external Na+ with choline or Li+. Perifusion of slices with media containing 1–2 μm TTX also reduced Idap by 55.5 ± 9.0 %. These results suggest that the generation of DAPs in SON neurones mainly involves a reduction in outward K+ current(s), which probably has little or no inactivation and can be inhibited by [Ca2+]i transients, due to Ca2+ influx during action potentials and Ca2+ release from internal stores. Na+ influx might provide a permissive influence for Ca2+‐induced reduction of K+ conductances and/or help to raise [Ca2+]i via reverse‐mode Ca2+‐Na+ exchange. Other conductances, making minor contributions to the Idap, may also be involved.

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confidence: 54%

Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Hatton²

1997

The Journal of Physiology

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“…In each of these cases, activation of the calcium channels contributes a depolarizing current that helps bring the cell to threshold during the bursts. Bursts are terminated by inactivation of the calcium channels (Kramer and Zucker, 1985;Huguenard and Prince, 1992;Bal and McCormick, 1997) or by activation of calciumactivated potassium channels after calcium entry (Wong and Prince, 1978;Del Negro et al, 1999;Golding et al, 1999). In Purkinje neurons, however, P/Q-type calcium channels are responsible for the abrupt termination of each burst by generating a dendritic calcium spike.…”

Section: Discussionmentioning

confidence: 99%

Dendritic Control of Spontaneous Bursting in Cerebellar Purkinje Cells

Womack¹,

Khodakhah²

2004

J. Neurosci.

123

128

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We investigated the mechanisms that contribute to spontaneous regular bursting in adult Purkinje neurons in acutely prepared cerebellar slices. Bursts consisted of 3-20 spikes and showed a stereotypic waveform. Each burst developed with an increase in firing rate and was terminated by a more rapid increase in firing rate and a decrease in spike height. Whole-cell current-clamp recordings showed that each burst ended with a rapid depolarization followed by a hyperpolarization. Dual dendritic and somatic extracellular recordings revealed that each burst was terminated by a dendritic calcium spike. The contributions of T-and P/Q-type calcium current, large (BK) and small (SK) conductance calcium-activated potassium currents, and hyperpolarization-activated (I H ) current to bursting were investigated with specific channel blockers. None of the currents, except for P/Q, were required to sustain spontaneous bursting or the stereotypic burst waveform. T-type calcium, BK, and SK channels contributed to interspike and interburst intervals. The effect of T-type calcium channel block was more pronounced after BK channel block and vice versa, indicating that these two currents interact to regulate burst firing. Block of I H current had no effect on bursting. Partial block of P/Q-type calcium channels concurrently eliminated dendritic calcium spikes and caused a switch from regular bursting to tonic firing or irregular bursting. Dendritic calcium spikes persisted in the presence of tetrodotoxin, indicating that their initiation did not require somatic sodium spikes. Our results demonstrate an important role for dendritic conductances in burst firing in intact Purkinje neurons.

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“…Details of the ganglion removal, desheathing, axotomy and solution changes have been previously described (Kramer & Zucker, 1985; Lando & Zucker, 1989). Most experiments were done on axotomized left upper quadrant neurons, particularly L3 and L6 which have been shown to possess a Ca2+-activated K+ conductance (IK(ca)) that is largely abolished by extracellular tetraethylammonium (TEA+) ions (Deitmer & Eckert, 1985).…”

Section: Methodsmentioning

confidence: 99%

“…Details of the two-electrode voltage clamp technique employed have been previously described (Smith & Zucker, 1980; Kramner & Zucker, 1985). In all Ica experiments, the voltage and current electrodes were filled with 3 M CsCl and had resistances of 1-5 MCI.…”

Section: Voltage Clampmentioning

confidence: 99%

Ca(2+)‐dependent inactivation of Ca2+ current in Aplysia neurons: kinetic studies using photolabile Ca2+ chelators.

Fryer

Zucker

1993

The Journal of Physiology

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SUMMARY1. The kinetics and sensitivity of the Ca2"-dependent inactivation of calcium current (Ic.) were examined in intact cell bodies from the abdominal ganglion of Aplysia californica under two-electrode voltage clamp.2. Rapid changes in the level of intracellular free calcium ([Ca2+]i) were generated at the cell surface by photolytic release of Ca2" (nitr-5 and dimethoxy nitrophen) or Ca2" buffer (diazo-4).3. Diazo-4 increased ICa by 10-15 % and slowed the rate of Ica decay when photolysed before a test pulse or between a prepulse and a test pulse. The predominant effect of further light flashes was to increase the amount of noninactivating current (I,, ) remaining at the end of long (> 1 s) depolarizing pulses.

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Calcium‐dependent inward current in Aplysia bursting pace‐maker neurones.

Cited by 124 publications

References 52 publications

Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Dendritic Control of Spontaneous Bursting in Cerebellar Purkinje Cells

Ca(2+)‐dependent inactivation of Ca2+ current in Aplysia neurons: kinetic studies using photolabile Ca2+ chelators.

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Calcium‐dependent inward current in Aplysia bursting pace‐maker neurones.

Cited by 124 publications

References 52 publications

Reduced outward K+ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Reduced outward K+ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Dendritic Control of Spontaneous Bursting in Cerebellar Purkinje Cells

Ca(2+)‐dependent inactivation of Ca2+ current in Aplysia neurons: kinetic studies using photolabile Ca2+ chelators.

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Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones

Reduced outward K⁺ conductances generate depolarizing after–potentials in rat supraoptic nucleus neurones