Direction-selective ganglion cells respond strongly to an image moving in the preferred direction and weakly to an image moving in the opposite, or null direction, and are critical for driving ocular-motor reflexes that stabilize images on the retina as we move through a visual scene. The preferred direction of direction-selective ganglion cells cluster along the cardinal directions (up, down, left and right) and the direction-selective ganglion cells sensitive to each cardinal direction are organized into mosaics such that at each point in space, each direction of motion is represented. The predominant model for the generation of direction selectivity in the retina is that a particular class of interneurons forms inhibitory synapses on the null side of the dendritic tree of direction- selective ganglion cells. The mechanisms that instruct the emergence of mosaics comprised of cells that receive an asymmetric distribution of inhibitory inputs during development are unknown. Here we propose to use a combination of state-of-the-art electrophysiological and imaging techniques to determine the mechanisms that underlie the development of these two essential features of direction-selectivity - the circuits that underlie the null side inhibition and the existence of direction-selective ganglion cells mosaics. In particular, we will determine whether spontaneous retinal activity plays a critical role in the formation of these circuits.

Public Health Relevance

Our research goal is to determine the factors that instruct the development of visual responses in the mammalian retina. In particular, we are studying the circuits that underlie the ability of the retina to detect the direction of motion of an object in the visual scene. This 'direction-selectivity' is critical for the normal visually-driven reflexes that stabilize an image on the retina as we move through a visual scene. Our work will determine what role neural activity in the retina plays in the wiring up of these direction-selective circuits. Developing a detailed understanding of the organizing principles that govern the normal development of the circuits may make it possible to understand the origin of neurological birth defects. Very early in the development, before visual experience is possible, both electrical and chemical activity is generated spontaneously throughout the immature visual system. There is growing evidence that this early activity is critical for the appropriate development of circuits that mediate vision. These findings give us insights as to why exposure of fetuses to pharmacological agents can lead to a variety of neuropathologies. In addition, gaining insights into the role of neural activity will provide critical insights into devising strategies that allow the nervous system to rewire normal functioning neural circuits in response to developmental abnormalities that affect vision.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Research Project (R01)
Project #
5R01EY019498-07
Application #
8866406
Study Section
Biology and Diseases of the Posterior Eye Study Section (BDPE)
Program Officer
Greenwell, Thomas
Project Start
2009-07-01
Project End
2016-06-30
Budget Start
2015-07-01
Budget End
2016-06-30
Support Year
7
Fiscal Year
2015
Total Cost
Indirect Cost
Name
University of California Berkeley
Department
Biochemistry
Type
Schools of Arts and Sciences
DUNS #
124726725
City
Berkeley
State
CA
Country
United States
Zip Code
94704
Marques, Tiago; Summers, Mathew T; Fioreze, Gabriela et al. (2018) A Role for Mouse Primary Visual Cortex in Motion Perception. Curr Biol 28:1703-1713.e6
Morrie, Ryan D; Feller, Marla B (2018) A Dense Starburst Plexus Is Critical for Generating Direction Selectivity. Curr Biol 28:1204-1212.e5
Tiriac, Alexandre; Smith, Benjamin E; Feller, Marla B (2018) Light Prior to Eye Opening Promotes Retinal Waves and Eye-Specific Segregation. Neuron 100:1059-1065.e4
Bos, RĂ©mi; Gainer, Christian; Feller, Marla B (2016) Role for Visual Experience in the Development of Direction-Selective Circuits. Curr Biol 26:1367-75
Rosa, Juliana M; Morrie, Ryan D; Baertsch, Hans C et al. (2016) Contributions of Rod and Cone Pathways to Retinal Direction Selectivity Through Development. J Neurosci 36:9683-95
Vlasits, Anna L; Morrie, Ryan D; Tran-Van-Minh, Alexandra et al. (2016) A Role for Synaptic Input Distribution in a Dendritic Computation of Motion Direction in the Retina. Neuron 89:1317-1330
Morrie, Ryan D; Feller, Marla B (2016) Development of synaptic connectivity in the retinal direction selective circuit. Curr Opin Neurobiol 40:45-52
Firl, Alana; Ke, Jiang-Bin; Zhang, Lei et al. (2015) Elucidating the role of AII amacrine cells in glutamatergic retinal waves. J Neurosci 35:1675-86
Morrie, Ryan D; Feller, Marla B (2015) An Asymmetric Increase in Inhibitory Synapse Number Underlies the Development of a Direction Selective Circuit in the Retina. J Neurosci 35:9281-6
Hamby, Aaron M; Rosa, Juliana M; Hsu, Ching-Hsiu et al. (2015) CaV3.2 KO mice have altered retinal waves but normal direction selectivity. Vis Neurosci 32:E003

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