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Showing 1–11 of 11 results
Advanced filters: Author: Jeetain Mittal Clear advanced filters

  • Theoretical schemes to predict colloidal crystals of arbitrary complexity are highly desirable. Here the authors develop a general approach based on symmetry and stoichiometric constraints that predicts the stability of multicomponent colloidal lattices more efficiently than traditional methodologies.

    • Nathan A. Mahynski
    • Evan Pretti
    • Jeetain Mittal
    ResearchOpen Access
    Nature Communications
    Volume: 10, P: 1-11

  • This study expands the molecular grammar of FUS, identifying tyrosine, arginine and glutamine as key drivers of phase separation and showing that flexibility from glycine enhances phase separation. Sequence and position affect the contributions of specific residues to phase separation and aggregation.

    • Noah Wake
    • Shuo-Lin Weng
    • Nicolas L. Fawzi
    Research
    Nature Chemical Biology
    Volume: 21, P: 1076-1088

  • Key molecular features that drive protein liquid–liquid phase separation (LLPS) for biomolecular condensate have been reported. A spectrum of additional interactions that influence protein LLPS and material properties have now been characterized. These interactions extend beyond a limited set of residue types and can be modulated by environmental factors such as temperature and salt concentration.

    • Shiv Rekhi
    • Cristobal Garcia Garcia
    • Jeetain Mittal
    Research
    Nature Chemistry
    Volume: 16, P: 1113-1124

  • 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

  • Cells spatially organize biochemical reactions within membrane-bound and membraneless compartments. The extent to which intrinsically disordered proteins themselves can form discrete compartments or condensed phases is poorly understood. Now a pair of model IDRs that display orthogonality in condensation and the chain features governing selective assembly have been identified.

    • Rachel M. Welles
    • Kandarp A. Sojitra
    • Matthew C. Good
    Research
    Nature Chemistry
    Volume: 16, P: 1062-1072

  • A carbon nanotube sensor enables real-time optical quantification of hybridization events of microRNA and other oligonucleotides in vivo and in whole urine and serum.

    • Jackson D. Harvey
    • Prakrit V. Jena
    • Daniel A. Heller
    Research
    Nature Biomedical Engineering
    Volume: 1, P: 1-11

  • Thermodynamic principles are used to map the phase behavior of a tunable protein-binding system under crowded cellular conditions. This study marks a substantial step forward in relating molecular interactions to material properties and cellular processes involving protein self-assembly.

    • Roshan Mammen Regy
    • Jeetain Mittal
    News & Views
    Nature Chemical Biology
    Volume: 16, P: 934-935

  • This Perspective reviews the complementary developments in synthetic biology and biomaterials and discusses how convergence of these two fields creates a promising design strategy for the fabrication of tailored living materials for medicine and biotechnology.

    • Allen P. Liu
    • Eric A. Appel
    • Ovijit Chaudhuri
    Reviews
    Nature Materials
    Volume: 21, P: 390-397