Project description:In this study, we are the first to use the MiniTurboID generation of the proximity-dependent biotin identification (BioID) technology to illuminate how the lymphatic endothelial cell (LEC) VE-cadherin interactome changes during junctional remodeling in response to the lymphangiocrine factor adrenomedullin. Here, we created a UBC-driven lentiviral expression vector containing the coding sequence for a Ve-Cadehrin-V5-MiniTurboID fusion-protein. After transduction of LECs with Ve-Cadehrin-MiniTurboID lentivirus, we treated these cells with 100 nM adrenomedullin (AM) or vehicle and labeled proximal proteins with 50 µM for 2 hours to capture dynamic changes in the Ve-Cadehrin interactome during AM-induced junctional rearrangement. Biotin-labeled proximity interactors were isolated via streptavidin-affinity purification (AP) and identified using LC-MS/MS mass spectrometry. Our dataset consists of distinct biological replicates consisting of AP enriched proteins from whole cell lysates (WCL, n = 2) or plasma membrane (PM, n = 3) fractions. WCL fractions allow us to capture proximity networks involved in Ve-Cadehrin trafficking and recycling to the PM, while PM fractions allows us to examine membrane-specific changes in AM-induced adherens junctions assembly.

Project description:DNA-protein interactions regulate critical biological processes. Identifying proteins that bind to specific, functional genomic loci is essential for understanding the underlying regulatory mechanisms on a molecular level. Here, we describe a novel co-binding-mediated protein profiling (CMPP) strategy to investigate the interactome of DNA G-quadruplexes (G4s) in cellular chromatin. CMPP involves cell-permeable, functionalized G4-ligand probes that bind endogenous G4s and subsequently crosslink to co-binding G4-interacting proteins in situ. We show the robustness of CMPP on proximity labelling of a G4 binding protein in vitro. Employing this approach in live cells, we identify hundreds of putative G4-interacting proteins from various functional classes. Next, we observe high G4 binding affinity and selectivity for several G4 interactors in vitro and confirm direct G4 interactions for one of the top candidates in chromatin. Our studies provide a chemical approach to map protein interactions of specific nucleic acid features in living cells.

Project description:• Marchantia polymorpha is a model liverwort and its overall low genetic redundancy is advantageous for dissecting complex pathways. Proximity-dependent in vivo biotin-labelling methods have emerged as powerful interactomics tools in recent years. However, interactomics studies applying proximity labelling are currently limited to angiosperm species in plants. • Here, we established and evaluated a miniTurbo-based interactomics method in M. polymorpha using MpSYP12A and MpSYP13B, two plasma membrane-localized SNARE proteins, as baits. • We show that our method yields a manifold of potential interactors of MpSYP12A and MpSYP13B compared to a co-immunoprecipitation approach. Our method could capture specific candidates for each SNARE. • We conclude that a miniTurbo-based method is a feasible tool for interactomics in M. polymorpha, potentially applicable to other model bryophytes. Our interactome dataset on MpSYP12A and MpSYP13B will be a useful resource to elucidate the evolution of SNARE functions.

Project description:The intracellular function of myosin motors requires a number of adaptor molecules, which control cargo attachment, but also fine-tune motor activity in time and space. These motor-adaptor-cargo interactions are often weak, transient or highly regulated. To overcome these problems we use a proximity labelling-based proteomics strategy (BioID) to map the interactome of the unique minus end-directed actin motor MYO6. Our analysis identified several distinct MYO6-adaptor modules including two complexes containing RHO GEFs which we screened using further BioID baits (LRCH3, DOCK7, GIPC1 and ARHGEF12). These complexes emphasise the multifunctionality of MYO6 provides the first in vivo interactome of a myosin motor protein, highlighting the power of this approach in uncovering dynamic and functionally diverse myosin motor complexes.

Project description:Understanding how small molecules bind to specific protein complexes in living cells is critical to understanding their mechanism-of-action. Unbiased chemical biology strategies for direct readout of protein interactome remodelling by small molecules would provide advantages over target-focused approaches, including the ability to detect previously unknown ligand targets and complexes. However, there are few current methods for unbiased profiling of small molecule interactomes. To address this, we envisioned a technology that would combine the sensitivity and live-cell compatibility of proximity labelling coupled to mass spectrometry, with the specificity and unbiased nature of photoaffinity labelling. In this manuscript, we describe the BioTAC system, a small-molecule guided proximity labelling platform that can rapidly identify both direct and complexed small molecule binding proteins. We benchmark the system against µMap, photoaffinity labelling, affinity purification coupled to mass spectrometry and proximity labelling coupled to mass spectrometry datasets. We also apply the BioTAC system to provide interactome maps of Trametinib and analogues. The BioTAC system overcomes a limitation of current approaches and supports identification of both inhibitor bound and molecular glue bound complexes.

Project description:The proteins interacting with CFTR and its mutants have been intensively studied using different experimental approaches, enabling to better understand the cellular processes leading to proper protein folding, routing to the plasma membrane, recycling, activation and degradation. Recently, several strategies have been developed based on the proximity labelling of protein partners or proteins in close vicinity and their subsequent identification by mass spectrometry. In this study, we evaluate TurboID and APEX2 proximity labelling approaches on WT CFTR and compare results to those obtained by co-immunoprecipitation and in databases. We then compared the CFTR-WT interactome to two mutants of CFTR (G551D and W1282X) and the structurally unrelated potassium channel KCNK3. The two methods efficiently identified both known and novel CFTR protein partners and in proximity such as multiple SLC transporters. Hence proximity labelling approaches enable to obtain a wider picture of the CFTR interactome, feeding databases and giving a better understanding of the CFTR environment.

Project description:The G-protein coupled estrogen receptor GPER1 is thought to mediate rapid estrogen signaling at the membrane. Despite considerable efforts over the last years, its physiological ligand(s), interactors, and regulators are still very poorly understood. This is particularly problematic at a time when the inducibility of GPER1 activity has been challenged. We therefore investigated both activity and interactome of GPER1. We could confirm that GPER1 can behave as a constitutivley active signaling protein. Using proximity labelling and immunoprecipitation coupled to mass spectrometry, we explored the GPER1 interactome. Intersecting the results of the two proteomic approaches and validating some candidate interactors, we generate a GPER1 a resource, which may be useful for further functional studies in the future.

Project description:We sought to map RBM6 interactome using ascorbate peroxidase (APEX2)-based proximity labelling combined with mass spectrometry. Toward this end, we used CRISPR-cas9 methodology to establish MCF10A cell line expressing APEX2 fused to the N-terminal of RBM6, hereafter called MCF10AAPEX2-RBM6. The peroxidase activity of APEX2-RBM6 fusion was confirmed. Next, RBM6 proximal proteins that were biotinylated by APEX2 activation using hydrogen peroxidase (H2O2) in the presence of biotin-phenol were isolated and subjected to mass spectrometry. We identified 173 (P-value<0.05) RBM6 proximity-interaction partners.

Project description:Proximity interactome labelling of Sis1 APEX2 during heat shock revealed its comprehensive interactome.

Project description:Affinity purification coupled with mass spectrometry (AP-MS) and proximity-dependent biotinylation identification (BioID) methods are powerful tools to define the interactome for a specific protein bait. Whereas AP-MS results in the identification of proteins that are in a stable complex, BioID labels and identifies proteins that are in close proximity to the bait, resulting in overlapping yet distinct protein identifications. In order to comprehensively characterize the IBTK interactome networks in cells, we developed a tag workflow which allows for both AP-MS and BioID analysis with a single construct, pcDNA5/FRT vector containing FLAG-BirA-IBTK.