Project description:we develop a series of arginine selective bifunctional aromatic glyoxal cross-linkers (ArGOs) and demonstrate their ability to cross-link model proteins and a protein complex. We also introduce the first arginine-lysine heterobifunctional cross-linker (KArGO), which provides significantly greater surface coverage than the corresponding homobifunctional reagents (e.g. ArGOs and BS3), due to access to the combined abundances of lysine and arginine residues.

Project description:Acidic residues (Asp and Glu) have a high prevalence on protein surfaces, but cross-linking reactions targeting these residues are limited. Existing methods either require high-concentration coupling reagents or have low structural compatibility. Here we extended our previously reported “plant-and-cast” strategy to develop two heterobifunctional cross-linkers DE1 and OPAAZ. These cross-linking reaction proceeds at neutral pH and room temperature without coupling reagents.

Project description:Objectives Pyrrolobenzodiazepine (PBD) dimers, tethered through inert propyldioxy or pentyldioxy linkers, possess potent bactericidal activity against a range of Gram-positive bacteria by virtue of their capacity to cross-link duplex DNA in sequence-selective fashion. Here we attempt to improve the antibacterial activity and cytotoxicity profile of PBD-containing conjugates by extension of dimer linkers and replacement of one PBD unit with phenyl-substituted or benzo-fused heterocycles that facilitate non-covalent interactions with duplex DNA. Methods DNase I footprinting was used to identify high-affinity DNA binding sites. A staphylococcal gene microarray was used to assess epidemic methicillin-resistant Staphylococcus aureus 16 phenotypes induced by PBD conjugates. Molecular dynamics simulations were employed to investigate the accommodation of compounds within the DNA helix. Results Increasing the length of the linker in PBD dimers led to a progressive reduction in antibacterial activity, but not in their cytotoxic capacity. Complex patterns of DNA binding were noted for extended PBD dimers. Modelling of DNA strand cross-linking by PBD dimers indicated distortion of the helix. A majority (26 of 43) of PBD-biaryl conjugates possessed potent antibacterial activity with little or no helical distortion and a more favourable cytotoxicity profile. Bactericidal activity of PBD-biaryl conjugates was determined by inability to excise covalently bound drug molecules from bacterial duplex DNA. Conclusions PBD-biaryl conjugates have a superior antibacterial profile compared with PBD dimers such as ELB-21. We have identified six PBD-biaryl conjugates as potential drug development candidates. [Data is also available from http://bugs.sgul.ac.uk/E-BUGS-118]

Project description:The combination of cross-linking/mass spectrometry (XL-MS) and ion mobility is still underexplored for conducting protein conformational and protein-protein interaction studies. We present a method for analyzing cross-linking mixtures on a timsTOF Pro mass spectrometer that allows separating ions based on their gas phase mobilities. Cross-linking was performed with three urea-based MS-cleavable cross-linkers that deliver distinct fragmentation patterns for cross-linked species upon collisional activation. The discrimination of cross-linked species from non-cross-linked peptides was readily performed based on their collisional cross sections. We demonstrate the general feasibility of our combined XL-MS/ion mobility approach for three protein systems of increasing complexity: (i) Bovine serum albumin, (ii) E. coli ribosome, and (iii) HEK293T cell nuclear extracts. We identified a total of 623 unique cross-linking sites for BSA, 670 for the E. coli ribosome, and 1,617 unique cross-links for nuclear extracts, corresponding to 1,088 intra- and 529 interprotein interactions and yielding 564 distinct protein-protein interactions. Our results underline the strength of combining XL-MS with ion mobility not only for deriving 3D-structures of single proteins, but also for performing system-wide protein interaction studies.

Project description:Cross-linking mass spectrometry (XL-MS) has become a valuable tool for investigating the structural morphology and plasticity of proteins. Traditional cross-linkers contain two N-hydroxy succinimide (NHS) esters that mainly react with lysine residues. In this work, we optimized the in-solution reactivity of the cross-linker disuccinimidyl sulfoxide (DSSO) carbamate. DSSO carbamate is a DSSO analogue bearing two NHS carbamate groups instead of NHS esters as reactive moiety. The higher stability of the carbamate function mitigates the degradation of DSSO via retro-ene sulfoxide elimination in standard XL-MS buffers which limits the cross-linking yield. Additionally, we elucidated its characteristic gas-phase dissociation behavior and optimized the collision energy (CE) for automated analysis with XL-MS search engines. Cross-link site analysis of bovine serum albumin highlighted an unexpected abundance of cross-link species involving the N-terminus of the protein. We attributed this to a higher N-terminal reactivity of the NHS carbamate group compared to NHS esters. We confirmed our hypothesis by cross-linking non-acetylated and N-terminally acetylated α-asynuclein with DSSO carbamate and the NHS ester-based disuccinimidyl dibutyric urea (DSBU) cross-linker. Finally, we applied the NHS carbamate-based cross-linker NNP9 and observed the same chemical propensity. NHS carbamate-based reagents give complementary XL-MS restraints to NHS ester-based cross-linkers and can be useful for studying systems where N-terminal binding plays a significant role. We anticipate that this unexpected selectivity of NHS carbamates to protein N-termini may have applications in bioconjugation and chemical proteomics in general.

Project description:Disuccinimidyl dibutyric urea (DSBU) is a mass spectrometry (MS)-cleavable cross-linker that has been applied to multiple applications in structural biology, ranging from isolated protein complexes to comprehensive system-wide interactomics. DSBU facilitates a rapid and reliable identification of cross-links through the dissociation of its urea group in the gas-phase. In this study, we further advance the structural capabilities of DSBU by twisting the urea group into an imide, thus introducing a novel class of cross-linkers. This modification preserves the MS-cleavability of the amide bond, granted by the two acyl groups of the imide function. The central nitrogen atom enables the introduction of affinity purification tags. Here, we introduce disuccinimidyl dibutyric imide (DSBI) as prototype of this class of cross-linkers. It features a phosphonate handle for immobilized metal ion affinity chromatography (IMAC) enrichment. We detail DSBI synthesis and describe its behavior in solution and in the gas-phase while cross-linking isolated proteins and human cell lysates. DSBI and DSBU cross-links are compared at the same enrichment depths to bridge these two cross-linker classes. We validate DSBI cross-links by mapping them in high-resolution structures of large protein assemblies . The cross-links observed yield insights into the morphology of intrinsically disordered proteins (IDPs) and their complexes. The DSBI linker might spearhead a novel class of MS-cleavable and enrichable cross-linkers

Project description:Chemical cross-linking mass spectrometry (XL-MS) is essential for studying protein structures and interactions. While lysine-targeted cross-linkers dominate current applications, this study introduces two urazole-derived MS-cleavable cross-linkers for tyrosine and lysine residues. A homobifunctional cross-linker (SBT) targets tyrosine via electrochemical click chemistry, while a heterobifunctional cross-linker (SCT) binds both lysine and tyrosine. Their efficiency was validated through reactions with peptides, proteins, and complexes. Additionally, AlphaFold 3-predicted BSA dimer structures were compared with crystallographic data, revealing improved structural coverage. These cross-linkers expand the XL-MS toolkit, enhancing protein structural analysis accuracy and scope.

Project description:Cross-linking mass spectrometry (XL-MS) is a powerful technique to study protein structures and protein–protein interactions. The coverage of amino acids determines the accuracy and depth of XL-MS analysis. In this work, we designed and synthesized a pair of novel tris-functional cross-linkers, succinimidyl-propargyl-aryl sulfonyl fluoride (SPSF), for multi-targeting cross-linking in vivo. The highly reactive succinimide ester reacts rapidly with Lys residues first, then the less reactive sulfonyl fluo-ride reacts with multiple nucleophilic amino acid sidechains subsequently via proximity-enhanced sulfur (vi) fluoride exchange (SuFEx) reaction. The compact structures and proper amphipathy of SPSF facilitate its rapid cellular penetration. We demon-strated that SPSF effectively cross-link proteins in various cellular compartments without apparent perturbation of cellular states. Utilizing an enrichment strategy combining click chemistry with biotin-streptavidin purification, the identification of cross-links was greatly improved, which include Lys-Lys, Lys-Ser, Lys-Thr, Lys-Tyr and Lys-His. Further analysis of the cross-links revealed that SPSF-mediated multi-site cross-linking effectively expands the coverage of proteins or domains with limited lysine residues. Notably, we observed a high degree of overlap between cross-linked Ser, Thr, and Tyr sites and the phosphorylation sites. Moreover, cross-linking sites were found to be enriched in functional domains such as the protein–protein interaction and nucleotide recognition, underscoring the potential of this approach to provide insights into protein func-tional states. Overall, the novel cross-linkers we developed represent a valuable contribution to the XL-MS toolbox, which has great potential to broaden its scope and enhance its capabilities for functional protein structure analysis.

Project description:We have implemented the use of a heterobifunctional, UV photoactivatable cross-linker, which greatly increases the number of identified cross-links compared with homobifunctional, NHS-ester based cross-linkers. We have cross-linked human serum albumin in the context of human blood serum. We present a novel methodology that combines the use of this high-resolution cross-linking with conformational space search to investigate the structure of proteins in their native environment.

Project description:UV cross-linking and immunoprecipitation (CLIP) and individual-nucleotide resolution CLIP (iCLIP) are the most frequently used methods to study protein-RNA interactions in the intact cells and tissues, but their relative advantages or inherent biases have not been evaluated. To benchmark CLIP and iCLIP method, we performed iCLIP with Nova protein, which is the most extensively studied protein by CLIP. Further, we assessed UV-C-induced cross-linking preferences, by exploiting the UV-independent formation of covalent RNA cross-links of the mutant RNA methylase NSUN2.