Investigation will continue of glial-neurone interactions and related questions for which the retina of the honeybee drone is a uniquely advantageous preparation. This tissue can be considered as composed of only three compartments: photoreceptor cells, extracellular space and a syncytium of glial cells. Measurements with ion-selective microelectrodes have shown that a physiological stimulus, light, causes changes in the free concentrations of K, Na and C1 in the three compartments. These measured changes do not maintain electroneutrality. A search for fluxes of additional, unidentified, ions will be made by investigating further the transmembrane fluxes of C1: coupled transport will be investigated with specific inhibitors and by use of pH microelectrodes. The emphasis will be on quantitative estimates of ion fluxes, and on the differences between the neurones and the glia. (Health relatedness: pathologies involving massive redistribution of ions such as epilepsy, ischemia.) Metabolic compartmentation in the drone retina is very marked: nearly all the mitochondria are in the photoreceptors and all detectable glycogen is in the glia. Stimulation with a single flash of light causes a transient threefold increase in 02 consumption and an increase in (ATP) in the photoreceptors has been predicted. This will be investigated by measuring light emission from luciferin/lucificerase injected into the photoreceptors. Light stimulation of the phtoreceptors modifies metabolism in the glia: changes in glial (ATP) and pH will be looked for. Glial Nai in superfused retinas is high and variable: studies will be made with electron microprobe X-ray analysis on tissue rapidly frozen on the living animal to see if the glia are used as a reservoir of Na in vivo. Starting from the desirability of more reliable estimates of the volume of the extracellular space, measurements will be made with ion-selective micro-electrodes of the diffusion of various ions through thin slices of retina. Comparison of different ions (monovalent, polyvalent, cations, anions) will provide information about the biophysical properties of the extracellular space.

Agency
National Institute of Health (NIH)
Institute
National Eye Institute (NEI)
Type
Research Project (R01)
Project #
5R01EY003504-08
Application #
3257837
Study Section
Visual Sciences A Study Section (VISA)
Project Start
1981-02-01
Project End
1990-01-31
Budget Start
1988-02-01
Budget End
1989-01-31
Support Year
8
Fiscal Year
1988
Total Cost
Indirect Cost
Name
University of Geneva
Department
Type
DUNS #
481076537
City
Geneva
State
Country
Switzerland
Zip Code
CH-1211
Poitry-Yamate, C; Tsacopoulos, M (1991) Glial (Muller) cells take up and phosphorylate [3H]2-deoxy-D-glucose in mammalian retina. Neurosci Lett 122:241-4
Coles, J A; Schneider-Picard, G (1989) Amplification of small signals by voltage-gated sodium channels in drone photoreceptors. J Comp Physiol A 165:109-18
Coles, J A; Orkand, R K; Yamate, C L (1989) Chloride enters glial cells and photoreceptors in response to light stimulation in the retina of the honey bee drone. Glia 2:287-97
Karwoski, C J; Coles, J A; Lu, H K et al. (1989) Current-evoked transcellular K+ flux in frog retina. J Neurophysiol 61:939-52
Coles, J A; Schneider-Picard, G (1989) Increase in glial intracellular K+ in drone retina caused by photostimulation but not mediated by an increase in extracellular K+. Glia 2:213-22
Coles, J A (1989) Functions of glial cells in the retina of the honeybee drone. Glia 2:1-9
Astion, M L; Coles, J A; Orkand, R K et al. (1988) K+ accumulation in the space between giant axon and Schwann cell in the squid Alloteuthis. Effects of changes in osmolarity. Biophys J 53:281-5
Coles, J A (1988) Bias current modifies the selectivity of liquid membrane ion-selective microelectrodes. Pflugers Arch 411:339-44
Munoz, J L; Coles, J A (1987) Quartz micropipettes for intracellular voltage microelectrodes and ion-selective microelectrodes. J Neurosci Methods 22:57-64
Astion, M L; Coles, J A; Orkand, R K (1987) Effects of bicarbonate on glial cell membrane potential in Necturus optic nerve. Neurosci Lett 76:47-52

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