Roles of TOG and jelly-roll domains of centrosomal protein CEP104 in its functions in cilium elongation and Hedgehog signaling

Takashi Yamazoe,Tomoaki Nagai,Shinya Umeda,Yuko Sugaya,Kensaku Mizuno

doi:10.1074/jbc.ra120.013334

Takashi Yamazoe, Tomoaki Nagai + Show 3 more

Open Access

https://doi.org/10.1074/jbc.ra120.013334

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Abstract

Primary cilia are generated through the extension of the microtubule-based axoneme. Centrosomal protein 104 (CEP104) localizes to the tip of the elongating axoneme, and CEP104 mutations are linked to a ciliopathy, Joubert syndrome. Thus, CEP104 has been implicated in ciliogenesis. However, the mechanism by which CEP104 regulates ciliogenesis remains elusive. We report here that CEP104 is critical for cilium elongation but not for initiating ciliogenesis. We also demonstrated that the tumor-overexpressed gene (TOG) domain of CEP104 exhibits microtubule-polymerizing activity and that this activity is essential for the cilium-elongating activity of CEP104. Knockdown/rescue experiments showed that the N-terminal jelly-roll (JR) fold partially contributes to cilium-elongating activity of CEP104, but neither the zinc-finger region nor the SXIP motif is required for this activity. CEP104 binds to a centriole-capping protein, CP110, through the zinc-finger region and to a microtubule plus-end-binding protein, EB1, through the SXIP motif, indicating that the binding of CP110 and EB1 is dispensable for the cilium-elongating activity of CEP104. Moreover, CEP104 depletion does not affect CP110 removal from the mother centriole, which suggests that CEP104 functions after the removal of CP110. Last, we also showed that CEP104 is required for the ciliary entry of Smoothened and export of GPR161 upon Hedgehog signal activation and that the TOG domain plays a critical role in this activity. Our results define the roles of the individual domains of CEP104 in its functions in cilium elongation and Hedgehog signaling and should enhance our understanding of the mechanism underlying CEP104 mutation-associated ciliopathies.

Highlights

Primary cilia are antenna-like protrusions that emanate from the surface of most vertebrate cells, and these structures consist of a microtubule (MT)-based axoneme that extends from a basal body and a ciliary membrane that envelopes the axoneme [1, 2]
We show that the Nterminal jelly-roll fold (JR fold) partially contributes to the cilium-elongating activity of Centrosomal protein 104 (CEP104), but neither the C-terminal ZF region nor the SXIP motif is necessary for this activity, which indicates that the cilium-elongating activity of CEP104 does not require its binding to centrosomal protein of 110 kDa (CP110), NIMArelated kinase-1 (NEK1), or end-binding protein-1 (EB1)
The removal of CP110 and centrosomal protein of 97 kDa (CEP97) is a key step required to initiate cilium extension, and CEP104 binds to these proteins at the distal ends of centrioles; CEP104 was proposed to play a role in ciliogenesis by affecting the centriolar-capping activity of CP110 and CEP97 or the removal of the two proteins from the mother centriole [29, 30]

Summary

Introduction

Primary cilia are antenna-like protrusions that emanate from the surface of most vertebrate cells, and these structures consist of a microtubule (MT)-based axoneme that extends from a basal body and a ciliary membrane that envelopes the axoneme [1, 2]. We investigated the role of the MT-polymerizing activity of the TOG domain in the cilium-elongating activity of CEP104; we constructed plasmids encoding yellow fluorescent protein (YFP)-tagged, siRNA-resistant (sr) WT CEP104 and its TOG domain mutant (WA/VD/RA) and used these in knockdown/rescue experiments.

Results

Conclusion