Project description:The Golgi apparatus contains many resident enzymes that must remain in place whilst their substrates flow through on their journey from the endoplasmic reticulum to elsewhere in the cell. COPI-coated vesicles bud from the rims of the Golgi stack to recycle Golgi residents to earlier cisternae. Different enzymes are present in different parts of the stack, and at least one COPI adaptor protein, GOLPH3, has been shown to recruit enzymes into vesicles in a specific part of the stack. We have used proximity biotinylation to identify further components of intra-Golgi transport vesicles and found FAM114A2, an uncharacterised cytosolic protein. Affinity chromatography with FAM114A2, and its paralogue FAM114A1 showed that they bind to numerous Golgi resident proteins, with membrane-proximal basic residues in the cytoplasmic tail being sufficient for the interaction. Deletion of both proteins from U2OS cells did not result in substantial defects in Golgi function. However, a Drosophila orthologue of these proteins (CG9590/FAM114A) is also localised to the Golgi and binds directly to COPI. Generation of Drosophila mutants lacking FAM114A revealed defects in glycosylation of glue proteins in the salivary gland. Thus, the FAM114A proteins are COPI vesicle resident proteins that bind to Golgi enzymes and so are candidate adaptors to contribute specificity to COPI vesicle recycling in the Golgi stack.

Project description:The Golgi apparatus contains many resident enzymes that must remain in place whilst their substrates flow through on their journey from the endoplasmic reticulum to elsewhere in the cell. COPI-coated vesicles bud from the rims of the Golgi stack to recycle Golgi residents to earlier cisternae. Different enzymes are present in different parts of the stack, and at least one COPI adaptor protein, GOLPH3, has been shown to recruit enzymes into vesicles in a specific part of the stack. We have used proximity biotinylation to identify further components of intra-Golgi transport vesicles and found FAM114A2, an uncharacterised cytosolic protein. Affinity chromatography with FAM114A2, and its paralogue FAM114A1 showed that they bind to numerous Golgi resident proteins, with membrane-proximal basic residues in the cytoplasmic tail being sufficient for the interaction. Deletion of both proteins from U2OS cells did not result in substantial defects in Golgi function. However, a Drosophila orthologue of these proteins (CG9590/FAM114A) is also localised to the Golgi and binds directly to COPI. Generation of Drosophila mutants lacking FAM114A revealed defects in glycosylation of glue proteins in the salivary gland. Thus, the FAM114A proteins are COPI vesicle resident proteins that bind to Golgi enzymes and so are candidate adaptors to contribute specificity to COPI vesicle recycling in the Golgi stack.

Project description:The Golgi apparatus contains many resident enzymes that must remain in place whilst their substrates flow through on their journey from the endoplasmic reticulum to elsewhere in the cell. COPI-coated vesicles bud from the rims of the Golgi stack to recycle Golgi residents to earlier cisternae. Different enzymes are present in different parts of the stack, and at least one COPI adaptor protein, GOLPH3, has been shown to recruit enzymes into vesicles in a specific part of the stack. We have used proximity biotinylation to identify further components of intra-Golgi transport vesicles and found FAM114A2, an uncharacterised cytosolic protein. Affinity chromatography with FAM114A2, and its paralogue FAM114A1 showed that they bind to numerous Golgi resident proteins, with membrane-proximal basic residues in the cytoplasmic tail being sufficient for the interaction. Deletion of both proteins from U2OS cells did not result in substantial defects in Golgi function. However, a Drosophila orthologue of these proteins (CG9590/FAM114A) is also localised to the Golgi and binds directly to COPI. Generation of Drosophila mutants lacking FAM114A revealed defects in glycosylation of glue proteins in the salivary gland. Thus, the FAM114A proteins are COPI vesicle resident proteins that bind to Golgi enzymes and so are candidate adaptors to contribute specificity to COPI vesicle recycling in the Golgi stack.

Project description:The Golgi apparatus contains many resident enzymes that must remain in place whilst their substrates flow through on their journey from the endoplasmic reticulum to elsewhere in the cell. COPI-coated vesicles bud from the rims of the Golgi stack to recycle Golgi residents to earlier cisternae. Different enzymes are present in different parts of the stack, and at least one COPI adaptor protein, GOLPH3, has been shown to recruit enzymes into vesicles in a specific part of the stack. We have used proximity biotinylation to identify further components of intra-Golgi transport vesicles and found FAM114A2, an uncharacterised cytosolic protein. Affinity chromatography with FAM114A2, and its paralogue FAM114A1 showed that they bind to numerous Golgi resident proteins, with membrane-proximal basic residues in the cytoplasmic tail being sufficient for the interaction. Deletion of both proteins from U2OS cells did not result in substantial defects in Golgi function. However, a Drosophila orthologue of these proteins (CG9590/FAM114A) is also localised to the Golgi and binds directly to COPI. Generation of Drosophila mutants lacking FAM114A revealed defects in glycosylation of glue proteins in the salivary gland. Thus, the FAM114A proteins are COPI vesicle resident proteins that bind to Golgi enzymes and so are candidate adaptors to contribute specificity to COPI vesicle recycling in the Golgi stack.

Project description:The retrograde transport inhibitor Retro-2 has a protective effect on cells and in mice against Shiga-like toxins and ricin. Retro-2 causes toxin accumulation in early endosomes, and the relocalization of the Golgi SNARE protein syntaxin-5 to the endoplasmic reticulum. The molecular mechanisms by which this is achieved remain unknown. Here, we show that Retro-2 targets the endoplasmic reticulum exit site component Sec16A, affecting anterograde transport of syntaxin-5 from the endoplasmic reticulum to the Golgi. The formation of canonical SNARE complexes involving syntaxin-5 is not affected in Retro-2-treated cells. In contrast, the interaction of syntaxin-5 with a newly discovered binding partner, the retrograde trafficking chaperone GPP130, is abolished, and we show that GPP130 must indeed bind to syntaxin-5 to drive Shiga toxin transport from endosomes to the Golgi. We thereby identify Sec16A as a druggable target, and provide evidence for a non-SNARE function for syntaxin-5 in interaction with the retrograde cycling protein GPP130. a) Clickable Retro-2 pulldown. To identify protein target of Retro-2.1, providing the first steps to explain effects of Retro-2 on inhibition of STxB retrograde trafficking from endosomes to Golgi. b) GFP-STX5 pulldown. To find interactors of STX5, to build a hypothesis to explain the affect of Retro-2-inhibited anterograde trafficking of STX5 to Golgi, which in turn inhibits STxB retrograde transport from endosomes to Golgi. c) GFP-Sec16A pulldown. The aim of this proteomics assay is to show the effects of Retro-2 on the Sec16A interactome. Results show the differential effects of Retro-2 treatment on the Sec16A interactome, giving insight into the mechanism by which Retro-2, via Sec16A, specifically affects the anterograde trafficking of Syntaxin-5.

Project description:Glycosylation plays an important role for modifications of lipids and sorting of proteins that is regulated by asymmetric intra-Golgi distribution and SPPL3-mediated cleavage of Golgi enzymes. We found that cells lacking the Golgi N-acetylglucosamine phosphotransferase (GNPT) retention factor LYSET/TMEM251 display a SPPL3-dependent hypersecretion of the galactosyltransferase B4GALT5 which is caused by the loss of its lysosomal mannose 6-phosphate (M6P) targeting signal. Similarly, loss of the COPI adaptors GOLPH3/GOLPH3L destabilized LYSET-GNPT complexes and led to a prominent hypersecretion of B4GALT5 and lysosomal enzymes. Mechanistically, we identified LYSET as a novel, atypical client of GOLPH3/GOLPH3L. GOLPH3/GOLPH3L hence ensure cis-Golgi localization of the LYSET-GNPT complex and maintain Golgi polarity, integrity of the M6P tagging machinery and homeostasis of lysosomes.

Project description:The Golgi is a membrane-bound organelle that is essential for protein and lipid biosynthesis. It represents a central trafficking hub that sorts proteins and lipids to various destinations or for secretion from the cell. The Golgi has emerged as a docking platform for cellular signaling pathways including LRRK2 kinase whose deregulation leads to Parkinson disease. Golgi dysfunction is associated with a broad spectrum of diseases including cancer, neurodegeneration, and cardiovascular diseases. To allow the study of the Golgi at high resolution, we report a rapid Golgi immunoprecipitation technique (Golgi-IP) to isolate intact Golgi mini-stacks for subsequent analysis of their content. By fusing the Golgi-resident protein TMEM115 to three tandem HA epitopes (GolgiTAG), we purified the Golgi using Golgi-IP with minimal contamination from other compartments. We then established an analysis pipeline using liquid chromatography coupled with mass spectrometry to characterize the human Golgi proteome, metabolome, and lipidome. Subcellular proteomics confirmed known Golgi proteins and identified proteins not previously associated with the Golgi. Metabolite profiling established the human Golgi metabolome and revealed the enrichment of uridine-diphosphate (UDP) sugars and their derivatives, which is consistent with their roles in protein and lipid glycosylation. Furthermore, targeted metabolomics validated SLC35A2 as the subcellular transporter for UDP-hexose. Finally, lipidomics analysis showed that phospholipids including phosphatidylcholine, phosphatidylinositol, and phosphatidylserine are the most abundant Golgi lipids and that glycosphingolipids are enriched in this compartment. Altogether, our work establishes a comprehensive molecular map of the human Golgi and provides a powerful method to study the Golgi with high precision in health and disease.

Project description:The Endoplasmic Reticulum (ER)-Golgi Intermediate Compartment (ERGIC) is a network of tubules and vesicles known for producing COPI vesicles and receiving COPII vesicles from the ER. Much about its identity, stability, and regulation remains unknown. Here, we show that the TUG (UBXN9, Aspscr1) protein, a central regulator of GLUT4 trafficking, localizes to the ERGIC, and its deletion enhances anterograde secretory flux, redistributes ERGIC markers to the cis-Golgi, and alters Golgi morphology. TUG forms biomolecular condensates in vitro and contains a central disordered region that mediates its recruitment to ERGIC membranes. A distinct N-terminal region mediates its oligomerization in cells. TUG deletion disrupts ERGIC-dependent processes, including autophagy and collagen secretion, and alters the targeting of CFTR, a model protein that undergoes unconventional secretion. We conclude that TUG organizes and stabilizes ERGIC membranes to support their roles in diverse cellular membrane trafficking pathways.

Project description:Here, we mapped subcellular proteome changes to lysosomes, mitochondrion, EEA1-positive endosomes, and Golgi caused by the NLRP3 inflammasome agonists nigericin and CL097. We identified a number of common disruptions to retrograde trafficking pathways, including COPI and Shiga toxin-related transport, in line with recent studies. We further characterized mouse NLRP3 trafficking throughout its activation using temporal proximity proteomics, which supports a recent model of NLRP3 recruitment to endosomes during inflammasome activation. Collectively, these findings provide additional granularity to our understanding of the molecular events driving NLRP3 activation and serve as a valuable resource for cell biological research.

Project description:The anterograde secretory pathway shapes the extracellular environment and the ability of cells to communicate, through the release of cytokines, growth factors, enzymes and extracellular matrix components, and through the regulation of the composition of the plasma membrane (PM). The underlying molecular machinery operates in a concerted and highly regulated manner and is frequently altered in cancer. The Golgi RabGAP protein TBC1D22B is overexpressed in breast cancer and predicts prognosis. Herein, deconvolution of the proximity-labeling and physical interactomes of TBC1D22B, reveals its role in the regulation of anterograde trafficking with liaisons with networks of proteins involved in cell adhesion, and in carbohydrate and lipid metabolism. The function of TBC1D22B in the anterograde pathway was formally demonstrated using the Retention Using Selective Hooks system which synchronizes transport of cargoes from the ER to the Golgi and the PM. TBC1D22B inhibits ER to Golgi transport in a GAP-dependent manner. RAB1B, a key RAB in the early secretory pathway, was found to be a substrate of the TBC1D22B GAP activity, and its silencing phenocopied TBC1D22B overexpression. Thus, TBC1D22B regulates ER to Golgi trafficking through its ability to work as a GAP for RAB1B.