Anterograde Microtubule Transport Drives Microtubule Bending in LLC-PK1 Epithelial Cells

Bicek, Andrew D.; Tüzel, Erkan; Demtchouk, Aleksey; Uppalapati, Maruti; Hancock, William O.; Kroll, D. M.; Odde, David J.

doi:10.1091/mbc.e08-09-0909

Cited by 83 publications

(118 citation statements)

References 53 publications

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“…This is reminiscent of the curvatures that occur in gliding assays when microtubules are pinned by a dead motor. This analogy between gliding assays and in vivo microtubule bending has recently been explored using curvature distributions of microtubules located in the periphery of LLC-PK1 epithelial cells (Bicek et al 2007(Bicek et al , 2009) and in kinesin gliding assays. It was shown that microtubule curvature distributions in vivo and in vitro both exhibited an exponential decay, indicating the involvement of active forces.…”

Section: Resultsmentioning

confidence: 99%

Loop formation of microtubules during gliding at high density

Liu¹,

Tüzel²,

Ross³

2011

J. Phys.: Condens. Matter

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The microtubule cytoskeleton, including the associated proteins, forms a complex network essential to multiple cellular processes. Microtubule-associated motor proteins, such as kinesin-1, travel on microtubules to transport membrane bound vesicles across the crowded cell. Other motors, such as cytoplasmic dynein and kinesin-5, are used to organize the cytoskeleton during mitosis. In order to understand the self-organization processes of motors on microtubules, we performed filament-gliding assays with kinesin-1 motors bound to the cover glass with a high density of microtubules on the surface. To observe microtubule organization, 3% of the microtubules were fluorescently labeled to serve as tracers. We find that microtubules in these assays are not confined to two dimensions and can cross one other. This causes microtubules to align locally with a relatively short correlation length. At high density, this local alignment is enough to create 'intersections' of perpendicularly oriented groups of microtubules. These intersections create vortices that cause microtubules to form loops. We characterize the radius of curvature and time duration of the loops. These different behaviors give insight into how crowded conditions, such as those in the cell, might affect motor behavior and cytoskeleton organization.

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Section: Resultsmentioning

confidence: 99%

Loop formation of microtubules during gliding at high density

Liu¹,

Tüzel²,

Ross³

2011

J. Phys.: Condens. Matter

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“…Despite the fact that the cause of microtubule buckling remains elusive, previous studies suggested mechanisms mediating microtubule bending and buckling. It has been shown that kinesin and dynein motors might result in microtubule buckling and breaking during telophase (Bicek et al, 2009). Because several microtubule motors are known to be necessary for the completion of cytokinesis (Zhu et al, 2005), perhaps these microtubule motors might also contribute to the central spindle buckling by either anchoring themselves to the PM or by anchoring to another microtubule to create a bending force.…”

Section: Discussionmentioning

confidence: 99%

Endocytic membrane fusion and buckling-induced microtubule severing mediate cell abscission

Schiel

Park

Morphew

et al. 2011

Journal of Cell Science

101

103

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Cytokinesis and abscission are complicated events that involve changes in membrane transport and cytoskeleton organization. We have used the combination of time-lapse microscopy and correlative high-resolution 3D tomography to analyze the regulation and spatio-temporal remodeling of endosomes and microtubules during abscission. We show that abscission is driven by the formation of a secondary ingression within the intracellular bridge connecting two daughter cells. The initiation and expansion of this secondary ingression requires recycling endosome fusion with the furrow plasma membrane and nested central spindle microtubule severing. These changes in endosome fusion and microtubule reorganization result in increased intracellular bridge plasma membrane dynamics and abscission. Finally, we show that central spindle microtubule reorganization is driven by localized microtubule buckling and breaking, rather than by spastin-dependent severing. Our results provide a new mechanism for mediation and regulation of the abscission step of cytokinesis.

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“…Microtubule sliding is central to the organization of the mitotic spindle and, here, might have a role in organelle partitioning during mitosis (see Goshima et al, 2005). The impact of motor force on microtubule structure would also have indirect consequences for any attached organelle (Bicek et al, 2009). A further example is provided by the attachment of the ER to microtubule tips, which results in the extension of the ER in response to microtubule polymerization (Grigoriev et al, 2008).…”

Section: Motors In Organelle Positioning and Signal Transductionmentioning

confidence: 99%

Functional coupling of microtubules to membranes – implications for membrane structure and dynamics

Stephens

2012

Journal of Cell Science

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SummaryThe microtubule network dictates much of the spatial patterning of the cytoplasm, and the coupling of microtubules to membranes controls the structure and positioning of organelles and directs membrane trafficking between them. The connection between membranes and the microtubule cytoskeleton, and the way in which organelles are shaped and moved by interactions with the cytoskeleton, have been studied intensively in recent years. In particular, recent work has expanded our thinking of this topic to include the mechanisms by which membranes are shaped and how cargo is selected for trafficking as a result of coupling to the cytoskeleton. In this Commentary, I will discuss the molecular basis for membrane-motor coupling and the physiological outcomes of this coupling, including the way in which microtubule-based motors affect membrane structure, cargo sorting and vectorial trafficking between organelles. Whereas many core concepts of these processes are now well understood, key questions remain about how the coupling of motors to membranes is established and controlled, about the regulation of cargo and/or motor loading and about the control of directionality.

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Anterograde Microtubule Transport Drives Microtubule Bending in LLC-PK1 Epithelial Cells

Cited by 83 publications

References 53 publications

Loop formation of microtubules during gliding at high density

Loop formation of microtubules during gliding at high density

Endocytic membrane fusion and buckling-induced microtubule severing mediate cell abscission

Functional coupling of microtubules to membranes – implications for membrane structure and dynamics

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