Cells in situ are often polarized and have multiple plasma membrane domains. To establish and maintain these domains, polarized transport is essential, and its impairment results in genetic disorders. Nevertheless, the underlying mechanisms of polarized transport have not been elucidated. Drosophila photoreceptor offers an excellent model for studying this. We found that Rab10 impairment significantly reduced basolateral levels of Na + K + ATPase, mislocalizing it to the stalk membrane, which is a domain of the apical plasma membrane. Furthermore, the shrunken basolateral and the expanded stalk membranes were accompanied with abnormalities in the Golgi cisternae of Rab10-impaired retinas. The deficiencies of Rab10-GEF Crag or the Rab10 effector Ehbp1 phenocopied Rab10 deficiency, indicating that Crag, Rab10 and Ehbp1 work together for polarized trafficking of membrane proteins to the basolateral membrane. These phenotypes were similar to those seen upon deficiency of AP1 or clathrin, which are known to be involved in the basolateral transport in other systems. Additionally, Crag, Rab10 and Ehbp1 colocalized with AP1 and clathrin on the trans-side of Golgi stacks. Taken together, these results indicate that AP1 and clathrin, and Crag, Rab10 and Ehbp1 collaborate in polarized basolateral transport, presumably in the budding process in the trans-Golgi network.
Stratum is required for polarized transport in Drosophila photoreceptors through the stable expression of Rab10 and Rab35, which regulate basolateral and rhabdomere transport, respectively.
Polarized transport is essential for constructing multiple plasma membrane domains in the cell. Drosophila photoreceptors are an excellent model system to study the mechanisms of polarized transport. Rab11 is the key factor regulating the post-Golgi transport of rhodopsin 1 (Rh1), a photoreceptive protein, to the rhabdomere, a photoreceptive plasma membrane. Here, we found that neuronal Synaptobrevin (nSyb) colocalizes with Rab11 on the trans-side of Golgi stacks and post-Golgi vesicles at the rhabdomere-base, and nSyb-deficiency impairs rhabdomeric transport and induces accumulation of Rh1 and vesicles in the cytoplasm; this is similar to the effects of Rab11 loss. These results indicate that nSyb acts as a post-Golgi SNARE toward rhabdomeres. Surprisingly, in Rab11-, Rip11-, and nSyb-deficient photoreceptors, illumination enhances cytoplasmic accumulation of Rh1 colocalizing with Rab11, Rabenosyn5, nSyb, and Arrestin 1 (Arr1). Arr1 loss but not Rab5 dominant negative (Rab5DN) protein expression inhibits the light enhanced cytoplasmic Rh1 accumulation. Rab5DN inhibits the generation of Rh1 containing multi-vesicle bodies rather than Rh1 internalization. Overall, these results indicate that exocytic Rh1 mingle with endocytosed Rh1 and are then transported together to rhabdomeres.
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