We show that various types of rods and cones in the dark-adapted salamander retina are electrically coupled with linear and symmetrical junctional conductances G(j) (40-223 pS) and a rank order: Rod(C)-large single cone, rod-large single cone, rod-small single cone, rod-accessory double cone and rod-principal double cone. By systematically comparing the transjunctional current-voltage (I(j)-V(j)) relations and average G(j) values of the five types of rod-cone pairs recorded at day and night times, our results suggest that the differences in G(j) values among various types of rod-cone pairs are not caused by circadian differences, and the circadian-dependent changes in rod-cone coupling observed in the fish and rodent retinas are not present in the tiger salamander. In addition to rod-cone coupling, there is a sign-inverting, unidirectional rod→cone current I(RC), and the I(RC)-V(Cone) relations are linear, with a reversal potential near the chloride reversal potential E(Cl). I(RC) can be observed in rods and cones separated by at least 260 μm, and its waveform resembles that of the rod-elicited horizontal cell (HC) response I(HC). A glutamate transporter-associated chloride channel blocker TBOA suppresses I(RC) but not I(HC). These results suggest that I(RC) is largely mediated by HCs via a sign-inverting feedback chemical synapse associated with a chloride channel. I(RC) significantly reduced rod→cone coupling in the frequency range below 15 Hz, allowing better separation of rod and cone signals in the dark-adapted retina.