Isolated retinal rods of the frog consisting of the outer segment and the ellipsoid were patch-clamped and recorded in the whole-cell mode. The recording pipettes were filled with solutions of different composition in order to alter the cytoplasmic content of sodium, phosphate, and calcium ions, and guanine nucleotides. When a simple medium with potassium as the principal cation was used, the dark voltage slowly approached more negative values. This tendency of spontaneous hyperpolarization was reduced significantly when cGMP or GTP were present in the pipette medium. Sodium ions, on the other hand, clearly increased the speed of hyperpolarization. In the presence of sodium (20 mM), the stabilizing effect of GTP did not occur and that of cGMP was clearly diminished. Phosphate (20 mM) neutralized the sodium effect. High calcium levels (100 μM) did not measurably influence the time course of hyperpolarization. We conclude that the normal cytoplasmic sodium level in rods does not exceed 10 mM and that higher internal sodium concentrations interfere with the sodium–calcium exchange mechanism.

Inside-out patches containing cGMP-gated channels were excised from catfish rod or cone outer segments and held under voltage clamp. The net cGMP-dependent currents elicited by saturating and subsaturating concentrations of cGMP at ±30 mV were measured and the dependence of current upon cGMP concentration was determined. The apparent affinity of the channel for its ligand was estimated by fitting these data with the Hill equation. The concentration of cGMP required to give half the maximum current (K1/2) in rod and cone channels at +30 mV was ~28 μM and ~37 μM, respectively, and was weakly voltage dependent. Thus, cone channels have an intrinsically higher K1/2 than rod channels. For both types of channel, the Hill coefficient was ~2.3. In the presence of calcium-calmodulin, the apparent affinity of the rod channel for cGMP decreased by about twofold, but the apparent affinity of the cone channels was unaffected. These results indicate that the open probability of the cone channel for its ligand cannot be modulated by calmodulin. This represents the first significant departure between rod and cone photoreceptors in mechanisms used by phototransduction and suggests that the β subunit of the cone channel must be different from that of the rod channel.

Single frog rods consisting of the outer segment and the ellipsoid were investigated by the whole-cell patch-clamp technique. When the recording pipette was filled with a simple intracellular medium containing potassium as the principal cation, a slow increase in dark voltage (hyperpolarization) associated with a decay of the photoresponses was observed. The hyperpolarization started at a dark voltage of −27 ± 8 mV, followed an exponential course, and leveled out at −52 ± 6 mV. The time constant was proportional to the access resistance of the preparations. With a pipette medium containing a 0.5 or 1.0 μM cGMP, the initial dark voltage was shifted to more positive values and the tendency of hyperpolarization was clearly attenuated. Similar results were obtained with 1 mM GTP. The effects of GDP and of ATP were less significant. In experiments with 1 mM GTP plus 1 mM ATP, the dark voltage behaved as in experiments with only GTP. The stabilizing action of GTP was amplified by EGTA so that with 1 mM GTP plus 1 mM free EGTA the dark voltage was stable at a level of −15 mV. It is concluded that the preparations lose intracellular components such as cGMP and GTP by diffusion into the recording pipette and that the losses are prevented or reduced when the pipette medium contains these nucleotides in nearly physiological concentrations. For the internal transmitter cGMP, the results suggest that its free concentration does not exceed 1 μM.

In retinal rods, light exposure decreases the total outer segment content of both cGMP and cAMP by about 50%. The functional role of the light-evoked change in cAMP is not known. It is postulated to trigger changes in the phosphorylation state of phosducin, a phosphoprotein that is phosphorylated in the dark by cAMP-dependent protein kinase (PKA) and dephosphorylated by basal phosphatase activity when PKA is inhibited by the light-evoked drop in cAMP. In biochemical studies, dephosphorylated phosducin binds to free βγ dimer of transducin (Tβγ) and prevents the regeneration of heterotrimeric transducin by blocking the re-association of the βγ and α subunits. Phosducin's interaction with Tβγ is blocked when it is phosphorylated on a single residue by PKA. To evaluate the effect of the light-evoked fall in cAMP, functionally intact isolated lizard rod outer segments were dialyzed in whole-cell voltage clamp with a standard internal solution and electrical light responses were recorded with and without adding cAMP to the dialysis solution. Since the total outer segment content of cAMP in darkness is ∼5 μM, internal dialysis with solution containing a much higher concentration (100 μM) of cAMP (or 8-bromo-cAMP) will overcome the effects of a light-evoked decrease in its concentration by keeping cAMP-dependent processes fully activated. Neither cyclic nucleotide had any influence on the generation, light sensitivity, recovery, or background adaptation of the flash response. These results also argue against the participation of phosducin in the sequence of events that are responsible for these aspects of rod function. This does not exclude the possibility of phosducin being involved in adaptation caused by higher light levels than used in the present study, that is, bleaching adaptation, or in light-dependent processes other than phototransduction.