Project description:UFM1 is a small, metazoan-specific, ubiquitin-like protein modifier that is essential for embryonic development. Although loss-of-function mutations in UFM1 conjugation are linked to ER stress, neither the biological function nor the relevant cellular targets of this protein modifier are known. Here we show that a largely uncharacterized ribosomal protein, RPL26, is the principal target of UFM1 conjugation. RPL26 UFMylation and deUFMylation is catalyzed by enzyme complexes tethered to the cytoplasmic surface of the ER and UFMylated RPL26 is highly enriched on ER membrane-bound ribosomes and polysomes. Biochemical analysis and structural modeling establish that UFMylated RPL26 and the UFMylation machinery are in close proximity to the SEC61 translocon, suggesting that this modification plays a direct role in cotranslational protein translocation into the ER. These data suggest that UFMylation is a ribosomal modification specialized to facilitate metazoan-specific protein biogenesis at the ER.

Project description:During co-translational translocation at the endoplasmic reticulum (ER), ribosomes can stall and become covalently modified with the ubiquitin-like protein UFM1 on the 60S ribosomal subunit RPL26 (uL24). This process, known as UFMylation, is mediated by the UFM1 Ribosome E3 Ligase (UREL) complex, comprised of UFL1, UFBP1, and CDK5RAP3. However, the functional consequences of UFMylation and catalytic mechanisms of UREL are unknown. Here, we present crosslinking-mass spectrometry (XL-MS) data of UREL bound to 60S ribosomes.

Project description:UFMylation, is a Ubiquitin-like modification occurring on RPL26, a ribosomal subunit, upon ribosome stalling at the ER membrane. This modification is achieved by a pool of enzymes commonly referred to as E1-activating, E2-conjugating and E3-ligase enzymes. The UFM1 E3 ligase comprises of three proteins: UFL1, UFBP1 and CDK5RAP3, referred to as UFM1 Ribosome E3 Ligase (UREL) complex. While UFL1 and UFBP1 are sufficient for E3 ligase activity in vitro, CDK5RAP3 is indispensable for ribosome UFMylation in vivo. In this work, we characterize in vitro UFMylation reaction of purified 60S ribosomes in the presence and absence of CDK5RAP3 using LC-MS/MS. Specifically, we analyse sites of UFMylation, linkage type and quantify monoUFMylation and diUFMylation on RPL26. Interestingly, we find UFMylation to occur on a specific lysine residue, K134, in the presence of UFL1/UFBP1 alone and in complex with CDK5RAP3. In addition, we also provide quantitative information on relative abundances of RPL26 mono- and di-UFMylation under these conditions.

Project description:UFMylation mediates the covalent modification of substrate proteins with UFM1 (Ubiquitin- fold modifier 1) and regulates the selective degradation of endoplasmic reticulum (ER) via autophagy (ER-phagy) to maintain ER homeostasis. Specifically, collisions of the ER-bound ribosomes trigger ribosome UFMylation, which in turn activates C53-mediated autophagy that clears the toxic incomplete polypeptides. C53 has evolved non-canonical shuffled ATG8 interacting motifs (sAIMs) that are essential for ATG8 interaction and autophagy initiation. Why these non-canonical motifs were selected during evolution, instead of canonical ATG8 interacting motifs remains unknown. Here, using a phylogenomics approach, we show that UFMylation is conserved across the eukaryotes and secondarily lost in fungi and some other species. Further biochemical assays have confirmed those results and showed that the unicellular algae, Chlamydomonas reinhardtii has a functional UFMylation machinery, overturning the assumption that this process is linked to multicellularity. Our conservation analysis also revealed that UFM1 co-evolves with the sAIMs in C53, reflecting a functional link between UFM1 and the sAIMs. Using biochemical and structural approaches, we confirmed the interaction of UFM1 with the C53 sAIMs and found that UFM1 and ATG8 bound to the sAIMs in a different mode. Conversion of sAIMs into canonical AIMs prevented binding of UFM1 to C53, while strengthening ATG8 interaction. This led to the autoactivation of the C53 pathway and sensitized Arabidopsis thaliana to ER stress. Altogether, our findings reveal an ancestral toggle switch embodied in the sAIMs that regulates C53- mediated autophagy to maintain ER homeostasis.

Project description:UFM1 is a post-translational modification that regulates protein function during the ER stress response, DNA damage response, and antiviral response. The goal of this experiment was to determine the role of UFM1 in regulating gene expression induced during RIG-I signaling. We found that deletion of UFM1 broadly decreases transcription of some interferon-stimulated genes during activation of antiviral innate immunity. In subsequent experiments, we found that this is due to UFM1/ufmylation regulation of RIG-I interaction with its trafficking protein 14-3-3epsilon.

Project description:Osteoarthritis (OA) is a widespread age-related joint disease caused by the gradual loss of chondrocyte function along with age. Here, we found that UFMylation modification was lower-leveled in senescent cartilage, mediated chondrocyte senescence and OA phenotypes through targeting CAVIN1, which acted as a stimulator in chondrocyte senescence, mainly through promoting CPT1 expression and activating fatty acid β-oxidation (FAO). Physiologically, FAO was at a very low level in chondrocytes, while the anomalous activation of FAO accelerated chondrocyte senescence. UFMylation of CAVIN1 promoted its binding with TRIP12, leading to ubiquitination degradation. Therefore, UFMylation played a pivotal role in post-translationally modification of CAVIN1. Polymeric micellar nanoparticles (NPs) conjugated with UFM1 improved the stability of UFM1 recombinant protein (UFM1-rp), and extended the retention time of UFM1-rp in the mouse joint cavity. The administration of UFM1 into mouse joints using an advanced NP delivery system is effective in attenuating age-related pathogenesis. Therefore, we uncovered a previously unknown mechanism, UFM1-CAVIN1-CPT1 axis, in the protection of OA progression and constructed a new drug for OA treatment, and have provided important preliminary evidence toward the translation of our findings into clinical usage.

Project description:The dynamic ribosome-translocon complex, which resides at the endoplasmic reticulum (ER) membrane, produces a major fraction of the human proteome . It governs the synthesis, translocation, membrane insertion, N-glycosylation, folding and disulfide-bond formation of nascent proteins. While individual components of this machine have been studied at high resolution in isolation, insights into their interplay in the native membrane remain limited. Here, we use electron cryo-tomography (cryo-ET), extensive classification and molecular modeling to capture molecular resolution snapshots of mRNA translation and protein maturation at the ER membrane. Comprehensively recapitulating the translational elongation cycle, we identify a highly abundant classical pre-translocation (PRE) intermediate with eEF1a in an extended conformation following the decoding state, which indicates that eEF1a remains ribosome-associated after GTP-hydrolysis during proofreading. The complete atomic structure of the most abundant ER translocon variant comprising the protein-conducting channel Sec61, the translocon-associated protein complex (TRAP) and the oligosaccharyltransferase complex A (OSTA) reveals the molecular framework for signal peptide (SP) membrane insertion and protein N-glycosylation. Associated with OSTA we observe stoichiometric and sub-stoichiometric cofactors, likely including protein isomerases. Collectively, comprehensive analysis of ER-associated protein biogenesis ex vivo reveals numerous mechanistic insights advancing beyond the study of isolated components.

Project description:Ubiquitination of Stalled Ribosome Triggers Ribosome-associated Quality Control

Project description:An essential first step in the posttranslational modification of proteins with UFM1, UFMylation, is the proteolytic cleavage of pro-UFM1 to expose a C-terminal glycine. Of the two UFM1-specific proteases (UFSPs) identified in humans, only UFSP2 is reported to be active since the annotated sequence of UFSP1 lacks critical catalytic residues. Nonetheless, efficient UFM1 maturation occurs in cells lacking UFSP2 suggesting the presence of another active protease. We hereby identify UFSP1 translated from a non-canonical start site to be this protease. Cells lacking both UFSPs show complete loss of UFMylation resulting from an absence of mature UFM1. While UFSP2, but not UFSP1, removes UFM1 from the ribosomal subunit RPL26, UFSP1 acts earlier in the pathway to mature UFM1 and cleave a potential auto-inhibitory modification on UFC1, thereby controlling activation of UFMylation. In summary, our studies reveal distinctions in substrate specificity and localization-dependent functions for the two proteases in regulating UFMylation. The present dataset includes Data Independent Acquisition (DIA) quantitative proteomics analysis of knockout cell lines reported in our study. Our analysis of the processed data is presented in Figure-6.

Project description:Localized protein synthesis is a fundamental mechanism for creating distinct subcellular environments. Here we developed a generalizable proximity-specific ribosome profiling strategy that enables global interrogation of translation in defined subcellular locations. We applied this approach to the endoplasmic reticulum (ER) in yeast and mammals. We observed the vast majority of secretory proteins to be co-translationally translocated, including substrates capable of post-translational insertion in vitro. Distinct translocon complexes engaged nascent chains at different points during synthesis. Whereas most proteins engaged the ER immediately following or even before signal sequence (SS) emergence, a class of Sec66-dependent proteins entered with a looped SS conformation. Finally, we observed rapid ribosome exchange into the cytosol following translation termination. These data provide insights into how distinct translocation mechanisms act in concert to promote efficient co-translational recruitment.