Animal cell cytokinesis requires a contractile ring of crosslinked actin filaments and myosin motors. How contractile rings form and are stabilized in dividing cells remains unclear. We address this problem by focusing on septins, highly conserved proteins in eukaryotes whose precise contribution to cytokinesis remains elusive. We use the cleavage of the Drosophila melanogaster embryo as a model system, where contractile actin rings drive constriction of invaginating membranes to produce an epithelium in a manner akin to cell division. In vivo functional studies show that septins are required for generating curved and tightly packed actin filament networks. In vitro reconstitution assays show that septins alone bundle actin filaments into rings, accounting for the defects in actin ring formation in septin mutants. The bundling and bending activities are conserved for human septins, and highlight unique functions of septins in the organization of contractile actomyosin rings.
Essential cellular functions as diverse as genome maintenance and tissue morphogenesis rely on the dynamic organization of filamentous assemblies. For example, the precise structural organization of DNA filaments has profound consequences on all DNA-mediated processes including gene expression, whereas control over the precise spatial arrangement of cytoskeletal protein filaments is key for mechanical force generation driving animal tissue morphogenesis. Polarized fluorescence is currently used to extract structural organization of fluorescently labeled biological filaments by determining the orientation of fluorescent labels, however with a strong drawback: polarized fluorescence imaging is indeed spatially limited by optical diffraction, and is thus unable to discriminate between the intrinsic orientational mobility of the fluorophore labels and the real structural disorder of the labeled biomolecules. Here, we demonstrate that quantitative single-molecule polarized detection in biological filament assemblies allows not only to correct for the rotational flexibility of the label but also to image orientational order of filaments at the nanoscale using superresolution capabilities. The method is based on polarized direct stochastic optical reconstruction microscopy, using dedicated optical scheme and image analysis to determine both molecular localization and orientation with high precision. We apply this method to double-stranded DNA in vitro and microtubules and actin stress fibers in whole cells.iological processes are inherently driven by the molecularscale organization of biomolecular assemblies, which arrange in precise structures that are essential for biological functions in cells and tissues. The extent to which the biological function depends on the underlying molecular-scale organization is particularly evident in filamentous assemblies, such as DNA filaments and cytoskeletal protein filaments. Changes in the local higher-order organization of DNA filaments is tightly linked to essential DNA-mediated processes including control of gene expression, DNA replication, and DNA repair. However, how specific DNA-binding proteins affect DNA filament architecture and thus DNA-mediated functions is poorly understood (1). Similarly, the spatial organization of cytoskeletal filaments in cells and tissues is also weakly explored, despite their central role in generating forces and driving cell motility, cell division, and tissue morphogenesis (2). Electron microscopy has been widely used to provide molecular-scale images of the structure of such filament assemblies; however, it typically involves several daylong sample preparation and ultrathin sectioning of the biological material, thus limiting investigations in whole cells and tissues.Polarized fluorescence imaging is a powerful approach for elucidating the structural organization of filament assemblies because it is compatible with a wide variety of microscopy techniques, thus enabling studies across multiple spatial and temporal scales. Polarized fluorescenc...
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