Alison Wirshing scite author profile

Disruption to the contractility of cells, including smooth muscle cells of the cardiovascular system and myoepithelial cells of the glandular epithelium, contributes to the pathophysiology of contractile tissue diseases, including asthma, hypertension, and primary Sjögren’s syndrome. Cell contractility is determined by myosin activity and actomyosin network organization and is mediated by hundreds of protein–protein interactions, many directly involving actin. Here we use a candidate RNA interference screen of more than 100 Caenorhabditis elegans genes with predicted actin-binding and regulatory domains to identify genes that contribute to the contractility of the somatic gonad. We identify the spectrin cytoskeleton composed of SPC-1/α-spectrin, UNC-70/β-spectrin, and SMA-1/β heavy-spectrin as required for contractility and actin organization in the myoepithelial cells of the C. elegans spermatheca. We use imaging of fixed and live animals as well as tissue- and developmental-stage-specific disruption of the spectrin cytoskeleton to show that spectrin regulates the production of prominent central actin bundles and is required for maintenance of central actin bundles throughout successive rounds of stretch and contraction. We conclude that the spectrin cytoskeleton contributes to spermathecal contractility by promoting maintenance of the robust actomyosin bundles that drive contraction.

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Evolutionary tuning of barbed end competition allows simultaneous construction of architecturally distinct actin structures

Wirshing

Rodriguez

Goode

2023

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How cells simultaneously assemble actin structures of distinct sizes, shapes, and filamentous architectures is still not well understood. Here, we used budding yeast as a model to investigate how competition for the barbed ends of actin filaments might influence this process. We found that while vertebrate capping protein (CapZ) and formins can simultaneously associate with barbed ends and catalyze each other’s displacement, yeast capping protein (Cap1/2) poorly displaces both yeast and vertebrate formins. Consistent with these biochemical differences, in vivo formin-mediated actin cable assembly was strongly attenuated by the overexpression of CapZ but not Cap1/2. Multiwavelength live cell imaging further revealed that actin patches in cap2∆ cells acquire cable-like features over time, including recruitment of formins and tropomyosin. Together, our results suggest that the activities of S. cerevisiae Cap1/2 have been tuned across evolution to allow robust cable assembly by formins in the presence of high cytosolic levels of Cap1/2, which conversely limit patch growth and shield patches from formins.

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A septin-Hof1 scaffold at the yeast bud neck binds and organizes actin cables

Garabedian

Wirshing

Vakhrusheva

et al. 2020

MBoC

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Cellular actin arrays are often highly organized, with characteristic patterns critical to their in vivo functions, yet the mechanisms for establishing these higher order geometries remain poorly understood. In Saccharomyces cerevisiae, formin-polymerized actin cables are spatially organized and aligned along the mother-bud axis to facilitate polarized vesicle traffic. Here, we show that the bud neck-associated F-BAR protein Hof1, independent of its functions in regulating the formin Bnr1, binds to actin filaments and organizes actin cables in vivo. Hof1 bundles actin filaments and links them to septins in vitro. F-actin binding is mediated by the ‘linker’ domain of Hof1, and its deletion leads to cable organization defects in vivo. Using super-resolution imaging, we show that Hof1 and septins are patterned at the bud neck into evenly-spaced axial pillars (∼200 nm apart), from which actin cables emerge and grow into the mother cell. These results suggest that Hof1, while bound to septins at the bud neck, not only regulates Bnr1 activity, but also binds to actin cables and aligns them along the mother-bud axis. More broadly, these findings provide a strong example of how an actin regulatory protein can be spatially patterned at the cell cortex to govern actin network geometry. [Media: see text] [Media: see text]

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Alison Wirshing

Myosin activity drives actomyosin bundle formation and organization in contractile cells of theCaenorhabditis elegansspermatheca

The myosin light-chain kinase MLCK-1 relocalizes duringCaenorhabditis elegansovulation to promote actomyosin bundle assembly and drive contraction

Spectrin regulates cell contractility through production and maintenance of actin bundles in theCaenorhabditis elegansspermatheca

Evolutionary tuning of barbed end competition allows simultaneous construction of architecturally distinct actin structures

A septin-Hof1 scaffold at the yeast bud neck binds and organizes actin cables

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