Calmodulin enhances ribbon replenishment and shapes filtering of synaptic transmission by cone photoreceptors

Hook, Matthew J. Van; Parmelee, Caitlyn; Chen, Ming‐Hui; Cork, Karlene M.; Curto, Carina; Thoreson, Wallace B.

doi:10.1083/jcb.2073oia192

Cited by 3 publications

(6 citation statements)

References 90 publications

(140 reference statements)

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“…Consistent with this interpretation, stx3pep blocked a component of neurotransmitter release in cone photoreceptors that has been shown previously to correspond to the Ca 2þ -accelerated, calmodulin-dependent recruitment of synaptic vesicles to the synaptic ribbons, followed by their subsequent fusion (Fig. 9) (18,66). Together our data indicate that new SNARE formation is critical for maintaining the supply of fusion-competent vesicles at synaptic ribbons.…”

Section: Continuous Neurotransmitter Release Requires the Recruitmentsupporting

confidence: 89%

“…9 D; stx3con: À1.225 5 0.2033 pC/s, n ¼ 14; stx3pep: À1.275 5 0.1652 pC/s, n ¼ 9; p > 0.8). In the presence of stx3con, this limiting slope increased significantly when the pulse strength was increased to À10 mV (p % 0.002, paired t-test) reflecting the Ca 2þ -dependent acceleration of vesicle replenishment to ribbons (18,66). By contrast, in the presence stx3pep, the rate of charge transfer did not increase significantly after increasing pulse strength to À10 mV (p > 0.1).…”

Section: Stx3pep Inhibits the Recruitment Of New Vesicles To The Synamentioning

confidence: 94%

“…9 A). After $1 s of stimulation under control conditions, the RP of vesicles on the ribbon is depleted and then charge transfer grows at a steady rate limited by the rate at which vesicles repopulate the ribbon (16,18,66).…”

Section: Stx3pep Inhibits the Recruitment Of New Vesicles To The Synamentioning

confidence: 99%

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Two Pools of Vesicles Associated with Synaptic Ribbons Are Molecularly Prepared for Release

Datta

Gilliam

Thoreson

et al. 2017

Biophysical Journal

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Neurons that form ribbon-style synapses are specialized for continuous exocytosis. To this end, their synaptic terminals contain numerous synaptic vesicles, some of which are ribbon associated, that have difference susceptibilities for undergoing Ca-dependent exocytosis. In this study, we probed the relationship between previously defined vesicle populations and determined their fusion competency with respect to SNARE complex formation. We found that both the rapidly releasing vesicle pool and the releasable vesicle pool of the retinal bipolar cell are situated at the ribbon-style active zones, where they functionally interact. A peptide inhibitor of SNARE complex formation failed to block exocytosis from either pool, suggesting that these two vesicle pools have formed the SNARE complexes necessary for fusion. By contrast, a third, slower component of exocytosis was blocked by the peptide, as was the functional replenishment of vesicle pools, indicating that few vesicles outside of the ribbon-style active zones were initially fusion competent. In cone photoreceptors, similar to bipolar cells, fusion of the initial ribbon-associated synaptic vesicle cohort was not blocked by the SNARE complex-inhibiting peptide, whereas a later phase of exocytosis, attributable to the recruitment and subsequent fusion of vesicles newly arrived at the synaptic ribbons, was blocked. Together, our results support a model in which stimulus-evoked exocytosis in retinal ribbon synapses is SNARE-dependent; where vesicles higher up on the synaptic ribbon replenish the rapidly releasing vesicle pool; and at any given time, there are sufficient SNARE complexes to support the fusion of the entire ribbon-associated cohort of vesicles. An important implication of these results is that ribbon-associated vesicles can form intervesicular SNARE complexes, providing mechanistic insight into compound fusion at ribbon-style synapses.

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Section: Continuous Neurotransmitter Release Requires the Recruitmentsupporting

confidence: 89%

Section: Stx3pep Inhibits the Recruitment Of New Vesicles To The Synamentioning

confidence: 94%

See 1 more Smart Citation

Two Pools of Vesicles Associated with Synaptic Ribbons Are Molecularly Prepared for Release

Datta

Gilliam

Thoreson

et al. 2017

Biophysical Journal

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“…The dynamics of release and replenishment of neurotransmitter at the photoreceptor synapses could be an important factor in encoding and transmitting the timing of light responses (Snellman et al, ; Van Hook et al, ). Therefore, photoreceptor ribbon synaptic structure depends on the cytoskeleton arrangement, both at the active zone‐related with exocytosis—as well as at the endocytic zone—the periactive zone.…”

Section: Discussionmentioning

confidence: 99%

The role of PDLIM1, a PDZ‐LIM domain protein, at the ribbon synapses in the chicken retina

Rı́os

Paganelli

Fosser

2020

J of Comparative Neurology

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PDLIM's protein family is involved in the rearrangement of the actin cytoskeleton. In the present study, we describe the localization of PDLIM1 in chicken photoreceptors.This study provides evidence that this protein is present at the cone pedicles, as well as in other synapses of the chicken retina. Here, we demonstrate the expression pattern of PDLIM1 through immunofluorescence staining, immunoblots, subcellular fractionation, and immunoprecipitation experiments. Also, we consider the possibility that PDLIM1 may be involved in the synaptic vesicle endocytosis and/or the presynaptic trafficking of synaptic vesicles back to the nonready releasable pool. This endocytotic/exocytotic coupling requires a tight link between exocytic vesicle fusion at defined release sites and endocytic retrieval of synaptic vesicle membranes. In turn, photoreceptor ribbon synaptic structure depends on the cytoskeleton arrangement, both at the active zone-related with exocytosis-as well as at the endocytic zoneperiactive zone. To our knowledge, the PDLIM1 protein has not been observed in the pre synapses of the retina. Thus, the present study describes the expression and subcellular localization of PDLIM1 for the first time, as well as its modulation by visual environment in the chicken retina. K E Y W O R D SPDLIM1, PDZ and Lim protein 1, photoreceptors, retina, ribbon synapses, RRID:

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“…These detailed biophysical models exhibit improved biophysical interpretability, elegantly depicting the cascade of vesicle movements in presynaptic terminals. However, the design of these biophysical models requires precise knowledge beyond the reach of experimental techniques, such as vesicle resupply processes from the cytoplasm to the RRP (31)(32)(33). In addition, it's infeasible to perform theoretical analysis on these models due to their complicated kinetics, severely preventing them from being widely used as an analytical tool in adaptation research.…”

Section: Introductionmentioning

confidence: 99%

A computational framework linking synaptic adaptation to circuit behaviors in the early visual system

Lun

et al. 2022

Preprint

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Retina ribbon synapses are the first synapses in the visual system. Unlike the conventional synapses in the central nervous system triggered by action potentials, ribbon synapses are uniquely driven by graded membrane potentials and are thought to transfer early sensory information faithfully. However, how ribbon synapses compress the visual signals and contribute to visual adaptation in retina circuits is less understood. To this end, we introduce a physiologically constrained module for the ribbon synapse, termed Ribbon Adaptive Block (RAB), and an extended "hierarchical Linear-Nonlinear-Synapse" (hLNS) framework for the retina circuit. Our models can elegantly reproduce a wide range of experimental recordings on synaptic and circuit-level adaptive behaviors across different cell types and species. In particular, it shows strong robustness to unseen stimulus protocols. Intriguingly, when using the hLNS framework to fit intra-cellular recordings from the retina circuit under stimuli similar to natural conditions, we revealed rich and diverse adaptive time constants of ribbon synapses. Furthermore, we predicted a frequency-sensitive gain-control strategy for the synapse between the photoreceptor and the CX bipolar cell, which differ from the classic contrast-based strategy in retina circuits. Overall, our framework provides a powerful analytical tool for exploring synaptic adaptation mechanisms in early sensory coding.

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Calmodulin enhances ribbon replenishment and shapes filtering of synaptic transmission by cone photoreceptors

Cited by 3 publications

References 90 publications

Two Pools of Vesicles Associated with Synaptic Ribbons Are Molecularly Prepared for Release

Two Pools of Vesicles Associated with Synaptic Ribbons Are Molecularly Prepared for Release

The role of PDLIM1, a PDZ‐LIM domain protein, at the ribbon synapses in the chicken retina

A computational framework linking synaptic adaptation to circuit behaviors in the early visual system

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