Kari Barlan scite author profile

The conversion of chemical energy into mechanical force by AAA+ (ATPases associated with diverse cellular activities) ATPases is integral to cellular processes, including DNA replication, protein unfolding, cargo transport, and membrane fusion1. The AAA+ ATPase motor cytoplasmic dynein regulates ciliary trafficking2, mitotic spindle formation3, and organelle transport4, and dissecting its precise functions has been challenging due to its rapid timescale of action and the lack of cell-permeable, chemical modulators. Here we describe the discovery of ciliobrevins, the first specific small-molecule antagonists of cytoplasmic dynein. Ciliobrevins perturb protein trafficking within the primary cilium, leading to their malformation and Hedgehog signaling blockade. Ciliobrevins also prevent spindle pole focusing, kinetochore-microtubule attachment, melanosome aggregation, and peroxisome motility in cultured cells. We further demonstrate the ability of ciliobrevins to block dynein-dependent microtubule gliding and ATPase activity in vitro. Ciliobrevins therefore will be useful reagents for studying cellular processes that require this microtubule motor and may guide the development of additional AAA+ ATPase superfamily inhibitors.

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Opposite-polarity motors activate one another to trigger cargo transport in live cells

Ally

et al. 2009

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Fat2 and Lar Define a Basally Localized Planar Signaling System Controlling Collective Cell Migration

2017

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SUMMARY Collective migration of epithelial cells underlies diverse tissue remodeling events, but the mechanisms that coordinate individual cell migratory behaviors for collective movement are largely unknown. Studying the Drosophila follicular epithelium, we show that the cadherin Fat2 and the receptor tyrosine phosphatase Lar function in a planar signaling system that coordinates leading and trailing edge dynamics between neighboring cells. Fat2 signals from each cell’s trailing edge to induce leading edge protrusions in the cell behind, in part, by stabilizing Lar’s localization in these cells. Conversely, Lar signals from each cell’s leading edge to stimulate trailing edge retraction in the cell ahead. Fat2/Lar signaling is similar to planar cell polarity signaling in terms of subcellular protein localization; however, Fat2/Lar signaling mediates short-range communication between neighboring cells instead of transmitting long-range information across a tissue. This work defines a key mechanism promoting epithelial migration and establishes a different paradigm for planar cell-cell signaling.

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Microtubule-Based Transport and the Distribution, Tethering, and Organization of Organelles

Barlan

Gelfand

2017

Cold Spring Harb Perspect Biol

199

165

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SUMMARY Microtubules provide long tracks along which a broad range of organelles and vesicles are transported by kinesin and dynein motors. Motor protein complexes also tether cargoes to cytoskeletal filaments, helping facilitate their interaction and communication. The generation of biochemically distinct microtubule subpopulations allows subsets of motors to recognize a given microtubule identity, allowing further organization within the cytoplasm. Both transport and tethering are spatiotemporally regulated through multiple modes, including acute modification of both motor–cargo and motor–track associations by various physiological signals. Strict regulation of intracellular transport is particularly important in specialized cell types such as neurons. Here, we review general mechanisms by which cargo transport is controlled and also highlight examples of transport regulated by multiple mechanisms.

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The Microtubule-Binding Protein Ensconsin Is an Essential Cofactor of Kinesin-1

2013

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SUMMARY Kinesin-1 is a major microtubule motor that drives transport of numerous cellular cargoes toward the plus-ends of microtubules. In the cell, kinesin-1 exists primarily in an inactive, autoinhibited state [1, 2], and motor activation is thought to occur upon binding to cargo through the C-terminus [3, 4]. Using RNAi-mediated depletion in Drosophila S2 cells, we demonstrate that kinesin-1 requires ensconsin (MAP7, E-MAP-115), a ubiquitous microtubule-associated protein [5, 6], for its primary function of organelle transport. We show that ensconsin is required for organelle transport in Drosophila neurons, and that Drosophila homozygous for ensconsin gene deletion are unable to survive to adulthood. An ensconsin N-terminal truncation that cannot bind microtubules is sufficient to activate organelle transport by kinesin-1, indicating that this activating domain functions independently of microtubule binding. Interestingly, ens mutant flies retaining expression of this truncation show normal viability. A “hingeless” mutant of kinesin-1, which mimics the active conformation of the motor, does not require ensconsin for transport in S2 cells, suggesting that ensconsin plays a role in relieving autoinhibition of kinesin-1. Together with other recent works [7, 8], our study suggests that ensconsin is an essential cofactor for all known functions of kinesin-1.

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Kari Barlan

Small-molecule inhibitors of the AAA+ ATPase motor cytoplasmic dynein

Opposite-polarity motors activate one another to trigger cargo transport in live cells

Fat2 and Lar Define a Basally Localized Planar Signaling System Controlling Collective Cell Migration

Microtubule-Based Transport and the Distribution, Tethering, and Organization of Organelles

The Microtubule-Binding Protein Ensconsin Is an Essential Cofactor of Kinesin-1

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