Abstract
Cyclic GMP has been implicated in controlling the light-regulated conductance of rod photoreceptors of the vertebrate retina. However, there is little direct evidence correlating changes in cGMP concentration with the light-regulated permeability mechanism in living cells. A preparation of intact frog rod outer segments suspended in a Ringer's medium containing low Ca2+ has been used to demonstrate that initial changes in total cellular cGMP concentration parallel changes in the light-regulated membrane current over a wide range of light intensities. At light intensities bleaching from 160 to 5.6 X 10(6) rhodopsin molecules/rod/s, decreases in the response latency for the cGMP kinetics parallel decreases in the latent period of the electrical response. Further, changes in the rate of the cGMP decrease parallel the rate of membrane current suppression as the light intensity is varied. Up to 10(5) cGMP molecules are hydrolyzed per photolyzed rhodopsin, consistent with in vitro studies showing that each bleached rhodopsin can activate over 100 phosphodiesterase molecules. Addition of the Ca2+ ionophore, A23187, does not affect the initial kinetics of the cGMP decrease or of the electrical response, excluding a direct role for Ca2+ in the initial events of phototransduction. These results are consistent with cGMP being the intracellular messenger that links rhodopsin isomerization with changes in membrane permeability upon illumination. It is unlikely, however, that light-induced changes in total cGMP concentration are the sole regulators of membrane current. This is suggested by several observations: at bright light intensities, the subsecond light-induced cGMP decrease is essentially complete prior to complete suppression of membrane current; maximal light-induced decreases in cGMP concentration occur at all light intensities tested, whereas the extent of membrane current suppression varies over the same range of light intensities; changing the external Ca2+ concentration from 1 mM to 10 nM in the dark causes an increase in membrane current that is significantly more rapid than corresponding changes in cGMP concentration. Thus, light-induced changes in total cellular cGMP concentration correlate with some, but not all, aspects of the visual excitation process in vertebrate photoreceptors.
Highlights
Tro studies showingthat each bleached rhodopsin can Yau et al, 1986; Stern et al, 1986).It appears that thecGMP
Evidence for light-induced decreases in cGMP concentration hasbeen obtained in whole retinas, the outer segment layer of microdissected retinas,andin isolated rods
The major finding of this study is that initial changes in totalintrace~~ulareoncentr~tionof cGMP correIate with some, but not all, aspects of the electrical response of rod photoreceptors to illumination
Summary
Perchloric acid a t various times after addition of EGTA with and Preparation of Frog Photoreceptors-Retinas from dark-adapted without A23187. The quenched used to position a diffuse beam of light that illuminated the entire samples were analyzed for cGMP concentration as described above. The amount of shift in the current-response relation induced cGMP decrease was statistically significant) the data were that occurred when the diffuse spot was focused alloweda calculation analyzed using a cumulative sum control chart (Duncan, 1974).This of the light intensity of the unattenuated 75-pm diameter spot of method provides two estimates of the latentperiod of the cGMP light light (1.9 X lo R*/rod/s) In this way the light sources used for response: 1) the time at which there isastatistically significant biochemical and electrophysiological measurements were calibrated difference in the mean value of the light-exposed sample compared to deliver nearly identical illumination to isolated photoreceptors.
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