Nireekshit Addanki Tirumala scite author profile

Several key processes in the cell, such as vesicle transport and spindle positioning, are mediated by the motor protein cytoplasmic dynein, which produces force on the microtubule. For the functions that require movement of the centrosome and the associated nuclear material, dynein needs to have a stable attachment at the cell cortex. In fission yeast, Mcp5 is the anchor protein of dynein and is required for the oscillations of the horsetail nucleus during meiotic prophase. Although the role of Mcp5 in anchoring dynein to the cortex has been identified, it is unknown how Mcp5 associates with the membrane as well as the importance of the underlying attachment to the nuclear oscillations. Here, we set out to quantify Mcp5 organization and identify the binding partner of Mcp5 at the membrane. We used confocal and total internal reflection fluorescence microscopy to count the number of Mcp5 foci and the number of Mcp5 molecules in an individual focus. Further, we quantified the localization pattern of Mcp5 in fission yeast zygotes and show by perturbation of phosphatidylinositol 4-phosphate 5-kinase that Mcp5 binds to phosphatidylinositol 4,5-bisphosphate [PI(4,5)P]. Remarkably, we discovered that the myosin I protein in fission yeast, Myo1, which is required for organization of sterol-rich domains in the cell membrane, facilitates the localization of Mcp5 and that of cytoplasmic dynein on the membrane. Finally, we demonstrate that Myo1-facilitated association of Mcp5 and dynein to the membrane determines the dynamics of nuclear oscillations and, in essence, dynein activity.

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

Tirumala

Parton

2019

Biochemistry

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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.

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Single-molecule imaging of cytoplasmic dyneinin celluloreveals the mechanism of motor activation and cargo movement

Tirumala

Parton

2021

Preprint

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Cytoplasmic dynein 1 (dynein) is the primary minus end-directed motor protein in most eukaryotic cells (1). Dynein remains in an inactive conformation until the formation of a tripartite complex comprising dynein, its regulator dynactin and a cargo adaptor (2-5). Thereupon, dynein transports cargo towards the minus ends of microtubules. How this process of motor activation occurs is unclear, since it entails the formation of a three-protein complex inside the crowded environs of a cell. Here, we employed live-cell, single-molecule imaging to visualise and track fluorescently tagged dynein. First, we observed that dynein that bound to the microtubule engaged in minus end-directed movement only ~30% of the time and resided on the microtubule for a short duration. Next, using high-resolution imaging in live and fixed cells, we discovered that dynactin remained persistently attached to microtubules, and endosomal cargo remained in proximity to the microtubules and dynactin. Finally, we employed two-colour imaging to visualise cargo movement effected by single motor binding. Taken together, we discovered a search strategy that is facilitated by dynein's frequent microtubule binding-unbinding kinetics: (1) in a futile event when dynein does not encounter cargo anchored in proximity to the microtubule, dynein unbinds and diffuses into the cytoplasm, (2) when dynein encounters cargo and dynactin upon microtubule binding, it moves cargo in a short run. In conclusion, we demonstrate that dynein activation and cargo capture are coupled in a step that relies on reduction of dimensionality to enable minus end-directed transport in vivo.

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Single-molecule imaging of cytoplasmic dynein in cellulo reveals the mechanism of motor activation and cargo capture

Tirumala¹,

Redpath²,

Kapoor‐Kaushik³

et al. 2022

Biophysical Journal

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Single-Molecule Imaging of Cytoplasmic Dynein in vivo Reveals the Mechanism of Motor Activation and Cargo Capture

Tirumala

2020

Biophysical Journal

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We investigated contraction-relaxation coupling using a computer model (My-oSim) that simulates dynamically coupled thick and thin filaments and includes force-dependent transitions between the OFF and ON states of myosin. Initial calculations simulated twitch contractions at different muscle lengths and exhibited contraction-relaxation coupling. We then perturbed the model by systematically varying the values of parameters associated with each sarcomere-level process. This produced a wide range of twitch responses. Contraction-relaxation coupling was maintained in nearly every case. The only exceptions were observed due to the perturbations which reduced the occupancy of the myosin OFF state. We conclude that rapid transitions from the ON to the OFF state of myosin are essential for contraction-relaxation coupling.

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