Dye-coupling visualizes networks of large-field motion-sensitive neurons in the fly

In the fly, visually guided course control is accomplished by a set of 60 large-field motion-sensitive neurons in each brain hemisphere. These neurons have been shown to receive retinotopic motion information from local motion detectors on their dendrites. In addition, recent experiments revealed ex...

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Veröffentlicht in:	Journal of Comparative Physiology 2005-05, Vol.191 (5), p.445-454
Hauptverfasser:	Haag, J, Borst, A
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Sprache:	eng
Schlagworte:	Animals Axons - physiology Biotin - analogs & derivatives Biotin - analysis brain Calliphora vicina differential staining Diptera Diptera - physiology Dyes Electric Stimulation electrical coupling electrical synapses electrophysiology Female fluorescein Fluorescein - analysis fluorescent dyes labeling techniques Motion detectors motion vision Movement Nerve Net - cytology Nerve Net - physiology neurobiotin Neurons - cytology Neurons - physiology receptive fields sensory neurons synapse synaptic transmission vision
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creator	Haag, J Borst, A
description	In the fly, visually guided course control is accomplished by a set of 60 large-field motion-sensitive neurons in each brain hemisphere. These neurons have been shown to receive retinotopic motion information from local motion detectors on their dendrites. In addition, recent experiments revealed extensive coupling between the large-field neurons through electrical synapses. These two processes together give rise to their broad and elaborate receptive fields significantly surpassing the extent of their dendritic fields. Here, we demonstrate that the electrical connections between different large-field neurons can be visualized using Neurobiotin dye injection into a single one of them. When combined with a fluorescent dye which does not cross electrical synapses, the injected cell can be identified unambiguously. The Neurobiotin staining corroborates the electrical coupling postulated amongst the cells of the vertical system (VS-cells) and between cells of the horizontal system (HS-cells and CH-cells). In addition, connections between some cells are revealed that have so far not been considered as electrically coupled.
doi_str_mv	10.1007/s00359-005-0605-0
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subjects	Animals Axons - physiology Biotin - analogs & derivatives Biotin - analysis brain Calliphora vicina differential staining Diptera Diptera - physiology Dyes Electric Stimulation electrical coupling electrical synapses electrophysiology Female fluorescein Fluorescein - analysis fluorescent dyes labeling techniques Motion detectors motion vision Movement Nerve Net - cytology Nerve Net - physiology neurobiotin Neurons - cytology Neurons - physiology receptive fields sensory neurons synapse synaptic transmission vision
title	Dye-coupling visualizes networks of large-field motion-sensitive neurons in the fly
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