In vivo cGMP levels in frog photoreceptor cells as a function of light exposure.

By employing a combination of highly sensitive radioimmunoassays and histochemical techniques, an in vivo time course of cGMP levels has been determined in the outer segment, photoreceptor cell and outer plexiform layers of frog retina. Frogs (Rana pipiens) were dark-adapted overnight and either frozen rapidly (approximately 3 sec) in liquid nitrogen or exposed to periods of light varying between 0.1 sec and 2 hr before freezing. Frozen retinal sections were cut, freeze-dried, and samples of individual layers dissected out and analysed for cGMP. In the outer plexiform layer, there was a 42% drop in cGMP concentration after 2 sec of light (250 ft candles) followed by a 34% rise after 2 min; a steep concentration gradient formed around the layer after the 2 min exposure. In both the outer-segment layer and photoreceptor-cell layer (which includes outer segments, inner segments and outer nuclear layers), cGMP levels declined from a dark value of 56 mumol kg-1 (dry) to 9 mumol kg-1 (dry) as a result of increasing exposure to several types of light source: levels appear to be primarily a function of total ft candle min. Cyclic GMP concentrations at the longest exposures (2 min with a fiber optic light source or 2 hr with fluorescent room light) reached identical minimum levels. In the outer segments, a 15% decrease in cGMP was observed after 0.1 sec of light exposure. Although the freezing time is too long to be able to say whether the 15% decrease in cGMP at the 0.1 sec exposure is involved in transduction, the low identical levels reached gradually after longer exposures appear to indicate that a light-induced biochemical adjustment in cGMP metabolism occurs over a relatively long time period separate from the msec time course of the transduction process.

Adenine nucleotide and P-creatine levels in layers of frog retina as a function of dark and light adaptation.

Eight layers of frog retina were analyzed for ATP, P-creatine, ATP + ADP, and AMP under conditions of dark, 2 sec, 2 min, and in the case of AMP, 2 hr of light adaptation. Samples of each layer, usually ranging between 5 and 50 ng, were dissected from lyophilized frozen sections. After brief light exposure, ATP dropped while ADP rose sharply in the pigment epithelium, outer segments, and inner segments; ADP was too low to be measured accurately in the inner retina. The profile of ATP, P-creatine, and ATP + ADP concentrations showed peaks in the inner nuclear and ganglion layers. AMP, by contrast, was highest in the two plexiform layers. Levels in the inner retina dropped after only 2 sec of light but rose after 2 hr to levels that were higher than dark values in all retinal layers. AMP was often characterized by a non-uniform distribution: adjacent areas of a layer agreed very closely in value to each other but could vary several-fold from a different section of the same frog or from another frog exposed to the same conditions. This distribution produced clusters of values, particularly prominent in dark-adapted animals, something not observed with the other metabolites measured. The peaks of AMP in the plexiform layers suggest that AMP may be a by-product of dopamine-stimulated adenylate cyclase which also has peaks in these same layers.