Chemically inducible diffusion trap at cilia reveals molecular sieve-like barrier

Takanari Inoue; Yu Chun Lin; Pawel Niewiadomski; Benjamin Lin; Hideki Nakamura; Siew Cheng Phua; John Jiao; Andre Levchenko; Takafumi Inoue; Rajat Rohatgi

doi:10.1038/nchembio.1252

Chemically inducible diffusion trap at cilia reveals molecular sieve-like barrier

Takanari Inoue^*, Yu Chun Lin, Pawel Niewiadomski, Benjamin Lin, Hideki Nakamura, Siew Cheng Phua, John Jiao, Andre Levchenko, Takafumi Inoue^*, Rajat Rohatgi

^*この研究の対応する著者

先進理工学部

研究成果: Article › 査読

109 被引用数 (Scopus)

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Primary cilia function as specialized compartments for signal transduction. The stereotyped structure and signaling function of cilia inextricably depend on the selective segregation of molecules in cilia. However, the fundamental principles governing the access of soluble proteins to primary cilia remain unresolved. We developed a methodology termed 'chemically inducible diffusion trap at cilia' to visualize the diffusion process of a series of fluorescent proteins ranging in size from 3.2 nm to 7.9 nm into primary cilia. We found that the interior of the cilium was accessible to proteins as large as 7.9 nm. The kinetics of ciliary accumulation of this panel of proteins was exponentially limited by their Stokes radii. Quantitative modeling suggests that the diffusion barrier operates as a molecular sieve at the base of cilia. Our study presents a set of powerful, generally applicable tools for the quantitative monitoring of ciliary protein diffusion under both physiological and pathological conditions

本文言語	English
ページ（範囲）	437-443
ページ数	7
ジャーナル	Nature Chemical Biology
巻	9
号	7
DOI	https://doi.org/10.1038/nchembio.1252
出版ステータス	Published - 2013 7月

ASJC Scopus subject areas

分子生物学
細胞生物学

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10.1038/nchembio.1252

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title = "Chemically inducible diffusion trap at cilia reveals molecular sieve-like barrier",

abstract = "Primary cilia function as specialized compartments for signal transduction. The stereotyped structure and signaling function of cilia inextricably depend on the selective segregation of molecules in cilia. However, the fundamental principles governing the access of soluble proteins to primary cilia remain unresolved. We developed a methodology termed 'chemically inducible diffusion trap at cilia' to visualize the diffusion process of a series of fluorescent proteins ranging in size from 3.2 nm to 7.9 nm into primary cilia. We found that the interior of the cilium was accessible to proteins as large as 7.9 nm. The kinetics of ciliary accumulation of this panel of proteins was exponentially limited by their Stokes radii. Quantitative modeling suggests that the diffusion barrier operates as a molecular sieve at the base of cilia. Our study presents a set of powerful, generally applicable tools for the quantitative monitoring of ciliary protein diffusion under both physiological and pathological conditions",

author = "Takanari Inoue and Lin, {Yu Chun} and Pawel Niewiadomski and Benjamin Lin and Hideki Nakamura and Phua, {Siew Cheng} and John Jiao and Andre Levchenko and Takafumi Inoue and Rajat Rohatgi",

note = "Funding Information: We thank A. Seki (Stanford University) for the 5HT6 construct, S. Takeda (University of Yamanashi) for the GFP-IFT88 construct and M. Wolfgang (Johns Hopkins University) for β-Gal and luciferase constructs. We also thank D.N.R., T.K., H.I. and S.T. for helpful discussions. This study was supported in part by the US National Institutes of Health (the Baltimore Polycystic Kidney Disease Research and Clinical Core Center provided pilot funds GM092930 and P30 DK090868 to Takanari Inoue and R00CA129174 and R21NS074091 to R.R.) and other grants (Grant-in-Aid for Challenging Exploratory Research 23650197 to H.N. and Pew Foundation to R.R.).",

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AU - Inoue, Takanari

AU - Lin, Yu Chun

AU - Niewiadomski, Pawel

AU - Lin, Benjamin

AU - Nakamura, Hideki

AU - Phua, Siew Cheng

AU - Jiao, John

AU - Levchenko, Andre

AU - Inoue, Takafumi

AU - Rohatgi, Rajat

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N2 - Primary cilia function as specialized compartments for signal transduction. The stereotyped structure and signaling function of cilia inextricably depend on the selective segregation of molecules in cilia. However, the fundamental principles governing the access of soluble proteins to primary cilia remain unresolved. We developed a methodology termed 'chemically inducible diffusion trap at cilia' to visualize the diffusion process of a series of fluorescent proteins ranging in size from 3.2 nm to 7.9 nm into primary cilia. We found that the interior of the cilium was accessible to proteins as large as 7.9 nm. The kinetics of ciliary accumulation of this panel of proteins was exponentially limited by their Stokes radii. Quantitative modeling suggests that the diffusion barrier operates as a molecular sieve at the base of cilia. Our study presents a set of powerful, generally applicable tools for the quantitative monitoring of ciliary protein diffusion under both physiological and pathological conditions

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Chemically inducible diffusion trap at cilia reveals molecular sieve-like barrier

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