Project description:The OTU deubiquitinase TRABID is highly tuned for the recognition and cleavage of K29 and K33-linked ubiquitin chains. Yet the cellular functions of these atypical ubiquitin signals remain unclear. Here, we compared the interactome of two different catalytically-dead TRABID constructs, one that lacks the OTU domain and the other a single point mutant that is catalytically inactive. Since both constructs also act as ubiquitin trapping mutants, this approach was used to differentiate between interactors and substrates. The E3 ubiquitin ligase HECTD1 was confirmed as a TRABID substrate, and using UbiCREST and Ubiquitin-AQUA proteomics, we determined that HECTD1 preferentially assembles K29- and K48-linked ubiquitin chains. Further in vitro autoubiquitination assays using ubiquitin mutants established that in contrast to UBE3C, HECTD1 requires the formation of branched K29/K48-linked chains for its full activity. Finally, we used transient knockdown and genetic knock out of TRABID in mammalian cells to show that TRABID stabilises HECTD1 protein levels. This study identifies TRABID-HECTD1 as a K29-specific DUB/E3 pair and provides novel insights on the assembly of branched ubiquitin signals.

Project description:Coenzyme A is an important cellular metabolite critical for metabolic processes and the regulation of gene expression. The recent discovery of its antioxidant role has highlighted its protective function that leads to the formation of a mixed-disulfide bond with protein cysteines, termed protein CoAlation. To date, more than 2,000 CoAlated bacterial and mammalian proteins have been identified in cellular response to oxidative stress with the majority being involved in metabolic pathways (60%). In vitro and cellular studies have shown that protein CoAlation is a widespread post-translational modification, which modulates the activity and conformation of the modified proteins. The induction of protein CoAlation by oxidative stress was found to be rapidly reversed after the removal of oxidizing agents from the medium of cultured cells. In this study, we developed an ELISA-based deCoAlation assay to detect deCoAlation activity from B. subtilis and B. megaterium lysates. We then used a combination of ELISA-based assay and purification strategies to show that deCoAlation is an enzyme-driven mechanism. Using mass-spectrometry and deCoAlation assays (anti-CoA WB), we identified B. subtilis YtpP (thioredoxin-like protein) and thioredoxin A (TrxA) as enzymes that can remove CoA from different substrates. With mutagenesis studies, we identified YtpP and TrxA catalytic cysteine residues and proposed a possible deCoAlation mechanism for MsrA and PRDX5, which results in the release of both CoA and the reduced form of MsrA or PRDX5. Overall, this paper reveals deCoAlation activity of YtpP and TrxA, and opens doors to future studies on the CoA-mediated redox regulation of CoAlated proteins under various cellular stress conditions.

Project description:A collection of stable Drosophila S2 cell lines was established, each one expressing a (His)-PC SNAP tagged version of each of the six Elongator subunits. From these stable lines, the endogenous Elongator complex can be recovered by pulling on the exogenous subunit via the PC tag. This allowed us to test which subunit can be over-expressed and used to recover the full Elongator complex for further in vitro experiments.

Project description:Microtubules (MTs) are fundamental to cellular architecture, function and organismal development. They are nucleated from microtubule organizing centres by the evolutionary conserved ?-tubulin ring complex (?TuRC). However, the molecular mechanism of nucleation remains elusive. Here, we used cryo-electron tomography (cryo-ET) to determine the structure of the native ?TuRC capping the minus end of a MT in the context of enriched budding yeast spindles. In our structure, ?TuRC presents a ring of ?-tubulin subunits to seed nucleation of exclusively 13-protofilament microtubules, and it adopts an active closed conformation to function as a perfect geometric template for MT nucleation. Our cryo-ET reconstruction also revealed that a novel coiled-coil protein staples the first row of ?/?-tubulin molecules to alternating positions along the ?-tubulin ring. This positioning of ?/?-tubulin onto ?TuRC suggests a role for the coiled-coil protein in augmenting ?TuRC-mediated microtubule nucleation. Based on our results we describe a molecular model for budding yeast ?TuRC activation and MT nucleation.

Project description:The main force generators in eukaryotic cilia and flagella are axonemal outer dynein arms (ODAs). During cilio-genesis, these ∼1.8 MDa complexes are assembled in the cytoplasm and targeted to cilia via an unknown mechanism. Here we use the ciliate Tetrahymena to identify two novel factors (Q22YU3 and Q22MS1) which bind ODAs in the cytoplasm and are required for their delivery to cilia. We show that Q22YU3, which we name Shulin, locks the ODA motor domains into a closed conformation and inhibits motor activity. Cryo-EM reveals how Shulin stabilizes this compact form of ODAs by binding to the dynein tails. Our findings provide a molecular explanation for how newly assembled dyneins are packaged for delivery to the cilia.

Project description:Although the pathological hallmark of amyotrophic lateral sclerosis (ALS) is the nucleocytoplasmic mislocalisation of RNA binding proteins (RBPs), such as TDP-43 and FUS, the nucleocytoplasmic distribution of mRNA remains uncharacterised. Here, we used subcellular fractionation with RNA sequencing and proteomics to assess nucleocytoplasmic mRNA and protein localisation in human induced pluripotent stem cell-derived motor neurons (iPSNs) from ALS patients with TARDBP mutations, VCP mutations, and controls with VCP mutations knocked-in with CRISPR/Cas9. In each mutant group, we found substantial nucleocytoplasmic mRNA redistribution, particularly in transcripts involved in protein binding. Redistributed transcripts in ALS iPSNs were enriched in protein-coding biotypes, exhibited longer lengths, and had enhanced interactions with RBPs, including TDP-43 and FUS. Using mass spectrometry in TARDBP mutant, VCP mutant, and VCP mutant knock-in iPSNs, we reveal widespread protein mislocalisation, especially in RBPs. We find that mislocalised proteins exhibit substantially greater binding to redistributed transcripts than non-redistributed mRNAs, suggesting that RBP mislocalisation may be directly coupled to mRNA redistribution. Remarkably, treatment with the VCP D2 ATPase domain inhibitor ML240 restored both nucleocytoplasmic mRNA redistribution and protein mislocalisation not only in VCP mutants but also in TARDBP mutant iPSNs. Functional assays in VCP mutant iPSNs further confirmed that ML240 restores lysosomal localisation from the perinuclear region towards the neurites and reduces oxidative stress. Our findings demonstrate that ALS motor neurons exhibit concomitant nucleocytoplasmic mRNA redistribution and RBP

Project description:TAP-GluN1 (840 kDa and 1.5 MDa), PSD95-TAP (1.5 MDa) and WT (control; 1.5 MDa) native complexes from Grin1^TAP/TAP, Dlg4^TAP/TAP, and WT mouse forebrain (cortex and hippocampus), respectively. Purified samples were seperated by blue native PAGE. Bands were excised, digested with trypsin. Peptides were identified by LC-MS/MS.

Project description:Proximity labeling provides a powerful in vivo tool to characterize the proteome of subcellular structures and the interactome of specific proteins. Using the highly active biotin ligase TurboID, we optimize a proximity labeling protocol for C. elegans. We use this protocol to characterise the proteomes of the worm’s gut, muscle, skin, and nervous system. We express TurboID exclusively in the pair of AFD neurons and show we can identify known and previously unknown proteins expressed selectively in AFD. We knock TurboID into the endogenous elks-1 gene, which encodes a presynaptic active zone protein. We identify many known ELKS-1 interacting proteins as well as previously uncharacterised synaptic proteins. Versatile vectors, and the inherent advantage of C. elegans for biochemistry, make proximity labeling a valuable addition to the nematode’s armory.

Project description:Starvation in diploid budding yeast cells triggers a cell-fate program culminating in meiosis and spore formation. Transcription activation of early meiotic genes (EMGs) hinges on the transcription activator Ime1, its DNA-binding partner Ume6, and GSK-3 kinase Rim11. Phosphorylation of Ume6 by Rim11 is key for EMG activation. We report that Rim11 functions as the central signal integrator for controlling Ume6 phosphorylation and EMG transcription. In nutrient-rich conditions, PKA suppresses Rim11 levels, while TORC1 retains Rim11 in the cytoplasm. Inhibiting PKA and TORC1 induces Rim11 expression and nuclear localization. Remarkably, nuclear Rim11 is required, but not sufficient, for Rim11-dependent Ume6 phosphorylation. Additionally, Ime1 is an essential anchor protein for phosphorylating Ume6. Subsequently, Ume6-Ime1 coactivator complexes form, which drive EMG transcription. Our results demonstrate how varied signalling inputs (PKA/TORC1/Ime1) converge through Rim11 to regulate EMG expression and meiosis initiation. We posit that the signalling-regulatory network elucidated here generates robustness in cell-fate control.

Project description:The spike (S) protein of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) binds the cell surface protein ACE2 to mediate fusion of the viral membrane with target cells1-4. S comprises a large external domain, a transmembrane domain (TMD) and a short cytoplasmic tail5,6. To elucidate the intracellular trafficking of S protein in host cells we applied proteomics to identify cellular factors that interact with its cytoplasmic tail. We confirm interactions with components of the COPI, COPII and SNX27/retromer vesicle coats, and with FERM domain actin regulators and the WIPI3 autophagy component. The interaction with COPII promotes efficient exit from the endoplasmic reticulum (ER), and although COPI-binding should retain S in the early Golgi system where viral budding occurs, the binding is weakened by a suboptimal histidine residue in the recognition motif. As a result, S leaks to the surface where it accumulates as it lacks an endocytosis motif of the type found in many other coronaviruses7-10. It is known that when at the surface S can direct cell:cell fusion leading to the formation of multinucleate syncytia7-9. Thus, the trafficking signals in the cytoplasmic tail of S protein indicate that syncytia formation is not an inadvertent by-product of infection but rather a key aspect of the replicative cycle of SARS-CoV-2 and potential cause of pathological symptoms.