Ting-Jui Chang scite author profile

Ting-Jui Chang

3Publications

98Citation Statements Received

275Citation Statements Given

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148

233

Affiliations

National Taiwan University, Institute of Atomic and Molecular Sciences, Academia Sinica, National Taiwan University of Science and Technology

Publications

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Super-resolution microscopy reveals coupling between mammalian centriole subdistal appendages and distal appendages

Chong

Wang

et al. 2020

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Subdistal appendages (sDAPs) are centriolar elements that are observed proximal to the distal appendages (DAPs) in vertebrates. Despite the obvious presence of sDAPs, structural and functional understanding of them remains elusive. Here, by combining super-resolved localization analysis and CRISPR-Cas9 genetic perturbation, we find that although DAPs and sDAPs are primarily responsible for distinct functions in ciliogenesis and microtubule anchoring, respectively, the presence of one element actually affects the positioning of the other. Specifically, we find dual layers of both ODF2 and CEP89, where their localizations are differentially regulated by DAP and sDAP integrity. DAP depletion relaxes longitudinal occupancy of sDAP protein ninein to cover the DAP region, implying a role of DAPs in sDAP positioning. Removing sDAPs alter the distal border of centrosomal γ-tubulins, illustrating a new role of sDAPs. Together, our results provide an architectural framework for sDAPs that sheds light on functional understanding, surprisingly revealing coupling between DAPs and sDAPs.

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Single-molecule localization microscopy reveals the ultrastructural constitution of distal appendages in expanded mammalian centrioles

2023

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Distal appendages (DAPs) are vital in cilia formation, mediating vesicular and ciliary docking to the plasma membrane during early ciliogenesis. Although numerous DAP proteins arranging a nine-fold symmetry have been studied using superresolution microscopy analyses, the extensive ultrastructural understanding of the DAP structure developing from the centriole wall remains elusive owing to insufficient resolution. Here, we proposed a pragmatic imaging strategy for two-color single-molecule localization microscopy of expanded mammalian DAP. Importantly, our imaging workflow enables us to push the resolution limit of a light microscope well close to a molecular level, thus achieving an unprecedented mapping resolution inside intact cells. Upon this workflow, we unravel the ultra-resolved higher-order protein complexes of the DAP and its associated proteins. Intriguingly, our images show that C2CD3, microtubule triplet, MNR, CEP90, OFD1, and ODF2 jointly constitute a unique molecular configuration at the DAP base. Moreover, our finding suggests that ODF2 plays an auxiliary role in coordinating and maintaining DAP nine-fold symmetry. Together, we develop an organelle-based drift correction protocol and a two-color solution with minimum crosstalk, allowing a robust localization microscopy imaging of expanded DAP structures deep into the gel-specimen composites.

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Single-molecule localization microscopy reveals the ultrastructural root constitution of distal appendages in expanded mammalian centrioles

Chang

Hsu

Yang

2022

Preprint

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Distal appendages (DAPs) are vital in cilia formation, mediating vesicular and ciliary docking to the plasma membrane during early ciliogenesis. Although numerous DAP proteins arranging a nine-fold symmetry have been studied using superresolution microscopy analyses, the extensive ultrastructural understanding of the DAP root structure developing from the centriole wall remains elusive owing to insufficient resolution. Here, we proposed a pragmatic imaging strategy for two-color single-molecule localization microscopy of swellable mammalian DAP proteins. Importantly, our imaging workflow enables us to push the resolution limit of a light microscope well close to an electron microscopy level, thus achieving an unprecedented λ/200 mapping precision inside intact cells. Upon this workflow, we unravel the ultra-resolved higher-order protein complexes of the core DAP. Intriguingly, C2CD3, microtubule triplet, and ODF2 jointly constitute the spatial basis of DAP, suggesting a unique configuration of the DAP assembly. Moreover, our results show that the distal-layered ODF2 labeled at the N- and C-terminus construct a fastening unit encircling the microtubule triplets. Together, we develop an organelle-based drift correction protocol and a two-color imaging solution with minimum crosstalk, allowing a robust localization microscopy imaging of expanded cellular structures deep into the gel-specimen composites.

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Ting-Jui Chang

Super-resolution microscopy reveals coupling between mammalian centriole subdistal appendages and distal appendages

Single-molecule localization microscopy reveals the ultrastructural constitution of distal appendages in expanded mammalian centrioles

Single-molecule localization microscopy reveals the ultrastructural root constitution of distal appendages in expanded mammalian centrioles

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