Kausalya Murthy scite author profile

Microtubules stimulate contractile ring formation in the equatorial cortex and simultaneously suppress contractility in the polar cortex; how they accomplish these differing activities is incompletely understood. We measured the behavior of GFP-actin in mammalian cells treated with nocodazole under conditions that either completely eliminate microtubules or selectively disassemble astral microtubules. Selective disassembly of astral microtubules resulted functional contractile rings that were wider than controls and had altered dynamic activity, as measured by FRAP. Complete microtubule disassembly or selective loss of astral microtubules resulted in wave-like contractile behavior of actin in the non-equatorial cortex and mislocalization of myosin II and Rho. FRAP experiments showed that both contractility and actin polymerization contributed to the wave-like behavior of actin. Wave-like, contractile behavior in anaphase cells was Rho-dependent. We conclude that dynamic astral microtubules function to suppress Rho activation in the nonequatorial cortex, limiting the contractile activity of the polar cortex.

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Quantification of microtubule nucleation, growth and dynamics in wound-edge cells

Salaycik

Fagerstrom

Murthy

et al. 2005

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Mammalian cells develop a polarized morphology and migrate directionally into a wound in a monolayer culture. To understand how microtubules contribute to these processes, we used GFP-tubulin to measure dynamic instability and GFP-EB1, a protein that marks microtubule plus-ends, to measure microtubule growth events at the centrosome and cell periphery. Growth events at the centrosome, or nucleation, do not show directional bias, but are equivalent toward and away from the wound. Cells with two centrosomes nucleated approximately twice as many microtubules/minute as cells with one centrosome. The average number of growing microtubules per μm2 at the cell periphery is similar for leading and trailing edges and for cells containing one or two centrosomes. In contrast to microtubule growth, measurement of the parameters of microtubule dynamic instability demonstrate that microtubules in the trailing edge are more dynamic than those in the leading edge. Inhibition of Rho with C3 transferase had no detectable effect on microtubule dynamics in the leading edge, but stimulated microtubule turnover in the trailing edge. Our data demonstrate that in wound-edge cells, microtubule nucleation is non-polarized, in contrast to microtubule dynamic instability, which is highly polarized, and that factors in addition to Rho contribute to microtubule stabilization.

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Myosin-II-Dependent Localization and Dynamics of F-Actin during Cytokinesis

Murthy

Wadsworth

2005

Current Biology

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In Murthy and Wadsworth (Current Biology 15, pp. 724-731), the Figure 1C legend should have read: "Graph of GFPactin fluorescence intensity in the contractile ring." The second-to-last sentence in the legend for Figure 2 should read: "Corresponding graphs of recovery are shown in (A) and (C), and in (B), a graph of recovery for a representative cell in early anaphase is shown; the solid line shows fluorescence in the bleached region, and the dotted line shows fluorescence in an unbleached region." The Acknowledgments section should have included the following sentence:

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Cargo crowding at actin‐rich regions along axons causes local traffic jams

Sood

Murthy

Kumar

et al. 2018

Traffic

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Steady axonal cargo flow is central to the functioning of healthy neurons. However, a substantial fraction of cargo in axons remains stationary up to several minutes. We examine the transport of precursors of synaptic vesicles (pre-SVs), endosomes and mitochondria in Caenorhabditis elegans touch receptor neurons, showing that stationary cargo are predominantly present at actin-rich regions along the neuronal process. Stationary vesicles at actin-rich regions increase the propensity of moving vesicles to stall at the same location, resulting in traffic jams arising from physical crowding. Such local traffic jams at actin-rich regions are likely to be a general feature of axonal transport since they also occur in Drosophila neurons. Repeated touch stimulation of C. elegans reduces the density of stationary pre-SVs, indicating that these traffic jams can act as both sources and sinks of vesicles. This suggests that vesicles trapped in actin-rich regions are functional reservoirs that may contribute to maintaining robust cargo flow in the neuron. A video abstract of this article can be found at: Video S1; Video S2.

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Kausalya Murthy

Myosin-II-Dependent Localization and Dynamics of F-Actin during Cytokinesis

Dual role for microtubules in regulating cortical contractility during cytokinesis

Quantification of microtubule nucleation, growth and dynamics in wound-edge cells

Myosin-II-Dependent Localization and Dynamics of F-Actin during Cytokinesis

Cargo crowding at actin‐rich regions along axons causes local traffic jams

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