Visual receptor cycle in normal and period mutant Drosophila: microspectrophotometry, electrophysiology, and ultrastructural morphometry.

Visual pigment, sensitivity, and rhabdomere size were measured throughout a 12-h light/12-h dark cycle in Drosophila. Visual pigment and sensitivity were measured during subsequent constant darkness [dark/dark (D/D)]. MSP (microspectrophotometry) and the ERG (electroretinogram) revealed a cycling of visual pigment and sensitivity, respectively. A visual pigment decrease of 40% was noted at 4 h after light onset that recovered 2-4 h later in white-eyed (otherwise wild-type, w per+) flies. The ERG sensitivity [in w per+ flies in light/dark (L/D)] decreased by 75% at 4 h after light onset, more than expected if mediated by visual pigment (MSP) changes alone. ERG sensitivity begins decreasing 8 h before light onset while decreases in visual pigment begin 2 h after light onset. These cycles continue in constant darkness (D/D), suggesting a circadian rhythm. White-eyed period (per) mutants show similar cycles of visual pigment level and sensitivity in L/D; per's alterations, if any on the D/D cycles were subtle. The cross-sectional areas of rhabdomeres in w per+ were measured using electron micrographic (EM) morphometry. Area changed little through the L/D cycle.

Turnover of membrane and opsin in visual receptors of normal and mutant Drosophila.

Electron microscopy was used to investigate membrane turnover in the photoreceptors of Drosophila. Coated pits and vesicles, multivesicular bodies, primary lysosomes, multilamellate bodies, residual bodies and Golgi complexes are present throughout a light/dark cycle. Serial sections reveal that the membrane bounding of multivesicular bodies is only seen at an optimal plane of section. The temperature-sensitive shibire (shi(ts)) mutant has a defect in conversion of coated pits into vesicles which may also affect visual receptors. We used monoclonal antibodies to Rh1 in R1-6 receptors in the compound eye (also to Rh2 in ocellar receptors in the simple eyes) ro relate turnover processes at the visual pigment compared with membrane levels. Compound eye rhabdomeres but not rhabdomere caps stained selectively. Immunogold labelling was equivocal in multivesicular bodies. Further, early in the process of carotenoid replacement therapy, labelling is high in the rough endoplasmic reticulum, demonstrating de novo opsin synthesis.

Carotenoid replacement therapy in Drosophila: recovery of membrane, opsin and visual pigment.

Rhabdomeres are substantially smaller and visual pigment is nearly eliminated when Drosophila are carotenoid-deprived from egg to adult. Rhabdomeres enlarge and visual pigment increases with carotenoid replacement in adults using carrot juice. We used a monoclonal antibody to the opsin in R1-6 receptors in the compound eye to further quantify opsin recovery in such carotenoid replacement therapy. Density of immunogold, specific to R1-6 (vs. R7), increases between days 1 and 3 of replacement as visual pigment and rhabdomeres recover. In summary, visual pigment, opsin and the opsin-containing organelle recover during carotenoid replacement therapy in carotenoid-deprived Drosophila.