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The potent BECN2-ATG14 coiled-coil interaction is selectively critical for endolysosomal degradation of GPRASP1/GASP1-associated GPCRs.

Xianxiu QiuNa LiQifan YangShuai WuXiaohua LiXuehua PanSoh YamamotoXiaozhe ZhangJincheng ZengJiahao LiaoCongcong HeRenxiao WangYanxiang Zhao
Published in: Autophagy (2023)
BECN2 is a mammal-specific homolog of BECN1. Both proteins serve as a scaffolding molecule in the class III phosphatidylinositol 3-kinase complex (PtdIns3K) to promote macroautophagy/autophagy and endolysosomal trafficking. Our previous studies have shown that the BECN1 coiled-coil domain forms a metastable homodimer and readily self-dissociate to form the BECN1-ATG14 or BECN1-UVRAG coiled-coil complex as part of the scaffolding "arm" of the PtdIns3K complex. Here we report the crystal structure of the BECN2 coiled-coil domain, which forms a metastable homodimer similar to BECN1 but shows reduced stability and large deviation from the ideal coiled-coil geometry due to extra "imperfect" residues. We also report the crystal structure of BECN2-ATG14 coiled-coil complex, which is structurally similar to the BECN1-UVRAG coiled-coil complex we reported previously but functionally distinct. The potent BECN2-ATG14 interaction is selectively critical for endolysosomal degradation of the GPRASP1-associated DRD2/D2R but shows limited effect on EGFR, a cargo that depends on the BECN1-UVRAG interaction. We designed stapled peptides that selectively interacted with the BECN2 coiled-coil domain to enhance the BECN2-ATG14 or BECN1-UVRAG interaction. One such peptide specifically promoted BECN2-dependent processes including autophagy and endolysosomal degradation of DRD2/D2R but did not affect BECN1-dependent EGFR degradation. Our findings suggest that, despite high sequence identity to BECN1, BECN2 coiled-coil domain has unique structural features and the BECN2-ATG14 interaction selectively promotes autophagic or endolysosomal degradation of BECN2-specific cargos including GPRASP1-associated GPCRs.
Keyphrases
  • small cell lung cancer
  • cell death
  • amino acid
  • protein kinase