Project description:We investigated the RNA-protein interactome of Enterococcus faecalis V583 and Enterococcus faecium Aus0004 by native gradient fractionation of complexes coupled to RNA-sequencing. Whole bacterial cell lysates were analysed by size and density in a glycerol gradient. At native conditions, RNA-protein complexes stay intact and sediment as a whole. Sedimentation profiles of individual RNAs appear correlated in case of interaction in a complex. The profile of KhpB caught our attention and we determined its RNA interactome by immunoprecipitation that suggests a role at the post-transcriptional level, binding notably several tRNAs, sRNAs, and 3’UTRs.

Project description:Co-fractionation mass spectrometry experiments (CF-MS) using native-like protein separations such as Blue Native electrophoresis (BNE) or size exclusion chromatography (SEC) enable a global characterization of protein networks, and a better understanding of cellular functions. They do, however, pose significant requirements on sample amounts, on wet lab and on instrument time, which frequently renders statistically useful replication or comparative experiments between multiple biological states non-feasible. Here we present a fast workflow called mini-Complexome Profiling (mCP) for global targeted detection of annotated protein-protein complexes. It comprises mild extraction of complexes, fractionation by BNE and analysis by data independent acquisition mass spectrometry (DIA-MS). Of note, BNE fractionation into 35 fractions is achieved using commercial mini-gels, with minimal requirements on sample amounts. Complexes are detected using a novel, bespoke R package with a controlled false discovery rate (FDR) approach. The tool is available to the community on a Github repository (https://github.com/hugoagno3/mCP ). We first benchmarked our workflow using Hek293 cell lysates as a well established cell line model. We then challenged mCP by investigating changes in the complexome of mouse cardiomyocytes isolated from different heart cavities of single mice. In these challenging and limited samples we detected 48 annotated protein complexes per compartment on average and were able to perform differential inter-cavity comparisons from single animals. These reduced sample and instrument time requirements suggest the suitability of our workflow for complexome screening in sparse samples, e.g. in human patient biopsies.

Project description:Co-fractionation mass spectrometry experiments (CF-MS) using native-like protein separations such as Blue Native electrophoresis (BNE) or size exclusion chromatography (SEC) enable a global characterization of protein networks, and a better understanding of cellular functions. They do, however, pose significant requirements on sample amounts, on wet lab and on instrument time, which frequently renders statistically useful replication or comparative experiments between multiple biological states non-feasible. Here we present a fast workflow called mini-Complexome Profiling (mCP) for global targeted detection of annotated protein-protein complexes. It comprises mild extraction of complexes, fractionation by BNE and analysis by data independent acquisition mass spectrometry (DIA-MS). Of note, BNE fractionation into 35 fractions is achieved using commercial mini-gels, with minimal requirements on sample amounts. Complexes are detected using a novel, bespoke R package with a controlled false discovery rate (FDR) approach. The tool is available to the community on a Github repository (https://github.com/hugoagno3/mCP ).

Project description:Centromeres of most eukaryotes are multi-megabase arrays of satellite DNA that assemble proteinaceous kinetochores to facilitate faithful chromosome segregation. However, the nature of the chromatin landscape at centromeres remains unclear, in part due to the difficulty of isolating intact centromeric chromatin rendered insoluble by megadalton-size kinetochore protein complexes. To address this challenge we combined classical salt fractionation with chromatin immunoprecipitation to recover human centromeric chromatin under native conditions. We found that >85% of the total centromeric chromatin is insoluble under conditions typically used for native chromatin extraction. To map both soluble and insoluble chromatin in situ, we combined CUT&RUN, a targeted nuclease method, with salt fractionation. Using this approach, we found that the strength of Centromere Protein B (CENP-B) binding and the density of CENP-B motifs corresponds to the occupancy of Constitutive Centromere-Assocated Network (CCAN) complexes bound to α-satellite arrays. We also observed unexpected structural variations of CENP-A-containing complexes on different α-satellite dimeric units within highly homogenous arrays. Our results suggest that slight α-satellite sequence differences controls the structure and occupancy of the associated centromeric chromatin complex.

Project description:Stable protein complexes, including those formed with RNA, are major building blocks of every living cell. Escherichia coli has been the leading organism with respect to global bacterial protein-protein networks. However, there has been no global census of RNA/protein complexes in this model species of microbiology. Here, we performed Grad-seq to establish an RNA/protein complexome, reconstructing sedimentation profiles in a glycerol gradient for ~85% of all E. coli transcripts and ~49% of the proteins. In presenting use cases for this resource to be exploited, we show that its stable association with 30S ribosomes gives the seemingly noncoding RNA RyeG of prophage origin away as an mRNA of a toxic small protein. Similarly, we show that the broadly conserved uncharacterized protein YggL is a 50S subunit factor in assembled 70S ribosomes. Overall, this study complements existing interactome resources for the primary model bacterium E. coli with valuable RNA/protein complexome information and should facilitate functional discovery in this and many related species.

Project description:Protein correlation profiling using size exclusion and blue native page analysis of protein complexes coupled with SILAC to enable the comparsion between conditions

Project description:The overall aim of the project is the definition and characterization of the mitochondrial proteome of human cells, referred to as MitoCoP. To this end, we combined the complementary strengths of subtractive proteomics, ImportOmics and subcellular protein profiling in a global multidimensional classification approach (see dataset PXD016924). In this part of the project, we (1) performed subtractive proteomics experiments of gradient-purified versus crude mitochondrial fractions prepared from multiple cell lines (multi-cell lines pM-vs-cM experiments), (2) studied the organization of mitochondrial proteins in large functional assemblies by Blue Native (BN) complexome profiling, and (3) analyzed the effect of LYRM9 knockout on mitochondrial protein complexes by BN-PAGE (LYRM9KO-vs-control experiment) to complement the characterization of MitoCoP.

Project description:The majority of proteins are organized in protein complexes. Protein complexes represent an important cellular organizational layer, which regulate and catalyze most of the cellular processes. Within the field of proteomics several techniques such as Affinity Purification (AP) and co-fractionation (co-Frac) coupled to mass spectrometry (MS) were developed in order to study protein complexes. Our approach, deep interactome profiling coupled to MS (DIP-MS), is a combination of the benefits of these approaches by combining the selectivity of AP-MS together with a blue native-page size-based fractionation, in order to deconvolute the co-purified complexes, in which the bait is a constitutive subunit. To ensure high-quality quantitation along the fractionation gradient, and to keep data acquisition time limited, we developed a high-throughput (HT) sample preparation method and high-throughput data independent acquisition (DIA) method, enabling us to acquire almost one co-Frac gradient per day. Additionally, a tailored machine learning approach was devised – protein-protein interaction prophet (PPIprophet) which enabled the scoring of the co-elution proteins to retrieve PPIs respectively protein complexes. The method was employed to depict the complex modularity within the prefoldin and prefoldin-like protein complexes, allowing us to I) describe protein complex isoforms, II) derive stoichiometries and abundance distributions of co-purified complexes and III) identify reported and new client proteins and client complexes of the PAQosome, a multi-subunit co-chaperone complex, necessary for the stabilization and formation of multiple complexes such as the RNA polymerases (RNA Pol I, RNA Pol II, RNA Pol III). This study thereby demonstrates the applicability of our method and shows it strength and sensitivity by depicting the prefoldin complexes within only a single experiment.

Project description:Here we aimed to improve native gel electrophoresis-based complexome profiling (CP) method for examination of mitochondrial (mt)DNA-/RNA-protein complexes. We compared the performance of Blue Native PAGE (BNE) and high resolution Clear Native PAGE (hrCNE). We found that hrCNE much better preserves the integrity of mtDNA-/RNA-protein complexes.To further improve the detection of mtDNA-binding proteins, we treated solubilized mitochondrial samples with DNase I prior to separation on hrCNE or BNE. To characterize the detected by hrCNE mtRNA-protein complexes, we performed CP with samples treated with RNase A. To validate the utility of the method, we performed CP using mitochondria isolated from cells treated with ethidium bromide as well as from cells recovering after this treatment. Our study not only helps to validate and unveil proteins involved in mitochondrial DNA- and RNA-related processes, but also offers a convenient and systematic way for analysing these interactions that can be used equally well for the investigation of the nucleus and other DNA-/RNA-containing cell compartments.

Project description:Blue Native-PAGE resolves protein complexes in their native state. When coupled with immunoblotting, it can be used to identify the presence of high molecular weight complexes at high resolution for any protein, given a suitable antibody. To identify proteins in high molecular weight complexes on a large-scale and to bypass the requirement for specific antibodies, we applied a tandem mass spectrometry (MS/MS) approach to BN-PAGE-resolved chloroplasts. Fractionation of wild-type chloroplasts into 6 bands allowed identification and label-free quantification of 1000 chloroplast proteins with native molecular weight resolution. Significantly, our approach achieves a depth of identification comparable to traditional shotgun proteomic analyses of chloroplasts, indicating much of the known chloroplast proteome is amenable to our ‘mass western’ approach to BN-PAGE. The coupling of BN-PAGE to MS/MS allows for a large-scale comparison of protein complexes between samples and the identification of proteins in high molecular weight complexes. In parallel we have analyzed chloroplasts from a leaf reticulate mutant (re-6) to demonstrate the possibility for comparative analyses. Our results provide a useful resource for the chloroplast community and this strategy is anticipated to be widely adaptable to other sub-cellular compartments.