Mechanisms Underlying Signal Filtering at a Multisynapse Contact

Budisantoso, Timotheus; Matsui, Kosuke; Kamasawa, Naomi; Fukazawa, Yugo; Shigemoto, Ryuichi

doi:10.1523/jneurosci.5243-11.2012

Cited by 47 publications

(120 citation statements)

References 77 publications

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“…Transmitter spillover most likely occurs when the transmitter concentration is high, e.g. after MVR, when release sites are closely spaced, or in the absence of glial diffusion barriers and uptake machinery [48–51]. A clear distinction between spillover from a neighboring release site and MVR is often difficult because both phenomena can result in prolonged presence of transmitter in the synaptic cleft and at extrasynaptic sites [52–54].…”

Section: How Mvr Shapes Synaptic Transmissionmentioning

confidence: 99%

“…Hence, desensitization occurs at some but not all MVR synapses. For example, there is minimal desensitization of AMPARs at synapses where glutamate is rapidly cleared by glial and neuronal EAATs (CF�Purkinje cell (CF�PC) synapses) [69, 70], whereas MVR results in profound desensitization at retinogeniculate contacts [51]. In conclusion, MVR can exacerbate desensitization, but synapse tortuosity, glial coverage, receptor composition and spacing of release sites are likely the main factors [71, 72].…”

Section: How Mvr Shapes Synaptic Transmissionmentioning

confidence: 99%

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The ubiquitous nature of multivesicular release

Rudolph¹,

Tsai²,

Gersdorff³

et al. 2015

Trends in Neurosciences

133

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“Simplicity is prerequisite for reliability.”EW Dijkstra [1] Presynaptic action potentials trigger the fusion of vesicles to release neurotransmitter onto postsynaptic neurons. Each release site was originally thought to liberate at most one vesicle per action potential in a probabilistic fashion, rendering synaptic transmission unreliable. However, the simultaneous release of several vesicles, or multivesicular release (MVR), represents a simple mechanism to overcome the intrinsic unreliability of synaptic transmission. MVR was initially identified at specialized synapses but is now known to be common throughout the brain. MVR determines the temporal and spatial dispersion of transmitter, controls the extent of receptor activation, and contributes to adapting synaptic strength during plasticity and neuromodulation. MVR consequently represents a widespread mechanism that extends the dynamic range of synaptic processing.

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Section: How Mvr Shapes Synaptic Transmissionmentioning

confidence: 99%

Section: How Mvr Shapes Synaptic Transmissionmentioning

confidence: 99%

The ubiquitous nature of multivesicular release

Rudolph¹,

Tsai²,

Gersdorff³

et al. 2015

Trends in Neurosciences

133

View full text Add to dashboard Cite

show abstract

“…Glutamate is the excitatory neurotransmitter packed into numerous round vesicles contained in large synaptic terminals along the axon (Montero & Wenthold, 1989). A single retinal axon terminal can span ~1–4 microns in diameter and contain multiple spatially distinct neurotransmitter release sites (cat and mouse studies: Famiglietti & Peters, 1972; Rafols & Valverde, 1973; Sur & Sherman, 1982; Hamos et al, 1987; Robson, 1993; Bickford et al, 2010; Budisantoso et al, 2012; Morgan et al, 2016). RGC boutons contact a TC neuron near its cell body, synapsing directly onto the dendritic shaft or dendritic appendages that protrude from the proximal shaft or primary dendritic branch points (Rafols & Valverde, 1973; Robson & Mason, 1979; Wilson et al, 1984; Hamos et al, 1987; Bickford et al, 2010; Morgan et al, 2016).…”

Section: Retinogeniculate Synaptic Structurementioning

confidence: 99%

“…Large simple boutons in the rat contain an average of 27 independent release sites, whereas each of the boutons in a glomerulus has approximately 6 (Hamos et al, 1987; Budisantoso et al, 2012; Hammer et al, 2015). Notably, multiple RGCs may contribute to the same cluster or glomerulus of boutons (Hammer et al, 2015; Morgan et al, 2016).…”

Section: Retinogeniculate Synaptic Structurementioning

confidence: 99%

“…Fig. 1D shows an example of two such close retinogeniculate boutons along one TC neuron dendrite, highlighting that glutamate released from one bouton can diffuse to postsynaptic release sites of the neighboring bouton (Budisantoso et al, 2012). At a developmental phase when boutons are less clustered (Sur et al, 1984; Hong et al, 2014) and glomeruli have not yet formed, retinogeniculate transmission exhibits extensive gluta-mate spillover between neighboring boutons.…”

Section: Retinogeniculate Synaptic Structurementioning

confidence: 99%

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An evolving view of retinogeniculate transmission

Litvina

Chen

2017

Vis Neurosci

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The thalamocortical (TC) relay neuron of the dorsoLateral Geniculate Nucleus (dLGN) has borne its imprecise label for many decades in spite of strong evidence that its role in visual processing transcends the implied simplicity of the term “relay”. The retinogeniculate synapse is the site of communication between a retinal ganglion cell and a TC neuron of the dLGN. Activation of retinal fibers in the optic tract causes reliable, rapid, and robust postsynaptic potentials that drive postsynaptics spikes in a TC neuron. Cortical and subcortical modulatory systems have been known for decades to regulate retinogeniculate transmission. The dynamic properties that the retinogeniculate synapse itself exhibits during and after developmental refinement further enrich the role of the dLGN in the transmission of the retinal signal. Here we consider the structural and functional substrates for retinogeniculate synaptic transmission and plasticity, and reflect on how the complexity of the retinogeniculate synapse imparts a novel dynamic and influential capacity to subcortical processing of visual information.

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New Insight into the Structure–Activity Relationships of the Selective Excitatory Amino Acid Transporter Subtype 1 (EAAT1) Inhibitors UCPH‐101 and UCPH‐102

et al. 2016

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In the present study, we made further investigations on the structure-activity requirements of the selective excitatory amino acid transporter 1 (EAAT1) inhibitor, 2-amino-4-(4-methoxyphenyl)-7-(naphthalen-1-yl)-5-oxo-5,6,7,8-tetrahydro-4H-chromene-3-carbonitrile (UCPH-101), by exploring 15 different substituents (R(1) ) at the 7-position in combination with eight different substituents (R(2) ) at the 4-position. Among the 63 new analogues synthesized, we identified a number of compounds that unexpectedly displayed inhibitory activities at EAAT1 in light of understanding the structure-activity relationship (SAR) of this inhibitor class extracted from previous studies. Moreover, the nature of the R(1) and R(2) substituents were observed to contribute to the functional properties of the various analogues in additive and non-additive ways. Finally, separation of the four stereoisomers of analogue 14 g (2-amino-4-([1,1'-biphenyl]-4-yl)-3-cyano-7-isopropyl-5-oxo-5,6,7,8-tetrahydro-4H-chromene) was carried out, and in agreement with a study of a related scaffold, the R configuration at C4 was found to be mandatory for inhibitory activity, while both the C7 diastereomers were found to be active as EAAT1 inhibitors. A study of the stereochemical stability of the four pure stereoisomers 14 g-A-D showed that epimerization takes places at C7 via a ring-opening, C-C bond rotation, ring-closing mechanism.

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Mechanisms Underlying Signal Filtering at a Multisynapse Contact

Cited by 47 publications

References 77 publications

The ubiquitous nature of multivesicular release

The ubiquitous nature of multivesicular release

An evolving view of retinogeniculate transmission

New Insight into the Structure–Activity Relationships of the Selective Excitatory Amino Acid Transporter Subtype 1 (EAAT1) Inhibitors UCPH‐101 and UCPH‐102

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