A Role for Synaptic Input Distribution in a Dendritic Computation of Motion Direction in the Retina

Vlasits, Anna; Morrie, Ryan D.; Tran-Van-Minh, Alexandra; Bleckert, Adam; Gainer, Christian F.; DiGregorio, David A.; Feller, Marla B.

doi:10.1016/j.neuron.2016.02.020

Cited by 88 publications

(185 citation statements)

References 45 publications

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“…Given the striking abundance of OSGCs in these two mammalian species, as well as reports of OSGCs in primates (Passaglia et al, 2002), it is likely that these cells directly contribute to orientation selectivity in higher visual centers. In line with this idea, several studies in rodents and primates have identified orientationselective neurons in noncortical areas, such as the dorsal lateral geniculate nucleus (dLGN; Cheong et al, 2013;Piscopo et al, 2013) and superior colliculus (Wang et al, 2010). Further supporting this possibility, recent studies have shown that mouse dLGN axonal projections provide orientation-selective inputs to primary visual cortex (Sun et al, 2016) and that inactivating primary visual cortex does not change the orientation tuning of dLGN neurons (Zhao et al, 2013).…”

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confidence: 90%

“…By comparison, our understanding of the mechanisms generating orientation selectivity in the retina is still rudimentary, largely due to the lack of specific molecular markers. Additionally, there is a drive to characterize the diversity of ganglion cell types, or feature channels, based on their functional, morphological, and genetic profiles (Baden et al, 2016). To date, how many OSGC types are present in the retina and how evolutionarily conserved they are across species remains unclear.…”

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confidence: 99%

“…For example, the alignment of dendrites along a preferred direction has a role in generating direction selectivity in some ganglion cells (Kim et al, 2008). To describe the dendritic morphology of ON-OSGCs and assess its potential role in generating orientation tuning, Nath and Schwartz (2016) and Venkataramani and Taylor (2016) filled functionally identified ON-OSGCs with fluorescent dyes.…”

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confidence: 99%

“…If scenario (2) is correct, the difference in their dendritic morphology is coincidental, not causative of orientation selectivity. Experiments mapping presynaptic inputs using 3D electron microscopy tracing (Briggman et al, 2011), high-resolution immunohistochemistry (Sigal et al, 2015), or neurotransmitter sensors/uncaging (Yonehara et al, 2013;Vlasits et al, 2016) would provide evidence on whether orientation selectivity is a consequence of a bias in the distribution of inputs on their dendritic arbors.…”

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confidence: 99%

“…In a previous study, Venkataramani and Taylor (2010) described two types of rabbit cardinal axes-tuned OFF-OSGCs, and in Venkataramani and Taylor (2016) they conclude that, collectively, OSGCs account for ϳ5% of all rabbit ganglion cells. In a comprehensive functional classification of mouse ganglion cells, Baden et al (2016) identified ON, OFF, and ON-OFF OSGCs comprising different cardinally and obliquely tuned types, which collectively represent ϳ15% of the retinal output. Given the striking abundance of OSGCs in these two mammalian species, as well as reports of OSGCs in primates (Passaglia et al, 2002), it is likely that these cells directly contribute to orientation selectivity in higher visual centers.…”

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confidence: 99%

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Orientation Selectivity in the Retina: ON Cell Types and Mechanisms

Antinucci

Abbas

Hunter

2016

Journal of Neuroscience

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confidence: 90%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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confidence: 99%

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Orientation Selectivity in the Retina: ON Cell Types and Mechanisms

Antinucci

Abbas

Hunter

2016

Journal of Neuroscience

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Embedded ensemble encoding hypothesis: The role of the “Prepared” cell

Antic

Hines

Lytton

2018

J of Neuroscience Research

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We here reconsider current theories of neural ensembles in the context of recent discoveries about neuronal dendritic physiology. The key physiological observation is that the dendritic plateau potential produces sustained depolarization of the cell body (amplitude 10-20 mV, duration 200-500 ms). Our central hypothesis is that synaptically-evoked dendritic plateau potentials lead to a prepared state of a neuron that favors spike generation. The plateau both depolarizes the cell toward spike threshold, and provides faster response to inputs through a shortened membrane time constant. As a result, the speed of synaptic-to-action potential (AP) transfer is faster during the plateau phase. Our hypothesis relates the changes from "resting" to "depolarized" neuronal state to changes in ensemble dynamics and in network information flow. The plateau provides the Prepared state (sustained depolarization of the cell body) with a time window of 200-500 ms. During this time, a neuron can tune into ongoing network activity and synchronize spiking with other neurons to provide a coordinated Active state (robust firing of somatic APs), which would permit "binding" of signals through coordination of neural activity across a population. The transient Active ensemble of neurons is embedded in the longer-lasting Prepared ensemble of neurons. We hypothesize that "embedded ensemble encoding" may be an important organizing principle in networks of neurons.

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Electrotonic signal processing in AII amacrine cells: compartmental models and passive membrane properties for a gap junction-coupled retinal neuron

2018

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Amacrine cells are critical for processing of visual signals, but little is known about their electrotonic structure and passive membrane properties. AII amacrine cells are multifunctional interneurons in the mammalian retina and essential for both rod- and cone-mediated vision. Their dendrites are the site of both input and output chemical synapses and gap junctions that form electrically coupled networks. This electrical coupling is a challenge for developing realistic computer models of single neurons. Here, we combined multiphoton microscopy and electrophysiological recording from dye-filled AII amacrine cells in rat retinal slices to develop morphologically accurate compartmental models. Passive cable properties were estimated by directly fitting the current responses of the models evoked by voltage pulses to the physiologically recorded responses, obtained after blocking electrical coupling. The average best-fit parameters (obtained at - 60 mV and ~ 25 °C) were 0.91 µF cm for specific membrane capacitance, 198 Ω cm for cytoplasmic resistivity, and 30 kΩ cm for specific membrane resistance. We examined the passive signal transmission between the cell body and the dendrites by the electrotonic transform and quantified the frequency-dependent voltage attenuation in response to sinusoidal current stimuli. There was significant frequency-dependent attenuation, most pronounced for signals generated at the arboreal dendrites and propagating towards the soma and lobular dendrites. In addition, we explored the consequences of the electrotonic structure for interpreting currents in somatic, whole-cell voltage-clamp recordings. The results indicate that AII amacrines cannot be characterized as electrotonically compact and suggest that their morphology and passive properties can contribute significantly to signal integration and processing.

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A Role for Synaptic Input Distribution in a Dendritic Computation of Motion Direction in the Retina

Cited by 88 publications

References 45 publications

Orientation Selectivity in the Retina: ON Cell Types and Mechanisms

Orientation Selectivity in the Retina: ON Cell Types and Mechanisms

Embedded ensemble encoding hypothesis: The role of the “Prepared” cell

Electrotonic signal processing in AII amacrine cells: compartmental models and passive membrane properties for a gap junction-coupled retinal neuron

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