Cryo-EM Reveals How Human Cytoplasmic Dynein Is Auto-inhibited and Activated

Cytoplasmic dynein-1 binds dynactin and cargo adaptor proteins to form a transport machine capable of long-distance processive movement along microtubules. However, it is unclear why dynein-1 moves poorly on its own or how it is activated by dynactin. Here, we present a cryoelectron microscopy struc...

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Bibliographic Details
Published in:Cell 2017-06, Vol.169 (7), p.1303-1314.e18
Main Authors: Zhang, Kai, Foster, Helen E., Rondelet, Arnaud, Lacey, Samuel E., Bahi-Buisson, Nadia, Bird, Alexander W., Carter, Andrew P.
Format: Article
Language:English
Subjects:
activation
Animals
auto-inhibition
cryo-EM
Cryoelectron Microscopy
Cytoplasmic Dyneins - chemistry
Cytoplasmic Dyneins - metabolism
Cytoplasmic Dyneins - ultrastructure
Dimerization
dynactin
Dynactin Complex - chemistry
Dynactin Complex - metabolism
dynein
Humans
Mice
microtubule
Microtubules - chemistry
Microtubules - metabolism
Models, Molecular
Molecular Motor Proteins - chemistry
Molecular Motor Proteins - metabolism
motor
Multiprotein Complexes - chemistry
Multiprotein Complexes - metabolism
Multiprotein Complexes - ultrastructure
phi-particle
Sf9 Cells
Spodoptera
Swine
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Summary:Cytoplasmic dynein-1 binds dynactin and cargo adaptor proteins to form a transport machine capable of long-distance processive movement along microtubules. However, it is unclear why dynein-1 moves poorly on its own or how it is activated by dynactin. Here, we present a cryoelectron microscopy structure of the complete 1.4-megadalton human dynein-1 complex in an inhibited state known as the phi-particle. We reveal the 3D structure of the cargo binding dynein tail and show how self-dimerization of the motor domains locks them in a conformation with low microtubule affinity. Disrupting motor dimerization with structure-based mutagenesis drives dynein-1 into an open form with higher affinity for both microtubules and dynactin. We find the open form is also inhibited for movement and that dynactin relieves this by reorienting the motor domains to interact correctly with microtubules. Our model explains how dynactin binding to the dynein-1 tail directly stimulates its motor activity. [Display omitted] •Cryo-EM shows human cytoplasmic dynein-1 in its auto-inhibited, phi-particle form•Phi-particle disruption in vitro and in cells reveals its role in dynein regulation•There is a transition from phi-particle to open-dynein: both forms are inhibited•Dynactin binds open-dynein and aligns its motors to activate processive movement Cryo-EM of human cytoplasmic dynein-1 reveals the mechanism underlying its auto-inhibition and activation.
ISSN:0092-8674
1097-4172
DOI:10.1016/j.cell.2017.05.025