Ruth Heidelberger

Calcium influx and calcium current in single synaptic terminals of goldfish retinal bipolar neurons.

1. The calcium influx pathway in large synaptic terminals of acutely isolated bipolar neurons from goldfish retina was characterized using Fura‐2 measurements of intracellular calcium and patch‐clamp recordings of whole‐cell calcium current. 2. Depolarization of bipolar cells with high [K+]o resulted in a sustained, reversible increase in [Ca2+]i in both synaptic terminals and somata. Removal of external calcium abolished the response, as did the addition of 200 microM‐cadmium to the bathing solution, indicating that the rise in [Ca2+]i was due to entry of external calcium. Dihydropyridine blockers of voltage‐gated Ca2+ channels also blocked the influx, and the Ca2+ channel agonist Bay K 8644 potentiated influx, implicating voltage‐activated, dihydropyridine‐sensitive channels in the influx pathway. 3. Under voltage clamp, depolarization from a holding potential of ‐60 mV evoked a slowly inactivating inward current that began to activate at ‐50 to ‐40 mV and reached a maximal amplitude between ‐20 and ‐15 mV. This current was identified as a calcium current because it decreased when the extracellular calcium concentration was lowered, increased when barium was the charge carrier, and was blocked by 200 microM‐external cadmium. The current was substantially blocked by 1 microM‐nitrendipine and potentiated by 0.1 microM‐Bay K 8644, as expected for L‐type Ca2+ channels; it was unaffected by omega‐conotoxin. No evidence for transient or rapidly inactivating Ca2+ current was found. 4. At a given level of potassium depolarization, both the amplitude and the speed of increase in [Ca2+]i were greater in synaptic terminals than in somata. For instance, depolarization by 32.6 mM‐potassium caused an increase in intracellular calcium of 400 +/‐ 23 nM in terminals and 180 +/‐ 20 nM in somata (mean +/‐ S.E.M., n = 73 terminals, n = 30 somata), with maximal rates of change of 40 +/‐ 3 and 12 +/‐ 2 nM/s, respectively. 5. The contribution of terminal and somatic currents to the total whole‐cell Ca2+ current was determined under voltage clamp by local application of calcium or of blocking agents. While there was no qualitative difference between currents in terminals and somata, synaptic terminals accounted for 64 +/‐ 3% (mean +/‐ S.E.M., n = 12) of the total whole‐cell calcium current, and somata accounted for 39 +/‐ 2%. Thus, the density of Ca2+ current was higher in the terminal, accounting for the greater magnitude and speed of Ca2+ influx observed in terminals in Fura‐2 experiments.(ABSTRACT TRUNCATED AT 400 WORDS)

Synaptic transmission at retinal ribbon synapses.

The molecular organization of ribbon synapses in photoreceptors and ON bipolar cells is reviewed in relation to the process of neurotransmitter release. The interactions between ribbon synapse-associated proteins, synaptic vesicle fusion machinery and the voltage-gated calcium channels that gate transmitter release at ribbon synapses are discussed in relation to the process of synaptic vesicle exocytosis. We describe structural and mechanistic specializations that permit the ON bipolar cell to release transmitter at a much higher rate than the photoreceptor does, under in vivo conditions. We also consider the modulation of exocytosis at photoreceptor synapses, with an emphasis on the regulation of calcium channels.

A Highly Ca2+-Sensitive Pool of Vesicles Contributes to Linearity at the Rod Photoreceptor Ribbon Synapse

Studies of the properties of synaptic transmission have been carried out at only a few synapses. We analyzed exocytosis from rod photoreceptors with a combination of physiological and ultrastructural techniques. As at other ribbon synapses, we found that rods exhibited rapid kinetics of release, and the number of vesicles in the releasable pool is comparable to the number of vesicles tethered at ribbon-style active zones. However, unlike other previously studied neurons, we identified a highly Ca(2+)-sensitive pool of releasable vesicles with a relatively shallow relationship between the rate of exocytosis and [Ca(2+)](i) that is nearly linear over a presumed physiological range of intraterminal [Ca(2+)]. The low-order [Ca(2+)] dependence of release promotes a linear relationship between Ca(2+) entry and exocytosis that permits rods to relay information about small changes in illumination with high fidelity at the first synapse in vision.

SV2 Acts via Presynaptic Calcium to Regulate Neurotransmitter Release

Synaptic vesicle 2 (SV2) proteins, critical for proper nervous system function, are implicated in human epilepsy, yet little is known about their function. We demonstrate, using direct approaches, that loss of the major SV2 isoform in a central nervous system nerve terminal is associated with an elevation in both resting and evoked presynaptic Ca(2+) signals. This increase is essential for the expression of the SV2B(-/-) secretory phenotype, characterized by changes in synaptic vesicle dynamics, synaptic plasticity, and synaptic strength. Short-term reproduction of the Ca(2+) phenotype in wild-type nerve terminals reproduces almost all aspects of the SV2B(-/-) secretory phenotype, while rescue of the Ca(2+) phenotype in SV2B(-/-) neurons relieves every facet of the SV2B(-/-) secretory phenotype. Thus, SV2 controls key aspects of synaptic functionality via its ability to regulate presynaptic Ca(2+), suggesting a potential new target for therapeutic intervention in the treatment of epilepsy.

Synaptotagmin-2 Controls Regulated Exocytosis but Not Other Secretory Responses of Mast Cells

Mast cell degranulation is a highly regulated, calcium-dependent process, which is important for the acute release of inflammatory mediators during the course of many pathological conditions. We previously found that Synaptotagmin-2, a calcium sensor in neuronal exocytosis, was expressed in a mast cell line. We postulated that this protein may be involved in the control of mast cell-regulated exocytosis, and we generated Synaptotagmin-2 knock-out mice to test our hypothesis. Mast cells from this mutant animal conferred an abnormally decreased passive cutaneous anaphylaxis reaction on mast cell-deficient mice that correlated with a specific defect in mast cell-regulated exocytosis, leaving constitutive exocytosis and nonexocytic mast cell effector responses intact. This defect was not secondary to abnormalities in the development, maturation, migration, morphology, synthesis, and storage of inflammatory mediators, or intracellular calcium transients of the mast cells. Unlike neurons, the lack of Synaptotagmin-2 in mast cells was not associated with increased spontaneous exocytosis.

Dopamine enhances Ca2+ responses in synaptic terminals of retinal bipolar neurons

The effect of dopamine on depolarization-induced Ca2+ influx was studied using the fluorescent Ca2+ indicator fura-2 in synaptic terminals of bipolar neurons from gold-fish retina. Dopamine reversibly enhanced the rise in intracellular Ca2+ elicited by elevated external potassium. The enhancement was slowly reversible. The effect of dopamine was mimicked by forskolin and CPT-cAMP, a membrane-permeant analog of cAMP. However, 1,9-dideoxyforskolin, a forskolin analog that does not activate adenylyl cyclase, was ineffective. This suggests that dopamine, via cAMP, regulates the rise in presynaptic Ca2+ concentration in response to depolarization, potentially enhancing transmitter release.

Quantitative Analysis of Synaptic Release at the Photoreceptor Synapse

Exocytosis from the rod photoreceptor is stimulated by submicromolar Ca(2+) and exhibits an unusually shallow dependence on presynaptic Ca(2+). To provide a quantitative description of the photoreceptor Ca(2+) sensor for exocytosis, we tested a family of conventional and allosteric computational models describing the final Ca(2+)-binding steps leading to exocytosis. Simulations were fit to two measures of release, evoked by flash-photolysis of caged Ca(2+): exocytotic capacitance changes from individual rods and postsynaptic currents of second-order neurons. The best simulations supported the occupancy of only two Ca(2+) binding sites on the rod Ca(2+) sensor rather than the typical four or five. For most models, the on-rates for Ca(2+) binding and maximal fusion rate were comparable to those of other neurons. However, the off-rates for Ca(2+) unbinding were unexpectedly slow. In addition to contributing to the high-affinity of the photoreceptor Ca(2+) sensor, slow Ca(2+) unbinding may support the fusion of vesicles located at a distance from Ca(2+) channels. In addition, partial sensor occupancy due to slow unbinding may contribute to the linearization of the first synapse in vision.

Regulation of presynaptic calcium in a mammalian synaptic terminal

Ca(2+) signaling in synaptic terminals plays a critical role in neurotransmitter release and short-term synaptic plasticity. In the present study, we examined the role of synaptic Ca(2+) handling mechanisms in the synaptic terminals of mammalian rod bipolar cells, neurons that play a pivotal role in the high-sensitivity vision pathway. We found that mitochondria sequester Ca(2+) under conditions of high Ca(2+) load, maintaining intraterminal Ca(2+) near resting levels. Indeed, the effect of the mitochondria was so powerful that the ability to clamp intraterminal Ca(2+) with a somatically positioned whole cell patch pipette was compromised. The plasma membrane Ca(2+)-ATPase (PMCA), but not the Na(+)/Ca(2+) exchanger (NCX) or the sarco(endo)plasmic reticulum Ca(2+)-ATPase (SERCA), was an important regulator of resting Ca(2+). Furthermore, PMCA activity, but not NCX or SERCA activity, was essential for the recovery of Ca(2+) levels following depolarization-evoked Ca(2+) entry. Loss of PMCA function was also associated with impaired restoration of membrane surface area following depolarization-evoked exocytosis. Given its roles in the regulation of intraterminal Ca(2+) at rest and after a stimulus-evoked Ca(2+) rise, the PMCA is poised to modulate luminance coding and adaptation to background illumination in the mammalian rod bipolar cell.

Distribution of proteins associated with synaptic vesicle endocytosis in the mouse and goldfish retina

Current models of synaptic transmission require retrieval of membrane from the presynaptic terminal following neurotransmitter exocytosis. Dynamin, a GTPase, is thought to be critical for this retrieval process. At ribbon synapses of retinal bipolar neurons, however, compensatory endocytosis does not require GTP hydrolysis, suggesting that endocytosis mechanisms may differ among synapses. To understand better the synaptic vesicle recycling at conventional and ribbon synapses, the distributions of dynamin and two associated proteins, amphiphysin and clathrin, were examined in the retinas of goldfish and mouse by using immunocytochemical methods. Labeling for dynamin, clathrin, and amphiphysin was distributed differentially among conventional and ribbon synapses in retinas of both species. Ribbon synapses of photoreceptors and most bipolar cells labeled only weakly for dynamin relative to conventional synapses. Amphyiphysin labeling was strong at many ribbon synapses, and labeling in rod terminals was stronger than in cone terminals in the mouse retina. Clathrin labeling was heterogeneous among ribbon synapses. Similarly to the case with amphiphysin, mouse rod terminals showed stronger clathrin labeling than cone terminals. Among conventional synapses, there was heterogeneous labeling for all three endocytic proteins. Some labeling for each protein might have been associated with postsynaptic terminals. The differential distribution of labeling for these proteins among identified synapses in the retina suggests considerable heterogeneity in the molecular mechanisms underlying synaptic membrane retrieval, even among synapses with similar active zone ultrastructure. Thus, as with exocytosis, mechanisms of synaptic membrane retrieval may be tuned by the precise complement of proteins expressed within the synaptic terminal. J. Comp. Neurol. 484:440–457, 2005.

Mechanisms of tonic, graded release: lessons from the vertebrate photoreceptor

The release of neurotransmitter via exocytosis is a highly conserved, fundamental feature of nervous system function. At conventional synapses, neurotransmitter release occurs as a brief burst of exocytosis triggered by an action potential. By contrast, at the first synapse of the vertebrate visual pathway, not only is the calcium‐dependent release of neurotransmitter typically graded with respect to the presynaptic membrane potential, but release can be maintained throughout the duration of a sustained stimulus. The specializations that provide for graded and sustained release are not well‐defined. However, recent advances in our understanding of basic synaptic vesicle dynamics and the calcium sensitivity of the release process at these and other central, glutamatergic neurons have shed some light on the photoreceptors extraordinary abilities.