Abstract
Amacrine cells were targeted for whole cell recording using two-photon fluorescence microscopy in a transgenic mouse line in which the promoter for dopamine receptor 2 drove expression of green fluorescent protein in a narrow field tristratified amacrine cell (TNAC) that had not been studied previously. Light evoked a multiphasic response that was the sum of hyperpolarizing and depolarization synaptic inputs consistent with distinct dendritic ramifications in the off and on sublamina of the inner plexiform layer. The amplitude and waveform of the response, which consisted of an initial brief hyperpolarization at light onset followed by recovery to a plateau potential close to dark resting potential and a hyperpolarizing response at the light offset varied little over an intensity range from 0.4 to ~10^6 Rh*/rod/s. This suggests that the cell functions as a differentiator that generates an output signal (a transient reduction in inhibitory input to downstream retina neurons) that is proportional to the derivative of light input independent of its intensity. The underlying circuitry appears to consist of rod and cone driven on and off bipolar cells that provide direct excitatory input to the cell as well as to GABAergic amacrine cells that are synaptically coupled to TNAC. Canonical reagents that blocked excitatory (glutamatergic) and inhibitory (GABA and glycine) synaptic transmission had effects on responses to scotopic stimuli consistent with the rod driven component of the proposed circuit. However, responses evoked by photopic stimuli were paradoxical and could not be interpreted on the basis of conventional thinking about the neuropharmacology of synaptic interactions in the retina.
Highlights
Amacrine cells are the most diverse class of retinal neurons and the least understood [1]
Cells dialyzed with pipette filling solution containing neurobiotin were examined using confocal microscopy and found to be narrow field amacrine cells (Fig 1C)
A single process extended from the cell body in the inner nuclear layer (INL) traveled vertically a short distance into the inner plexiform layer (IPL) before giving rise to three separate sets of lateral branches each extending over an area of 40–60 μm in diameter (Fig 1D)
Summary
Amacrine cells are the most diverse class of retinal neurons and the least understood [1]. There are approximately 40 different types—roughly 2 amacrines for each type of ganglion cell—but only a few have been studied in detail This list would include the AII [2,3,4], A17 [5,6,7,8], starburst [9,10,11,12] and dopaminergic amacrine cells [11,13,14,15,16]. The intact retina is an amorphous tissue that, with few exceptions, makes it impossible to accurately identify a particular cell type on what appears to be a homogeneous background sea of neurons. This problem may be surmounted, by using transgenic methods to selectively express fluorescent protein in specific retinal cells
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