Abstract
A primary cilium is present on most eukaryotic cells and represents a specialized organelle dedicated to signal transduction and mechanosensing. Defects in cilia function are the cause for several human diseases called ciliopathies. The serologically defined colon cancer antigen-3 (SDCCAG3) is a recently described novel endosomal protein mainly localized at early and recycling endosomes and interacting with several components of membrane trafficking pathways. Here we describe localization of SDCCAG3 to the basal body of primary cilia. Furthermore, we demonstrate that decreased expression levels of SDCCAG3 correlate with decreased ciliary length and a reduced percentage of ciliated cells. We show that SDCCAG3 interacts with the intraflagellar transport protein 88 (IFT88), a crucial component of ciliogenesis and intraciliary transport. Mapping experiments revealed that the N-terminus of SDCCAG3 mediates this interaction by binding to a region within IFT88 comprising several tetratricopeptide (TRP) repeats. Finally, we demonstrate that SDCCAG3 is important for ciliary localization of the membrane protein Polycystin-2, a protein playing an important role in the formation of polycystic kidney disease, but not for Rab8 another ciliary protein. Together these data suggest a novel role for SDCCAG3 in ciliogenesis and in localization of cargo to primary cilia.
Highlights
The cilium is a specialized membranous microtubule dependent protrusion of the plasma membrane dedicated to signal transduction as well as chemo- and mechanosensing[1,2,3]
Retinal pigment epithelial (RPE) cells stably expressing EGFP-Arl13b were stained for endogenous serologically defined colon cancer antigen-3 (SDCCAG3) using a specific anti-SDCCAG3 antibody
We observed similar basal body staining for SDCCAG3 in mouse Inner medullary Connecting Duct (IMCD)−3 cells and in human embryonic kidney (HEK) cells
Summary
The cilium is a specialized membranous microtubule dependent protrusion of the plasma membrane dedicated to signal transduction as well as chemo- and mechanosensing[1,2,3]. Cilia have a specialized ciliary protein translocation system for membrane and soluble proteins, the intraflagellar transport (IFT) system, which moves proteins into and within the cilium. This transport system consists of two main supramolecular IFT protein subcomplexes A and B, which are arranged in higher order protein arrays named IFT trains to move cargo along the axoneme microtubules via motor proteins[6,16,17,18]. We demonstrate that SDCCAG3 plays an important role in ciliogenesis and cargo localization in primary cilia
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