Login / Signup

Homotypic SCOTIN assemblies form ER-endosome membrane contacts and regulate endosome dynamics.

Hyeri YunMin-Kyo JungHojin LeeSungjin JungTae-Hyeon KimNari KimSeung-Yeol ParkWon Jong KimJi Young MunJoo-Yeon Yoo
Published in: EMBO reports (2023)
The ER regulates the spatiotemporal organization of endolysosomal systems by membrane contact. In addition to tethering via heterotypic interactions on both organelles, we present a novel ER-endosome tethering mechanism mediated by homotypic interactions. The single-pass transmembrane protein SCOTIN is detected in the membrane of the ER and endosomes. In SCOTIN-knockout (KO) cells, the ER-late endosome contacts are reduced, and the perinuclear positioning of endosomes is disturbed. The cytosolic proline-rich domain (PRD) of SCOTIN forms homotypic assemblies in vitro and is necessary for ER-endosome membrane tethering in cells. A region of 28 amino acids spanning 150-177 within the SCOTIN PRD is essential to elicit membrane tethering and endosomal dynamics, as verified by reconstitution in SCOTIN-KO cells. The assembly of SCOTIN (PRD) is sufficient to mediate membrane tethering, as purified SCOTIN (PRD), but not SCOTIN (PRDΔ150-177), brings two different liposomes closer in vitro. Using organelle-specific targeting of a chimeric PRD domain shows that only the presence on both organellar membranes enables the ER-endosome membrane contact, indicating that the assembly of SCOTIN on heterologous membranes mediates organelle tethering.
Keyphrases
  • induced apoptosis
  • estrogen receptor
  • endoplasmic reticulum
  • breast cancer cells
  • cell cycle arrest
  • amino acid
  • endoplasmic reticulum stress
  • mesenchymal stem cells
  • cell proliferation
  • bone marrow