bims-nucpor Biomed News
on Nuclear pore complex and nucleoporins in stress, aging and disease
Issue of 2022‒07‒03
three papers selected by
Sara Mingu
Johannes Gutenberg University
  1. Unraveling docking and initiation of mRNA export through the nuclear pore complex.
  2. RanGTPase links nucleo-cytoplasmic transport to the recruitment of cargoes into small extracellular vesicles.
  3. A unified statistical potential reveals that amino acid stickiness governs nonspecific recruitment of client proteins into condensates.
  1. Bioessays. 2022 Jun 26. e2200027
    Unraveling docking and initiation of mRNA export through the nuclear pore complex.
    Mark Tingey, Weidong Yang.
      The nuclear export of mRNA through the nuclear pore complex (NPC) is a process required for the healthy functioning of human cells, making it a critical area of research. However, the geometries of mRNA and the NPC are well below the diffraction limit of light microscopy, thereby presenting significant challenges in evaluating the discrete interactions and dynamics involved in mRNA nuclear export through the native NPC. Recent advances in biotechnology and single-molecule super-resolution light microscopy have enabled researchers to gain granular insight into the specific contributions made by discrete nucleoporins in the nuclear basket of the NPC to the export of mRNA. Specifically, by expanding upon the docking step facilitated by the protein TPR in the nuclear basket as well as identifying NUP153 as being the primary nuclear basket protein initiating export through the central channel of the NPC.
    DOI:  https://doi.org/10.1002/bies.202200027
  2. Cell Mol Life Sci. 2022 Jul 02. 79(7): 392
    RanGTPase links nucleo-cytoplasmic transport to the recruitment of cargoes into small extracellular vesicles.
    Sakalya Chavan, Deepak Khuperkar, Akshay Lonare, Swagatika Panigrahi, Jayesh Bellare, Srikanth Rapole, Vasudevan Seshadri, Jomon Joseph.
      Small extracellular vesicle (sEV)-mediated intercellular communication regulates multiple aspects of growth and development in multicellular organisms. However, the mechanism underlying cargo recruitment into sEVs is currently unclear. We show that the key nucleo-cytoplasmic transport (NCT) protein-RanGTPase, in its GTP-bound form (RanGTP), is enriched in sEVs secreted by mammalian cells. This recruitment of RanGTP into sEVs depends on the export receptor CRM1 (also called XPO1). The recruitment of GAPDH, a candidate cargo protein, into sEVs is regulated by the RanGTP-CRM1axis in a nuclear export signal (NES)-dependent manner. Perturbation of NCT through overexpression or depletion of nuclear transport components affected the recruitment of Ran, CRM1 and GAPDH into sEVs. Our studies, thus, suggest a link between NCT, particularly the Ran-CRM1 axis, and recruitment of NES-containing cargoes into the sEVs. Collectively, these findings implicate RanGTPase as a link between NCT and sEV mediated intercellular communication.
    Keywords:  Exosome; Exportin1/CRM1; Intercellular communication; Nuclear export signal; RanGTPase; Small extracellular vesicles
    DOI:  https://doi.org/10.1007/s00018-022-04422-y
  3. Protein Sci. 2022 Jul;31(7): e4361
    A unified statistical potential reveals that amino acid stickiness governs nonspecific recruitment of client proteins into condensates.
    José A Villegas, Emmanuel D Levy.
      Membraneless organelles are cellular compartments that form by liquid-liquid phase separation of one or more components. Other molecules, such as proteins and nucleic acids, will distribute between the cytoplasm and the liquid compartment in accordance with the thermodynamic drive to lower the free energy of the system. The resulting distribution colocalizes molecular species to carry out a diversity of functions. Two factors could drive this partitioning: the difference in solvation between the dilute versus dense phase and intermolecular interactions between the client and scaffold proteins. Here, we develop a set of knowledge-based potentials that allow for the direct comparison between stickiness, which is dominated by desolvation energy, and pairwise residue contact propensity terms. We use these scales to examine experimental data from two systems: protein cargo dissolving within phase-separated droplets made from FG repeat proteins of the nuclear pore complex and client proteins dissolving within phase-separated FUS droplets. These analyses reveal a close agreement between the stickiness of the client proteins and the experimentally determined values of the partition coefficients (R > 0.9), while pairwise residue contact propensities between client and scaffold show weaker correlations. Hence, the stickiness of client proteins is sufficient to explain their differential partitioning within these two phase-separated systems without taking into account the composition of the condensate. This result implies that selective trafficking of client proteins to distinct membraneless organelles requires recognition elements beyond the client sequence composition. STATEMENT: Empirical potentials for amino acid stickiness and pairwise residue contact propensities are derived. These scales are unique in that they enable direct comparison of desolvation versus contact terms. We find that partitioning of a client protein to a condensate is best explained by amino acid stickiness.
    Keywords:  amino acid stickiness; biomolecular condensates; contact potential; interface propensity; sequence-function relationships; statistical energy
    DOI:  https://doi.org/10.1002/pro.4361
This page is being maintained by Thomas Krichel. It was last updated on 2022‒07‒10 at 18:45:15.