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1. Long range mutual activation establishes Rho and Rac polarity during cell migration

   https://doi.org/10.1101/2024.10.01.616161  

   De_Belly, Henry; Gallen, Andreu Fernandez; Strickland, Evelyn; Estrada, Dorothy C; Zager, Patrick J; Nagy, Tamas L; Burkhardt, Janis K; Turlier, Hervé; Weiner, Orion D (October 2024, bioRxiv)

   In migrating cells, the GTPase Rac organizes a protrusive front, whereas Rho organizes a contractile back. How these GTPases are appropriately positioned at the opposite poles of migrating cells is unknown. Here we leverage optogenetics, manipulation of cell mechanics, and mathematical modeling to reveal a surprising mechanochemical long-range mutual activation of the front and back polarity programs that complements their well-known local mutual inhibition. Rac-based protrusion stimulates Rho activation at the opposite side of the cell via membrane tension-based activation of mTORC2. Conversely, Rho-based contraction induces cortical-flow-based regulation of phosphoinositide signaling to trigger Rac activation at the opposite side of the cell. We develop a minimal unifying mechanochemical model of the cell to explain how this long-range facilitation complements local inhibition to enable robust Rho and Rac partitioning. We show that this long-range mutual activation of Rac and Rho is conserved in epithelial cells and is also essential for efficient polarity and migration of primary human T cells, indicating the generality of this circuit. Our findings demonstrate that the actin cortex and plasma membrane function as an integrated mechanochemical system for long-range partitioning of Rac and Rho during cell migration and likely other cellular contexts. 

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2. Investigation of Protein/Lipid Interactions via Scanning Probe Acceleration Microscopy: Theory and Experiment

   https://doi.org/10.1115/DETC2012-70228  

   Legleiter, Justin; Burke, Kathleen A.; Yates, Elizabeth A. (August 2012, ASME 2012 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference)

   There is great interest in the application of proximal probe techniques to simultaneously image and measure mechancial properties of surfaces with nanoscale spatial resolution. There have been several innovations in generating time-resolved force interaction between the tip and surface while acquiring a tapping mode AFM image. These tip/sample forces contain information regarding mechanical properties of surfaces in an analogous fashion to a force curve experiment. Here, we demonstrate, via simulation, that the maximum and minimum tapping forces change with respect to the Young’s modulus and adhesiveness of a surface, but the roughness of the surfaces has no effect on the tapping forces. Using these changes in tapping forces, we determine the mechanical changes of a lipid membrane after exposure to a huntingtin exon1 (htt exon1) protein with an expanded polyglutamine (polyQ) domain. Expanded polyQ domains in htt is associated with Huntington’s disease, a genetic neurodegenerative disorder. The htt exon1 protein caused regions of increased surface roughness to appear in the lipid membrane, and these areas were associated with decreased elasticity and adhesion to the AFM probe. 

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3. Octopus‐Inspired Adhesives with Switchable Attachment to Challenging Underwater Surfaces

   https://doi.org/10.1002/advs.202407588  

   Lee, Chanhong; Via, Austin_C; Heredia, Aldo; Adjei, Daniel_A; Bartlett, Michael_D (October 2024, Advanced Science)

   Abstract Adhesives that excel in wet or underwater environments are critical for applications ranging from healthcare and underwater robotics to infrastructure repair. However, achieving strong attachment and controlled release on difficult substrates, such as those that are curved, rough, or located in diverse fluid environments, remains a major challenge. Here, an octopus‐inspired adhesive with strong attachment and rapid release in challenging underwater environments is presented. Inspired by the octopus's infundibulum structure, a compliant, curved stalk, and an active deformable membrane for multi‐surface adhesion are utilized. The stalk's curved shape enhances conformal contact on large‐scale curvatures and increases contact stress for adaptability to small‐scale roughness. These synergistic mechanisms improve contact across multiple length scales, resulting in switching ratios of over 1000 within ≈30 ms with consistent attachment strength of over 60 kPa on diverse surfaces and conditions. These adhesives are demonstrated through the robust attachment and precise manipulation of rough underwater objects. 

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4. Mechanisms of negative membrane curvature sensing and generation by ESCRT III subunit Snf7

   https://doi.org/10.1002/pro.3851  

   Nepal, Binod; Sepehri, Aliasghar; Lazaridis, Themis (March 2020, Protein Science)

   Abstract Certain proteins have the propensity to bind to negatively curved membranes and generate negative membrane curvature. The mechanism of action of these proteins is much less studied and understood than those that sense and generate positive curvature. In this work, we use implicit membrane modeling to explore the mechanism of an important negative curvature sensing and generating protein: the main ESCRT III subunit Snf7. We find that Snf7 monomers alone can sense negative curvature and that curvature sensitivity increases for dimers and trimers. We have observed spontaneous bending of Snf7 oligomers into circular structures with preferred radius of ~20 nm. The preferred curvature of Snf7 filaments is further confirmed by the simulations of preformed spirals on a cylindrical membrane surface. Snf7 filaments cannot bind with the same interface to flat and curved membranes. We find that even when a filament has the preferred radius, it is always less stable on the flat membrane surface than on the interior cylindrical membrane surface. This provides an additional energy for membrane bending which has not been considered in the spiral spring model. Furthermore, the rings on the cylindrical spirals are bridged together by helix 4 and hence are extra stabilized compared to the spirals on the flat membrane surface. 

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5. WALLFLOWER, a RLK, simultaneously localizes to opposite sides of root hair cells & functions to position hairs

   https://doi.org/10.1101/2023.03.16.533027  

   Toth, Jessica N; Rodriguez-Furlan, Cecilia; Van_Norman, Jaimie M (March 2023, bioRxiv)

   ABSTRACT Polarized cells are frequently partitioned into subdomains with unique features or functions. As plant cells are surrounded by walls, polarized cell shape and protein polarity in the plasma membrane are particularly important for normal physiology and development. We have identified WALLFLOWER (WFL), a transmembrane receptor kinase that is asymmetrically distributed at the inner face of epidermal cells and this localization is maintained independent of cell type. In epidermal hair (H) cells in the elongation and differentiation zones, WFL exhibits a dual polar localization, accumulating at the inner domain as well as at the root hair initiation domain (RHID). Furthermore, overexpression of WFL leads to a downward shift in root hair (RH) position suggesting WFL operates in a signaling pathway that functions across H cells to inform RH position. WFL asymmetric distribution and function is affected by deletion of the intracellular domains resulting in its mislocalization to the outer polar domain of H cells and exclusion from RHIDs and bulges. Thus, our results demonstrate that in epidermal H cells the WFL intracellular domains are required to direct its dual polar localization and influence RH position. ONE SENTENCE SUMMARYA receptor kinase with dual polar localization, to the inner polar domain and root hair initiation domain, in root epidermal cells, requires its intracellular domain for localization and function. 

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