A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

Joseph Atherton; Kai Jiang; Marcel M. Stangier; Yanzhang Luo; Shasha Hua; Klaartje Houben; Jolien J.E. Van Hooff; Agnel Praveen Joseph; Guido Scarabelli; Barry J. Grant; Anthony J. Roberts; Maya Topf; Michel O. Steinmetz; Marc Baldus; Carolyn A. Moores; Anna Akhmanova

doi:10.1038/nsmb.3483

A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

Joseph Atherton
, Kai Jiang
, Marcel M. Stangier
, Yanzhang Luo
, Shasha Hua
, Klaartje Houben
, Jolien J.E. Van Hooff
, Agnel Praveen Joseph
, Guido Scarabelli
, Barry J. Grant
, Anthony J. Roberts
, Maya Topf
, Michel O. Steinmetz
, Marc Baldus
, Carolyn A. Moores^*
, Anna Akhmanova

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

CAMSAP and Patronin family members regulate microtubule minus-end stability and localization and thus organize noncentrosomal microtubule networks, which are essential for cell division, polarization and differentiation. Here, we found that the CAMSAP C-terminal CKK domain is widely present among eukaryotes and autonomously recognizes microtubule minus ends. Through a combination of structural approaches, we uncovered how mammalian CKK binds between two tubulin dimers at the interprotofilament interface on the outer microtubule surface. In vitro reconstitution assays combined with high-resolution fluorescence microscopy and cryo-electron tomography suggested that CKK preferentially associates with the transition zone between curved protofilaments and the regular microtubule lattice. We propose that minus-end-specific features of the interprotofilament interface at this site serve as the basis for CKK's minus-end preference. The steric clash between microtubule-bound CKK and kinesin motors explains how CKK protects microtubule minus ends against kinesin-13-induced depolymerization and thus controls the stability of free microtubule minus ends.

Original language	English
Pages (from-to)	931-943
Number of pages	13
Journal	Nature Structural and Molecular Biology
Volume	24
Issue number	11
DOIs	https://doi.org/10.1038/nsmb.3483
Publication status	Published - 1 Nov 2017

Keywords

Cryoelectron microscopy
Cryoelectron tomography
Kinesin
Microtubules
NMR spectroscopy

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10.1038/nsmb.3483

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Atherton, J., Jiang, K., Stangier, M. M., Luo, Y., Hua, S., Houben, K., Van Hooff, J. J. E., Joseph, A. P., Scarabelli, G., Grant, B. J., Roberts, A. J., Topf, M., Steinmetz, M. O., Baldus, M., Moores, C. A., & Akhmanova, A. (2017). A structural model for microtubule minus-end recognition and protection by CAMSAP proteins. Nature Structural and Molecular Biology, 24(11), 931-943. https://doi.org/10.1038/nsmb.3483

@article{f198e8f987eb4f38ba858643e93e4ef5,

title = "A structural model for microtubule minus-end recognition and protection by CAMSAP proteins",

abstract = "CAMSAP and Patronin family members regulate microtubule minus-end stability and localization and thus organize noncentrosomal microtubule networks, which are essential for cell division, polarization and differentiation. Here, we found that the CAMSAP C-terminal CKK domain is widely present among eukaryotes and autonomously recognizes microtubule minus ends. Through a combination of structural approaches, we uncovered how mammalian CKK binds between two tubulin dimers at the interprotofilament interface on the outer microtubule surface. In vitro reconstitution assays combined with high-resolution fluorescence microscopy and cryo-electron tomography suggested that CKK preferentially associates with the transition zone between curved protofilaments and the regular microtubule lattice. We propose that minus-end-specific features of the interprotofilament interface at this site serve as the basis for CKK's minus-end preference. The steric clash between microtubule-bound CKK and kinesin motors explains how CKK protects microtubule minus ends against kinesin-13-induced depolymerization and thus controls the stability of free microtubule minus ends.",

keywords = "Cryoelectron microscopy, Cryoelectron tomography, Kinesin, Microtubules, NMR spectroscopy",

author = "Joseph Atherton and Kai Jiang and Stangier, \{Marcel M.\} and Yanzhang Luo and Shasha Hua and Klaartje Houben and \{Van Hooff\}, \{Jolien J.E.\} and Joseph, \{Agnel Praveen\} and Guido Scarabelli and Grant, \{Barry J.\} and Roberts, \{Anthony J.\} and Maya Topf and Steinmetz, \{Michel O.\} and Marc Baldus and Moores, \{Carolyn A.\} and Anna Akhmanova",

note = "Funding Information: We thank F. Govers (Wageningen University), V. Gelfand (Northwestern University) and M. Harterink (Utrecht University) for sharing reagents; E. Katrukha for advice on processing fluorescence microscopy data; R. Boelens for providing access to the solution-state NMR instrumentation; and S. Yokoyama and A. Nomura for sharing NMR resonance assignments of free CKK. A.A. was supported by ERC Synergy grant 609822. J.A., C.A.M. (MR/J000973/1), A.-P.J. and M.T. (MR/M019292/1) were supported by the Medical Research Council, UK. A.J.R. was supported by a Sir Henry Dale Fellowship from the Wellcome Trust and Royal Society (104196/Z/14/Z). G.S. and B.J.G. were supported by the National Institutes of Health (R01GM070862). M.B., Y.L. (grant 718.015.001) and K.H. (grant 718.015.001 and 184.032.207) were supported by the Netherlands Organization for Scientific Research (NWO). ssNMR experiments were supported by uNMR-NL, an NWO-funded National Roadmap Large-scale Facility of the Netherlands (grant 184.032.207). M.O.S. was supported by grants from the Swiss National Science Foundation (31003A\_ 166608) and from SystemsX.ch (RTD-TubeX). Publisher Copyright: {\textcopyright} 2017 Nature America, Inc., part of Springer Nature. All rights reserved.",

year = "2017",

month = nov,

day = "1",

doi = "10.1038/nsmb.3483",

language = "English",

volume = "24",

pages = "931--943",

journal = "Nature Structural and Molecular Biology",

issn = "1545-9993",

publisher = "Nature Research",

number = "11",

}

Atherton, J, Jiang, K, Stangier, MM, Luo, Y, Hua, S, Houben, K, Van Hooff, JJE, Joseph, AP, Scarabelli, G, Grant, BJ, Roberts, AJ, Topf, M, Steinmetz, MO, Baldus, M, Moores, CA & Akhmanova, A 2017, 'A structural model for microtubule minus-end recognition and protection by CAMSAP proteins', Nature Structural and Molecular Biology, vol. 24, no. 11, pp. 931-943. https://doi.org/10.1038/nsmb.3483

TY - JOUR

T1 - A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

AU - Atherton, Joseph

AU - Jiang, Kai

AU - Stangier, Marcel M.

AU - Luo, Yanzhang

AU - Hua, Shasha

AU - Houben, Klaartje

AU - Van Hooff, Jolien J.E.

AU - Joseph, Agnel Praveen

AU - Scarabelli, Guido

AU - Grant, Barry J.

AU - Roberts, Anthony J.

AU - Topf, Maya

AU - Steinmetz, Michel O.

AU - Baldus, Marc

AU - Moores, Carolyn A.

AU - Akhmanova, Anna

N1 - Funding Information: We thank F. Govers (Wageningen University), V. Gelfand (Northwestern University) and M. Harterink (Utrecht University) for sharing reagents; E. Katrukha for advice on processing fluorescence microscopy data; R. Boelens for providing access to the solution-state NMR instrumentation; and S. Yokoyama and A. Nomura for sharing NMR resonance assignments of free CKK. A.A. was supported by ERC Synergy grant 609822. J.A., C.A.M. (MR/J000973/1), A.-P.J. and M.T. (MR/M019292/1) were supported by the Medical Research Council, UK. A.J.R. was supported by a Sir Henry Dale Fellowship from the Wellcome Trust and Royal Society (104196/Z/14/Z). G.S. and B.J.G. were supported by the National Institutes of Health (R01GM070862). M.B., Y.L. (grant 718.015.001) and K.H. (grant 718.015.001 and 184.032.207) were supported by the Netherlands Organization for Scientific Research (NWO). ssNMR experiments were supported by uNMR-NL, an NWO-funded National Roadmap Large-scale Facility of the Netherlands (grant 184.032.207). M.O.S. was supported by grants from the Swiss National Science Foundation (31003A_ 166608) and from SystemsX.ch (RTD-TubeX). Publisher Copyright: © 2017 Nature America, Inc., part of Springer Nature. All rights reserved.

PY - 2017/11/1

Y1 - 2017/11/1

N2 - CAMSAP and Patronin family members regulate microtubule minus-end stability and localization and thus organize noncentrosomal microtubule networks, which are essential for cell division, polarization and differentiation. Here, we found that the CAMSAP C-terminal CKK domain is widely present among eukaryotes and autonomously recognizes microtubule minus ends. Through a combination of structural approaches, we uncovered how mammalian CKK binds between two tubulin dimers at the interprotofilament interface on the outer microtubule surface. In vitro reconstitution assays combined with high-resolution fluorescence microscopy and cryo-electron tomography suggested that CKK preferentially associates with the transition zone between curved protofilaments and the regular microtubule lattice. We propose that minus-end-specific features of the interprotofilament interface at this site serve as the basis for CKK's minus-end preference. The steric clash between microtubule-bound CKK and kinesin motors explains how CKK protects microtubule minus ends against kinesin-13-induced depolymerization and thus controls the stability of free microtubule minus ends.

AB - CAMSAP and Patronin family members regulate microtubule minus-end stability and localization and thus organize noncentrosomal microtubule networks, which are essential for cell division, polarization and differentiation. Here, we found that the CAMSAP C-terminal CKK domain is widely present among eukaryotes and autonomously recognizes microtubule minus ends. Through a combination of structural approaches, we uncovered how mammalian CKK binds between two tubulin dimers at the interprotofilament interface on the outer microtubule surface. In vitro reconstitution assays combined with high-resolution fluorescence microscopy and cryo-electron tomography suggested that CKK preferentially associates with the transition zone between curved protofilaments and the regular microtubule lattice. We propose that minus-end-specific features of the interprotofilament interface at this site serve as the basis for CKK's minus-end preference. The steric clash between microtubule-bound CKK and kinesin motors explains how CKK protects microtubule minus ends against kinesin-13-induced depolymerization and thus controls the stability of free microtubule minus ends.

KW - Cryoelectron microscopy

KW - Cryoelectron tomography

KW - Kinesin

KW - Microtubules

KW - NMR spectroscopy

UR - https://www.scopus.com/pages/publications/85032996350

U2 - 10.1038/nsmb.3483

DO - 10.1038/nsmb.3483

M3 - Article

C2 - 28991265

AN - SCOPUS:85032996350

SN - 1545-9993

VL - 24

SP - 931

EP - 943

JO - Nature Structural and Molecular Biology

JF - Nature Structural and Molecular Biology

IS - 11

ER -

A structural model for microtubule minus-end recognition and protection by CAMSAP proteins

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Keywords

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