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Showing 1–12 of 12 results
Advanced filters: Author: Amy S. Gladfelter Clear advanced filters

  • Amy Gladfelter discusses our current knowledge of the functions and regulation of the septins and formins in filamentous fungi, and makes the case that a concerted research effort on these proteins in these organisms could yield significant insights into fundamental eukaryotic cellular processes.

    • Amy S. Gladfelter
    Reviews
    Nature Reviews Microbiology
    Volume: 4, P: 223-229

  • In fungi, nuclei move in a microtubule- and microtubule motor-dependent manner. In this Review, Judith Berman and Amy Gladfelter discuss how fungi use the movement of intact nuclei within and between cells to control the integrity, ploidy and assortment of specific genomes or individual chromosomes.

    • Amy Gladfelter
    • Judith Berman
    Reviews
    Nature Reviews Microbiology
    Volume: 7, P: 875-886

  • The authors use high-speed AFM to study the interaction of yeast septin filaments with yeast lipid membranes, showing that septin is lipid phase selective and organizes into higher-order structures without the contribution of other cellular components.

    • James A. Goodchild
    • Brandy N. Curtis
    • Simon Scheuring
    ResearchOpen Access
    Nature Communications
    Volume: 16, P: 1-11

  • In this work, the authors report that protein-RNA condensates with shared proteins and distinct RNAs can form and persist in vitro and in cells as distinct entities if the nonshared RNA molecules are dynamically arrested, but the shared protein components are dynamically exchangeable.

    • Andrew Z. Lin
    • Kiersten M. Ruff
    • Rohit V. Pappu
    ResearchOpen Access
    Nature Communications
    Volume: 14, P: 1-17

  • The assembly of germ granules remains unknown, but recent attention to the role of RNA structure in membrane-less organelle assembly is changing our understanding of RNAs in the cell. Two studies now show how RNA–RNA interactions drive germ granule assembly and how germ granules spatially regulate embryonic mRNA translation.

    • Ameya P. Jalihal
    • Zachary M. Geisterfer
    • Amy S. Gladfelter
    News & Views
    Nature Cell Biology
    Volume: 26, P: 1828-1829

  • Snead et al. report that membrane tethering facilitates assembly of ribonucleoprotein condensates while also restricting condensate size by reducing the diffusion of protein and RNA.

    • Wilton T. Snead
    • Ameya P. Jalihal
    • Amy S. Gladfelter
    Research
    Nature Cell Biology
    Volume: 24, P: 461-470

  • The realization that the cell is abundantly compartmentalized into biomolecular condensates has opened new opportunities for understanding the physics and chemistry underlying many cellular processes1, fundamentally changing the study of biology2. The term biomolecular condensate refers to non-stoichiometric assemblies that are composed of multiple types of macromolecules in cells, occur through phase transitions, and can be investigated by using concepts from soft matter physics3. As such, they are intimately related to aqueous two-phase systems4 and water-in-water emulsions5. Condensates possess tunable emergent properties such as interfaces, interfacial tension, viscoelasticity, network structure, dielectric permittivity, and sometimes interphase pH gradients and electric potentials614. They can form spontaneously in response to specific cellular conditions or to active processes, and cells appear to have mechanisms to control their size and location1517. Importantly, in contrast to membrane-enclosed organelles such as mitochondria or peroxisomes, condensates do not require the presence of a surrounding membrane.

    • Simon Alberti
    • Paolo Arosio
    • Tanja Mittag
    Comments & OpinionOpen Access
    Nature Communications
    Volume: 16, P: 1-14

  • Septins are GTP-binding proteins involved in diverse cellular processes including division, polarity maintenance and membrane remodeling. Here authors use high-speed atomic force microscopy to show that assembly of septin filaments is a diffusion-driven process, while septin assembly into higher-order involves septin self-templating

    • Fang Jiao
    • Kevin S. Cannon
    • Simon Scheuring
    ResearchOpen Access
    Nature Communications
    Volume: 11, P: 1-13

  • Recent studies have highlighted the contribution of RNA to cellular liquid–liquid phase separation and condensate formation. RNA features modulate the composition and biophysical properties of RNA–protein condensates, which have various cellular functions, including RNA transport and localization, supporting catalytic processes and responding to stress.

    • Christine Roden
    • Amy S. Gladfelter
    Reviews
    Nature Reviews Molecular Cell Biology
    Volume: 22, P: 183-195