Spatial structure of disordered proteins dictates conductance and selectivity in nuclear pore complex mimics
Adithya N. Ananth (Kavli institute of nanoscience Delft, TU Delft - BN/Cees Dekker Lab)
Ankur Mishra (University Medical Center Groningen)
Steffen Frey (Max Planck Institute for Biophysical Chemistry (Karl Friedrich Bonhoeffer Institute))
Arvind Dwarkasing (TU Delft - ImPhys/Practicum support, Kavli institute of nanoscience Delft)
Roderick Versloot (Student TU Delft, Kavli institute of nanoscience Delft)
Erik van der Giessen (University Medical Center Groningen)
Dirk Görlich (Max Planck Institute for Biophysical Chemistry (Karl Friedrich Bonhoeffer Institute))
Patrick Onck (University Medical Center Groningen)
Cees Dekker (TU Delft - BN/Cees Dekker Lab, Kavli institute of nanoscience Delft)
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Abstract
Nuclear pore complexes (NPCs) lined with intrinsically disordered FG-domains act as selective gatekeepers for molecular transport between the nucleus and the cytoplasm in eukaryotic cells. The underlying physical mechanism of the intriguing selectivity is still under debate. Here, we probe the transport of ions and transport receptors through biomimetic NPCs consisting of Nsp1 domains attached to the inner surface of solid-state nanopores. We examine both wildtype FG- domains and hydrophilic SG-mutants. FG-nanopores showed a clear selectivity as transport receptors can translocate across the pore whereas other proteins cannot. SG mutant pores lack such selectivity. To unravel this striking difference, we present coarse-grained molecular dynamics simulations that reveal that FG-pores exhibit a high-density, nonuniform protein distribution, in contrast to a uniform and significantly less-dense protein distribution in the SG-mutant. We conclude that the sequence-dependent density distribution of disordered proteins inside the NPC plays a key role for its conductivity and selective permeability.