Project description:We have created a synthetic crosslinked peptide library to benchmark crosslinking mass spectrometry search engines. The unique benefit of the library is knowing which identified crosslinks are true and which are false. The data collected from mass spectrometry measurements of the peptide library were used to assess the most frequently used search algorithms. The datasets included will provide an important resource for the crosslinking community to evaluate and optimise search engines, results from which have far-reaching implications.

Project description:Intermolecular interactions stabilising the CAL1–CENP-A/H4 complex were analysed using chemical Cross-Linking Mass Spectrometry (CLMS). Purified recombinant CAL11-160–CENP-A101-225–H4 complex was crosslinked using EDC and BS3. The crosslinked peptides were analysed by mass spectrometry to identify intra- and intermolecular contacts. Notably, the data revealed several intramolecular crosslinks between the N- and C-terminal regions of CAL11-160, suggesting a direct interaction between these regions.

Project description:RAF-family kinases are activated by recruitment to the plasma membrane by GTP-bound RAS, where they initiate signaling through the MAP kinase cascade. Here we crosslinked (BS3), digested (trypsin), and analyzed via LC-MS/MS KRAS (human, residues 1-169) bound to intact BRAF (human) in an autoinhibited state with MEK1 (human, ) and a 14-3-3 (SF9) dimer . Analysis of this KRAS/BRAF/MEK1/14-3-3 complex reveals both interprotein and intraprotein crosslinks.

Project description:We propose a pipeline that combines AlphaFold2 (AF2) and crosslinking mass spectrometry (XL-MS) to model the structure of proteins with multiple conformations. The pipeline consists of two main steps: ensemble generation using AF2, and conformer selection using XL-MS data. For conformer selection, we developed two scores – the monolink probability score (MP) and the crosslink probability score (XLP), both of which are based on residue depth. We benchmarked MP and XLP on a large dataset of decoy protein structures, and showed that our scores outperform previously developed scores. We then tested our methodology on three proteins having an open and closed conformation in the Protein Data Bank: Complement component 3 (C3), luciferase, and glutamine-binding periplasmic protein (QBP), first generating ensembles using AF2, which were then screened for the open and closed conformations using experimental XL-MS data. In five out of six cases, the most accurate model within the AF2 ensembles – or a conformation within 1 Å of this model – was identified using crosslinks, as assessed through the XLP score. In the remaining case, only the monolinks (assessed through the MP score) successfully identified the open conformation of QBP. This serves as a compelling proof-of-concept for the effectiveness of monolinks. In contrast, the AF2 assessment score (pTM) was only able to identify the most accurate conformation in two out of six cases. Our results highlight the complementarity of AF2 with experimental methods like XL-MS, with the MP and XLP scores providing reliable metrics to assess the quality of the predicted models.

Project description:Cysteine desulfurase plays central role in mitochondrial iron-sulfur cluster biogenesis not only by providing sulfur through the catalysis of L-cysteine to L-alanine but also by serving as the platform for the assembly of other components of the biosynthetic machinery, including ISCU, frataxin, and ferredoxin. Human mitochondrial cysteine desulfurase complex consists of a homodimer with three components: NFS1, ISD11 and acyl carrier protein (ACP). In this study we used chemical crosslinking coupled with tandem mass spectrometry (XC-MS) to investigate the structures of cysteine desulfurase complexes.

Project description:Cysteine desulfurase plays central role in mitochondrial iron-sulfur cluster biogenesis not only by providing sulfur through the catalysis of L-cysteine to L-alanine but also by serving as the platform for the assembly of other components of the biosynthetic machinery, including ISCU, frataxin, and ferredoxin. Human mitochondrial cysteine desulfurase complex consists of a homodimer with three components: NFS1, ISD11 and acyl carrier protein (ACP). In this study we used chemical crosslinking coupled with tandem mass spectrometry (XC-MS) to investigate the structures of cysteine desulfurase complexes.

Project description:We applied quantitative cross-linking/mass spectrometry (QCLMS) to interrogate the structure of iC3 (or C3(H2O)), the activated hydrolytic product of the abundant human complement protein C3. The slow but spontaneous and ubiquitous formation of iC3 from C3 initiates antibody-independent activation of the complement system that is a key first line of antimicrobial defense. QCLMS revealed structural differences and similarities between iC3 and C3, as well as between iC3 and C3b that is a pivotal proteolytic cleavage product of C3 and is functionally similar to iC3. Considered in combination with the crystal structures of C3 and C3b, our data support a model wherein the thioester-containing domain of C3 swings to the other end of the molecule creating, in iC3, a stable C3b-like platform for binding the zymogen, factor B, or the regulator, factor H. The integration of available crystallographic and QCLMS data allowed the determination of a 3D model for iC3. The unique arrangement of domains in iC3, which retains the anaphylatoxin (ANA) domain (while ANA is excised when C3 is enzymatically activated to C3b), is consistent with observed differences in activation and regulation between iC3 and C3b.

Project description:Vaccinia virus immunomodulator A46 is a member of the poxviral Bcl-2-like protein family that inhibits the cellular innate immune response at the level of the TIR domain-containing TLR adaptor proteins MAL, MyD88, TRAM and TRIF. The mechanism of interaction of A46 with its targets has remained unclear. We used BS3 and EDC + sulfo-NHS to cross-link A46 to the TIR domains of MAL and MyD88 to help identify interacting residues and regions.

Project description:We have developed quantitative cross-linking/mass spectrometry (QCLMS) to interrogate conformational rearrangements of proteins in solution. Our workflow was tested using a structurally well-described reference system, the human complement protein C3 and its activated cleavage product C3b. We found that small local conformational changes affect the yields of cross-linking residues that are near in space while larger conformational changes affect the detectability of cross-links. Distinguishing between minor and major changes required robust analysis based on replica analysis and a label-swapping procedure. By providing workflow, code of practice and a framework for semi-automated data processing, we lay the foundation for QCLMS as a tool to monitor the domain choreography that drives binary switching in many protein-protein interaction networks.

Project description:The PTEN:P-Rex2 complex is a commonly mutated signaling nodes in metastatic cancer. The dual-specificity phosphatase PTEN canonically functions as a tumour suppressor by hydrolysing PI(3,4,5)P3 to PI(4,5)P2 to inhibit PI3K-AKT signaling. P-Rex2 is a RhoGTPase guanine nucleotide exchange factor activated by both Gβγ and PI(3,4,5)P3 downstream of G protein-coupled receptor and receptor tyrosine kinase signaling. Assembly of the PTEN:P-Rex2 complex inhibits the activity of both proteins, and its dysregulation can drive PI3K-AKT signaling and cell proliferation. However, structural insights into both PTEN:P-Rex2 complex assembly and its dysregulation by cancer-associated mutations remain limited. Here, using crosslinking mass spectrometry and functional studies, we provide mechanistic insights into PTEN:P-Rex2 complex assembly and co-inhibition. PTEN is anchored to P-Rex2 by interactions between the PTEN C-terminal tail PDZ-interacting motif and the second PDZ domain of P-Rex2. This interaction bridges PTEN across the P-Rex2 surface, occluding PI(3,4,5)P3 hydrolysis. Conversely, PTEN both allosterically promotes an autoinhibited P-Rex2 conformation and occludes Gβγ binding. These insights allow us to define a new gain-of-function class of cancer mutations within the PTEN:P-Rex2 interface that uncouples PTEN inhibition of Rac1 signaling. In addition, we observe synergy between PTEN deactivating and P-Rex2 truncation mutations that combine to drive Rac1 activation to a greater extent than either single mutation alone.