Cargo rigidity affects the sensitivity of dynein ensembles to individual motor pausing

Driller-Colangelo, Amalia R.; Chau, Karen W.L.; Morgan, Joe P.; Derr, Nathan D.

doi:10.1002/cm.21339

Cited by 17 publications

(15 citation statements)

References 41 publications

(98 reference statements)

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“…The mechanical interaction between two coupled motors also depends on the stiffness of the cargo and properties of the motor (15,27,28). Here we showed that two myoVc motors have longer run lengths when coupled via a flexible DNA linker compared with a rigid linker.…”

Section: Myovc Molecules Coordinate To Transport Cargomentioning

confidence: 76%

Small teams of myosin Vc motors coordinate their stepping for efficient cargo transport on actin bundles

Krementsova

Furuta

Oiwa

et al. 2017

Journal of Biological Chemistry

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Myosin Vc (myoVc) is unique among vertebrate class V myosin isoforms in that it requires teams of motors to move continuously on single actin filaments. Single molecules of myoVc cannot take multiple hand-over-hand steps from one actin-binding site to the next without dissociating, in stark contrast to the well studied myosin Va (myoVa) isoform. At low salt, single myoVc motors can, however, move processively on actin bundles, and at physiologic ionic strength, even teams of myoVc motors require actin bundles to sustain continuous motion. Here, we linked defined numbers of myoVc or myoVa molecules to DNA nanostructures as synthetic cargos. Using total internal reflectance fluorescence microscopy, we compared the stepping behavior of myoVc myoVa ensembles and myoVc stepping patterns on single actin filaments actin bundles. Run lengths of both myoVc and myoVa teams increased with motor number, but only multiple myoVc motors showed a run-length enhancement on actin bundles compared with actin filaments. By resolving the stepping behavior of individual myoVc motors with a quantum dot bound to the motor domain, we found that coupling of two myoVc motors significantly decreased the futile back and side steps that were frequently observed for single myoVc motors. Changes in the inter-motor distance between two coupled myoVc motors affected stepping dynamics, suggesting that mechanical tension coordinates the stepping behavior of two myoVc motors for efficient directional motion. Our study provides a molecular basis to explain how teams of myoVc motors are suited to transport cargos such as zymogen granules on actin bundles.

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Section: Myovc Molecules Coordinate To Transport Cargomentioning

confidence: 76%

Small teams of myosin Vc motors coordinate their stepping for efficient cargo transport on actin bundles

Krementsova

Furuta

Oiwa

et al. 2017

Journal of Biological Chemistry

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“…Our data raise the possibility these faster speeds are due to more two-dynein complexes. However, previous reports suggested that whereas artificially tethering dyneins increased run length, it had little or no effect on velocity 26 , 27 .…”

Section: Two Dyneins Increase Force and Speedmentioning

confidence: 79%

Cryo-EM shows how dynactin recruits two dyneins for faster movement

Urnavicius

Lau

Elshenawy

et al. 2018

Nature

261

399

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Dynein and its cofactor dynactin form a highly processive microtubule motor in the presence of an activating adaptor, such as BICD2. Different adaptors link dynein/dynactin to distinct cargos. Here we use electron microscopy (EM) and single molecule studies to show that adaptors can recruit a second dynein to dynactin. Whereas BICD2 is biased toward recruiting a single dynein, the adaptors BICDR1 and HOOK3 predominantly recruit two. We find that the shift toward a double dynein complex increases both force and speed. A 3.5 Å cryo-EM reconstruction of a dynein tail/dynactin/BICDR1 complex reveals how dynactin can act as a scaffold to coordinate two dyneins side by side. Our work provides a structural basis for how diverse adaptors recruit different numbers of dyneins and regulate the motile properties of the dynein/dynactin transport machine.

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“…Our data raise the possibility these faster speeds are due to more complexes containing two dyneins. However, artificial tethering of processive dynein or kinesin motors had suggested motor number has little or no effect on velocity (Derr et al 2012;Jamison et al 2012;Furuta et al 2013;Driller-Colangelo et al 2016).…”

Section: Two Dyneins Increase Force and Speedmentioning

confidence: 99%