The complexity of eukaryotic cells requires intracellular organization, coordination, and locomotion. To overcome these challenges, cells utilize ATP-driven molecular motors, which transport intracellular components unidirectionally along cytoskeletal tracks. Kinesin and cytoplasmic dynein motors facilitate bidirectional transport of a variety of cargos by moving towards the plus- and minus-ends of microtubules (MTs), respectively. Detailed mechanistic models exist for kinesin, but the mechanism and regulation of dynein motility are still emerging. We found that S. cerevisiae dynein walks on a MT through uncoordinated stepping of its two catalytic domains and its mechanism of action differs significantly from the coordinated hand-over- hand stepping of kinesin. Surprisingly, despite recent advances in structural characterization of dynein, the molecular origin of its strong directional preference to move towards the MT minus-end remains unclear. Recently, a recombinant expression system was developed for human dynein, opening the doors for detailed studies of its molecular mechanism for the first time. Surprisingly, human dynein exhibited only short processive runs and produces significantly lower forces than S. cerevisiae dynein in vitro, inconsistent with the ability of human dynein to transport large intracellular cargos over long distances inside cells. New work has revealed that processivity of human dynein is activated when it forms a 2.5 MDa ternary complex (referred to as DDB) with its cofactor dynactin and a cargo binding adaptor BicD2. In our preliminary work, we showed that dynactin and BicD2 also significantly enhance human dynein's force generation, suggesting that the DDB complex is a strong motor and a formidable opponent of kinesin when attached to the same cargo. The goal of this proposal is to dissect the mechanism of active human dynein complexes and determine how dynactin and BicD2 regulate dynein's ability to compete against kinesin-1 during bidirectional cargo transport. We have three specific aims. First, using protein engineering and single-molecule imaging, we will identify the mechanical components of dynein that give rise to its minus-end directed motility. We will also solve the MT-bound structure of ?reverse directionality? constructs via cryo-electron microscopy (cryoEM) to reveal the structural basis of dynein directionality. Second, we will identify which part(s) of the motor is responsible for its autoinhibition and characterize how dynactin and BicD2 regulate the mechanochemical cycle, stepping pattern and force generation of human dynein. Third, we will reconstitute bidirectional cargo transport on MTs in vitro using purified human kinesin and DDB complexes and reveal the mechanism and regulation of ?tug-of-war? between these motors. Success of our aims will significantly advance the understanding of the fundamental mechanochemistry of human dynein and learn how it achieves retrograde transport of intracellular cargos.

Public Health Relevance

Consistent with its fundamental roles in neurobiology and cell development, complete knockouts of dynein stop the entire MT transport machinery and inhibit mitosis. Mutations that alter the processivity or velocity of dynein movement lead to pathogenesis of motor neuron degeneration, Alzheimer's disease, ALS, lissencephaly and schizophrenia. A detailed investigation of dynein's mechanochemical cycle and its regulation by dynactin and cargo adaptor proteins will significantly contribute to our understanding of how certain point mutants of the dynein/dynactin complex lead to human disease and the development of specific chemical inhibitors/modifiers of dynein function for the treatment of these diseases in future studies.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Research Project (R01)
Project #
3R01GM094522-08S1
Application #
9709025
Study Section
Program Officer
Gindhart, Joseph G
Project Start
2011-04-01
Project End
2020-03-31
Budget Start
2018-04-01
Budget End
2019-03-31
Support Year
8
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of California Berkeley
Department
Physics
Type
Schools of Arts and Sciences
DUNS #
124726725
City
Berkeley
State
CA
Country
United States
Zip Code
94704
Urnavicius, Linas; Lau, Clinton K; Elshenawy, Mohamed M et al. (2018) Cryo-EM shows how dynactin recruits two dyneins for faster movement. Nature 554:202-206
Fu, Guo; Bandaria, Jigar N; Le Gall, Anne Valérie et al. (2018) MotAB-like machinery drives the movement of MreB filaments during bacterial gliding motility. Proc Natl Acad Sci U S A 115:2484-2489
Chien, Alexander; Shih, Sheng Min; Bower, Raqual et al. (2017) Dynamics of the IFT machinery at the ciliary tip. Elife 6:
Chen, Janice S; Dagdas, Yavuz S; Kleinstiver, Benjamin P et al. (2017) Enhanced proofreading governs CRISPR-Cas9 targeting accuracy. Nature 550:407-410
Wichner, Sara M; Mann, Victor R; Powers, Alexander S et al. (2017) Covalent Protein Labeling and Improved Single-Molecule Optical Properties of Aqueous CdSe/CdS Quantum Dots. ACS Nano 11:6773-6781
Qin, Peiwu; Parlak, Mahmut; Kuscu, Cem et al. (2017) Live cell imaging of low- and non-repetitive chromosome loci using CRISPR-Cas9. Nat Commun 8:14725
Belyy, Vladislav; Shih, Sheng-Min; Bandaria, Jigar et al. (2017) PhotoGate microscopy to track single molecules in crowded environments. Nat Commun 8:13978
Dagdas, Yavuz S; Chen, Janice S; Sternberg, Samuel H et al. (2017) A conformational checkpoint between DNA binding and cleavage by CRISPR-Cas9. Sci Adv 3:eaao0027
Can, Sinan; Yildiz, Ahmet (2017) Measurement of Force-Dependent Release Rates of Cytoskeletal Motors. Methods Mol Biol 1486:469-481
Belyy, V; Yildiz, A (2017) Studying the Mechanochemistry of Processive Cytoskeletal Motors With an Optical Trap. Methods Enzymol 582:31-54

Showing the most recent 10 out of 26 publications