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Advanced filters: Author: Monika Fuxreiter Clear advanced filters

  • Monika Fuxreiter discusses recent studies indicating that generic interactions that determine the biophysical properties of condensates are important for condensate function.

    • Monika Fuxreiter
    Research Highlights
    Nature Reviews Molecular Cell Biology
    Volume: 22, P: 162-163

  • In this Comment article, Monika Fuxreiter discusses possible roles of dynamic, fuzzy protein interactions and their importance in changing cellular environments.

    • Monika Fuxreiter
    Comments & Opinion
    Nature Reviews Molecular Cell Biology
    Volume: 26, P: 169-170

  • In this Perspective, Fuxreiter and Vendruscolo discuss the fundamental nature of the droplet and amyloid states of proteins, the regulatory mechanisms controlling their formation, and the cellular functions associated with these condensed states.

    • Monika Fuxreiter
    • Michele Vendruscolo
    Reviews
    Nature Cell Biology
    Volume: 23, P: 587-594

  • 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

  • In this review, the authors define protein condensation diseases as conditions caused by aberrant liquid-like or solid-like states of proteins, and describe opportunities for therapeutic interventions to restore the normal phase behaviour of proteins. The review accompanies the related collection of articles published in Nature Communications focusing on possible therapeutic approaches involving liquid-liquid phase separation.

    • Michele Vendruscolo
    • Monika Fuxreiter
    ReviewsOpen Access
    Nature Communications
    Volume: 13, P: 1-11

  • Nuclear magnetic resonance spectroscopy is transforming our views of proteins by revealing how their structures and dynamics are closely intertwined to underlie their functions and interactions. Compelling representations of proteins as statistical ensembles are uncovering the presence and biological relevance of conformationally heterogeneous states, thus gradually making it possible to go beyond the dichotomy between order and disorder through more quantitative descriptions that span the continuum between them.

    • Pietro Sormanni
    • Damiano Piovesan
    • Michele Vendruscolo
    Comments & Opinion
    Nature Chemical Biology
    Volume: 13, P: 339-342