114 results found
    1. Microbiology and Infectious Disease

    c-di-GMP heterogeneity is generated by the chemotaxis machinery to regulate flagellar motility

    Bridget R Kulasekara et al.
    Real time measurements of c-di-GMP in individual cells reveal an unexpected mechanism by which the chemotaxis machinery controls c-di-GMP heterogeneity, thereby regulating flagellar-based motility.
    1. Cell Biology

    Intraflagellar transport drives flagellar surface motility

    Sheng Min Shih et al.
    The transport of proteins along flagellar microtubules generates the force that enables flagella to propel cells across surfaces.
    1. Cell Biology

    TTC26/DYF13 is an intraflagellar transport protein required for transport of motility-related proteins into flagella

    Hiroaki Ishikawa et al.
    Loss of one protein from the intraflagellar transport complex leads to a defect in import of a specific sub-set of proteins into the flagellum.
    1. Physics of Living Systems

    Dynamic density shaping of photokinetic E. coli

    Giacomo Frangipane et al.
    The concentration of motile bacteria, expressing a light-driven proton pump, can be precisely controlled in space and time by spatially modulating their swimming speeds with a structured light pattern.
    1. Microbiology and Infectious Disease

    Cyclic di-GMP differentially tunes a bacterial flagellar motor through a novel class of CheY-like regulators

    Jutta Nesper et al.
    Precise control of the bacterial flagellar motor determines bacterial cell dispersal and bacteria-surface interactions.
    1. Cell Biology

    Flagellar Growth: Boarder control on the IFT train

    Cécile Fort, Philippe Bastin
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    1. Physics of Living Systems
    2. Microbiology and Infectious Disease

    Phototaxis: Life in focus

    Carol Dieckmann, Telsa Mittelmeier
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    1. Microbiology and Infectious Disease
    2. Ecology

    The Natural History of Model Organisms: The unexhausted potential of E. coli

    Zachary D Blount
    A better understanding of the remarkable diversity, natural history and complex ecology of E. coli in the wild could shed new light on its biology and role in disease, and further expand its many uses as a model organism.

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