306,278 research outputs found
Discrete changes of cell membrane capacitance observed under conditions of enhanced secretion in bovine adrenal chromaffin cells
No full textThe capacitance of the surface membrane of small adrenal chromaffin cells was measured with patch-clamp pipettes. Continuous and discrete changes of capacitance were observed. They were interpreted as changes of surface area connected to exocytotic or endocytotic processes. Most of the measurements were performed in the "whole-cell" recording configuration [Hamill, O. P., Marty, A., Neher, E., Sakmann, B. & Sigworth, F. J. (1981) Pflügers Arch. 391, 85-100], which allows the intracellular Ca2+ concentration to be controlled. With an internal solution highly buffered to low values of Ca2+ concentration (10 nM), the surface capacitance usually decreased and could not be markedly changed by electrical stimulation. At low buffering capacity and medium Ca2+ concentrations (0.1-1 microM), the capacitance measurement showed large fluctuations and discrete steps, reflecting both capacitance decrease and increase. A large transient increase of capacitance could be induced by electrical stimulation under these conditions. It was linked to Ca2+ currents through the membrane. Relatively large (2-6 x 10(-14) F) steps of capacitance decrease were common after extensive stimulation. The size distribution of step-like capacitance changes is well compatible with the idea that steps of capacitance increase reflect individual events of exocytosis of chromaffin granules, whereas steps of the opposite polarity reflect the formation of vesicles or vacuoles by endocytosis
A patch-clamp study of bovine chromaffin cells and of their sensitivity to acetylcholine.
No full textBovine chromaffin cells were enzymatically isolated and kept in short term tissue culture. Their electrical properties were studied using recent advances of the patch-clamp technique (Hamill, Marty, Neher, Sakmann & Sigworth, 1981). 2. When a patch pipette was sealed tightly to a chromaffin cell ('cell-attached configuration') current wave forms due to intracellular action potentials could be observed. The frequency of the wave forms was altered by changing the pipette potential. When acetylcholine was present in the pipette solution, acetylcholine-induced single channel currents were evident in the patch recording. Action potential wave forms were then often seen to follow acetycholine-induced single channel currents. 3. In the cell-attached configuration, large single channel current events did not resemble square pulses but showed exponential relaxations with time constants of the order of 50 ms. 4. After rupture of the patch of membrane, the pipette--cell seal remained stable ('whole-cell recording', Hamill et al. 1981). Chromaffin cells were found to have a resting potential of -50 to -80 mV, and an input resistance around 5 G omega. The high cell resistance accounts for the relaxing currents evident in the cell-attached configuration. 5. In the best cases, the effective time constant of the voltage clamp in the whole-cell recording mode was 15 microseconds. Exchange of small ions such as Na+ ions between pipette and cell interior solutions was then complete within 15 s. 6. Acetylcholine-induced currents were obtained at various acetylcholine concentrations. Single acetylcholine-induced channels had a slope conductance of 44 pS between -100 and -55 mV, and a mean duration of 27 ms at -80 mV (at room temperature)
The influence of intracellular calcium concentration on degranulation of dialysed mast cells from rat peritoneum
No full text1. Mast cells, isolated from rat peritoneum, were studied under tight-seal, whole-cell recording conditions. Membrane conductance, membrane capacitance and the concentration of free intracellular Ca2+, [Ca2+]i, were measured simultaneously. 2. [Ca2+]i could be accurately buffered to values between 0 and 1.5 microM only if relatively high concentrations of calcium buffers (in the millimolar range) were added to the pipette filling solution against which the cytoplasm was dialysed. At lower buffer concentrations [Ca2+]i was markedly increased by hyperpolarizing the membrane. 3. When added to the pipette, guanosine-3-thio-triphosphate (GTP-gamma-S), a nonhydrolysable analogue of guanosine triphosphate, stimulated a 3.3-fold increase in membrane capacitance, which is indicative of mast cell degranulation (Fernandez, Neher & Gomperts, 1984). 4. In weakly buffered cells, GTP-gamma-S also induced a transient increase in [Ca2+]i which, usually, preceded degranulation. Calcium buffers at 1-5 mM concentration suppressed this transient. 5. High [Ca2+]i alone did not induce degranulation. However, it markedly accelerated GTP-gamma-S-induced degranulation. When [Ca2+]i was buffered to zero, an appreciable fraction of cells degranulated in response to GTP-gamma-S, but very slowly, and only after a long lag phase. 6. Transient increases in [Ca2+]i, evoked either by GTP-gamma-S, or by voltage changes, did not elicit capacitance changes during the lag phase, but accelerated the GTP-gamma-S-induced degranulation response at later times. 7. Internally applied inositol 1,4,5-trisphosphate (IP3) also induced transient increases in [Ca2+]i which did not lead to secretion in the absence of GTP-gamma-S. 8. It is concluded that an increase in [Ca2+]i is neither necessary nor sufficient for secretion from dialysed mast cells. [Ca2+]i, however, acts synergistically with other stimuli to promote secretion. It is the more efficient the more time the other stimulus had been allowed for priming the cell
Modeling buffered Ca2+ diffusion near the membrane: Implications for secretion in neuroendocrine cells
No full textSecretion of catecholamines from neuroendocrine cells is relatively slow and it is likely that redistribution and buffering of Ca2+ is a major factor for delaying the response after a stimulus. In fact, in a recent study (Chow, R. H., J. Klingauf, and E. Neher. 1994. Time course of Ca2+ concentration triggering exocytosis in neuroendocrine cells. Proc. Natl. Acad. Sci. U.S.A. 91:12765–12769) Chow et al. concluded that the concentration of free calcium ([Ca2+]i) at a release site peaks at <10μM during short-step depolarizations, and then decays to baseline over tens of milliseconds. To check whether such a time course is consistent with diffusion theory, we modeled buffered diffusion in the vicinity of a Ca2+ channel pore. Peak [Ca2+]i and the slow decay were well simulated when release-ready granules were randomly distributed within a regular grid of Ca2+ channels with mean interchannel distances of 300–600 nm. For such large spacings, however, the initial rise in [Ca2+]i was underestimated, suggesting that a small fraction of the release-ready pool (∼10%) experiences much higher [Ca2+]i, and thus might be collocalized with Ca2+ channels. A model that accommodates these findings then correctly predicts many recent observations, including the result that single action potentials evoke near-synchronous transmitter release with low quantal yield, whereas trains of action potentials lead to desynchronized release, but with severalfold increased quantal yield. The simulations emphasize the role of Ca2+ not only in triggering, but also in modulating the secretory response: buffers are locally depleted by residual Ca2+ of a preceding stimulus, so that a second pulse leads to a larger peak [Ca2+]i at the fusion sites
Quantitative Relationship between Transmitter Release and Calcium Current at the Calyx of Held Synapse
No full textA newly developed deconvolution method (Neher and Sakaba, 2001) allowed us to resolve the time course of neurotransmitter release at the calyx of Held synapse and to quantify some basic aspects of transmitter release. First, we identified a readily releasable pool (RRP) of synaptic vesicles. We found that the size of the RRP, when tested with trains of strong stimuli, was constant regardless of the exact stimulus patterns, if stimuli were confined to a time interval of ∼60 msec. For longer-lasting stimulus patterns, recruitment of new vesicles to the RRP made a substantial contribution to the total release. Second, the cooperativity of transmitter release as a function of Ca2+ current was estimated to be 3–4, which confirmed previous results (Borst and Sakmann, 1999; Wu et al., 1999). Third, an initial small Ca2+ influx increased the efficiency of Ca2+ currents in subsequent transmitter release. This type of facilitation was blocked by a high concentration of EGTA (0.5 mm). Fourth, the release rates of synaptic vesicles at this synapse turned out to be heterogeneous: once a highly Ca2+-sensitive population of vesicles was consumed, the remaining vesicles released at lower rates. These components of release were more clearly separated in the presence of 0.5 mm EGTA, which prevented the buildup of residual Ca2+. Conversely, raising the extracellular Ca2+ concentration facilitated the slower population such that its release characteristics became more similar to those of the faster population under standard conditions. Heterogeneous release probabilities are expected to support the maintenance of synaptic transmission during high-frequency stimulation
High-resolution measurement of current flowing through isolated membrane patches from nerve and muscle cells
No full textThe charge carried by single‐channel currents of rat cultured muscle cells in the presence of local anaesthetics
No full textAcetylcholine-induced single-channel currents were measured in the presence of the lignocaine derivative QX222. Unit responses appeared as bursts of short current pulses as a result of the fast blocking action of the drug (QX222). The amplitude of the individual current pulses was not changed by the presence of the drug up to a concentration of 250 microM. The time integral of current during a burst, which for a sequential blocking model should be independent of drug concentration, decreased at concentrations of QX222 higher than 40 microM. The distribution of gap times within a burst could not be fitted by a single exponential for high concentrations of QX222. It is concluded that the simple sequential model of channel blockade does not apply for concentrations of QX222 higher than 40 microM
Noise analysis of drug-induced voltage clamp currents in denervated frog muscle fibres
No full textVoltage clamp currents were recorded during iontophoretic application of steady doses of acetylcholine (ACh), carbachol or suberyldicholine to hyperpersensitive extrasynaptic regions of chronically denervated frog muscle fibers. Autocorrelation functions of drug induced current fluctuations were calculated and estimates of conductance gamma and average open time tau of the extrasynaptic ion channels were derived. 2. The average open time of an extrajunctional channel induced by acetylcholine is tauACh = 11 +/- 1-6 msec (+/- S.E.) at -80 mV and 8 degrees C. Carbachol and suberyldicholine open channels of tauCarb = 3-9 +/- 0-4 msec and tauSubCh = 19 +/- 2-5 msec (+/- S.E.) duration under the same conditions. The average open time of the extrasynaptic channel produced by each drug is three to five times longer than the value found for junctional channels in normal fibres. 3. The average open time of the extrajunctional channel is dependent on temperature and membrane potential. Lowering the temperature or increasing the membrane potential increases the average open time of the channels induced by any one of the drugs. 4. The conductance of a single extrajunctional channel opened by the action of acetylcholine is estimated to be gammaextra = 15 +/- 1-8 pmho (+/- S.E.). This is somewhat lower than the value of gammaep = 23 +/- 2 pmho (+/- S.E.) found for the conductance of a single open channel in the junctional membrane of normal fibres. The extrasynaptic channels opened by the action of carbachol and suberyldicholine have similar conductances to those produced by ACh. 5. The autocorrelation function of drug-induced current fluctuations, recorded at the former end-plate region of chronically denervated fibres often shows both a fast and a slow time constant. They correspond in value to the time constant of the autocorrelation function obtained from end-plate currents in normal fibres and from extrasynaptic currents in denervated fibres respectively. This could indicate that two populations of channels exist at the former end-plate region of denervated muscle fibres
Time course of Ca2+ concentration triggering exocytosis in neuroendocrine cells.
No full textWe have used the secretory response of chromaffin cells to estimate the submembrane intracellular Ca2+ concentration ([Ca2+]i) "seen" by secretory granules during short depolarizations. The rate of secretion during a depolarization was assessed by combining the electrochemical method of amperometry and electrical capacitance measurements. The rate was then related to [Ca2+]i based on a previous characterization of how Ca2+ affects the dynamics of vesicle priming and fusion in chromaffin cells [Heinemann, C., Chow, R. H., Neher, E. & Zucker, R. S. (1994) Biophys. J. 67, in press]. Calculated [Ca2+]i rose during the depolarization to a peak of < 10 microM, then decayed over tens of milliseconds. In synapses, vesicles are presumed to be located within nanometers of Ca2+ channels where [Ca2+]i is believed to rise in only microseconds to near steady-state levels of hundreds of micromolar. Channel closure should lead to a decrease in [Ca2+]i also in microseconds. Our findings of the slower time course and the lower peak [Ca2+]i suggest that in chromaffin cells, unlike synapses, Ca2+ channels and vesicles are not strictly colocalized. This idea is consistent with previously published data on dense-core vesicle secretion from diverse cell types
Separation of presynaptic and postsynaptic contributions to depression by covariance analysis of successive EPSCs at the calyx of Held synapse
No full textSynaptic short-term plasticity is considered to result from multiple cellular mechanisms, which may include presynaptic and postsynaptic contributions. We have recently developed a non- stationary EPSC fluctuation analysis (Scheuss and Neher, 2001) to estimate synaptic parameters and their transient changes during short-term synaptic plasticity. Extending the classical variance-mean approach, a short train of stimuli is applied repetitively, and the resulting EPSCs are analyzed for means, variances, and covariances. This provides estimates of the quantal size and quantal content for each EPSC in the train, and furthermore, an estimate of the number of release sites. The latter is less sensitive to heterogeneity in the release probability than that of the variance-mean approach. Here, we applied this analysis to the calyx of Held synapse in brainstem slices of young rats (postnatal day 8-10). We found significant negative covariance in the amplitude of successive EPSCs in a train. The analysis showed that the 10-fold depression in the EPSC amplitude during 100 Hz trains at elevated extracellular Ca2+ concentration resulted from a 2.5-fold reduction in quantal size caused by postsynaptic AMPA receptor desensitization and saturation, and a fourfold reduction in quantal content, which was partially relieved by application of cyclothiazide. The number of release sites estimated by covariance analysis was approximate to2000 and significantly larger than estimates from variance-mean parabolas
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