Kinesin and dynein use distinct mechanisms to bypass obstacles

Ferro, Luke S.; Can, Sinan; Turner, Meghan A; Elshenawy, Mohamed M.; Yıldız, Ahmet

doi:10.7554/elife.48629

Cited by 59 publications

(58 citation statements)

References 48 publications

(102 reference statements)

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“…Intriguingly, these linear motor proteins do not always follow a strictly linear path along actin filaments or microtubules (MTs). They also produce force perpendicular to their direction of movement, generating sidesteps or off-axis movement along their filamentous tracks (Ricca & Rock, 2010;Brunnbauer et al, 2012;Ferro et al, 2019). Torque generation of motor proteins was first demonstrated by the purified Tetrahymena axonemal dynein, which rotates the microtubules around their axes while translocating them (Vale & Toyoshima, 1988).…”

Section: Introductionmentioning

confidence: 99%

“…Torque generation of motor proteins was first demonstrated by the purified Tetrahymena axonemal dynein, which rotates the microtubules around their axes while translocating them (Vale & Toyoshima, 1988). Subsequently, in vitro studies revealed that such torsional and axial force generation appears to be a prevalent feature for all three families of molecular motors (Nishizaka et al, 1993;Yajima & Cross, 2005;Beausang et al, 2008;Yajima et al, 2008;Ricca & Rock, 2010;Brunnbauer et al, 2012;Can et al, 2014;Ferro et al, 2019). However, it remains unclear whether motor proteins take sidesteps and generate torque in a living cell.…”

Section: Introductionmentioning

confidence: 99%

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Optimal sidestepping of intraflagellar transport kinesins regulates structure and function of sensory cilia

Xie

et al. 2020

The EMBO Journal

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Cytoskeletal‐based molecular motors produce force perpendicular to their direction of movement. However, it remains unknown whether and why motor proteins generate sidesteps movement along their filamentous tracks in vivo. Using Hessian structured illumination microscopy, we located green fluorescent protein (GFP)‐labeled intraflagellar transport (IFT) particles inside sensory cilia of live Caenorhabditis elegans with 3–6‐nanometer accuracy and 3.4‐ms resolution. We found that IFT particles took sidesteps along axoneme microtubules, demonstrating that IFT motors generate torque in a living animal. Kinesin‐II and OSM‐3‐kinesin collaboratively drive anterograde IFT. We showed that the deletion of kinesin‐II, a torque‐generating motor protein, reduced sidesteps, whereas the increase of neck flexibility of OSM‐3‐kinesin upregulated sidesteps. Either increase or decrease of sidesteps of IFT kinesins allowed ciliogenesis to the regular length, but changed IFT speeds, disrupted axonemal ninefold symmetry, and inhibited sensory cilia‐dependent animal behaviors. Thus, an optimum level of IFT kinesin sidestepping is associated with the structural and functional fidelity of cilia.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Optimal sidestepping of intraflagellar transport kinesins regulates structure and function of sensory cilia

Xie

et al. 2020

The EMBO Journal

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“…Microtubule surfaces in cells are crowded by numerous microtubule-associated proteins, which act as obstacles for processively moving molecular motors. When kinesin-1 encounters an obstacle, its run length decreases as kinesin-1 is more likely to dissociate from the microtubule 30,49 than to continue its run by switching the protofilaments by side-stepping and circumventing the obstacle 31 . In vitro single molecule experiments in cell lysate imitate the physiological state of microtubules crowded with microtubule associated proteins 30,59 , while rigor-binding kinesin-1 mutants provide static roadblocks masking the kinesin-1 binding sites 31 .…”

Section: Discussionmentioning

confidence: 99%

“…7 The microtubule surface in cells is crowded with numerous microtubule-associated proteins hindering the motion of molecular motors. Crowding of the microtubule surface results in a drastic shortening of the run length of kinesin-1 30,31,49,50 . Since we observed that TRAK1 increased the processivity of KIF5B, we wondered whether TRAK1 can extend the movement range of kinesin-1 in crowded conditions.…”

Section: Trak1 Increases the Processivity Of Kif5bmentioning

confidence: 99%

Mitochondria-adaptor TRAK1 promotes kinesin-1 driven transport in crowded environments

Henrichs

Grycová

Bařinka

et al. 2020

Preprint

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Intracellular trafficking of organelles, driven by kinesin-1 stepping along microtubules, underpins essential processes including neuronal activity. In absence of other proteins on the microtubule surface, kinesin-1 performs micron-long runs. Under protein crowding conditions, however, kinesin-1 motility is drastically impeded. It is thus unclear how kinesin-1 acts as an efficient transporter in crowded intracellular environments. Here, we demonstrate that TRAK1 (Milton), an adaptor protein essential for mitochondrial trafficking, activates kinesin-1 and increases its robustness of stepping in protein crowding conditions. Interaction with TRAK1 i) facilitated kinesin-1 navigation around obstacles, ii) increased the probability of kinesin-1 passing through cohesive envelopes of tau and iii) increased the run length of kinesin-1 in cell lysate.We explain the enhanced motility by the observed direct interaction of TRAK1 with microtubules, providing an additional anchor for the kinesin-1-TRAK1 complex. We propose adaptor-mediated tethering as a mechanism regulating kinesin-1 motility in various cellular environments.

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“…Microtubules are essential for maintaining the cell shape, polarity, migration and division [ 5 ]. Furthermore, they are utilized by protein motors kinesins and dyneins to transport molecules inside a cell [ 8 ].…”

Section: Microtubule Inhibitorsmentioning

confidence: 99%

Mitotic Poisons in Research and Medicine

et al. 2020

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Cancer is one of the greatest challenges of the modern medicine. Although much effort has been made in the development of novel cancer therapeutics, it still remains one of the most common causes of human death in the world, mainly in low and middle-income countries. According to the World Health Organization (WHO), cancer treatment services are not available in more then 70% of low-income countries (90% of high-income countries have them available), and also approximately 70% of cancer deaths are reported in low-income countries. Various approaches on how to combat cancer diseases have since been described, targeting cell division being among them. The so-called mitotic poisons are one of the cornerstones in cancer therapies. The idea that cancer cells usually divide almost uncontrolled and far more rapidly than normal cells have led us to think about such compounds that would take advantage of this difference and target the division of such cells. Many groups of such compounds with different modes of action have been reported so far. In this review article, the main approaches on how to target cancer cell mitosis are described, involving microtubule inhibition, targeting aurora and polo-like kinases and kinesins inhibition. The main representatives of all groups of compounds are discussed and attention has also been paid to the presence and future of the clinical use of these compounds as well as their novel derivatives, reviewing the finished and ongoing clinical trials.

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Kinesin and dynein use distinct mechanisms to bypass obstacles

Cited by 59 publications

References 48 publications

Optimal sidestepping of intraflagellar transport kinesins regulates structure and function of sensory cilia

Optimal sidestepping of intraflagellar transport kinesins regulates structure and function of sensory cilia

Mitochondria-adaptor TRAK1 promotes kinesin-1 driven transport in crowded environments

Mitotic Poisons in Research and Medicine

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