Outer segments of rod photoreceptors with the attached ellipsoid region of the inner segment were isolated from Rana pipiens retinae, and their membrane photocurrents measured with the suction electrode technique in the 'ellipsoid‐in' configuration. Under dark adapted conditions in standard Ringer solution, isolated rod outer segments with ellipsoids exhibited maximal photocurrents of 10‐30 pA, and light sensitivities of 0.2‐1.0 pA/isomerization. A local perfusion technique was employed to change rapidly the solution bathing the outer segment. Rods were tested for their sensitivity to protons by perfusion with Ringer solution of altered pH. The dark current was reversibly suppressed by low pH: in Ringer solution with Calcium activity aCa = 10(‐3)M dark current suppression obeyed a hyperbolic saturation law with apparent dissociation constant, pKa = 4.8. The decay of dark current of rods following poisoning with ouabain was retarded by low pH perfusion, as it was by light. Protons thus act to suppress the outer segment Na+ conductance. Three experiments support the hypothesis that protons act interior to the plasma membrane in suppressing the dark current. (1) Perfusion of rods at constant pH with Ringer solution having increased CO2 suppressed the dark current. (2) Removal of perfusate containing 50 mM‐NH4Cl causes transient dark current suppression. (3) Acetate, which acts as a neutral proton carrier, when added to Ringer solution, shifts the apparent pKa of dark current suppression to a higher pH. Dark current suppression by protons and recovery occurred with a time constant of ca. 1 s. Low pH perfusion retarded the recovery of the dark current from a saturating flash, slowed the light response in its linear range, and increased light sensitivity. Perfusion at pH = 10.5 caused a slight increase in dark current, sped up the recovery of the rod from a saturating flash, accelerated the linear response and decreased the light sensitivity. Lowering aCa of the Ringer solution caused the proton sensitivity of the dark current to drop. At aCa = 5 X 10(‐6) M the apparent pKa of dark current suppression was shifted about 0.8 pH units to pH = 4.0. Cells at aCa = 10(‐9) M were insensitive to pH = 3.5, which completely suppressed the dark current at normal aCa. Lowered aCa decreased light sensitivity. Both proton sensitivity and light sensitivity of dark current suppression were estimated for each member of a population of rods in various aCaS:proton sensitivity and light sensitivity were found to be linearly correlated over a range of 3 log units.(ABSTRACT TRUNCATED AT 400 WORDS)
[1]
E. Racker,et al.
CATION TRANSPORT IN RECONSTITUTED SYSTEMS *
,
1980,
Annals of the New York Academy of Sciences.
[2]
J. I. Korenbrot,et al.
Light-induced calcium release by intact retinal rods.
,
1980,
Proceedings of the National Academy of Sciences of the United States of America.
[3]
D. Fleischman,et al.
Guanylate cyclase of isolated bovine retinal rod axonemes.
,
1979,
Biochemistry.
[4]
T. Ebrey,et al.
Light-initiated changes of cyclic guanosine monophosphate levels in the frog retina measured with quick-freezing techniques
,
1979,
The Journal of general physiology.
[5]
R. Steinhardt,et al.
Intracellular pH controls protein synthesis rate in the sea urchine egg and early embryo.
,
1979,
Developmental biology.
[6]
S. E. Ostroy,et al.
Hydrogen ion effects of the vertebrate photoreceptor. The pK's of ionizable groups affecting cell permeability.
,
1978,
Archives of biochemistry and biophysics.
[7]
L. Pinto,et al.
Ionizable groups and conductances of the rod photoreceptor membrane
,
1978,
The Journal of general physiology.
[8]
R. Pannbacker.
Control of Guanylate Cyclase Activity in the Rod Outer Segment
,
1973,
Science.
[9]
W. A. Hagins,et al.
Kinetics of the photocurrent of retinal rods.
,
1972,
Biophysical journal.
[10]
P. Liebman,et al.
Real time assay of rod disk membrane cGMP phosphodiesterase and its controller enzymes.
,
1982,
Methods in enzymology.