BaseSpace
Correlation Engine 2.0
Import Your Data
Literature

FAQ

More FAQs

Back to top
Clear Search sequence regions
(e.g. Obesity, Hippocampus, Avian flu virus, Ciprofibrate, rs2476601, PBX1)
Bookmark Forward

Structural basis of sterol binding and transport by a yeast StARkin domain.

Julian-Alexander Jentsch, Irene Kiburu, Kalpana Pandey, Michael Timme, Trudy Ramlall, Bodo Levkau, Jin Wu, David Eliezer, Olga Boudker, Anant K Menon

The Journal of biological chemistry 2018 Apr 13


filter terms:
  • antiporters (2)
  • engages (1)
  • intracellular lipid transport (1)
  • intracellular transport (1)
  • lipid (2)
  • lipid transport (1)
  • plasma membrane (1)
  • protein domains (1)
  • reticulum (2)
  • sterol (11)
  • sterol homeostasis (1)
  • sterol transport (3)
  • transport vesicle (1)
  • yeast (3)
    • Sizes of these terms reflect their relevance to your search.

    The StARkin superfamily comprises proteins with steroidogenic acute regulatory protein-related lipid transfer (StART) domains that are implicated in intracellular, non-vesicular lipid transport. A new family of membrane-anchored StARkins was recently identified, including six members, Lam1-Lam6, in the yeast Saccharomyces cerevisiae. Lam1-Lam4 are anchored to the endoplasmic reticulum (ER) membrane at sites where the ER is tethered to the plasma membrane and proposed to be involved in sterol homeostasis in yeast. To better understand the biological roles of these proteins, we carried out a structure-function analysis of the second StARkin domain of Lam4, here termed Lam4S2. NMR experiments indicated that Lam4S2 undergoes specific conformational changes upon binding sterol, and fluorescence-based assays revealed that it catalyzes sterol transport between vesicle populations in vitro, exhibiting a preference for vesicles containing anionic lipids. Using such vesicles, we found that sterols are transported at a rate of ∼50 molecules per Lam4S2 per minute. Crystal structures of Lam4S2, with and without bound sterol, revealed a largely hydrophobic but surprisingly accessible sterol-binding pocket with the 3-OH group of the sterol oriented toward its base. Single or multiple alanine or aspartic acid replacements of conserved lysine residues in a basic patch on the surface of Lam4S2 near the likely sterol entry/egress site strongly attenuated sterol transport. Our results suggest that Lam4S2 engages anionic membranes via a basic surface patch, enabling "head-first" entry of sterol into the binding pocket followed by partial closure of the entryway. Reversal of these steps enables sterol egress. © 2018 Jentsch et al.

    Citation

    Julian-Alexander Jentsch, Irene Kiburu, Kalpana Pandey, Michael Timme, Trudy Ramlall, Bodo Levkau, Jin Wu, David Eliezer, Olga Boudker, Anant K Menon. Structural basis of sterol binding and transport by a yeast StARkin domain. The Journal of biological chemistry. 2018 Apr 13;293(15):5522-5531

    Expand section icon Mesh Tags

    Expand section icon Substances


    PMID: 29463678

    View Full Text
    • Copyright © 2024 Illumina Inc. All rights reserved.