All-in-One Pseudo-MS3 Method for the Analysis of Gas-Phase Cleavable Protein Crosslinking Reactions.

Crosslinking mass spectrometry (XL-MS) supports structure analysis of individual proteins and highly complex whole-cell interactomes. The identification of crosslinked peptides from enzymatic digests remains challenging, especially at the cell level. Empirical methods that use gas-phase cleavable crosslinkers can simplify the identification process by enabling an MS3-based strategy that turns crosslink identification into a simpler problem of detecting two separable peptides. However, the method is limited to select instrument platforms and is challenged by duty cycle constraints. Here, we revisit a pseudo-MS3 concept that incorporates in-source fragmentation, where a fast switch between gentle high-transmission source conditions and harsher in-source fragmentation settings liberates peptides for standard MS2-based peptide identification. We present an all-in-one method where retention time matches between the crosslink precursor and the liberated peptides establish linkage, and MS2 sequencing identifies the source-liberated peptides. We demonstrate that DC4, a very labile cleavable crosslinker, generates high-intensity peptides in-source. Crosslinks can be identified from these liberated peptides, as they are chromatographically well-resolved from monolinks. Using bovine serum albumin (BSA) as a crosslinking test case, we detect 27% more crosslinks with pseudo-MS3 over a best-in-class MS3 method. While performance is slightly lower for whole-cell lysates (generating two-thirds of the identifications of a standard method), we find that 60% of these hits are unique, highlighting the complementarity of the method.

High-Sensitivity Proteome-Scale Searches for Crosslinked Peptides Using CRIMP 2.0.

Crosslinking mass spectrometry (XL-MS) is a valuable technique for generating point-to-point distance measurements in protein space. However, cell-based XL-MS experiments require efficient software that can detect crosslinked peptides with sensitivity and controlled error rates. Many algorithms implement a filtering strategy designed to reduce the size of the database prior to mounting a search for crosslinks, but concern has been expressed over the possibility of reduced sensitivity using these strategies. We present a new scoring method that uses a rapid presearch method and a concept inspired by computer vision algorithms to resolve crosslinks from other conflicting reaction products. Searches of several curated crosslink datasets demonstrate high crosslink detection rates, and even the most complex proteome-level searches (using cleavable or noncleavable crosslinkers) can be completed efficiently on a conventional desktop computer. The detection of protein-protein interactions is increased twofold through the inclusion of compositional terms in the scoring equation. The combined functionality is made available as CRIMP 2.0 in the Mass Spec Studio.

The novel isotopically coded short-range photo-reactive crosslinker 2,4,6-triazido-1,3,5-triazine (TATA) for studying protein structures.

Short-distance molecular-modeling constraints are advantageous for elucidating the structures of individual proteins and protein conformational changes. Commonly used amine-reactive crosslinks are relatively long (14Å), partly due to the length of the lysine side-chain, and are sparsely distributed throughout a protein. Short-distance non-specific crosslinkers can provide a larger number of tighter molecular-modeling constraints. Here we describe the use of a short-range homo-trifunctional isotopically-coded non-specific photo-reactive crosslinking reagent, 2,4,6-triazido-1,3,5-triazine (TATA)-12C3/13C3, for MS-based protein crosslinking studies. Upon activation by 254nm UV light, TATA-12C3/13C3 generates up to three nitrene radicals capable of non-selective crosslinking at ~5Å. This reagent was validated using cyclohexane, several test peptides, and myoglobin, and was found to react with a large number of amino acids, forming multiple crosslinked products. The myoglobin crosslinks detected by MS agreed with the known structure of myoglobin; arranging the protein's secondary-structure motifs into their correct fold was possible based solely on the constraints imposed by the crosslinks. Finally, TATA was used to crosslink the α-synuclein monomer. The 10 short-distance constraints provided by TATA crosslinking led to an initial model of the molten-globule form of the native α-synuclein monomer; this provides a suggested structure for the precursor of the misfolded α-synuclein proteoforms involved in synucleopathies. BIOLOGICAL SIGNIFICANCE: The isotopically labeled short-range non-specific crosslinker TATA-12C3/13C3 was characterized for use in crosslinking-based protein structural studies. The crosslinking products of TATA can provide a distance constraint of merely 5Ǻ between crosslinked residues. TATA-12C3/13C3 had broad reactivity, crosslinking a wide variety of amino acids, including lysine, glutamic and aspartic acid, asparagine, glutamine, glycine, alanine, valine, proline, methionine, serine, cysteine, tyrosine, and the N-terminus. The short-distance crosslinking constraints provided by TATA allowed us to predict the fold of myoglobin using a combination of these distance constraints with a prediction of myoglobin's secondary structure motifs. TATA was also used to crosslink α-synuclein in its native, molten globule form, which has not been characterized using other structural biology techniques. The distance constraints provided by the crosslinks allowed for the manual modeling of a rudimentary structure for the α-synuclein monomer.