Project description:Reversible modification of proteins with linkage-specific ubiquitin chains is critical for intracellular signaling. Yet, information on physiological roles and underlying signaling mechanisms of particular ubiquitin linkages during human development are limited. Here, relying on genomic constraint scores, we identify 10 patients with a novel multiple congenital anomaly disorder caused by hemizygous variants in OTUD5, encoding a K48-/K63-linkage-specific deubiquitylase. By studying these mutations, we find that OTUD5 controls neuroectodermal differentiation through cleaving K48-linked ubiquitin chains to counteract degradation of a select group of chromatin regulators. These include ARID1A/B, HDAC2, and HCF1, mutation of which underlie different developmental disorders that exhibit phenotypic overlap with OTUD5 patients. Consequently, loss of OTUD5 during early differentiation leads to less accessible chromatin at neuroectodermal enhancers and thus aberrant rewiring of gene expression networks. Our study describes a novel developmental disorder we name LINKED (LINKage-specific-deubiquitylation-deficiency-induced Embryonic Defects) syndrome, provides a previously unrecognized mechanistic link between phenotypically related diseases, and reveals linkage-specific ubiquitin cleavage from substrate groups (i.e. chromatin remodelers) as an essential mode of signaling required to coordinate embryonic differentiation pathways.

Project description:DUBs are involved in various pathways and signalling networks by pairing with E3 ubiquitin ligases in protein complexes. In order to test whether OTUD5 associates with an E3 ubiquitin ligase to regulate cell proliferation, the stable Flag-OTUD5/Hep3B cell line was established by transfecting Hep3B cells with plasmids expressing pCIN4-Flag-OTUD5. The cellular factors interacting with OTUD5 were purified by anti-Flag antibody-conjugated M2 beads.

Project description:Linkage-specific deubiquitylation by OTUD5 defines an embryonic pathway intolerant to genomic variation

Project description:Linkage-specific deubiquitylation by OTUD5 defines an embryonic pathway intolerant to genomic variation [ATAC-Seq]

Project description:Linkage-specific deubiquitylation by OTUD5 defines an embryonic pathway intolerant to genomic variation [RNA-Seq]

Project description:Whole-transcriptome analysis was performed on RNA from OTUD5-wild type, OTUD5-null, and GDC0349-treated HEK293 cells to identify the cellular processes regulated by OTUD5 and mTOR simultaneously.

Project description:Ubiquitin is a highly conserved eukaryotic protein responsible for regulating a variety of functions when conjugated to target proteins. Ubiquitin is essential, accumulates during the stress response, and is the canonical signal for protein degradation by the proteasome. Still, the function of ubiquitin in response to oxidative stress, particularly in the removal of oxidized proteins remains elusive because of the number of potential targets and different roles that polyubiquitin chains can play. Since polyubiquitin chains linked by K48 ubiquitin are the most abundant and canonical signal for protein degradation, we investigated the roles of K48 ubiquitin in the degradation of oxidized proteins. Combining protein oxidation, linkage-specific ubiquitination screens, and quantitative proteomics, we found K48 ubiquitin accumulated in a bimodal fashion, at both the early and late phase of response. We further showed that a fraction of oxidized proteins are conjugated with K48 ubiquitin in vivo. Using quantitative proteomics we identified ~750 ubiquitinated proteins and ~400 oxidized proteins that were differentially modified during the stress response, and around half the proteins were both oxidized and ubiquitinated. These proteins were highly abundant and function in translation and energy metabolism. Finally, we showed that the ubiquitination system is required for degradation of oxidized proteins, suggesting that oxidized proteins that rapidly accumulate during stress are ubiquitinated, and degraded during the later recovery phase. This temporal disconnect may be necessary for reprogramming protein dynamics, restoring proteostasis, and resuming cell growth.

Project description:Ferroptosis is an iron-dependent programmed cell death associated with severe kidney diseases, linked to decreased glutathione peroxidase 4 (GPX4). However, the spatial distribution of renal GPX4-mediated ferroptosis and the molecular events causing GPX4 reduction during ischemia-reperfusion (I/R) remain largely unknown. Using spatial transcriptomics, we identify that GPX4 is situated at the interface of the inner cortex and outer medulla, a hyperactive ferroptosis site post-I/R injury. We show that OTU deubiquitinase 5 (OTUD5) is a GPX4-binding protein that confers ferroptosis resistance by stabilizing GPX4. During I/R, ferroptosis is induced by mTORC1-mediated autophagy, causing OTUD5 degradation and subsequent GPX4 decay. Functionally, OTUD5 deletion intensifies renal tubular cell ferroptosis and exacerbates acute kidney injury, while AAV-mediated OTUD5 delivery mitigates ferroptosis and promotes renal function recovery from I/R injury. In this work, our study highlights a new autophagy-dependent ferroptosis module: hypoxia/ischemia-induced OTUD5 autophagy triggers GPX4 degradation, offering a potential therapeutic avenue for I/R-related kidney diseases.

Project description:SpyTagged branched and unbranched K48- and K63-linked Tetra-Ubiquitin chains were immobilized on SpyCatcher agarose (48Ub4; 63Ub4; [Ub]2-48,63Ub-48Ub; [Ub]2-48,63Ub-63Ub). Pulldown were performed from protease-inhibitor treated U2OS cell lines to identify specific binders of K48-K63-branched Ub4.

Project description: Not available