SummaryRab GTPases regulate various membrane trafficking pathways but the mechanisms by which GTPase-activating proteins recognise specific Rabs are not clear. Rab8 is involved in controlling several trafficking processes, including the trafficking of transferrin receptor from the early endosome to the recycling endosome. Here, we provide evidence to show that TBC1D17, a Rab GTPase-activating protein, through its catalytic activity, regulates Rab8-mediated endocytic trafficking of transferrin receptor. Optineurin, a Rab8-binding effector protein, mediates the interaction and colocalisation of TBC1D17 with Rab8. A non-catalytic region of TBC1D17 is required for direct interaction with optineurin. Co-expression of Rab8, but not other Rabs tested, rescues the inhibition of transferrin receptor trafficking by TBC1D17. The activated GTP-bound form of Rab8 is localised to the tubules emanating from the endocytic recycling compartment. Through its catalytic activity, TBC1D17 inhibits recruitment of Rab8 to the tubules and reduces colocalisation of transferrin receptor and Rab8. Knockdown of optineurin or TBC1D17 results in enhanced recruitment of Rab8 to the tubules. A glaucoma-associated mutant of optineurin, E50K, causes enhanced inhibition of Rab8 by TBC1D17, resulting in defective endocytic recycling of transferrin receptor. Our results show that TBC1D17, through its interaction with optineurin, regulates Rab8-mediated endocytic recycling of transferrin receptor and recruitment of Rab8 to the endocytic recycling tubules. We describe a mechanism of regulating a Rab GTPase by an effector protein (optineurin) that acts as an adaptor to bring together a Rab (Rab8) and its GTPase-activating protein (TBC1D17).
Transferrin and its receptor play an important role in iron homeostasis. Binding of transferrin to its receptor (TFRC, transferrin receptor protein 1) initiates endocytic trafficking and subsequent recycling of TFRC to the plasma membrane. RAB8-positive tubules emanating from the endocytic recycling compartment play an important role in receptor recycling. However, the signaling pathways or mechanisms that mediate formation of RAB8-positive tubules are not clear. Here, we have investigated the role of transferrin-induced signaling in the regulation of RAB8- and MICAL-L1-positive tubules. Addition of transferrin to the serum starved HeLa cells resulted in enhanced recruitment of RAB8 as well as MICAL-L1 to the tubules, which was mediated by TFRC. Dynasore, an inhibitor of dynamin and endocytosis, completely blocked transferrin-induced formation of RAB8/MICAL-L1-positive tubules. RAB8 showed strong colocalization with MICAL-L1 on the tubules. Blocking of SRC or AKT kinase activity by specific inhibitors abolished transferrin-induced recruitment of RAB8 and MICAL-L1 to the tubules. Recycling of transferrin receptor was inhibited by blocking of AKT activity. TBC1D17, a GTPase activating protein for RAB8, inhibited RAB8/MICAL-L1-positive tubule formation. A phospho-mimicking mutant S366D of TBC1D17 did not inhibit formation of RAB8-positive tubules. Overall, these results show that transferrin induces TFRC mediated signaling dependent on endocytosis that is essential for the formation of RAB8- and MICAL-L1-positive tubules involved in recycling of transferrin receptor. Our results also show that AKT regulates transferrin-induced formation of RAB8- and MICAL-L1-positive tubules, which might be mediated by phosphorylation of TBC1D17.
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