Synaptic pathways that shape the excitatory drive in an OFF retinal ganglion cell

Buldyrev, Ilya; Puthussery, Theresa; Taylor, W. Rowland

doi:10.1152/jn.00924.2011

Cited by 41 publications

(71 citation statements)

References 77 publications

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“…The AMPA receptor-mediated component of the DSGC's synaptic response only appeared at higher stimulus contrasts. In contrast, however, a number of other studies indicate that AMPA/NMDA receptor-mediated inputs to DSGCs scale together as a function of contrast, consistent with observations in other types of ganglion cells, suggesting that AMPA and NMDA receptors are driven by a common source of glutamate (Buldyrev et al, 2012; Diamond and Copenhagen, 1995; Manookin et al, 2010; Poleg-Polsky and Diamond, 2016b; Stafford et al, 2014). These diverging results have given rise to two distinct models that explain how the DS circuit coordinates inhibition/excitation over a range of stimulus contrasts (Figure 1A & D), which underlies the DSGC's robust ability to compute direction (Grzywacz and Amthor, 2007; Nowak et al, 2011; Poleg-Polsky and Diamond, 2016b).…”

Section: Introductionsupporting

confidence: 68%

“Silent” NMDA Synapses Enhance Motion Sensitivity in a Mature Retinal Circuit

Sethuramanujam

Yao

deRosenroll

et al. 2017

Neuron

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Summary Retinal direction-selective ganglion cells (DSGCs) have the remarkable ability to encode motion over a wide range of contrasts, relying on well-coordinated excitation and inhibition (E/I). E/I is orchestrated by a diverse set of glutamatergic bipolar cells that drive DSGCs directly, as well as indirectly through feed-forward GABAergic/cholinergic signals mediated by starburst amacrine cells. Determining how direction-selective responses are generated across varied stimulus conditions requires understanding how glutamate, acetylcholine and GABA signals are precisely coordinated. Here, we use a combination of paired patch-clamp recordings, serial EM and large-scale multi-electrode array recordings to show that a single high-sensitive source of glutamate is processed differentially by starbursts via AMPA receptors and DSGCs via NMDA receptors. We further demonstrate how this novel synaptic arrangement enables DSGCs to encode direction robustly near threshold contrasts. Together, these results reveal a space-efficient synaptic circuit model for direction computations, in which ‘silent’ NMDA receptors play a critical roles.

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Section: Introductionsupporting

confidence: 68%

“Silent” NMDA Synapses Enhance Motion Sensitivity in a Mature Retinal Circuit

Sethuramanujam

Yao

deRosenroll

et al. 2017

Neuron

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“…In the retina, the distinct roles of these receptor types are less clear. Some ganglion cell types use NMDA receptors for the primary depolarizing response, whereas others have minimal NMDA receptor activity under physiological conditions (i.e., light-evoked responses with intact inhibition) (Manookin et al 2010, Venkataramani & Taylor 2010, Buldyrev et al 2012, Crook et al 2014). Both receptor types can respond to rapidly modulated presynaptic glutamate release (Stafford et al 2014).…”

Section: Parallel Excitatory Pathways Are Established At the First Rementioning

confidence: 99%

Functional Circuitry of the Retina

Demb

Singer

2015

Annu. Rev. Vis. Sci.

161

131

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The mammalian retina is an important model system for studying neural circuitry: Its role in sensation is clear, its cell types are relatively well defined, and its responses to natural stimuli—light patterns—can be studied in vitro. To solve the retina, we need to understand how the circuits pre-synaptic to its output neurons, ganglion cells, divide the visual scene into parallel representations to be assembled and interpreted by the brain. This requires identifying the component interneurons and understanding how their intrinsic properties and synapses generate circuit behaviors. Because the cellular composition and fundamental properties of the retina are shared across species, basic mechanisms studied in the genetically modifiable mouse retina apply to primate vision. We propose that the apparent complexity of retinal computation derives from a straightforward mechanism—a dynamic balance of synaptic excitation and inhibition regulated by use-dependent synaptic depression—applied differentially to the parallel pathways that feed ganglion cells.

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“…The basis for this deficit and shift in response amplitudes is not clear, but retinal pathology or reduced photon capture may cause some circuits to fall below detection threshold while the response of others is increased. 38,39 Quality and Limitations of Vision in Rds P90 Mice…”

Section: Visual Signal Generation and Transmissionmentioning

confidence: 99%