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SAYSD1 senses UFMylated ribosome to safeguard co-translational protein translocation at the endoplasmic reticulum

Lihui Wang, Yue Xu, Sijung Yun, Quan Yuan, Prasanna Satpute‐Krishnan, Yihong Ye

2023Cell Reports30 citationsDOIOpen Access PDF

Abstract

Translocon clogging at the endoplasmic reticulum (ER) as a result of translation stalling triggers ribosome UFMylation, activating translocation-associated quality control (TAQC) to degrade clogged substrates. How cells sense ribosome UFMylation to initiate TAQC is unclear. We conduct a genome-wide CRISPR-Cas9 screen to identify an uncharacterized membrane protein named SAYSD1 that facilitates TAQC. SAYSD1 associates with the Sec61 translocon and also recognizes both ribosome and UFM1 directly, engaging a stalled nascent chain to ensure its transport via the TRAPP complex to lysosomes for degradation. Like UFM1 deficiency, SAYSD1 depletion causes the accumulation of translocation-stalled proteins at the ER and triggers ER stress. Importantly, disrupting UFM1- and SAYSD1-dependent TAQC in Drosophila leads to intracellular accumulation of translocation-stalled collagens, defective collagen deposition, abnormal basement membranes, and reduced stress tolerance. Thus, SAYSD1 acts as a UFM1 sensor that collaborates with ribosome UFMylation at the site of clogged translocon, safeguarding ER homeostasis during animal development.

Topics & Concepts

TransloconEndoplasmic reticulumCell biologyRibosomeTranslation (biology)BiologyChromosomal translocationChemistryBiochemistryRNAMessenger RNAGeneRNA and protein synthesis mechanismsRNA modifications and cancerRNA regulation and disease