Project description:Here, we apply large scale cross-linking mass spectrometry to profile the interactome of isolated and intact Saccharomyces cerevisiae nuclei. Two independent biological replicates (nuclei isolated from different cultures) were performed.

Project description:Eukaryotic mRNA has long been considered monocistronic, but nowadays, alternative proteins (AltProts) challenge this tenet. The alternative or ghost proteome has largely been neglected and the involvement of AltProts in biological processes. Here, we used subcellular fractionation to increase the information about AltProts and facilitate the detection of protein-protein interactions by the identification of crosslinked peptides. In total, 112 unique AltProts were identified, and we were able to identify 220 crosslinks without peptide enrichment. Among these, 16 crosslinks between AltProts and Referenced Proteins (RefProts) were identified. We further focused on specific examples such as the interaction between IP_2292176 (AltFAM227B) and HLA-B, in which this protein could be a potential new immunopeptide, and the interactions between HIST1H4F and several AltProts which can play a role in mRNA transcription. Thanks to the study of the interactome and the localization of AltProts, we can reveal more of the importance of the ghost proteome.

Project description:Crosslinking mass spectrometry (XL-MS) has emerged as a powerful tool in its own right for the investigation of protein structures and interactions. Utilizing standard shotgun MS mass spectrometry equipment and specialized database search software, crosslinked peptide-pairs can be identified and directly translated into distance constraints for protein structure and protein-protein interaction investigations. Whereas the gas-phase dissociation behavior of linear peptides is well understood, less is however known about the gas-phase dissociation behavior of crosslinked peptides. In this work, we set out to expose the behavior of commonly used crosslinking reagents, both non- as well as gas-phase cleavable, using synthetic peptides to establish mechanistic insights. We describe that crosslinked peptide pairs generate specific fragmentation patterns under HCD and CID fragmentation conditions, distinct from mono-linked peptide and non-modified peptides. We discuss in detail the resulting diagnostic ions that can help distinguishing linear peptides from mono-linked and crosslinked peptide pairs and how that may be used to further increase the efficiency of XL-MS analysis.

Project description:Fun30 is the prototype of the Fun30-SMARCAD1-ETL sub-family of nucleosome remodelers involved in DNA repair and gene silencing. These proteins appear to act as single subunit nucleosome remodelers, but their molecular mechanisms are, at this point, poorly understood. Using multiple sequence alignment and structure prediction, we identify an evolutionarily conserved domain that is modeled to contain a SAM-like fold with one long, protruding helix, which we term SAM-key. Deletion of the SAM-key within budding yeast Fun30 leads to a defect in DNA repair and gene silencing similar to that of the fun30 mutant. In vitro, Fun30 protein lacking the SAM key is able to bind nucleosomes but is deficient in DNA-stimulated ATPase activity as well as nucleosome sliding and eviction. A structural model based on AlphaFold2 prediction and verified by crosslinking-MS indicates an interaction of the long SAM-key helix with protrusion I, a subdomain located between the two ATPase lobes that is critical for control of enzymatic activity. Mutation of the interaction interface phenocopies the domain deletion with a lack of DNA-stimulated ATPase activation and a nucleosome remodeling defect, thereby confirming a role of the SAM-key helix in regulating ATPase activity. Our data thereby demonstrate a central role of the SAM-key domain in mediating the activation of Fun30 catalytic activity, thus highlighting the importance of allosteric activation for this class of enzymes.

Project description:Here we performed a cross-linking mass spectrometry analysis of the inner kinethocore complex CCAN and of the complex associated with a CenpA-nucleosome (CCAN-CenpA)from budding yeast. These experiments validated the cryo-EM structure of both complexes and provided additional structural insights on the complex organization.

Project description:Comparison of the gene expression in the two pancreatic lymph nodes: gastric lymph node (GLN) and pancreatico-duodenal lymph node (PDLN) in NOD mice. The analysis was done in an attempt to explain the preferential homing of bone marrow-derived dendritic cells to the GLN after intravenous injection. GLN and PDLN were excised from 4 individual 12-wk old female NOD mice and RNA was extracted after tissue homogenization in Trizol for processing onto microarray (Agilent 4x44K). Each array corresponds to one single mouse, thus this study comprise 4 biological replicates.

Project description:The core cell cycle machinery genes are transcriptionally regulated by the MuvB family of protein complexes in a cell cycle specific manner. During cell cycle exit in quiescence or senescence, the DREAM complex, which is the repressive form of MuvB, directs transcriptional repression of cell cycle genes; conversely during cell proliferation, the complex of MuvB with the transcription factors (TFs) B-MYB and FOXM1 activate mitotic genes during the G2 phase of the cell cycle. The mechanisms of transcriptional regulation of these complexes are still poorly characterised. Here we combine biochemical analysis and in vitro reconstitution, with structural analysis by cryo-electron microscopy (cryo-EM) and cross-linking mass spectrometry (XL-MS), to functionally examine these complexes. Our data suggests that MuvB is a chromatin regulator whereby a core region binds the nucleosome and remodels it, thereby exposing nucleosomal DNA. This remodelling activity is supported by B-MYB which directly binds the remodelled DNA. Given the remodelling activity on the nucleosome, we propose that the MuvB complex with B-MYB (MMB) function as a pioneer transcription factor complex. Our data rationalises prior biochemical and cellular studies and provides a molecular framework of interactions on a protein complex, which is key for cell cycle regulation.

Project description:Mass spectrometry was used to investigate the crosslinks between proteins cryptochrome and tieless.

Project description:Chemical crosslinking mass spectrometry is rapidly emerging as a prominent technique to study protein structures. Structural information is obtained by covalently connecting peptides in close proximity by small reagents and identifying the resulting peptide pairs by mass spectrometry. However, sub-stoichiometric reaction efficiencies render routine detection of crosslinked peptides problematic. Here we present a new tri-functional crosslinking reagent, termed PhoX, which is decorated with a stable phosphonic acid handle. This makes the crosslinked peptides amenable to the well-established IMAC enrichment. The handle allows for 300x enrichment efficiency and 97% specificity, dramatically reducing measurement time and improving data quality. We exemplify the approach on various model proteins and protein complexes, e.g. resulting in a structural model of LRP1/RAP complex. PhoX is also applicable to whole cell lysates. When focusing the database search on ribosomal proteins, our first attempt resulted in 355 crosslinks, out-performing current efforts in less measurement time.

Project description:Gas Vesicles (GVs) are gas-filled protein nanostructures employed by several species of bacteria and archaea as flotation devices to enable access to optimal light and nutrients. The unique physical properties of GVs have led to their use as genetically-encodable contrast agents for ultrasound and MRI. Currently, however, the structure and assembly mechanism of GVs remain unknown. Here we employ cryo-electron tomography to reveal how the GV shell is formed by a helical filament of highly-conserved GvpA subunits. This filament changes polarity at the center of the GV cylinder, a site that may act as an elongation center. High-resolution subtomogram averaging reveals a corrugated pattern of the shell arising from polymerization of GvpA into a β-sheet. The accessory protein GvpC forms a helical cage around the GvpA shell, providing reinforcement. Together, our results help explain the remarkable mechanical properties of GVs and their ability to adopt different diameters and shapes.