Calcium role in depolarization-secretion coupling: an aequorin study in squid giant synapse

Insights into the mediation of Ca2+ signaling in the promoting effects of LETX-VI on the synthesis and release of dopamine

Latroeggtoxin-VI (LETX-VI) is an active protein and was previously demonstrated to have effects on the synthesis and release of dopamine. Hererin, the involvement of Ca2+ signaling in the effects of LETX-VI on dopamine was systematically investigated, using PC12 cells as a neuron model. LETX-VI was shown to promote dopamine release from PC12 cells both in the presence and absence of extracellular Ca2+; however the presence of extracellular Ca2+ was favorable for enhancing the promoting effects of LETX-VI on dopamine, because LETX-VI facilitated the influx of extracellular Ca2+ through the L-type calcium channels in plasma membrane (PM) to increase cytosolic Ca2+ concentration. LETX-VI was able to penetrate the PM of PC12 cells to act on the Ca2+ channel proteins IP3Rs and RyRs in the endoplasm reticulum (ER) membrane, opening the Ca2+ channels and promoting the release of ER Ca2+ to elevate cytosolic Ca2+ level. With the help of intracellular Ca2+ chelator BAPTA, the elevated cytosolic Ca2+ level was proven to play crucial role for the enhanced promoting effects of LETX-VI on dopamine. Taken together, LETX-VI is able to open the Ca2+ channels in both PM and ER membrane simultaneously to facilitate extracellular Ca2+ influx and ER Ca2+ release, and thus increases the cytosolic Ca2+ concentration to enhance the promoting effects on the synthesis and release of dopamine.

Miniscope GRIN Lens System for Calcium Imaging of Neuronal Activity from Deep Brain Structures in Behaving Animals

Visualizing neural activity from deep brain regions in freely behaving animals through miniature fluorescent microscope (miniscope) systems is becoming more important for understanding neural encoding mechanisms underlying cognitive functions. Here we present our custom-designed miniscope GRadient INdex (GRIN) lens system that enables simultaneously recording from hundreds of neurons for months. This article includes miniscope design, the surgical procedure for GRIN lens implantation, miniscope mounting on the head of a mouse, and data acquisition and analysis. First, a target brain region is labeled with virus expressing GCaMP6; second, a GRIN lens is implanted above the target brain region; third, following mouse surgical recovery, a miniscope is mounted on the head of the mouse above the GRIN lens; and finally, neural activity is recorded from the freely behaving mouse. This system can be applied to recording the same population of neurons longitudinally, enabling the elucidation of neural mechanisms underlying behavioral control. © 2018 by John Wiley & Sons, Inc.

Advances in two photon scanning and scanless microscopy technologies for functional neural circuit imaging

Recent years have seen substantial developments in technology for imaging neural circuits, raising the prospect of large scale imaging studies of neural populations involved in information processing, with the potential to lead to step changes in our understanding of brain function and dysfunction. In this article we will review some key recent advances: improved fluorophores for single cell resolution functional neuroimaging using a two photon microscope; improved approaches to the problem of scanning active circuits; and the prospect of scanless microscopes which overcome some of the bandwidth limitations of current imaging techniques. These advances in technology for experimental neuroscience have in themselves led to technical challenges, such as the need for the development of novel signal processing and data analysis tools in order to make the most of the new experimental tools. We review recent work in some active topics, such as region of interest segmentation algorithms capable of demixing overlapping signals, and new highly accurate algorithms for calcium transient detection. These advances motivate the development of new data analysis tools capable of dealing with spatial or spatiotemporal patterns of neural activity, that scale well with pattern size.

Glutamate Release

Our aim was to review the processes of glutamate release from both biochemical and neurophysiological points of view. A large body of evidence now indicates that glutamate is specifically accumulated into synaptic vesicles, which provides strong support for the concept that glutamate is released from synaptic vesicles and is the major excitatory neurotransmitter. Evidence suggests the notion that synaptic vesicles, in order to sustain the neurotransmitter pool of glutamate, are endowed with an efficient mechanism for vesicular filling of glutamate. Glutamate-loaded vesicles undergo removal of Synapsin I by CaM kinase II-mediated phosphorylation, transforming to the release-ready pool. Vesicle docking to and fusion with the presynaptic plasma membrane are thought to be mediated by the SNARE complex. The Ca(2+)-dependent step in exocytosis is proposed to be mediated by synaptotagmin.

Calcium imaging in single neurons from brain slices using bioluminescent reporters

Responses of three bioluminescent Ca(2+) sensors were studied in vitro and in neurons from brain slices. These sensors consisted of tandem fusions of green fluorescent protein (GFP) with the photoproteins aequorin, obelin, or a mutant aequorin with high Ca(2+) sensitivity. Kinetics of GFP-obelin responses to a saturating Ca(2+) concentration were faster than those of GFP-aequorin at all Mg(2+) concentrations tested, whereas GFP-mutant aequorin responses were the slowest. GFP-photoproteins were efficiently expressed in pyramidal neurons following overnight incubation of acute neocortical slices with recombinant Sindbis viruses. Expression of GFP-photoproteins did not result in conspicuous modification of morphological or electrophysiological properties of layer V pyramidal cells. The three sensors allowed the detection of Ca(2+) transients associated with action potential discharge in single layer V pyramidal neurons. In these neurons, depolarizing steps of increasing amplitude elicited action potential discharge of increasing frequency. Bioluminescent responses of the three sensors were similar in several respects: detection thresholds, an exponential increase with stimulus intensity, photoprotein consumptions, and kinetic properties. These responses, which were markedly slower than kinetics measured in vitro, increased linearly during the action potential discharge and decayed exponentially at the end of the discharge. Onset slopes increased with stimulus intensity, whereas decay kinetics remained constant. Dendritic light emission contributed to whole-field responses, but the spatial resolution of bioluminescence imaging was limited to the soma and proximal apical dendrite. Nonetheless, the high signal-to-background ratio of GFP-photoproteins allowed the detection of Ca(2+) transients associated with 5 action potentials in single neurons upon whole-field bioluminescence recordings.

Methylmercury-Induced Increase of Intracellular Ca2+ Increases Spontaneous Synaptic Current Frequency in Rat Cerebellar Slices

The relationship between increased intracellular calcium concentration ([Ca(2+)](i)) and changes in spontaneous synaptic current frequency caused by the neurotoxicant methylmercury (MeHg) was examined in Purkinje cells of cerebellar slices using confocal microscopy and whole-cell recording. MeHg (10-100 microM) stimulated and then suppressed completely the frequency of spontaneous excitatory and inhibitory postsynaptic currents (sEPSCs and sIPSCs). Current amplitude was also initially increased. The same MeHg concentrations markedly increased fluorescence of the Ca(2+) indicator Fluo-4 throughout the molecular layer as well as the granule cells. No changes in fluorescence occurred in Purkinje cell soma, although fluorescence increased in their subplasmalemmal shell. Simultaneous confocal imaging and whole-cell recording revealed that time to onset of MeHg-induced increase in fluorescence in the molecular layer correlated with that of increased sEPSC and sIPSC frequency in Purkinje cells. Pretreatment with the intracellular Ca(2+) chelator 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid (BAPTA) significantly suppressed the MeHg-induced increase in sIPSC frequency, further suggesting that MeHg-induced elevation of [Ca(2+)](i) is partially responsible for its early stimulatory effects on spontaneous synaptic responses. However when spontaneous synaptic currents ceased with MeHg, Fluo-4 fluorescence remained elevated. Thus synaptic transmission cessation is apparently not related to changes in [Ca(2+)](i). It may result from effects of MeHg on transmitter release or sensitivity of postsynaptic receptors. The lack of effect of MeHg on Purkinje cell somal fluorescence reinforces that they are more resistant to MeHg-induced elevations of [Ca(2+)](i) than other cells, including cerebellar granule cells.

A new cytochemical method for ultrastructural localization of Co2+ in rat hippocampal CA1 pyramidal neurons in vitro

This paper describes new cytochemical method for the ultrastructural localization of Co(2+) following blockade of synaptic transmission. In the CA1 region of rat hippocampal slices, electrical stimulation of the Schaffer collaterals elicited field excitatory postsynaptic potentials (fEPSPs). The fEPSPs were completely blocked within 2 min after the addition of Co(2+) (2 mM). The slice was then fixed and precipitated Co(2+) was examined by means of a solution containing 2.5% glutaraldehyde and 10 mM K(3)[Fe(3+)(CN)(6)] in 90 mM NaCl. Electron spectroscopic imaging confirmed Co in the precipitate. The precipitates were found as clusters on the membranes of the fine apical dendrites and their spine heads of CA1 pyramidal neurons. No clustered precipitate was found when slices were treated: (1) without Co(2+); (2) after recovery from the Co(2+)-induced blockade of fEPSPs; (3) without electrical stimulation of the Schaffer collaterals; and (4) with dl-2-amino-5-phosphonopentanoate and 6-cyano-7-nitroquinoxaline-2,3-dione. After administrating glutamate (5 mM) in the presence of tetrodotoxin (1 microM) and Co(2+), precipitates were found on dendritic membranes and spine heads. These results indicate that the Schaffer collaterals stimulation induces the binding of Co(2+) on CA1 pyramidal neuron membrane.

Mitral cell presynaptic Ca(2+) influx and synaptic transmission in frog amygdala

Dextran-conjugated Ca(2+) indicators were injected into the accessory olfactory bulb of frogs in vivo to selectively fill presynaptic terminals of mitral cells at their termination in the ipsilateral amygdala. After one to three days of uptake and transport, the forebrain hemisphere anterior to the tectum was removed and maintained in vitro for simultaneous electrophysiological and optical measurements. Ca(2+) influx into these terminals was compared to synaptic transmission between mitral cells and amygdala neurons under conditions of reduced Ca(2+) influx resulting from reduced extracellular [Ca(2+)], blockade of N- and P/Q-type channels, and application of the cholinergic agonist carbachol. Reducing extracellular [Ca(2+)] had a non-linear effect on release; release was proportional to Ca(2+) influx raised to the power of approximately 3.6, as observed at numerous other synapses. The N-type Ca(2+) channel blocker, omega-conotoxin-GVIA (1 microM), blocked 77% of Ca(2+) influx and 88% of the postsynaptic field potential. The P/Q-type Ca(2+) channel blocker, omega-agatoxin-IVA (200 nM), blocked 19% of Ca(2+) influx and 25% of the postsynaptic field, while the two toxins combined to block 92% of Ca(2+) influx and 97% of the postsynaptic field. The relationship between toxin blockade of Ca(2+) influx and synaptic transmission was therefore only slightly non-linear; release was proportional to Ca(2+) influx raised to the power approximately 1.4. Carbachol (100 microM) acting via muscarinic receptors had no effect on the afferent volley, but rapidly and reversibly reduced Ca(2+) influx through both N- and P/Q-type channels by 51% and postsynaptic responses by 78%, i.e. release was proportional to Ca(2+) raised to the power approximately 2.5. The weak dependence of release on changes in Ca(2+) when channel toxins block channels suggests little overlap between Ca(2+) microdomains from channels supporting release or substantial segregation of channel subtypes between terminals. The proportionately greater reduction of transmission by muscarinic receptors compared to Ca(2+) channel toxins suggests that they directly affect the release machinery in addition to reducing Ca(2+) influx.

Age-related changes in the subtypes of voltage-dependent calcium channels in rat brain cortical synapses

Age-related changes in the relative contribution of voltage-dependent calcium channel (VDCC) subtypes to depolarization-induced Ca(2+) influx and in the density of VDCC subtypes in cortical synapses were investigated using synaptosomes and their membrane preparations from brain cortices of Wistar rats. The relative contribution of VDCC subtypes to Ca(2+) influx was determined by measuring the inhibition of depolarization-induced Ca(2+) influx with four VDCC subtype-specific peptide blockers. In adult rat synaptosomes, L-, N-, P- and Q-type channels accounted for 24, 32, 27 and 12% of the total Ca(2+) influx, respectively. Brain aging significantly reduced the relative contributions of N- and P-type channels and increased the contribution of the channels resistant to the four blockers used. The densities of VDCC subtypes, determined by binding experiments using radiolabeled PN200 -110, omega-conotoxin GVIA and omega-conotoxin MVIIC, were found to be significantly decreased in aged synaptic plasma membranes. On the contrary, the dissociation constants of the blockers were not changed except for PN200-110-sensitive L-type channels. These results suggest that aging alters the relative contributions of each VDCC subtype to depolarization-induced Ca(2+) influx and decreases the number of VDCCs in rat brain cortical synapses. These changes in VDCCs may lead to age-related hypofunction of synaptic neurotransmission in brain cortices.

Localized detection of action potential-induced presynaptic calcium transients at a Xenopus neuromuscular junction

1. Action potential (AP)-induced fluorescence transients were measured, using Ca2+ indicators and a spot-detection method, at single nerve terminals of a cultured Xenopus neuromuscular junction preparation with simultaneous measurement of neurotransmitter release. 2. Transients obtained using the low affinity Ca2+ indicator Oregon Green 488 BAPTA-5N (OGB-5N) exhibited rapid rising (t1/2 (time at which one-half of the peak fluorescence was attained) = 0.54 ms) and decaying (tau fast = 1.9 ms) phases. The higher affinity indicator Oregon Green 488 BAPTA-2 (OGB-2) produced transients with significantly slower kinetics (t1/2 = 2 ms; tau slow = 73 ms). 3. Tetanic stimulation elicited distinct increases in fluorescence in response to each AP. Each OGB-5N fluorescence increase was more rapid than those observed using OGB-2. Furthermore, a smaller proportion of residual fluorescence at the end of the train was observed using OGB-5N. 4. When OGB-5N was used, a significant [Ca2+] increase was observed prior to the release of neurotransmitter. This was not observed when OGB-2 was used. 5. We conclude that the use of localized optical detection coupled with low affinity Ca2+ indicators can help elucidate rapid changes in presynaptic [Ca2+] dynamics underlying evoked neurotransmitter release.

Presynaptic inhibition of elicited neurotransmitter release

Activation of presynaptic receptors for a variety of neurotransmitters and neuromodulators inhibits transmitter release at many synapses. Such presynaptic inhibition might serve as a means of adjusting synaptic strength or preventing excessive transmitter release, or both. Previous evidence showed that presynaptic modulators inhibit Ca2+ channels and activate K+ channels at neuronal somata. These modulators also inhibit spontaneous transmitter release by mechanisms downstream of Ca2+ entry. The relative contribution of the above mechanisms to the inhibition of elicited release has been debated for a long time. Recent evidence at synapses where the relationship between transmitter release and presynaptic Ca2+ influx has been well characterized suggests that inhibition of presynaptic voltage-dependent Ca2+ channels plays the major role in presynaptic inhibition of elicited neurotransmitter release. In addition, modulation of the release machinery might contribute to inhibition of elicited release.

Local Ca2+ release from internal stores controls exocytosis in pituitary gonadotrophs

Exocytosis and the cell-averaged cytosolic [Ca2+], [Ca2+]i, were tracked in single gonadotrophs. Cells released 100 granules/s at 1 microM = [Ca2+]i when gonadotropin-releasing hormone (GnRH) activated IP3-mediated Ca2+ release from internal stores, but only 1 granule/s when [Ca2+]i was raised uniformly to 1 microM by other means. Strong exocytosis was then seen only at higher [Ca2+]i (half-maximal at 16 microM). Parallel second messengers did not contribute to GnRH-induced exocytosis, because IP3 alone was as effective as GnRH, and because even GnRH failed to trigger rapid exocytosis when the [Ca2+]i rise was blunted by EGTA. When [Ca2+]i was released from stores, exocytosis depended on [Ca2+]i rising rapidly, as if governed by Ca2+ flux into the cytosol. We suggest that IP3 releases Ca2+ selectively from subsurface cisternae, raising [Ca2+] near exocytic sites 5-fold above the cell average.

Adaptation of Ca(2+)-triggered exocytosis in presynaptic terminals

Rapid increases in Ca2+ concentration, produced by photolysis of caged Ca2+, triggered exocytosis in squid nerve terminals. This exocytosis was transient in nature, decaying with a time constant of approximately 30 ms. The decay could not be explained by a decline in presynaptic Ca2+ concentration, depletion of synaptic vesicles, or desensitization of postsynaptic receptors. Experiments in which Ca2+ was increased either in a series of steps or continuously at different rates suggested that the decay is caused by adaptation of the exocytotic Ca2+ receptor to higher levels of Ca2+. This adjustable sensitivity to Ca2+ represents a novel property of the triggering mechanism that can be used to evaluate molecular models of exocytosis. Adaptation can limit the amount of transmitter released by a nerve terminal and permit the speed of a presynaptic Ca2+ rise to serve as a critical determinant of synaptic efficacy.

Modulation of cholinergic synaptic functions by sialylcholesterol

The effects of sialylcholesterol, a synthetic ganglioside analogue, on cholinergic synaptic functions were investigated using synaptosomes prepared from C57BL/6 mouse brain cortices. Addition of alpha-sialylcholesterol stimulated high K (50 mM)-evoked acetylcholine (ACh) release from synaptosomes at concentrations ranging from 1 to 5 microM. The beta-anomer of the sialyl compound also increased the neurotransmitter release at 5 microM, but the effect was much smaller than that of the alpha-anomer. Beta-sialylcholesterol appeared to increase high-affinity choline uptake and Ach synthesis, resulting in an increment in the release of ACh. On the other hand, alpha-sialylcholesterol did not change the synthetic rate of ACh, and instead it increased the depolarization=induced influx of calcium ions into synaptosomes, while the beta-anomer did not affect the divalent cation influx. The enhanced calcium influx is thought to increase ACh release from synaptosomes treated with alpha-sialylcholesterol. These results imply that the two anomers of sialylcholesterol may modulate the synaptic membrane machinery differently, that is, the alpha-anomer may activate voltage-dependent calcium channels and the beta-anomer may facilitate high-affinity choline uptake. In order to evaluate the ameliorating effect of sialylcholesterol, alpha-sialylcholesterol was applied to the synaptosomes from aged mice (34 months old), which have been shown to have a decreased ACh release (Tanaka et al., 1995, J Neurosci Res, in press [1]). The reduced neurotransmitter release recovered to the levels of younger animals, suggesting that sialylcholesterol might have a potential therapeutic use for restoring synaptic function that occurs in aged brains.

Impaired synaptic functions with aging as characterized by decreased calcium influx and acetylcholine release

Age-related alterations of presynaptic functions were studied in terms of acetylcholine (ACh) synthesis and release using synaptosomes isolated from mouse brain cortices. The following three findings were obtained: 1) Choline acetyltransferase activity and ACh production rate remained constant throughout all ages tested. This observation, obtained with synaptosomes, was not consistent with data reported for brain slices (Gibson GE, Peterson C: J Neurochem 37:978-984, 1981). Various conditions, such as low glucose or membrane depolarization, modulated ACh synthesis to similar extents in young and aged synaptosomes. 2) Depolarization-induced release of ACh from synaptosomes significantly decreased in the senescent stage. The fraction of ACh released from aged synaptosomes was less than that released from young synaptosomes, although the ACh contents in the synaptosomes did not change with age. 3) Calcium influx induced by depolarization was lower in the synaptosomal preparations from aged mice than in those from young mice. A strong positive correlation was observed between the amounts of ACh released and the increased calcium levels when the data for all preparations, both from young and aged mice, were plotted. This indicates that diminished calcium influx may cause the reduced ACh release by aged synapses. The present study provides evidence for an age-related decrease in presynaptic functions, that is, a reduction in calcium influx via voltage-dependent calcium channels followed by a decreased ACh release from synapses despite an abundance of ACh within the synapses.

Intracellular calcium and vasopressin release of rat isolated neurohypophysial nerve endings

1. Monitoring of [Ca2+]i and vasopressin secretion in isolated nerve endings from the rat neurohypophysis were studied to determine the relationship between the time course of vasopressin secretion and depolarization-induced changes in [Ca2+]i. 2. Membrane depolarization by increasing the extracellular [K+] led to concentration-dependent, parallel increases in the amount of vasopressin release and in peak increases in [Ca2+]i. Half-maximal activation of a change in [Ca2+]i was attained at 40 mM extracellular K+. 3. The Ca2+ chelator dimethyl-BAPTA (1,2-bis(O-aminophenoxy)ethane-N,N,N'N'-tetraacetic acid), loaded into the nerve endings, reduced K+ depolarization-evoked vasopressin release and efficiently antagonized K(+)-induced changes in [Ca2+]i. Moreover, dimethyl-BAPTA dramatically reduced basal [Ca2+]i without a reduction in basal secretion. 4. The duration of the vasopressin secretory response was similar regardless of applied 50 mM K+ depolarizations longer than 30 s. The t1/2 of the secretory response was 45 s. Application of repetitive K+ depolarization pulses repetitive secretory responses of similar amplitude and duration. 5. The K(+)-induced changes in [Ca2+]i remained elevated throughout the duration of the depolarizing stimulus decreasing less than 30% over 3 min. The sustained increase in [Ca2+]i resulted largely from continued enhanced Ca2+ influx, demonstrated by susceptibility to the dihydropyridine, L-type calcium channel blocker, nicardipine. 6. Vasopressin secretion could be reinitiated following its decline to a step K+ depolarization by a further step increase in K+ or by removal and readdition of extracellular [Ca2+]. Alterations in [Ca2+]i paralleled periods of secretory activity. 7. Analysis of secretory responsiveness and change in [Ca2+]i to K+ depolarization in medium of altered extracellular [Ca2+] indicates that [Ca2+]i of 20 microM is sufficient to trigger vasopressin release. K(+)-induced alterations in [Ca2+]i could be observed at [Ca2+]o as low as 5 microM. Although smaller in amplitude to that observed at 2.2 mM [Ca2+]o the duration of the K(+)-induced secretory response increased at lower [Ca2+]o. 8. Transient vasopressin secretory responses were observed to sustained levels of [Ca2+] in digitonin and streptolysin-O-permeabilized nerve endings. Secretion could be re-evoked, following its decline, by a step increase in [Ca2+] or by removal and readdition of [Ca2+]o.(ABSTRACT TRUNCATED AT 400 WORDS)

Effects of depolarizing agents on transglutaminase activity, Ca2+ influx, and protein synthesis in superior cervical and nodose ganglia excised from rats

Rapid changes in transglutaminase (TG) activity, 45Ca(2+)-influx and [3H]leucine incorporation in superior cervical ganglia (SCG), and nodose ganglia (NG) excised from adult rats were examined following addition of membrane-depolarizing agents veratridine (Ver) or high extracellular [K+]o during aerobic incubation in vitro at 37 degrees C. Addition of KCl (50 mM) stimulated TG activity to a maximal extent (four to six-fold) in SCG and NG after 30 min. Ver (0.2 mM) also increased TG activity in both ganglia after 30 min. Kinetic studies showed that the stimulation of TG activity in both ganglia caused by each depolarization condition was associated with a decrease in Km and an increase in Vmax value. The depolarizing agents Ver and high [K+]o also caused significant increases in 45Ca2+ influx into both ganglia. The Ver-induced increases in TG activity and 45Ca2+ accumulation were antagonized by tetrodotoxin (TTX, 1 microM), a sodium channel blocker. The K(+)-induced increase in TG activity was not blocked by tetraethylammonium (TEA, 20 mM), a potassium channel antagonist, although TEA did block the K(+)-induced increase in 45Ca2+ accumulation. The membrane-perturbing, sialic acid-containing compounds, GM1-ganglioside (GM1, 5 nM) and alpha-sialyl cholesterol (alpha-SC, 20 microM), were moderate inhibitors of the K(+)-induced effects on TG activity and 45Ca2+ accumulation. The sialyl compounds had little effect on Ver-induced accumulation of 45Ca2+ but enhanced the Ver-evoked stimulation in TG activity. These results suggests that the veratridine- and K(+)-induced increases in TG activity occur via modulation of Ca2+ and Na+ channel gating mechanisms that are pharmacologically distinct for each depolarizing agent. The veratridine- and K(+)-induced decrease in [3H]leucine incorporation could be a result of stimulation of TG activity as a consequence of degenerative alterations.

Characterization of constitutive exocytosis in the yeast Saccharomyces cerevisiae

Constitutive exocytosis was investigated in the yeast Saccharomyces cerevisiae using temperature-sensitive mutant (sec) strains which do not allow vesicle fusion to the plasma membrane at the restrictive temperature. Secretory vesicles were accumulated in the cell at the restrictive temperature and then protein synthesis was blocked with cycloheximide. Upon returning the cells to the permissive temperature the contents of the accumulated vesicles were secreted. This allowed the study of constitutive exocytosis independent of the processes responsible for vesicular biosynthesis. Neither the kinetics nor magnitude of exocytosis were affected by removal of external Ca2+ or perturbations of cytosolic Ca2+. This suggests that in those systems where calcium is required for exocytosis it is a regulatory molecule and not part of the mechanism of membrane fusion. Release occurred over a very broad range of pH and in media with different ionic compositions, suggesting that ionic and potential gradients across the plasma membrane play no role in exocytosis in yeast. High osmolarity inhibited the rate, but not the extent, of release. A novel inhibitory effect of azide was detected which occurred only at low pH. Vanadate also inhibited release in a pH-independent manner. Secretion occurred at the same rate in cells with or without accumulated vesicles. This infers a rate-limiting step following vesicle accumulation, perhaps a limiting number of release sites on the plasma membrane.

Intracellular and extracellular changes of [Ca2+] in hypoxia and ischemia in rat brain in vivo

Changes in intra- and extracellular free calcium concentration were evaluated with ion-selective microelectrodes during periods of anoxia and ischemia in three different regions of intact rat brain. Recordings stable for at least 2 min and in most cases for 4-6 min were chosen for analysis. Under normoxic conditions neuronal [Ca2+]i varied between less than 10(-8) and 10(-7) M from cell to cell but no systematic regional differences were observed. Elimination of O2 or interruption in blood flow caused, within 30-60 s, slight intracellular alkalinization followed by a small rise in [Ca2+]i, a mild degree of hyperpolarization, and disappearance of electrical activity in the cortex, in that order. It is postulated that a decline in cellular energy levels, as manifested by H+ uptake associated with creatine phosphate hydrolysis, leads to an increase in [Ca2+]i, which activates Ca2(+)-dependent K+ channels and consequently enhances gK. 2-4 min later there was a sudden, large rise in [K+]e, a fall in [Ca2+]e and a rapid elevation of [Ca2+]i. The magnitude of the latter was greatest in a high proportion of hippocampal neurons in area CA1 and some cortical cells, while it was smallest and relatively delayed in thalamic neurons. In the hippocampus area CA1 increases in [Ca2+]i to as much as 6-8 x 10(-4) were observed; some of these could be reversed when O2 or blood flow were restored to normal. Pretreatment of animals with ketamine and MK-801, antagonists of excitatory amino acid transmitters, markedly slowed and decreased the rises in [Ca2+]i. The effects of the two agents were most pronounced in the hippocampus. It is concluded that the receptor-operated channels are largely responsible for Ca2+ entry into certain cells during hypoxia/ischemia. This pathway may be of primary importance in parts of the hippocampus and cortex, regions of the brain that are particularly vulnerable to O2 deprivation and which receive high glutamatergic input and have an abundance of excitatory amino acid receptors.

Calcium dependence of quantal release triggered by graded depolarization pulses to nerve terminals on crayfish and frog muscle

Quantal transmitter release was measured in small portions of neuromuscular junctions by means of a perfused macro-patch-clamp electrode. Release was elicited by graded current pulses through the recording electrode (excitation blocked by TTX). On increasing the stimulation current from a threshold amplitude, release rose steeply for several orders of magnitude and finally approached a saturation level of about 10 quanta/pulse. Reduction of the Ca concentration in the perfusate of the electrode, Cae, depressed the saturation level of release relatively little and had practically no effect on the threshold current amplitude, as long as the Ca concentration in the superfusion of the bath, Cab, remained high. When Cab was reduced too, the depression of release was more severe. The dependence of release on Cae was determined for a large range of Cae for saturating depolarization pulses. In crayfish, at 0 Cab, in double-logarithmic release-Cae plots the maximum slope was on average 3.9, and this slope dropped to on average 2.1 in 13.5 mM Cab. In frog, at 0 Cab, the respective double-logarithmic slope was 3.5, while in 1.8 mM Cab this slope declined dramatically, the rate of release decreasing on average only by a factor of 3.8 from 10 mM to 0.02 mM Cae. These results are interpreted by the assumption that the resting Ca concentration in the terminal, Cair, has strong influence on the rate of release due to depolarization pulses in low Cae, and that Cab has control on Cair in the terminal.

Alpha-adrenergic inhibition of sympathetic neurotransmitter release mediated by modulation of N-type calcium-channel gating

In sympathetic neurons, catecholamines interact with prejunctional alpha-adrenergic receptors to reduce delivery of transmitter to postjunctional target organs. This autoinhibitory feedback is a general phenomenon seen in diverse neurons containing a variety of transmitters. The underlying mechanisms of alpha-adrenergic inhibition are not clear, although decreases in cyclic AMP and cAMP-mediated phosphorylation have been implicated. We have studied depolarization-induced catecholamine release and calcium-channel currents in frog sympathetic neurons. Here we show that alpha-adrenergic inhibition of transmitter release can be explained by inhibition of Ca2+-channel currents and not by modulation of intracellular proteins. Noradrenaline strongly reduces the activity of N-type Ca2+ channels, the dominant calcium entry pathway triggering sympathetic transmitter release, whereas L-type Ca2+ channels are not significantly inhibited. The down-modulation of N-type channels involves changes in rapid gating kinetics but not in unitary flux. This is the first detailed description of inhibition of a high-voltage activated neuronal Ca2+ channel at the single-channel level. The coupling between alpha-adrenergic receptors and N-type channels involves a G protein, but not a readily diffusible cytoplasmic messenger or protein kinase C, and may be well suited for rapid and spatially localized feedback-control of transmitter release.

ATP-dependent directional movement of rat synaptic vesicles injected into the presynaptic terminal of squid giant synapse

The question as to whether synaptic vesicles prepared from vertebrate brain can be transported to the active zones of the squid giant synapse was studied by using a combined optical and electrophysiological approach. In order to visualize the behavior of the vertebrate synaptic vesicles in situ, synaptic vesicles isolated from rat brain were labeled with a fluorescent dye (Texas red) and injected into the presynaptic terminal of the squid giant synapse. The pattern of fluorescence that would result from passive diffusion was determined by coinjection of an unconjugated fluorescent dye (fluorescein). The patterns obtained with fluorescent synaptic vesicles were strikingly different from that obtained by simple diffusion of fluorescein. Although the fluorescein diffused freely in both directions, the vesicles moved preferentially into the terminal--i.e., toward the release sites--at a rate of 0.5 microns/sec. The final distribution of the injected fluorescent synaptic vesicles displayed a discrete localization that suggested a distribution coincident with the active zones of the presynaptic terminal. Like fast axonal transport, but unlike fluorescein movements in the terminal, the vesicle movement was energy dependent, since the addition of 2,4-dinitrophenol blocked the redistribution of vesicles completely. In addition, reduction of extracellular calcium concentration reversibly blocked vesicular movement as well. In conclusion, mammalian synaptic vesicles retain the cytoplasmic surface components necessary for translocation, sorting, and targeting to the proper locations by the native machinery of the squid giant synapse.

Calcium and neuronal function

Calcium is unique among metals because its ions have a very large concentration gradient across the plasma membrane of all cells, from 10(-3) M Ca2+ outside, to 10(-7) M Ca2+ inside. This gradient is maintained by the use of metabolic energy through ion pumping, and its existence allows cells to use transient increases in the intracellular Ca2+ concentration as signals, which regulate cell function. In neurones these Ca signals are initiated by electrical activity (action potentials) which open voltage-dependent Ca channels in the plasma membrane, allowing Ca to enter the cell. Intracellular Ca signals can also be produced by transmitters at synapses, which open Ca channels, either directly, or indirectly by causing local depolarization and the opening of voltage-dependent Ca channels. The main effects of Ca signals on neurones are to alter their electrical activity, by modifying the opening and closing of Na and K channels, and to stimulate the release of transmitter substance. Ca has a host of other effects, such as the regulation of metabolic activity, the regulation of cell growth, and the long-term modification of synaptic efficiency, and it is even implicated in the destruction of neurones.

The effects of ethanol on the electrophysiology of calcium channels

Acute ethanol intoxication affects many systems in the body, especially the central nervous system. Because early experiments using axonal preparations required very high concentrations of ethanol to produce ionic current alterations, researchers turned their attention away from specific effects on electrogenesis and looked for effects at the synapse. The role of Ca2+ in the release of neurotransmitters was well known and was considered a possible site of action for ethanol. Indeed, several studies demonstrated that ethanol alters Ca2+ binding or transport in synaptosomes and neural tissue. The purpose of this chapter is to present electrophysiological evidence for the acute effects of ethanol on calcium channels. It is necessary first to define the relevant ethanol concentrations and to describe the characteristics of tissue preparations that may best help to determine the effects of ethanol. A discussion of these two points along with a brief synopsis of the role of Ca2+ in excitable tissues is presented. This is followed by a discussion of the effects of ethanol on Ca2+ and Ca2+-activated conductances in both nonmammalian and mammalian cells, and a model is presented in an attempt to unify the experimental evidence of the acute effects of ethanol.

Ethanol effects on voltage-dependent membrane conductances: comparative sensitivity of channel populations in Aplysia neurons

The study of ethanol (EtOH) action is interesting because of its clinical relevance and for the insights it provides into structure-function relationships of excitable membranes. This paper describes the concentration dependencies of various parameters of four currents in Aplysia cells. ICa is the most sensitive of the currents studied. There was a significant reduction of ICa at concentrations of 50 mM EtOH. At low concentrations, the reduction of amplitude was the primary effect of ethanol, with the kinetics and voltage dependency of activation not affected. INa and IA were also affected, but at EtOH levels higher than those which altered ICa. The primary effect of EtOH on INa was a reduction in its amplitude, although the time to peak current flow was increased by EtOH. The effects of EtOH on IA were cell specific and, for the purposes of this paper, we examined the giant metacerebral cell (MCC). In MCC, the primary effect of EtOH on IA was an increase in the time course of inactivation. The time to peak IA was also increased by high concentrations of EtOH, but its amplitude was unaffected even at high concentrations. The delayed rectifier current, IK, was the most EtOH resistant of the currents examined. High EtOH concentrations augmented the amplitude of IK, although even at 600 mM concentrations, the percentage change was only 30%. Our results indicate that the calcium channel is very susceptible to the influence of ethanol and is a serious candidate to be the primary target of EtOH action in the nervous system. The differential sensitivity of voltage-dependent currents and individual components of a given current suggests further experiments to probe the relationship between membrane structure and channel function in excitable membranes.

Arsenazo III transients and calcium current in a normally non-spiking neuronal soma of crayfish

Arsenazo III was used to investigate Ca2+ transients in the normally non-excitable soma of the motor giant neurones of the crayfish Procambarus clarkii. Two kinds of regenerative potentials could be obtained depending on membrane potential conditioning: a fast spike after a pre-hyperpolarization to -90 mV and a slow action potential after a pre-depolarization to -50 mV. Only the second of these was accompanied by an Arsenazo III transient. In voltage-clamped, somata injected, with tetraethylammonium chloride, an absorbance change could be obtained by pulsing the membrane potential above -44 mV. The relationship between absorbance change and potential peaked between 0 and +10 mV then fell off to zero at ca. +150 mV. Changes in light absorbance studied using double-pulse protocols suggested that the inactivation of Ca2+ entry was predominantly mediated by the intracellular free Ca2+ concentration. External application of 1 mM-CdCl2 abolished both the absorbance changes and the (Ca2+) inward current. The voltage dependence of this current was similar to that of the absorbance change. For positive membrane potential the current-voltage relationship showed a voltage-dependent conductance property, the origin of which is discussed.

Two different presynaptic calcium currents in mouse motor nerve terminals

Extracellular recordings of potential changes under the perineural sheath of nerve bundles close to some of the nerve terminals were performed using the M. triangularis sterni of the mouse. The nerve signals consisted of a predominant double-peaked negativity which was often preceded by a small positive deflection. While the first negative peak is related to the propagating nerve action potential, the second negative deflection can be attributed to a potassium conductance since it was selectively blocked by tetraethylammonium (TEA) or 3,4-diaminopyridine (3,4-DAP). Combined application of TEA and 3,4-DAP gave rise to a prolonged positive-going wave which was blocked by Cd2+, thus, indicating its underlying cause to be a Ca current. Ionophoretic application of TEA and Cd2+ to the endplates affected potassium and calcium components of the subendothelial signals, respectively, thus indicating their presynaptic origin. This finding is supported by the decrease of the amplitude of these components with increasing distance from the endplate region. Maximal effects on K conductance attainable with 3,4-DAP could still be potentiated by TEA, indicating the presence of at least two distinct sets of K channels. The prolonged positive potential induced by TEA and 3,4-DAP consisted of a fast and slow component, both of which can be attributed to Ca conductances with different characteristics. The fast positive signal component is attributed to the voltage-dependent Ca channel, responsible for the initiation of transmitter release. Its amplitude and duration depend on extracellular Ca2+ -concentration. The fast component is still present when Ca2+ is substituted by Sr2+ or Ba2+.(ABSTRACT TRUNCATED AT 250 WORDS)

Neurotransmitter release and its facilitation in crayfish. VII. Another voltage dependent process beside Ca entry controls the time course of phasic release

Quantal synaptic currents were recorded at nerve terminations on the opener muscle of crayfish using a macro-patch-clamp electrode, and the release was elicited by depolarizing current pulses applied to the terminal through the same electrode. After 2 ms depolarization pulses at low temperature, release started with about 2 ms delay after the onset of depolarization, and the maximum rate of release occurred at about 4 ms delay. Large variations in Ca inflow during the pulses were concluded from the facilitation of test EPSCs. The time course of release proved to be remarkably invariant in spite of large changes in release. If a conditioning train of depolarization pulses preceded the test pulse, release due to the test pulse was facilitated up to 60-fold, but the shapes of distributions of quantal delays were practically not affected by this facilitation. Facilitation by the conditioning trains must have raised the [Ca]i level at the onset of the test pulse. The invariance of the time course of release with respect to the level of [Ca]i cannot be explained by theories in which [Ca]i alone controls the time course of release. The time courses of reactions controlling release were explored by mathematical analysis and simulation. A reaction scheme in which the activation of "release sites" directly by depolarization had rate limiting control on the release reactions, in which rise of [Ca]i only was a promoting cofactor, and in which a cooperative reaction involving the complex of release sites and Cai, (SCai) was one of the final steps eliciting release, was able to predict the delayed onset of release and the substantial latency between the end of the depolarization pulse and the maximum of the rate of release. Reaction schemes in which the direct effect of depolarization on release occurred at one or more steps following the entry of Ca could be excluded generally by showing conflict with the experimental findings.

Binding of lanthanum ions and ruthenium red to synaptosomes and its effects on neurotransmitter release

A technique for studying the binding of La3+ to synaptosomes in a double-beam spectrophotometer, using murexide as indicator, is described. The binding of La3+ was very rapid and Scatchard plots revealed two components, with KD values of 0.6 and 27 microM in a Na+-free medium (sucrose medium) and 2.3 and 63 microM in an ionic medium containing 135 mM Na+. The binding of the cationic dye ruthenium red (RuR) showed only one site, with a KD of 3.7 microM. La3+ binding was partially inhibited by RuR and vice versa, and La3+ was also capable of partially displacing RuR previously bound to the synaptosomes, particularly in the sucrose medium. The release of labeled gamma-aminobutyric acid (GABA) stimulated by K+ depolarization was inhibited by La3+ concentrations at or above 1 microM, in the ionic medium, whereas in the sucrose medium 2.5 microM or higher La3+ concentrations notably stimulated the spontaneous release of both GABA and glutamic acid. It is concluded that La3+ and RuR share at least one type of binding site, which is probably the high-affinity La3+ site. Since both La3+ and RuR at low concentrations have been shown to block the depolarization-induced Ca2+ entry in synaptosomes, this site might be related to the voltage-dependent Ca2+ entry involved in neurotransmitter release.

Calcium entry into voltage-clamped presynaptic terminals of squid

Voltage-clamp measurements of Ca current and Arsenazo III measurements of intracellular Ca concentration were used to assess Ca ion entry into voltage-clamped presynaptic terminals of squid 'giant' synapses. Depolarization of voltage-clamped terminals filled with Arsenazo III produced absorbance changes consistent with intracellular accumulation of Ca ions. These intracellular Ca transients had a bell-shaped dependence on presynaptic potential and were maximal at approximately -10 mV. Arsenazo III signals recorded from the proximal portion of voltage-clamped presynaptic terminals had a dependence on command potential which was shifted relative to signals recorded from other presynaptic regions. Micro-electrode measurements of presynaptic membrane potential showed that during voltage-clamp depolarizations the proximal region was less depolarized than the rest of the presynaptic terminal. This indicates that voltage-clamped presynaptic terminals may be poorly controlled at their proximal region due to current flow into the adjacent axon. This poor control can cause heterogeneous Ca entry into the presynaptic terminal and thus heterogeneous release of transmitter along the terminal. Application of Ca ions from an extracellular pipette positioned near the distal end of the presynaptic terminal was used to restrict Ca entry to this well-controlled region. Local Ca application decreased the contribution of release from the poorly controlled proximal region to synaptic transfer curves. Presynaptic Ca currents were derived by correcting membrane currents for leakage and capacitive currents and other currents measured in the absence of Ca application. Ca currents measured in this way activated along a sigmoidal time course and did not inactivate for depolarizations as long as 25 ms. Peak Ca currents occurred at approximately -10 mV and inward Ca currents had an apparent 'reversal potential' near +60 mV. Ca channel activation, assessed with tail current measurements, was half-maximal at -13 mV and maximal at +20 mV. Simultaneous measurements of presynaptic Ca currents and Arsenazo III transients revealed a quantitative correspondence between Ca current integrals and Arsenazo III signal amplitude. This suggests that both methods provide reliable measures of Ca ion entry into presynaptic terminals under these conditions.

Local cytoplasmic calcium gradients in living mitotic cells

Cytoplasmic free calcium has been proposed as a regulator of many microtubule-mediated processes, including mitosis. It has been difficult to test this hypothesis because methods for local measurement of free Ca2+ in the living cell have not been available. We have used the fluorescent calcium indicator dye Quin-2 (methoxyquinoline-1bis(o-aminophenoxy)ethane-N,N,N',N' -tetra acetic acid), which allows such observations to be made by digital processing of fluorescent images from the light microscope. Here we report the application of this technique to the study of local Ca2+ concentrations in mitotic endosperm cells of Haemanthus sp., and show that there is transient increase in free Ca2+ at the mitotic spindle poles during anaphase. This locally high Ca2+ may provide a mechanism for the regional control of microtubules and other cytoskeletal elements during anaphase.

Dopaminergic modulation of neuromuscular transmission in the prawn

The action of the putative crustacean neurohormone dopamine was examined in the fast extensor musculature of the prawn with intracellular and extracellular recording techniques. Dopamine produced a concentration-dependent (10(-7)-10(-5) M) decrease in the size of the excitatory junctional potential (e.j.p.). It had no effect on the muscle fibre resting membrane potential or input resistance. High concentrations (10(-5)M) of dopamine had no effect on the amplitude distribution or decay time of quantal unit currents, indicating that the agent does not act by blocking post-synaptic receptors or channels. Bath application of dopamine reduced the quantal content at single release sites with a similar time course and concentration dependence as that observed for the e.j.p. Dopamine had no effect on histograms of synaptic delays determined over a 10 degree C range, indicating that it does not modify the time course of phasic neurosecretion. Twin-impulse facilitation experiments showed a marked decrease in the duration of facilitation in the presence of dopamine. These results are interpreted according to recent theoretical and experimental findings as indicating that the dopamine-induced reduction in transmitter release is produced by a decrease in the entry of Ca during the nerve terminal action potential.

The rate of diffusion of Ca2+ and Ba2+ in a nerve cell body

A spectrophotometric method was developed to directly measure the diffusion rate of Ca2+ and some other ions in nerve cell bodies, using pulsed ionophoretic injections and an optical microprobe to record locally absorbance changes of the dye arsenazo III. We report here that Ca2+ and Ba2+ diffuse at approximately the same rate in nerve soma cytoplasm, having effective diffusion coefficients in the range of 7-12 X 10(-7) cm2/s, while identical measurements conducted in an electrolytic solution yielded values of 5.2 X 10(-6) cm2/s for Ca and 5.4 X 10(-6) cm2/s for Ba. The results are discussed in relation to the mechanisms that regulate the intracellular concentration of free Ca.

Stimulation of [3H]gamma-aminobutyric acid release by calcium chelators in synaptosomes

The effect of EGTA on the release of labeled gamma-aminobutyric acid (GABA), glutamate, acetylcholine, and dopamine was studied in superfused synaptosomes from mouse brain. In the absence of both Ca2+ and Mg2+, EGTA and also EDTA at 50 microM or higher concentrations induced a 2.5-5-fold stimulation of [3H]GABA release, similar to that produced by potassium depolarization, whereas only a slight effect, or no effect at all, was observed on the release of the other transmitters studied. The GABA-releasing action of EGTA was practically abolished in the presence of Mg2+. In contrast, the effect of EDTA was also observed when the medium contained Mg2+. Studies on the ionic dependence showed that the stimulation of GABA release by EGTA was abolished in a Na+-free medium. Li+ did not substitute Na+ for the EGTA effect, which was also independent of chloride. This Na+ dependence does not seem to involve voltage-sensitive channels, since tetrodotoxin did not affect the GABA-releasing action of EGTA, whereas in parallel superfusion chambers it blocked over 80% the stimulation of GABA release by veratridine. In contrast, two calcium channel blockers in synaptosomes, La3+ and the cationic dye ruthenium red, greatly inhibited the GABA-releasing effect of EGTA. L-2,4-Diaminobutyric acid, an inhibitor of the Na+-dependent GABA carrier, did not affect the releasing action of EGTA, whereas in a parallel experiment this drug inhibited by more than 90% the exchange of labeled GABA with unlabeled GABA.(ABSTRACT TRUNCATED AT 250 WORDS)

Phosphodiesterase activities for cyclic nucleotides in nerve endings from the bovine posterior pituitary gland

The cyclic nucleotide phosphodiesterase (PDE) activities were studied in a nerve ending fraction from bovine neural lobes. Most of the activity was particulate and unaffected by calcium. Lineweaver-Burk plots for this fraction showed negative cooperativity with apparent Km values for cyclic AMP of 11 microM and for cyclic GMP of 4 microM. The soluble activities for both cyclic nucleotides were activated by calcium and inhibited by calmodulin-binding drugs (trifluoperazine and calmidazolium). The apparent Km values were 50 microM for cyclic AMP and 20 microM for cyclic GMP for the soluble activities. Sucrose density gradients resolved the soluble activities into two peaks. The activity with the higher sedimentation rate (MW 122,000 daltons) hydrolysed both cyclic nucleotides and was calcium-calmodulin-dependent. The other peak (MW 47,000 daltons) had a higher affinity for cyclic AMP than for cyclic GMP and was calcium-independent. Solubilized particulate activities gave two main peaks on the density gradient, both calcium-independent. One was mainly for cyclic AMP (MW 47,000 daltons) and the other mainly for cyclic GMP (MW 133,000 daltons). The function of PDEs in relation to secretion was discussed.