Calcium dependence of exocytosis and endocytosis at the cochlear inner hair cell afferent synapse

Release of neurotransmitter at the inner hair cell (IHC) afferent synapse is a fundamental step in translating sound into auditory nerve excitation. To study the Ca2+ dependence of the underlying vesicle fusion and subsequent endocytosis, we combined Ca2+ uncaging with membrane capacitance measurements in mouse IHCs. Rapid elevations in [Ca2+]i above 8 microM caused a biphasic capacitance increase corresponding to the fusion of approximately 40,000 vesicles. The kinetics of exocytosis displayed a fifth-order Ca2+ dependence reaching maximal rates of >3 x 10(7) vesicle/s. Exocytosis was always followed by slow, compensatory endocytosis (tau congruent with 15 s). Higher [Ca2+]i increased the contribution of a faster mode of endocytosis with a Ca2+ independent time constant of approximately 300 ms. These properties provide for rapid and sustained transmitter release from this large presynaptic terminal.     

Negative regulation of neurotransmitter release by calpain: a possible involvement of specific SNAP-25 cleavage

Synaptic transmission is conducted by neurotransmitters released from presynaptic nerve terminals by means of Ca2+-dependent exocytosis of synaptic vesicles. Formation of a complex of soluble N-ethylmaleimide-sensitive fusion protein receptor (SNARE) proteins, including vesicle-associated membrane protein-2 (VAMP-2) in the synaptic vesicle membrane, and syntaxin 1 and synaptosomal-associated protein of 25 kDa (SNAP-25) in the plasma membrane, is essential for exocytosis. Ionomycin treatment of cultured rat cerebellar granule cells led to cleavage of SNAP-25, but not syntaxin 1 and VAMP-2, that was dependent on extracellular Ca2+. Cleavage was also induced by N-methyl-D-aspartate (NMDA) treatment, but not by depolarization. The use of various site-specific antibodies to SNAP-25, suggested that the cleavage site was in the N-terminal domain of SNAP-25. Calpain inhibitors abolished the Ca2+-dependent cleavage of SNAP-25 and markedly facilitated Ca2+-dependent glutamate (Glu) release from cerebellar granule cells. These results suggest that calpain may play an important role in the long-lasting regulation of synaptic transmission by suppressing neurotransmitter release, possibly through the proteolytic cleavage of SNAP-25.     

Neurotransmitter release at ribbon synapses in the retina

The synapses of photoreceptors and bipolar cells in the retina are easily identified ultrastructurally by the presence of synaptic ribbons, electron-dense bars perpendicular to the plasma membrane at the active zones, extending about 0.5 microm into the cytoplasm. The neurotransmitter, glutamate, is released continuously (tonically) from these 'ribbon synapses' and the rate of release is modulated in response to graded changes in the membrane potential. This contrasts with action potential-driven bursts of release at conventional synapses. Similar to other synapses, neurotransmitter is released at ribbon synapses by the calcium-dependent exocytosis of synaptic vesicles. Most components of the molecular machinery governing transmitter release are conserved between ribbon and conventional synapses, but a few differences have been identified that may be important determinants of tonic transmitter release. For example, the presynaptic calcium channels of bipolar cells and photoreceptors are different from those elsewhere in the brain. Differences have also been found in the proteins involved in synaptic vesicle recruitment to the active zone and in synaptic vesicle fusion. These differences and others are discussed in terms of their implications for neurotransmitter release from photoreceptors and bipolar cells in the retina.     

Role of residual calcium in synaptic depression and posttetanic potentiation: fast and slow calcium signaling in nerve terminals.

Trains of action potentials evoked rises in presynaptic Ca2+ concentration ([Ca2+]i) at the squid giant synapse. These increases in [Ca2+]i were spatially nonuniform during the trains, but rapidly equilibrated after the trains and slowly declined over hundreds of seconds. The trains also elicited synaptic depression and augmentation, both of which developed during stimulation and declined within a few seconds afterward. Microinjection of the Ca2+ buffer EGTA into presynaptic terminals had no effect on transmitter release or synaptic depression. However, EGTA injection effectively blocked both the persistent Ca2+ signals and augmentation. These results suggest that transmitter release is triggered by a large, brief, and sharply localized rise in [Ca2+]i, while augmentation is produced by a smaller, slower, and more diffuse rise in [Ca2+]i.     

In vitro binding of isolated synaptic vesicles to presynaptic plasma membranes: activation by Ca2+ and protein kinase C.

An in vitro model to study the molecular control of binding of highly purified synaptic vesicles to presynaptic plasma membranes has been developed. Presynaptic plasma membranes were immobilized by dotting onto nitrocellulose, and binding of iodinated synaptic vesicle membranes was studied under varying experimental conditions. Synaptic vesicles bind to presynaptic plasma membranes in the presence of Ca2+ and ATP. Binding is reduced in the presence of EGTA and abolished by the calmodulin antagonist trifluoperazine. Vesicle binding is stimulated 5-fold after incubation--prior to dotting--of presynaptic plasma membranes with ATP in the presence of the phorbol-ester 12-O-tetradecanoylphorbol-13-acetate (1 microM) and 2.5-fold after preincubation with Ca2+ (50 microM). Pretreatment of plasma membranes with alkaline phosphatase strongly reduces vesicle binding. Microsomes prepared from bovine liver did not bind to presynaptic plasma membranes. Our results suggest that activation of protein kinase C and Ca2+ stimulate binding of synaptic vesicles to the presynaptic membrane. In the intact nerve terminal this interaction may represent an initial step in synaptic vesicle exocytosis.     

Roles of Na(+)-Ca2+ exchange and of mitochondria in the regulation of presynaptic Ca2+ and spontaneous glutamate release

The release of neurotransmitter from presynaptic terminals depends on an increase in the intracellular Ca2+ concentration ([Ca2+]i). In addition to the opening of presynaptic Ca2+ channels during excitation, other Ca2+ transport systems may be involved in changes in [Ca2+]i. We have studied the regulation of [Ca2+]i in nerve terminals of hippocampal cells in culture by the Na(+)-Ca2+ exchanger and by mitochondria. In addition, we have measured changes in the frequency of spontaneous excitatory postsynaptic currents (sEPSC) before and after the inhibition of the exchanger and of mitochondrial metabolism. We found rather heterogeneous [Ca2+]i responses of individual presynaptic terminals after inhibition of Na(+)-Ca2+ exchange. The increase in [Ca2+]i became more uniform and much larger after additional treatment of the cells with mitochondrial inhibitors. Correspondingly, sEPSC frequencies changed very little when only Na(+)-Ca2+ exchange was inhibited, but increased dramatically after additional inhibition of mitochondria. Our results provide evidence for prominent roles of Na(+)-Ca2+ exchange and mitochondria in presynaptic Ca2+ regulation and spontaneous glutamate release.     

A metabotropic glutamate receptor regulates transmitter release from cone presynaptic terminals in carp retinal slices.

The role of group III metabotropic glutamate receptors (mGluRs) in photoreceptor-H1 horizontal cell (HC) synaptic transmission was investigated by analyzing the rate of occurrence and amplitude of spontaneous excitatory postsynaptic currents (sEPSCs) in H1 HCs uncoupled by dopamine in carp retinal slices. Red light steps or the application of 100 microM cobalt reduced the sEPSC rate without affecting their peak amplitude, which is consistent with hyperpolarization or the suppression of Ca(2+) entry into cone synaptic terminals reducing vesicular transmitter release. Conversely, postsynaptic blockade of H1 HC AMPA receptors by 500 nM CNQX reduced the amplitude of sEPSCs without affecting their rate. This analysis of sEPSCs represents a novel methodology for distinguishing between presynaptic and postsynaptic sites of action. The selective agonist for group III mGluRs, l-2-amino-4-phosphonobutyrate (L-APB or L-AP4; 20 microM), reduced the sEPSC rate with a slight reduction in amplitude, which is consistent with a presynaptic action on cone synaptic terminals to reduce transmitter release. During L-APB application, recovery of sEPSC rate occurred with 500 microM (s)-2-methyl-2-amino-4-phosphonobutyrate (MAP4), a selective antagonist of group III mGluR, and with 200 microM 4-aminopyridine (4-AP), a blocker of voltage-dependent potassium channels. Whole-cell recordings from cones in the retinal slice showed no effect of L-APB on voltage-activated Ca(2+) conductance. These results suggest that the activation of group III mGluRs suppresses transmitter release from cone presynaptic terminals via a 4-AP-sensitive pathway. Negative feedback, operating via mGluR autoreceptors, may limit excessive glutamate release from cone synaptic terminals.     

Calcium influx and mitochondrial alterations at synapses exposed to snake neurotoxins or their phospholipid hydrolysis products

Snake presynaptic phospholipase A2 neurotoxins (SPANs) bind to the presynaptic membrane and hydrolyze phosphatidylcholine with generation of lysophosphatidylcholine (LysoPC) and fatty acid (FA). The LysoPC+FA mixture promotes membrane fusion, inducing the exocytosis of the ready-to-release synaptic vesicles. However, also the reserve pool of synaptic vesicles disappears from nerve terminals intoxicated with SPAN or LysoPC+FA. Here, we show that LysoPC+FA and SPANs cause a large influx of extracellular calcium into swollen nerve terminals, which accounts for the extensive synaptic vesicle release. This is paralleled by the change of morphology and the collapse of membrane potential of mitochondria within nerve bulges. These results complete the picture of events occurring at nerve terminals intoxicated by SPANs and define the LysoPC+FA lipid mixture as a novel and effective agonist of synaptic vesicle release.     

Localized Ca2+ entry preferentially effects protein dephosphorylation, phosphorylation, and glutamate release.

The release of neurotransmitter glutamate from isolated nerve terminals (synaptosomes) was found to be tightly coupled to the entry of Ca2+ through voltage-dependent Ca2+ channels, but is relatively unresponsive to "bulk" increases in cytosolic Ca2+ concentrations ([Ca2+]c) effected by Ca2+ ionophore. Under the same conditions, this dependence on Ca2+ influx, specifically through Ca2+ channels, was also seen for the dephosphorylation of a 96-kDa protein, (P96), present in the nerve terminals, as well as the phosphorylation of proteins migrating at 75 kDa (P75), corresponding to the synapsins, a group of well characterized synaptic vesicle-associated proteins. P96 dephosphorylation, following Ca2+ influx, was persistent and insensitive to the phosphatase inhibitor okadaic acid, suggesting a phosphatase other than protein phosphatase 1 and 2A as being responsible. Perhaps through the same phosphatase activity the increase in P75 phosphorylation was rapidly reversed with a time course similar to P96 dephosphorylation. When release, P96 dephosphorylation, and P75 phosphorylation were considered as functions of the [Ca2+]c increases achieved by depolarization and Ca2+ ionophore, there was no correlation of any of these with the overall concentration of Ca2+ in the cytosol. Since the fura-2 method used to measure [Ca2+] gives an averaged [Ca2+]c, these results imply that the release and protein dephosphorylation events are functionally coupled to local [Ca2+]c, in the immediate vicinity of Ca2+ channels. The reported clustering of the latter at the active zone area of the synapse and the parallelism between synaptic vesicle exocytosis and the phosphorylation of synaptic vesicle-associated proteins (p75:synapsins Ia/Ib), suggests that P96 may be similarly localized at the active zone area and, therefore, may be of significance in a modulatory role in glutamate release.     

Bassoon and the synaptic ribbon organize Ca²+ channels and vesicles to add release sites and promote refilling

At the presynaptic active zone, Ca2+ influx triggers fusion of synaptic vesicles. It is not well understood how Ca2+ channel clustering and synaptic vesicle docking are organized. Here, we studied structure and function of hair cell ribbon synapses following genetic disruption of the presynaptic scaffold protein Bassoon. Mutant synapses--mostly lacking the ribbon--showed a reduction in membrane-proximal vesicles, with ribbonless synapses affected more than ribbon-occupied synapses. Ca2+ channels were also fewer at mutant synapses and appeared in abnormally shaped clusters. Ribbon absence reduced Ca2+ channel numbers at mutant and wild-type synapses. Fast and sustained exocytosis was reduced, notwithstanding normal coupling of the remaining Ca2+ channels to exocytosis. In vitro recordings revealed a slight impairment of vesicle replenishment. Mechanistic modeling of the in vivo data independently supported morphological and functional in vitro findings. We conclude that Bassoon and the ribbon (1) create a large number of release sites by organizing Ca2+ channels and vesicles, and (2) promote vesicle replenishment.     

Depolarization, intracellular calcium and exocytosis in single vertebrate nerve endings.

We have investigated the temporal relationship between depolarization, elevation of [Ca2+]i and exocytosis in single vertebrate neuroendocrine nerve terminals. The change of [Ca2+]i and vasopressin release were measured with a time resolution of less than 1 s in response to K(+)-induced depolarization. Exocytosis was also monitored in the whole-terminal patch-clamp configuration by time resolved capacitance measurements while [Ca2+]i was simultaneously followed by fura-2 fluorescence measurements. In intact as well as patch-clamped nerve terminals sustained depolarization leads to a sustained rise of [Ca2+]i. The rate of vasopressin release from intact nerve terminals rises in parallel with [Ca2+]i but then declines rapidly towards basal (t1/2 approximately 15 s) despite the maintained high [Ca2+]i indicating that only a limited number of exocytotic vesicles can be released. We demonstrate that in nerve terminals exocytosis can be followed during step depolarization by capacitance measurements. The capacitance increase starts instantaneously whereas [Ca2+]i rises with a half time of several hundred milliseconds. An instantaneous steep capacitance increase is followed by a slow increase with a slope of 25-50 fF/s indicating the sequential fusion of predocked and cytoplasmic vesicles. During depolarization the capacitance slope declines to zero with a similar time course as the vasopressin release indicating a decrease in exocytotic activity. Depolarization per se in the absence of a sufficient rise of [Ca2+]i does not induce exocytosis but elevation of [Ca2+]i in the absence of depolarization is as effective as in its presence. The experiments suggest that a rapid rise of [Ca2+]i in a narrow region beneath the plasma membrane induces a burst of exocytotic activity preceding the elevation of bulk [Ca2+]i in the whole nerve terminal.     

Vesicle cycle in the presynaptic nerve terminal

Presynaptic nerve terminals contain a great number ofsynaptic vesicles filled with neurotransmitter. The transmission of information in synapses is mediated by release of transmitter from vesicles: exocytosis, after their fusion with presynaptic membrane. At the functioning synapses, the continuous recycling of synaptic vesicles occurs (vesicle cycle), which provides multiple reuse of vesicular membrane material during synaptic activity. Vesicle cycle consists of large number of steps, including vesicle fusion--exocytosis, formation of new vesicles--endocytosis, vesicle sorting, filling of vesicles with transmitter, intraterminal vesicle transport driving the vesicles to different vesicle pools and preparing to next exocytic event. At this paper, I presented the latest literature and our data regarding the steps and mechanisms of vesicle cycle at synapses. Special attention was paid to neuromuscular synapse as the most thoroughly investigated and as my favorite preparation.     

Heterogeneity of the Ca2+ sensitivity of secretion in a pituitary gonadotrope cell line and its modulation by protein kinase C and Ca2+

Modulation of the Ca2+ sensitivity and cooperativity of secretion is an important means of regulating neurotransmission and hormone secretion. Employing high-time resolution measurement of membrane capacitance (Cm) stimulated by step-like or ramp [Ca2+]i elevation, we have identified the co-existence of both a high and low Ca2+-sensitive exocytosis in an immortal pituitary gonadotrope cell line, LbetaT2. Ramp [Ca2+]i generated by slow uncaging elicited a biphasic C(m) response. The first phase of response, which represents a highly Ca2+-sensitive pool (HCSP) of vesicles, began to secrete at low [Ca2+]i concentration (<1 microM) with low Ca2+ cooperativity. In contrast, the second phase, which represents a lowly Ca2+-sensitive pool (LCSP) of vesicles, only exocytozed at higher [Ca2+]i (>5 microM) and displayed a steep Ca2+ cooperativity. The co-existence of vesicle populations with different Ca2+ sensitivities was further confirmed by flash photolysis stimuli. The size of the HCSP was approximately 30 fF under resting conditions, but was dramatically increased (approximately threefold) by application of phorbol-12-myristate-13-acetate (PMA, an activator of protein kinase C). Forskolin (an activator of protein kinase A), however, exerted no significant effect on the size of both HCSP and LCSP. GnRH (gonadotropin releasing hormone) augmented the size of both pools to a larger extent (5- and 1.7-fold increase for HCSP and LCSP, respectively). The heterogeneity of Ca2+ sensitivity from different pools of vesicles and its differential modulation by intracellular signals suggests that LbetaT2 cells are an ideal model to further unravel the mechanism underlying the modulation of Ca2+-sensing machineries for exocytosis.     

Normal biogenesis and cycling of empty synaptic vesicles in dopamine neurons of vesicular monoamine transporter 2 knockout mice

The neuronal isoform of vesicular monoamine transporter, VMAT2, is responsible for packaging dopamine and other monoamines into synaptic vesicles and thereby plays an essential role in dopamine neurotransmission. Dopamine neurons in mice lacking VMAT2 are unable to store or release dopamine from their synaptic vesicles. To determine how VMAT2-mediated filling influences synaptic vesicle morphology and function, we examined dopamine terminals from VMAT2 knockout mice. In contrast to the abnormalities reported in glutamatergic terminals of mice lacking VGLUT1, the corresponding vesicular transporter for glutamate, we found that the ultrastructure of dopamine terminals and synaptic vesicles in VMAT2 knockout mice were indistinguishable from wild type. Using the activity-dependent dyes FM1-43 and FM2-10, we also found that synaptic vesicles in dopamine neurons lacking VMAT2 undergo endocytosis and exocytosis with kinetics identical to those seen in wild-type neurons. Together, these results demonstrate that dopamine synaptic vesicle biogenesis and cycling are independent of vesicle filling with transmitter. By demonstrating that such empty synaptic vesicles can cycle at the nerve terminal, our study suggests that physiological changes in VMAT2 levels or trafficking at the synapse may regulate dopamine release by altering the ratio of fillable-to-empty synaptic vesicles, as both continue to cycle in response to neural activity.     

Dissection of three Ca2+-dependent steps leading to secretion in chromaffin cells from mouse adrenal slices

In neurosecretory cells, intracellular Ca2+ ([Ca2+]i) not only acts as the trigger for secretion but also regulates earlier steps in the secretory pathway. Here, a novel approach was developed to control [Ca2+]i over a broad concentration range, which allowed the quantification of three distinct actions of [Ca2+]i on large dense-core vesicle (LDCV) fusion in chromaffin cells from mouse adrenal slices. Basal [Ca2+]i regulated the transfer of vesicles toward a slowly releasable state, whereas further maturation to the readily releasable state was Ca2+ independent. [Ca2+]i levels above 3 microM triggered exocytosis of all readily and slowly releasable vesicles in two parallel, kinetically distinct fusion reactions. In a molecular context, these results suggest that Ca2+ acts both before and after trans-SNARE complex formation to regulate fusion competence and fusion kinetics of LDCVs.     

Presynaptic actions of botulinal neurotoxins at vertebrate neuromuscular junctions

1. In the present paper we review some presynaptic aspects of the mode of action of botulinal toxins (BoTxs) at vertebrate neuromuscular junctions with emphasis on studies carried out in our laboratories using electrophysiological and morphological techniques. 2. Spontaneous quantal transmitter release recorded as miniature end-plate potentials is drastically affected by BoTxs. The low probability of release at poisoned terminals can be enhanced by carbonyl cyanide m-chlorophenylhydrazone (CCCP), Cd2+ and La3+. However, CCCP and La3+ which drastically deplete clear synaptic vesicles from unpoisoned terminals failed to markedly affect the density of synaptic vesicles at poisoned terminals. It is concluded that poisoned terminals have a reduced sensitivity to the release-promoting action of Ca2+, Cd2+ and La3+. 3. When comparing the effect of the various BoTxs on nerve-impulse evoked transmitter release it appears that increasing phasic Ca2+ entry into the terminals enhances evoked synchronized quantal release only from terminals poisoned with serotypes A and E. In contrast, enhanced Ca2+ entry into terminals poisoned with serotypes B, D and F induced a period of high frequency asynchronous release suggesting that these BoTxs may affect a presynaptic step beyond the influx of Ca2+, that may be involved in the synchronization of transmitter quanta. These data suggest that the actions of BoTxs involve several steps of the acetylcholine release process. 4. The analysis of presynaptic currents which depend on both Ca2+ entry and intraterminal background Ca2+ levels strongly suggests that neither Ca2+ entry nor intraterminal Ca2+ levels are altered by BoTxs. Furthermore, poisoned terminals are no more efficient than unpoisoned ones in dealing with Ca2+ overloads. 5. Finally, the morphological examination of junctions paralysed by BoTx-A indicates that the toxin triggers a particularly important overgrowth of the nerve terminals and suggests that the in vivo functional recovery may occur from an extension of the original nerve terminal arborization and the concomitant remodelling of postsynaptic structures.     

Synaptic vesicle recruitment for release explored by Monte Carlo stimulation at the crayfish neuromuscular junction

Neurotransmission at chemically transmitting synapses requires calcium-mediated fusion of synaptic vesicles with the presynaptic membrane. Utilizing ultrastructural information available for the crustacean excitatory neuromuscular junction, we developed a model that employs the Monte Carlo simulation technique to follow the entry and movement of Ca2+ ions at a presynaptic active zone, where synaptic vesicles are preferentially docked for release. The model includes interaction of Ca2+ with an intracellular buffer, and variable separation between calcium channels and vesicle-associated Ca(2+)-binding targets that react with Ca2+ to trigger vesicle fusion. The end point for vesicle recruitment for release was binding of four Ca2+ ions to the target controlling release. The results of the modeling experiments showed that intracellular structures that interfere with Ca2+ diffusion (in particular synaptic vesicles) influence recruitment or priming of vesicles for release. Vesicular recruitment is strongly influenced by the separation distance between an opened calcium channel and the target controlling release, and by the concentration and binding properties of the intracellular buffers, as in previous models. When a single opened calcium channel is very close to the target, a single synaptic vesicle can be recruited. However, many of the single-channel openings actuated by a nerve impulse are likely to be ineffective for release, although they contribute to the buildup of total intracellular Ca2+. Thus, the overall effectiveness of single calcium channels in causing vesicles to undergo exocytosis is likely quite low.     

Nitric oxide and cyclic GMP induce vesicle release at Drosophila neuromuscular junction.

Nitric oxide (NO) diffuses as short-lived messenger through the plasma membrane and serves, among many other functions, as an activator of the cGMP synthesizing enzyme soluble guanylyl cyclase (sGC). In view of recent genetic investigations that postulated a retrograde signal from the larval muscle fibers to the presynaptic terminals, we looked for the presence of an NO/cGMP signaling system at the neuromuscular junction (NMJ) of Drosophila melanogaster larvae. Application of NO donors induced cGMP immunoreactivity in the presynaptic terminals but not the postsynaptic muscle fibers at an identified NMJ. The NO-induced cGMP immunoreactivity was sensitive to a specific inhibitor (ODQ) of the sGC. Since presynaptic terminals which were surgically isolated from the central nervous system are capable of synthesizing cGMP, we suggest that an NO-sensitive guanylyl cyclase is present in the terminal arborizations. Using a fluorescent dye that is known to stain recycling synaptic vesicles, we demonstrate that NO donors and membrane permeant cGMP analogues cause vesicle release at the NMJ. Moreover, the NO-induced release could be blocked by the specific inhibitor of the sGC. A destaining of synaptic terminals after NO exposure in Ca2+-free solution in the presence of cobalt chloride as a channel blocker suggested that NO stimulates Ca2+-independent vesicle release at the NMJ. The combined immunocytochemical and exocytosis imaging experiments imply the involvement of cGMP and NO in the regulation of vesicle release at the NMJ of Drosophila larvae.     

Drosophila CAPS is an essential gene that regulates dense-core vesicle release and synaptic vesicle fusion

Calcium-activated protein for secretion (CAPS) is proposed to play an essential role in Ca2+-regulated dense-core vesicle exocytosis in vertebrate neuroendocrine cells. Here we report the cloning, mutation, and characterization of the Drosophila ortholog (dCAPS). Null dCAPS mutants display locomotory deficits and complete embryonic lethality. The mutant NMJ reveals a 50% loss in evoked glutamatergic transmission, and an accumulation of synaptic vesicles at active zones. Importantly, dCAPS mutants display a highly specific 3-fold accumulation of dense-core vesicles in synaptic terminals, which was not observed in mutants that completely arrest synaptic vesicle exocytosis. Targeted transgenic CAPS expression in identified motoneurons fails to rescue dCAPS neurotransmission defects, demonstrating a cell nonautonomous role in synaptic vesicle fusion. We conclude that dCAPS is required for dense-core vesicle release and that a dCAPS-dependent mechanism modulates synaptic vesicle release at glutamatergic synapses.     

Calcium microdomains in regulated exocytosis

Katz and co-workers showed that Ca(2+) triggers exocytosis. The existence of sub-micrometer domains of greater than 100 microM [Ca(2+)](i) was postulated on theoretical grounds. Using a modified, low-affinity aequorin, Llinas et al. were the first to demonstrate the existence of Ca(2+) 'microdomains' in squid presynaptic terminals. Over the past several years, it has become clear that individual Ca(2+) nano- and microdomains forming around the mouth of voltage-gated Ca(2+) channels ascertain the tight coupling of fast synaptic vesicle release to membrane depolarization by action potentials. Recent work has established different geometric arrangements of vesicles and Ca(2+) channels at different central synapses and pointed out the role of Ca(2+) syntillas - localized, store operated Ca(2+) signals - in facilitation and spontaneous release. The coupling between Ca(2+) increase and evoked exocytosis is more sluggish in peripheral terminals and neuroendocrine cells, where channels are less clustered and Ca(2+) comes from different sources, including Ca(2+) influx via the plasma membrane and the mobilization of Ca(2+) from intracellular stores. Finally, also non- (electrically) excitable cells display highly localized Ca(2+) signaling domains. We discuss in particular the organization of structural microdomains of Bergmann glia, specialized astrocytes of the cerebellum that have only recently been considered as secretory cells. Glial microdomains are the spatial substrate for functionally segregated Ca(2+) signals upon metabotropic activation. Our review emphasizes the large diversity of different geometric arrangements of vesicles and Ca(2+) sources, leading to a wide spectrum of Ca(2+) signals triggering release.