Project description:Dyneins are large microtubule motor proteins required for mitosis, intracellular transport and ciliary and flagellar motility. They generate force through a power-stroke mechanism, which is an ATP-consuming cycle of pre- and post-power-stroke conformational changes that cause relative motion between different dynein domains. However, key structural details of dynein's force generation remain elusive. Here, using cryo-electron tomography of intact, active (that is, beating), rapidly frozen sea urchin sperm flagella, we determined the in situ three-dimensional structures of all domains of both pre- and post-power-stroke dynein, including the previously unresolved linker and stalk of pre-power-stroke dynein. Our results reveal that the rotation of the head relative to the linker is the key action in dynein movement, and that there are at least two distinct pre-power-stroke conformations: pre-I (microtubule-detached) and pre-II (microtubule-bound). We provide three-dimensional reconstructions of native dyneins in three conformational states, in situ, allowing us to propose a molecular model of the structural cycle underlying dynein movement.

Project description:Cytoplasmic dynein is the major motor protein responsible for microtubule minus-end-directed movements in most eukaryotic cells. It transports a variety of cargoes and has numerous functions during spindle assembly and chromosome segregation. It is a large complex of about 1.4 MDa composed of six different subunits, interacting with a multitude of different partners. Most biochemical studies have been performed either with the native mammalian cytoplasmic dynein complex purified from tissue or, more recently, with recombinant dynein fragments from budding yeast and Dictyostelium. Hardly any information exists about the properties of human dynein. Moreover, experiments with an entire human dynein complex prepared from recombinant subunits with a well-defined composition are lacking. Here, we reconstitute a complete cytoplasmic dynein complex using recombinant human subunits and characterize its biochemical and motile properties. Using analytical gel filtration, sedimentation-velocity ultracentrifugation, and negative-stain electron microscopy, we demonstrate that the smaller subunits of the complex have an important structural function for complex integrity. Fluorescence microscopy experiments reveal that while engaged in collective microtubule transport, the recombinant human cytoplasmic dynein complex is an active, microtubule minus-end-directed motor, as expected. However, in contrast to recombinant dynein of nonmetazoans, individual reconstituted human dynein complexes did not show robust processive motility, suggesting a more intricate mechanism of processivity regulation for the human dynein complex. In the future, the comparison of reconstituted dynein complexes from different species promises to provide molecular insight into the mechanisms regulating the various functions of these large molecular machines.

Project description:Cytoplasmic dynein is a large, microtubule-dependent molecular motor (1.2 MDa). Although the structure of dynein by itself has been characterized, its conformation in complex with microtubules is still unknown. Here, we used cryoelectron microscopy (cryo-EM) to visualize the interaction between dynein and microtubules. Most dynein molecules in the nucleotide-free state are bound to the microtubule in a defined conformation and orientation. A 3D image reconstruction revealed that dynein's head domain, formed by a ring-like arrangement of AAA+ domains, is located approximately 280 A away from the center of the microtubule. The order of the AAA+ domains in the ring was determined by using recombinant markers. Furthermore, a 3D helical image reconstruction of microtubules with a dynein's microtubule binding domain [dynein stalk (DS)] revealed that the stalk extends perpendicular to the microtubule. By combining the 3D maps of the dynein-microtubule and DS-microtubule complexes, we present a model for how dynein in the nucleotide-free state binds to microtubules and discuss models for dynein's power stroke.

Project description: Not available

Project description:Cytoplasmic dynein-2 is the motor for retrograde intraflagellar transport (IFT), and mutations in dynein-2 are known to cause skeletal ciliopathies. Here, we define for the first time the composition of the human cytoplasmic dynein-2 complex. We show that the proteins encoded by the ciliopathy genes WDR34 and WDR60 are bona fide dynein-2 intermediate chains and are both required for dynein-2 function. In addition, we identify TCTEX1D2 as a unique dynein-2 light chain that is itself required for cilia function. We define several subunits common to both dynein-1 and dynein-2, including TCTEX-1 (also known as DYNLT1) and TCTEX-3 (also known as DYNLT3), roadblock-1 (also known as DYNLRB1) and roadblock-2 (also known as DYNLRB2), and LC8-1 and LC8-2 light chains (DYNLL1 and DYNLL2, respectively). We also find that NudCD3 associates with dynein-2 as it does with dynein-1. By contrast, the common dynein-1 regulators dynactin, LIS1 (also known as PAFAH1B1) and BICD2 are not found in association with dynein-2. These data explain why mutations in either WDR34 or WDR60 cause disease, as well as identifying TCTEX1D2 as a candidate ciliopathy gene.

Project description:We report here the cloning and sequencing of a cytoplasmic dynein heavy chain gene from the cellular slime mold Dictyostelium discoideum. Using a combination of approaches, we have isolated 14,318 bp of DNA sequence which contains an open-reading frame of 4,725 amino acids. The deduced molecular weight of the polypeptide predicted by this reading frame is 538,482 D. Overall, the polypeptide sequence is 51% similar and 28% identical to the recently published sequences of the beta-dynein heavy chain from sea urchin flagella (Gibbons, I. R., B. H. Gibbons, G. Mocz, and D. J. Asai. 1991. Nature (Lond.). 352: 640-643; Ogawa, K. 1991. Nature (Lond.). 352:643-645). It contains four GXXXXGKT/S motifs that form part of a consensus sequence for ATP-binding domains; these motifs are clustered near the middle of the polypeptide. The distribution of the regions sharing sequence similarity between the Dictyostelium and sea urchin heavy chain polypeptides suggests that the amino termini of dyneins may contain domains that specify axonemal or cytoplasmic functions.

Project description:In human cells, cytoplasmic dynein-1 is essential for long-distance transport of many cargos, including organelles, RNAs, proteins, and viruses, towards microtubule minus ends. To understand how a single motor achieves cargo specificity, we identified the human dynein interactome by attaching a promiscuous biotin ligase ('BioID') to seven components of the dynein machinery, including a subunit of the essential cofactor dynactin. This method reported spatial information about the large cytosolic dynein/dynactin complex in living cells. To achieve maximal motile activity and to bind its cargos, human dynein/dynactin requires 'activators', of which only five have been described. We developed methods to identify new activators in our BioID data, and discovered that ninein and ninein-like are a new family of dynein activators. Analysis of the protein interactomes for six activators, including ninein and ninein-like, suggests that each dynein activator has multiple cargos.

Project description:Overlapping cDNA clones encoding the heavy chain of rat brain cytoplasmic dynein have been isolated. The isolated cDNA clones contain an open reading frame of 13,932 bp encoding 4644 aa (M(r), 532,213). The deduced protein sequence of the heavy chain of rat brain dynein shows significant similarity to sea urchin flagellar beta-dynein (27.0% identical) and to Dictyostelium cytoplasmic dynein (53.5% identical) throughout the entire sequence. The heavy chain of rat brain (cytoplasmic) dynein contains four putative nucleotide-binding consensus sequences [GX4GK(T/S)] in the central one-third region that are highly similar to those of sea urchin and Dictyostelium dyneins. The N-terminal one-third of the heavy chain of rat brain (cytoplasmic) dynein shows high similarity (43.8% identical) to that of Dictyostelium cytoplasmic dynein but poor similarity (19.4% identical) to that of sea urchin flagellar dynein. These results suggested that the C-terminal two-thirds of the dynein molecule is conserved and plays an essential role in microtubule-dependent motility activity, whereas the N-terminal regions are different between cytoplasmic and flagellar dyneins.

Project description:Cytoplasmic dynein is a highly complex motor protein that generates forces toward the minus end of microtubules. Using optical tweezers, we demonstrate that the low processivity (ability to take multiple steps before dissociating) of human dynein limits its force generation due to premature microtubule dissociation. Using a high trap stiffness whereby the motor achieves greater force per step, we reveal that the motor's true maximal force ("stall force") is ~2 pN. Furthermore, an average force versus trap stiffness plot yields a hyperbolic curve that plateaus at the stall force. We derive an analytical equation that accurately describes this curve, predicting both stall force and zero-load processivity. This theoretical model describes the behavior of a kinesin motor under low-processivity conditions. Our work clarifies the true stall force and processivity of human dynein and provides a new paradigm for understanding and analyzing molecular motor force generation for weakly processive motors.

Project description:Cytoplasmic dynein is a giant ATP-driven molecular motor that proceeds to the minus end of the microtubule (MT). Dynein hydrolyzes ATP in a ring-like structure, containing 6 AAA+ (ATPases associated with diverse cellular activities) modules, which is ~15 nm away from the MT binding domain (MTBD). This architecture implies that long-distance allosteric couplings exist between the AAA+ ring and the MTBD in order for dynein to move on the MT, although little is known about the mechanisms involved. Here, we have performed comprehensive molecular simulations of the dynein motor domain based on pre- and post- power-stroke structural information and in doing so we address the allosteric conformational changes that occur during the power-stroke and recovery-stroke processes. In the power-stroke process, the N-terminal linker movement was the prerequisite to the nucleotide-dependent AAA1 transition, from which a transition cascade propagated, on average, in a circular manner on the AAA+ ring until it reached the AAA6/C-terminal module. The recovery-stroke process was initiated by the transition of the AAA6/C-terminal, from which the transition cascade split into the two directions of the AAA+ ring, occurring both clockwise and anti-clockwise. In both processes, the MTBD conformational change was regulated by the AAA4 module and the AAA5/Strut module.