Role Of Dynactin Research Articles

Role of Dynactin in the Intracellular Localization and Activation of Cytoplasmic Dynein.

Cytoplasmic dynein, the major minus end-directed motor protein in several cell types, transports a variety of intracellular cargo upon forming a processive tripartite complex with its activator dynactin and cargo adaptors such as Hook3 and BicD2. Our current understanding of dynein regulation stems from a combination of in vivo studies of cargo movement upon perturbation of dynein activity, in vitro single-molecule experiments, and cryo-electron microscopy studies of dynein structure and its interaction with dynactin and cargo adaptors. In this Perspective, we first consolidate data from recent publications to understand how perturbations to the dynein-dynactin interaction and dynactin's in vivo localization alter the behavior of dynein-driven cargo transport in a cell type- and experimental condition-specific manner. In addition, we touch upon results from in vivo and in vitro studies to elucidate how dynein's interaction with dynactin and cargo adaptors activates dynein and enhances its processivity. Finally, we propose questions that need to be addressed in the future with appropriate experimental designs so as to improve our understanding of the spatiotemporal regulation of dynein's function in the context of the distribution and dynamics of dynactin in living cells.

Dynactin pathway-related gene expression is altered by aging, but not by vitrification

The storage of surplus oocytes by cryopreservation (OC) is a widely used tool in assisted reproductive technology, but there is a great debate about the effects of cryopreservation on oocyte competence. It is known that OC may affect meiotic spindles but remains unclear if OC may increase the risk of aneuploidy. The aim of this study was to test the effects of OC and women aging on the expression of cytokinesis-related genes playing an important role in the segregation of chromosomes (DCTN1, DCTN2, DCTN3, DCTN6 and PLK1). Results highlighted that OC do not modify the expression of the selected genes, whereas women aging modulate the expression of all transcripts, confirming that aging is the crucial factor affecting meiosis and aneuploidy risk. A new role for Dynactin and PLK1 was shed in light, providing information on the ageing process in the oocyte which may be associated to reduced fertility.

Dynactin Functions as Both a Dynamic Tether and Brake during Dynein-Driven Motility

Dynactin is a large multi-subunit complex that is an important cofactor for cytoplasmic dynein in cellular processes including organelle trafficking and mitosis. Dynactin increases the processivity of dynein and also targets dynein to specific cellular locations. Although the role of dynactin in dynein-mediated processes is well established, the underlying mechanisms involved are unknown. Here, we use single molecule approaches to investigate the contribution of the dynactin subunit p150Glued to dynein motor function. We first characterized the motility of purified GFP-tagged mammalian dynein isolated from a knock-in mouse brain tissue (Zhang et al., 2013). Consistent with previous reports (Mallik et al., 2005; Ross et al., 2006), single molecules of dynein-GFP switch stochastically from processive to diffusive states of motion. We analyzed this motion by a novel algorithm that we developed to parse trajectories into different states and found that dynein is processive 60% of the time. To examine the activation of dynein by dynactin, we investigated the formation and co-migration of a dynein-p150Glued co-complex using dual-color TIRF microscopy. We provide direct evidence that p150Glued is sufficient to recruit and tether dynein to the microtubule and that this recruitment is concentration-dependent; p150Glued increases the on-rate and decreases the off-rate of dynein from microtubules. Single molecule imaging of motility in cell extracts demonstrates that the CAP-Gly domain of dynactin is essential for the decreased detachment rate of the dynein-dynactin complex from the microtubule and also acts as a brake to slow the dynein motor. Consistent with this important role, two neurodegenerative disease-causing mutations in the CAP-Gly domain abrogate these functions in our assays. Together, these observations support a model in which dynactin enhances the initial recruitment of dynein onto microtubules and promotes the sustained engagement of dynein with its cytoskeletal track.

2P158 A novel role of dynactin for dynein motility revealed by gliding assay(11. Molecular motor,Poster,The 52nd Annual Meeting of the Biophysical Society of Japan(BSJ2014))

2P158 A novel role of dynactin for dynein motility revealed by gliding assay(11. Molecular motor,Poster,The 52nd Annual Meeting of the Biophysical Society of Japan(BSJ2014))

Dynactin function in mitotic spindle positioning.

Dynactin is a multisubunit protein complex necessary for dynein function. Here, we investigated the function of dynactin in budding yeast. Loss of dynactin impaired movement and positioning of the mitotic spindle, similar to loss of dynein. Dynactin subunits required for function included p150(Glued), dynamitin, actin-related protein (Arp) 1 and p24. Arp10 and capping protein were dispensable, even in combination. All dynactin subunits tested localized to dynamic plus ends of cytoplasmic microtubules, to stationary foci on the cell cortex and to spindle pole bodies. The number of molecules of dynactin in those locations was small, less than five. In the absence of dynactin, dynein accumulated at plus ends and did not appear at the cell cortex, consistent with a role for dynactin in offloading dynein from the plus end to the cortex. Dynein at the plus end was necessary for dynactin plus-end targeting. p150(Glued) was the only dynactin subunit sufficient for plus-end targeting. Interactions among the subunits support a molecular model that resembles the current model for brain dynactin in many respects; however, three subunits at the pointed end of brain dynactin appear to be absent from yeast.

Dynactin drives dynein without microtubule binding

Dynactin might bind to and organize microtubules. But it doesn't need to bind microtubules to jump-start dynein motoring, Kim et al. report on page 641. Figure 1 Organelle cargo distribution is similar in wild-type cells (left) and cells expressing nonmicrotubule-binding dynactin (right), indicating that transport remains intact. Dynactin retrieves microtubule motors such as dynein from the cytoplasm and docks them onto their cargo. Dynactin also anchors the minus ends of microtubules on the centrosome. One dynactin isoform that is found in human neurons lacks its microtubule-binding domain (MBD). Kim and colleagues thus supposed that dynactin might be functional even without locking onto microtubules. They found that indeed cargo transport does not rely on the MBD. With or without a functional MBD, dynactin helped move four different physiological cargos, including vesicles and proteins, just as far along microtubules and at the same velocity and frequency. Dynactin's MBD was previously thought to increase dynein's processivity by giving it a second hand to hang onto microtubules. But this idea was based largely on studies of the transport of dynein-coated beads. This artificial cargo, or the way dynein and dynactin were attached to it, might have altered the normal relations between dynein and dynactin observed in a cell. Not all dynactin activities were unaffected by the loss of the MBD, however. Cells expressing the MBD-deleted form commonly arrested in prometaphase with multipolar spindles, suggesting a failure of microtubules to correctly conjoin in centrosomes and thus a role of dynactin in latching together microtubules.

A role for regulated binding of p150(Glued) to microtubule plus ends in organelle transport.

A subset of microtubule-associated proteins, including cytoplasmic linker protein (CLIP)-170, dynactin, EB1, adenomatous polyposis coli, cytoplasmic dynein, CLASPs, and LIS-1, has been shown recently to target to the plus ends of microtubules. The mechanisms and functions of this binding specificity are not understood, although a role in encouraging microtubule elongation has been proposed. To extend previous work on the role of dynactin in organelle transport, we analyzed p150Glued by live-cell imaging. Time-lapse analysis of p150Glued revealed targeting to the plus ends of growing microtubules, requiring the NH2-terminal cytoskeleton-associated protein–glycine rich domain, but not EB1 or CLIP-170. Effectors of protein kinase A modulated microtubule binding and suggested p150Glued phosphorylation as a factor in plus-end binding specificity. Using a phosphosensitive monoclonal antibody, we mapped the site of p150Glued phosphorylation to Ser-19. In vivo and in vitro analysis of phosphorylation site mutants revealed that p150Glued phosphorylation mediates dynamic binding to microtubules. To address the function of dynamic binding, we imaged GFP-p150Glued during the dynein-dependent transport of Golgi membranes. Live-cell analysis revealed a transient interaction between Golgi membranes and GFP-p150Glued–labeled microtubules just prior to transport, implicating microtubules and dynactin in a search–capture mechanism for minus-end–directed organelles.

In vitro reconstitution of fish melanophore pigment aggregation.

Movement and positioning of melanophore pigment organelles depend on microtubule- and actin-dependent motors, but the regulation of these forces are poorly understood. Here, we describe a cell free and fixed time motility assay for the study of the regulation of microtubule-dependent pigment organelle positioning in vitro. The assay involves introduction of microtubule-asters assembled in clam oocyte lysates into lysates prepared from Fundulus heteroclitus melanophores with either aggregated or dispersed pigment. When asters were introduced in lysates prepared from melanophores with dispersed pigment, pigment organelles bound astral microtubules and were evenly distributed throughout the aster. In contrast, when asters were introduced into lysates prepared from melanophores with aggregated pigment, pigment organelles accumulated around the centrosome, mimicking a pigment aggregate. The addition of anti-dynein intermediate chain antibody (m74-1), previously shown to interfere with binding of dynactin to dynein and thereby causing detachment of dynein from organelles, blocked the ATP-dependent aggregation of pigment in vitro and induced a depletion of pigment from the centrosomal area. The results show that dynein is essential for pigment aggregation and involved in maintenance of evenly dispersed pigment in vitro, analogous to cellular evidence, and suggest a possible role for dynactin in these processes as well.

Role of dynactin in endocytic traffic: effects of dynamitin overexpression and colocalization with CLIP-170.

The flow of material from peripheral, early endosomes to late endosomes requires microtubules and is thought to be facilitated by the minus end-directed motor cytoplasmic dynein and its activator dynactin. The microtubule-binding protein CLIP-170 may also play a role by providing an early link to endosomes. Here, we show that perturbation of dynactin function in vivo affects endosome dynamics and trafficking. Endosome movement, which is normally bidirectional, is completely inhibited. Receptor-mediated uptake and recycling occur normally, but cells are less susceptible to infection by enveloped viruses that require delivery to late endosomes, and they show reduced accumulation of lysosomally targeted probes. Dynactin colocalizes at microtubule plus ends with CLIP-170 in a way that depends on CLIP-170's putative cargo-binding domain. Overexpression studies using p150(Glued), the microtubule-binding subunit of dynactin, and mutant and wild-type forms of CLIP-170 indicate that CLIP-170 recruits dynactin to microtubule ends. These data suggest a new model for the formation of motile complexes of endosomes and microtubules early in the endocytic pathway.

Overexpression of normal and mutant Arp1alpha (centractin) differentially affects microtubule organization during mitosis and interphase.

Dynactin is a large multisubunit complex that regulates cytoplasmic dynein-mediated functions. To gain insight into the role of dynactin's most abundant component, Arp1alpha was transiently overexpressed in mammalian cells. Arp1alpha overexpression resulted in a cell cycle delay at prometaphase. Intracellular dynactin, dynein and nuclear/mitotic apparatus (NuMA) protein were recruited to multiple foci associated with ectopic cytoplasmic aggregates of Arp1alpha in transfected cells. These ectopic aggregates nucleated supernumerary microtubule asters at prometaphase. Point mutations were generated in Arp1alpha that identified specific amino acids required for the prometaphase delay and for the formation of supernumerary microtubule asters. The mutant Arp1alpha proteins formed aggregates in cells that colocalized with dynactin and dynein peptides, but in contrast to wild-type Arp1alpha, NuMA localization remained unaffected. Although expression of mutant Arp1alpha proteins had no effect on mitotic cells, in interphase cells expression of the mutants resulted in disruption of the microtubule network. Immunoprecipitation studies demonstrated that overexpressed Arp1alpha interacts with dynactin and NuMA proteins in cell extracts, and that these interactions are destabilized in the Arp1alpha mutants. We conclude that the amino acids altered in the Arp1alpha mutant proteins participate in stabilizing interactions between overexpressed Arp1alpha and components of the endogenous dynactin complex as well as the NuMA protein.

Overexpression of the dynamitin (p50) subunit of the dynactin complex disrupts dynein-dependent maintenance of membrane organelle distribution.

Dynactin is a multisubunit complex that plays an accessory role in cytoplasmic dynein function. Overexpression in mammalian cells of one dynactin subunit, dynamitin, disrupts the complex, resulting in dissociation of cytoplasmic dynein from prometaphase kinetochores, with consequent perturbation of mitosis (Echeverri, C.J., B.M. Paschal, K.T. Vaughan, and R.B. Vallee. 1996. J. Cell Biol. 132:617-634). Based on these results, dynactin was proposed to play a role in linking cytoplasmic dynein to kinetochores and, potentially, to membrane organelles. The current study reports on the dynamitin interphase phenotype. In dynamitin-overexpressing cells, early endosomes (labeled with antitransferrin receptor), as well as late endosomes and lysosomes (labeled with anti-lysosome-associated membrane protein-1 [LAMP-1]), were redistributed to the cell periphery. This redistribution was disrupted by nocodazole, implicating an underlying plus end-directed microtubule motor activity. The Golgi stack, monitored using sialyltransferase, galactosyltransferase, and N-acetylglucosaminyltransferase I, was dramatically disrupted into scattered structures that colocalized with components of the intermediate compartment (ERGIC-53 and ERD-2). The disrupted Golgi elements were revealed by EM to represent short stacks similar to those formed by microtubule-depolymerizing agents. Golgi-to-ER traffic of stack markers induced by brefeldin A was not inhibited by dynamitin overexpression. Time-lapse observations of dynamitin-overexpressing cells recovering from brefeldin A treatment revealed that the scattered Golgi elements do not undergo microtubule-based transport as seen in control cells, but rather, remain stationary at or near their ER exit sites. These results indicate that dynactin is specifically required for ongoing centripetal movement of endocytic organelles and components of the intermediate compartment. Results similar to those of dynamitin overexpression were obtained by microinjection with antidynein intermediate chain antibody, consistent with a role for dynactin in mediating interactions of cytoplasmic dynein with specific membrane organelles. These results suggest that dynamitin plays a pivotal role in regulating organelle movement at the level of motor-cargo binding.