Interphase gap decreases electrical stimulation threshold of retinal ganglion cells.

The most common electrical stimulation pulse used in retinal implants is a symmetric biphasic current pulse. Prior electrophysiological studies in peripheral nerve have shown that adding an interphase gap (IPG) between the two phases makes stimulation more efficient. We investigated the effect of IPG duration on retinal ganglion cell (RGC) electrical threshold. We used calcium imaging to measure the activity of RGCs in isolated retina in response to electrical stimulation. By varying IPG duration, we were able to examine the effect of duration on threshold. We further studied this effect by simulating RGC behavior with a Hodgkin-Huxley-type model. Our results indicate that the threshold for electrical activation of RGCs can be reduced by increasing the length of the IPG.

Biochemical changes contributing to functional quiescence in lacrimal gland acinar cells after chronic ex vivo exposure to a muscarinic agonist.

Profound secretory dysfunction can be associated with relatively modest lymphocytic infiltration of the lacrimal and salivary glands of Sjögren's syndrome (SjS) patients. SjS patients' sera contain autoantibodies to M3 muscarinic acetylcholine receptors (MAChR) that have variously been reported to have agonistic and antagonistic effects. We sought to identify consequences of chronic agonist stimulation by maintaining acinar cells from rabbit lacrimal glands for 20 h in the presence or absence of 10 microM carbachol (CCh). Exposure to CCh diminished the cells' ability to elevate cytosolic Ca2+ and secrete beta-hexosaminidase in response to acute stimulation with 100 microM CCh, but it enhanced their secretory responses to phenylephrine and ionomycin. Secretory vesicles appeared normal by electron microscopy, but confocal fluorescence microscopy revealed depletion of the secretory vesicle membrane marker, rab3D, and decreased ability to recruit secretory transport vesicles in response to acute 100 microM CCh. Additionally, the apical cortical actin cytoskeleton was disrupted and diminished compared to the basal-lateral cortical network. Subcellular fractionation analyses revealed that total membrane phase protein content was increased. The contents of beta-hexosaminidase and MAChR relative to total protein were not significantly altered, and MAChR abundance in the plasma membrane fraction was increased as the result of redistribution from endomembrane pools. However, relative cellular contents of the heterotrimeric guanosine triphosphate (GTP)-binding proteins, Gq and G11, were decreased. Additional biochemical changes included decreased contents of 47 kDa Gs and Gi3, protein kinase Calpha and rab3D and polymeric immunoglobulin (Ig) receptors; internalization of Na,K-ATPase from the plasma membranes to endomembrane compartments and decreased content of beta-hexosaminidase in the lysosomes. The observations demonstrate that chronic exposure to a MAChR agonist induces refractoriness to optimal stimulation, without causing receptor downregulation, by downregulating postreceptor-signalling mediators and effectors. The cells' secretory mechanisms for IgA and electrolytes also appear to be impaired, as does their ability to properly sort proteins to the lysosomes.

Red, yellow, green go!--A novel tool for microscopic segregation of secretory vesicle pools according to their age.

Large dense-core vesicles (LDCVs) were labelled in cultured bovine adrenal chromaffin cells expressing fluorescent chimaeric 'cargo' proteins that were targeted to these secretory vesicles. When the cells were stimulated with nicotine 48 h after transduction, the fractional loss of fluorescent LDCVs was much greater than the fractional catecholamine secretion, implying selective release of newly assembled vesicles. This was confirmed using a fluorescent 'timer' construct that changes its fluorescence emission from green to red over several hours, and by measurement of the location and mobility of LDCVs in live cells by confocal fluorescence microscopy. Newly assembled (green) LDCVs were located mostly in peripheral regions of the cells, were virtually immobile and could be released by nicotine, but not by Ba2+; in contrast, older (red) LDCVs were centrally located and relatively mobile, and their exocytotic release was triggered by Ba2+, but not by nicotine. We describe the image restoration procedure that is necessary in order to analyse the behaviour of LDCVs labelled with this construct.

Intracellular calcium dependence of large dense-core vesicle exocytosis in the absence of synaptotagmin I.

Synaptotagmin I is a synaptic vesicle-associated protein essential for synchronous neurotransmission. We investigated its impact on the intracellular Ca(2+)-dependence of large dense-core vesicle (LDCV) exocytosis by combining Ca(2+)-uncaging and membrane capacitance measurements in adrenal slices from mouse synaptotagmin I null mutants. Synaptotagmin I-deficient chromaffin cells displayed prolonged exocytic delays and slow, yet Ca(2+)-dependent fusion rates, resulting in strongly reduced LDCV release in response to short depolarizations. Vesicle recruitment, the shape of individual amperometric events, and endocytosis appeared unaffected. These findings demonstrate that synaptotagmin I is required for rapid, highly Ca(2+)-sensitive LDCV exocytosis and indicate that it regulates the equilibrium between a slowly releasable and a readily releasable state of the fusion machinery. Alternatively, synaptotagmin I could function as calcium sensor for the readily releasable pool, leading to the destabilization of the pool in its absence.

Is double C2 protein (DOC2) expressed in bovine adrenal medulla? A commercial anti-DOC2 monoclonal antibody recognizes a major bovine mitochondrial antigen.

We have examined the expression in bovine adrenal medulla of double C2 protein (DOC2), a vesicular protein which associates with intracellular phospholipid and Ca(2+) and is implicated in the modulation of regulated exocytosis. Extensive reverse transcription-PCR, Northern blot analyses and in vitro translation reactions have been combined with immunological studies to provide data to suggest that neither DOC2alpha nor DOC2beta is expressed at detectable levels in bovine adrenal chromaffin cells, and that a widely used monoclonal antibody directed against DOC2 also recognizes mitochondrial complex III core protein 2.

Double C2 protein. A review.

Concerted effort has led to the identification of dozens of synaptic proteins and has thereby opened the door for the characterisation of the molecular mechanisms underlying regulated exocytosis. Calcium is known to play a number of roles in regulated exocytosis, acting as the trigger for fast synaptic transmission and also acting at some of the steps preceding vesicle fusion. Investigators have therefore focussed considerable attention on possible calcium sensors. What many of the candidate proteins have in common is a C2 domain, one of the four conserved domains originally described in protein kinase C. Such domains have been shown to bind calcium and phospholipid in a large number of intracellular proteins. Synaptotagmin, a C2-domain protein, is a very strong candidate for the protein involved in triggering fast calcium-dependent vesicle fusion. Recent attention has also concerned the other calcium sensors, which may play roles in the 'priming' or transport of vesicles. This review concerns one of these tentative calcium-binding proteins, double C2 or DOC2. DOC2 was originally isolated from nervous tissue but subsequently has been found to be more widely expressed. DOC2 is a vesicular protein that may be involved in the early stages of preparing vesicles for exocytosis.

Transient, phorbol ester-induced DOC2-Munc13 interactions in vivo.

Munc13-1 and DOC2 have been implicated in the regulation of exocytosis. Here we demonstrate in vivo that these two proteins undergo a transient phorbol ester-mediated and protein kinase C-independent interaction, resulting in the translocation of DOC2 from a vesicular localization to the plasma membrane. The translocation of DOC2 is dependent upon the DOC2 Munc interacting domain that binds specifically to Munc13-1, whereas the association of DOC2 with intracellular membranes is dependent on its C2 domains. This is the first direct in vivo demonstration of a protein-protein interaction between two presynaptic proteins and may represent a molecular basis for phorbol ester-dependent enhancement of exocytosis.

High-efficiency Semliki Forest virus-mediated transduction in bovine adrenal chromaffin cells.

Adrenal chromaffin cells are commonly used in studies of exocytosis. Progress in characterizing the molecular mechanisms has been slow, because no simple, high-efficiency technique is available for introducing and expressing heterologous cDNA in chromaffin cells. Here we demonstrate that Semliki Forest virus (SFV) vectors allow high-efficiency expression of heterologous protein in chromaffin cells.

Evanescent-wave microscopy: a new tool to gain insight into the control of transmitter release.

Evanescent-wave excitation was used to visualize individual fluorescently labelled vesicles in an optical slice near the plasma membrane of bovine adrenal chromaffin cells. A standard upright microscope was modified to accommodate the optics used for directing a laser beam under a supracritical angle on to the glass-water interface on top of which the cells are grown. Whereas epi-illumination images appeared blurred and structureless, evanescent-wave excitation highlighted acridine orange-labelled vesicles as individual pinpoints. Three-dimensional (3D) trajectories of individual vesicles were obtained from time-resolved image stacks and used to characterize vesicles in terms of their average fluorescence F and mobility, expressed here as the 3D diffusion coefficient D(3). Based on the single-vesicle analysis, two groups of vesicles were identified. Transitions between these states were studied before and after stimulation of exocytosis by repetitive or maintained membrane depolarizations by elevated extracellular [K+]. Findings were interpreted as sequential transitions between the previously characterized pools of vesicles preceding the fusion step. The observed approach of vesicles to their docking sites was not explained in terms of free diffusion: most vesicles moved unidirectionally as if directed to their binding sites at the plasma membrane. Vesicle mobility at the membrane was low, such that the sites of docking and fusion were in close vicinity. Both the rim region and confined areas in the centre of the footprint region were the site of intense vesicle trafficking.

Multiple stimulation-dependent processes regulate the size of the releasable pool of vesicles.

In neuroendocrine cells and neurones, changes in the size of a limited pool of readily releasable vesicles contribute to the plasticity of secretion. We have studied the dynamic alterations in the size of a near-membrane pool of vesicles in living neuroendocrine cells. Using evanescent wave microscopy we monitored the behaviour of individual secretory vesicles at the plasma membrane. Vesicles undergo sequential transitions between several states of differing fluorescence intensity and mobility. The transitions are reversible, except for the fusion step, and even in nonstimulated conditions the vesicles change states in a dynamic equilibrium. Stimulation selectively speeds up the three forward transitions leading towards exocytosis. Vesicles lose mobility in all three dimensions upon approach of the plasma membrane. Their movement is directed and targeted to the docking fusion sites. Sites of vesicle docking and exocytosis are distributed non-uniformly over the studied "footprint" region of the cell. While some areas are the sites of repeated vesicle docking and fusion, others are completely devoid of spots. Vesicular mobility at the membrane is confined, as if the vesicle were imprisoned in a cage or tethered to a binding site.

Extrasynaptic vesicular transmitter release from the somata of substantia nigra neurons in rat midbrain slices.

Substantia nigra neurons release dopamine from their somatodendritic regions. A long-unresolved question is whether this release occurs by exocytosis or by a nonvesicular mechanism. We used carbon fiber microelectrodes in a brainstem slice to assay secretion from single cell bodies that had been cleared of connective tissue. Amperometry at the carbon fiber microelectrodes revealed unitary events in approximately 90% of cells in resting conditions. These events had charge integrals ranging from a few femtocoulombs to several hundred femtocoulombs (fC). Local glutamate application enhanced the event frequency by 3.5-fold on average and up to 10-fold in highly responsive cells, although the mean charge integral was not modified. Local application of a high K+-containing saline had effects similar to those of glutamate. The frequency of resting and stimulated amperometric events was much lower at 21-22 degreesC than at 32-35 degreesC. The addition of Cd2+ (50 microM), a blocker of voltage-dependent Ca2+ channels, to the bath solution blocked the stimulatory effects of glutamate. These results suggest that dopamine is released from the somata of substantia nigra neurons by exocytosis and that this mechanism is regulated by neuronal electrical activity. More generally, this study demonstrates the applicability of carbon fiber microelectrodes to the measurement of quantal monoamine secretion in brain slices.

The last few milliseconds in the life of a secretory granule. Docking, dynamics and fusion visualized by total internal reflection fluorescence microscopy (TIRFM).

We have monitored single vesicles (granules) in bovine adrenal chromaffin cells using an optical sectioning technique, total internal reflection fluorescence microscopy (TIRFM). With TIR, fluorescence excitation is limited to an optical slice near a glass/water interface. In cells located at the interface, granules loaded with fluorescent dye can be visualized near to or docked at the plasma membrane. Here we give evidence that (1) TIRFM resolves single vesicles and (2) the fluorescence signal originates from vesicles of roughly 350 nm diameter, presumably large dense core vesicles (LDCVs). (3) Diffusional spread of released vesicle contents can be resolved and serves as a convenient criterion for a fusion event. (4) We give details on vesicle properties in resting cells, such as lateral mobility of chromaffin granules, number density, and frequency of spontaneous fusion or withdrawal into the cytoplasm. (5) Upon stimulation with high extracellular potassium, TIRFM reports depletion of the 'visible pool' of vesicles closest to the plasma membrane within hundreds of milliseconds, consistent with previous concepts of a release-ready pool. We conclude that TIRFM constitutes an independent assay for pool depletion. TIRFM will allow us to study aspects of secretion that have previously been inaccessible in living cells, in particular the spatial relations and dynamics of vesicles prior to and during exocytosis and re-supply of the near-membrane pool of vesicles.

Comparison of secretory responses as measured by membrane capacitance and by amperometry.

We have compared capacitance and amperometric measurements in bovine chromaffin cells when secretion was elicited by flash photolysis of caged-calcium or step depolarizations. Total amperometric charge depended linearly on the amount of capacitance increase in both types of experiments. Furthermore, the properties of resolvable amperometric spikes after flashes were comparable to those observed after depolarizations, and their timing was compatible with the rate of capacitance increase. For a more detailed comparison, we used Monte Carlo simulations of multiple amperometric events occurring randomly over the surface of a sphere and summing together, to generate a reference amperometric signal for a given measured capacitance increase. Even after correction for endocytotic processes, the time courses of the integrated experimental records lagged behind the integrated Monte Carlo records by approximately 50 ms in flash and depolarization experiments. This delay was larger by approximately 40 ms than what can be expected from the "pre-foot delay" or the foot duration. Possible sources for the remaining delay could be diffusional barriers like the patch-pipette and the chamber bottom, which are not taken into account in the model. We also applied a novel type of fluctuation analysis to estimate the relative quantum size of an amperometric event. On average the estimates from experimental amperometric traces, in both flash and depolarization experiments, were 3-5 times smaller than estimates from simulated ones. This discrepancy can be due to contributions to the amperometric current from small vesicles, preferred release from cellular regions orientated toward the chamber bottom, or abundance of "foot-only" events. In conclusion, amperometric signals in flash and depolarization experiments displayed similar delayed average time courses and a lower estimate for the relative quantum size compared to the modeled amperometric signals. However, individual amperometric spikes were in agreement with expectations derived from capacitance signals.

Cylindrically etched carbon-fiber microelectrodes for low-noise amperometric recording of cellular secretion.

The most important sources of noise with disk-shaped carbon-fiber microelectrodes (CFMEs) are the exposed cut disk face of the fiber itself and the seal region between the carbon fiber and the applied insulating layer. To reduce noise and to fabricate simple, reproducible low-noise CFMEs, we sealed commercially available carbon fibers in pulled glass pipets and then we performed cylindrical etching of the fiber extending beyond the glass sheath, followed by insulation with anodic electrophoretic deposition of paint. The resulting CFMEs had electroactive carbon disks with radii as small as ∼0.5 µm. The noise of such electrodes was minimized by virtue of a design that ensures a good seal between the carbon fiber and its insulation and a reduced diameter of the exposed carbon. In contrast to CFMEs made of conically etched carbon fibers, cylindrically etched CFMEs offer the significant advantage that they can be easily reused: The cylindrically etched region extends over several hundreds of micrometers and, therefore, can be cut back repeatedly to expose a fresh carbon surface of uniform diameter. The low noise and small size of these electrodes make them ideal for the high-sensitivity measurements demanded in studies of single-vesicle transmitter release from secretory cells. Furthermore, the small cross-sectional diameter of the tips allows them to be used in restricted spaces, such as inside the tapering micrometer-diameter tips of melted and pulled glass microcapillaries (e.g., patch pipets).

Kinetics of exocytosis in adrenal chromaffin cells.

Upon repetitive or maintained stimulation, chromaffin cells secrete catecholamines initially at a very high rate which then relaxes with multiple kinetic components. The complex kinetics are often modeled as resulting from the successive depletion of several functional pools of secretory granules which may reflect specific protein-mediated steps in granule maturation. The fastest component represents granules fully primed for exocytosis. This 'readily releasable pool' may, under some circumstances, consist of only about a dozen granules which can be released within tens of milliseconds. Modulating the size of this pool may be an important way for cells to regulate secretion.

pH-induced reversible dissociation of tetrameric duck lens delta-crystallin.

Animal lenses constitute many soluble proteins, which play a prominent role in eyes' light transparency. delta2-Crystallin, one of the major taxon-specific crystallins in duck lens, is a tetrameric protein consisting of four identical subunits, which contain endogenous argininosuccinate lyase activity. Under a neutral pH environment in this work, the protein was cross-linked with glutaraldehyde as tetrameric and dimeric forms with tetramer as the major form. Under acidic conditions, the protein was time-dependently dissociated into monomers with amino acid residues of pKa values 6.29+/-0.45 and 7.17+/-0.49 being involved in the monomer-monomer interactions and 6.20+/-0.10 and 8.88+/-0.07 in the dimer-dimer interactions. Duck lens delta2-crystallin thus possesses a double dimer structure (alpha2)2 with stronger monomer-monomer interactions than the dimer-dimer interactions. The acidic protein solution's reneutralization caused rapid reassociation of monomers into dimers and tetramers. The tetramer-dimer-monomer dissociation-reassociation thus is a pH-dependent freely interconvertible process.

Rapid fluctuations in transmitter release from single vesicles in bovine adrenal chromaffin cells.

Single-vesicle release of catecholamines from chromaffin cells can be detected in real time as current spikes by the electrochemical method of amperometry. About 70% of spikes are preceded by a small "foot," the trickle of transmitter out of the early fusion pore. In addition, 20-50% of foot signals exhibit rapid fluctuations that we interpret as flickering of the fusion pore. There are also "stand-alone" foot signals, which may reflect transient fusions, in which the vesicles do not collapse completely into the plasma membrane. The number and frequency of the foot flickering are affected by intracellular Ca2+ concentration.

Mechanisms determining the time course of secretion in neuroendocrine cells.

Transmitter release from chromaffin cells differs from that in synapses in that it persists for a longer time after Ca2+ entry has stopped. This prolonged secretion is not due to a delay between vesicle fusion and transmitter release, nor to slow detection of released substance: step increases in capacitance due to single vesicle fusion precede the release detected by amperometry by only a few milliseconds. The persistence of secretion after a depolarization is reduced by addition of mobile calcium buffer. This suggests that most of the delay is due to diffusion of Ca2+ between channels and release sites, implying that Ca2+ channels and secretory vesicles are not colocalized in chromaffin cells, in contrast to presynaptic active zones.

A simple method for insulating carbon-fiber microelectrodes using anodic electrophoretic deposition of paint.

We describe a simple method for the insulation of carbon-fiber microelectrodes (CFMEs). Using the technique of anodic electrophoretic deposition of paint (EDP), we deposited thin and uniform films of electrodeposition paint onto 10-µm-diameter carbon fibers. The polymer films were then heat cured, leading to an electrically insulating coat. The insulated carbon fibers were transected perpendicular to their axes to expose a 10-µm carbon disk and characterized using conventional electrochemical methods and scanning electron microscopy. As expected, cyclic voltammograms measured with electropainted CFMEs in solutions containing ferricyanide displayed a sigmoidal response without hysteresis. The insulating films had a low dielectric constant, resulting in low capacitance. In addition, the film thickness could be controlled simply by varying such deposition parameters as the applied voltage and the duration of treatment. Electrical noise of the transected fibers was determined principally by the cut surface of the fiber, not by the exposed insulated surfaces. Compared to electropolymerization of phenol compounds, another electrochemical method for insulating CFMEs, insulation by anodic EDP has the very significant advantages of greater simplicity, much shorter processing time, and much lower toxicity of the reagents involved, important considerations for those who work with the procedure on a daily basis. Furthermore, electrodeposition paints are commercially available and have long shelf lives.

Swelling-induced catecholamine secretion recorded from single chromaffin cells.

We have studied osmotically induced catecholamine secretion from bovine adrenal chromaffin cells by combining patch-clamp measurements, electrochemical detection of secretion, and Fura-2 measurements of intracellular free calcium concentration ([Ca2+]i). We find that osmotically induced catecholamine release is exocytotic and calcium dependent. Furthermore, we demonstrate that cell swelling is coupled to such secretion via a volume-activated current, carrying predominantly chloride, which causes a plateau depolarization of the cell membrane potential and thus promotes voltage-activated calcium influx. Therefore, cell volume changes may modulate the secretory activity.