4CK6

Pseudo-atomic model of microtubule-bound human kinesin-5 motor domain in the ADP.AlFx state, based on cryo-electron microscopy experiment.

4CK6 の概要

• エントリーDOI: 10.2210/pdb4ck6/pdb
• 関連するPDBエントリー: 4CK5 4CK7
• EMDBエントリー: 2533
• 分子名称: TUBULIN ALPHA-1D CHAIN, TUBULIN BETA-2B CHAIN, KINESIN-LIKE PROTEIN KIF11, ... (9 entities in total)
• 機能のキーワード: motor protein, kinesins, mechanochemistry, microtubules, mitosis
• 由来する生物種: HOMO SAPIENS (HUMAN); 詳細
• 細胞内の位置: Cytoplasm, cytoskeleton : Q2HJ86 Q6B856; Cytoplasm : P52732
• タンパク質・核酸の鎖数: 3
• 化学式量合計: 144197.30

構造登録者

Goulet, A.,Major, J.,Jun, Y.,Gross, S.,Rosenfeld, S.,Moores, C. (登録日: 2013-12-30, 公開日: 2014-02-05, 最終更新日: 2024-05-08)

主引用文献

Goulet, A.,Major, J.,Jun, Y.,Gross, S.P.,Rosenfeld, S.S.,Moores, C.A.
Comprehensive Structural Model of the Mechanochemical Cycle of a Mitotic Motor Highlights Molecular Adaptations in the Kinesin Family.
Proc.Natl.Acad.Sci.USA, 111:1837-, 2014

PubMed Abstract: Kinesins are responsible for a wide variety of microtubule-based, ATP-dependent functions. Their motor domain drives these activities, but the molecular adaptations that specify these diverse and essential cellular activities are poorly understood. It has been assumed that the first identified kinesin--the transport motor kinesin-1--is the mechanistic paradigm for the entire superfamily, but accumulating evidence suggests otherwise. To address the deficits in our understanding of the molecular basis of functional divergence within the kinesin superfamily, we studied kinesin-5s, which are essential mitotic motors whose inhibition blocks cell division. Using cryo-electron microscopy and determination of structure at subnanometer resolution, we have visualized conformations of microtubule-bound human kinesin-5 motor domain at successive steps in its ATPase cycle. After ATP hydrolysis, nucleotide-dependent conformational changes in the active site are allosterically propagated into rotations of the motor domain and uncurling of the drug-binding loop L5. In addition, the mechanical neck-linker element that is crucial for motor stepping undergoes discrete, ordered displacements. We also observed large reorientations of the motor N terminus that indicate its importance for kinesin-5 function through control of neck-linker conformation. A kinesin-5 mutant lacking this N terminus is enzymatically active, and ATP-dependent neck-linker movement and motility are defective, although not ablated. All these aspects of kinesin-5 mechanochemistry are distinct from kinesin-1. Our findings directly demonstrate the regulatory role of the kinesin-5 N terminus in collaboration with the motor's structured neck-linker and highlight the multiple adaptations within kinesin motor domains that tune their mechanochemistries according to distinct functional requirements.

PubMed: 24449904
DOI: 10.1073/PNAS.1319848111

実験手法

ELECTRON MICROSCOPY (9.2 Å)