Evaluation of Different Stationary Phases in the Separation of Inter-Cross-Linked Peptides

Protein-Protein Interaction Network Mapping by Affinity Purification Cross-Linking Mass Spectrometry (AP-XL-MS) based Proteomics

Protein-protein interactions (PPIs) are the physical interactions formed among proteins. These interactions are primarily functional, i.e., they arise from specific biomolecular events, and each interaction interface serves a specific purpose. A significant number of methods have been developed for protein interactions in the field of proteomics in the last decade. Advanced mass spectrometry technology significantly contributed to the development of these methods. The rapid advancement of groundbreaking MS technology has greatly aided the mapping of protein interaction from large-data sets comprehensively. This chapter describes the affinity purification (AP) mass spectrometry (MS)-based methods combined with chemical cross-linking (XL) of protein complexes. This chapter includes sample preparation methods involving cell culture, cell treatments with ligands, drugs, and cross-linkers, protein extractions, affinity purification, sodium dodecyl sulfate (SDS) polyacrylamide gel separation, in-solution or in-gel digestion, liquid-chromatography, and mass spectrometry analysis of samples (LC-MS/MS). Application of a cleavable cross-linker, dual cleavable cross-linking technology (DUCCT) in combination with the affinity purification (AP) method has also been described. Methods for data analysis using unmodified and cross-linked peptide analysis are discussed.

Mass Spectrometry-Cleavable Protein N-Terminal Tagging Strategy for System-Level Protease Activity Profiling

Proteolysis is one of the most important protein post-translational modifications (PTMs) that influences the functions, activities, and structures of nearly all proteins during their lifetime. To facilitate the targeted identification of low-abundant proteolytic products, we devised a strategy incorporating a novel biotinylated reagent PFP (pentafluorophenyl)-Rink-biotin to specifically target, enrich and identify proteolytic N-termini. Within the PFP-Rink-biotin reagent, a mass spectrometry (MS)-cleavable feature was designed to assist in the unambiguous confirmation of the enriched proteolytic N-termini. The proof-of-concept study was performed with multiple standard proteins whose N-termini were successfully modified, enriched and identified by a signature ion (SI) in the MS/MS fragmentation, along with the determination of N-terminal peptide sequences by multistage tandem MS of the complementary fragment generated after the cleavage of MS-cleavable bond. For large-scale application, the enrichment and identification of protein N-termini from Escherichia coli cells were demonstrated, facilitated by an in-house developed NTermFinder bioinformatics workflow. We believe this approach will be beneficial in improving the confidence of identifying proteolytic substrates in a native cellular environment.

Synthesis, Pharmacological Evaluation, and Computational Studies of Cyclic Opioid Peptidomimetics Containing β3-Lysine

Our formerly described pentapeptide opioid analog Tyr-c[D-Lys-Phe-Phe-Asp]NH₂ (designated RP-170), showing high affinity for the mu (MOR) and kappa (KOR) opioid receptors, was much more stable than endomorphine-2 (EM-2) in the rat brain homogenate and displayed remarkable antinociceptive activity after central (intracerebroventricular) and peripheral (intravenous ) administration. In this report, we describe the further modification of this analog, which includes the incorporation of a β³-amino acid, (R)- and (S)-β³-Lys, instead of D-Lys in position 2. The influence of such replacement on the biological properties of the obtained analogs, Tyr-c[(R)-β³-Lys-Phe-Phe-Asp]NH₂ (RP-171) and Tyr-c[(S)-β³-Lys-Phe-Phe-Asp]NH₂, (RP-172), was investigated in vitro. Receptor radiolabeled displacement and functional calcium mobilization assays were performed to measure binding affinity and receptor activation of the new analogs. The obtained data revealed that only one of the diastereoisomeric peptides, RP-171, was able to selectively bind and activate MOR. Molecular modeling (docking and molecular dynamics (MD) simulations) suggests that both compounds should be accommodated in the MOR binding site. However, in the case of the inactive isomer RP-172, fewer hydrogen bonds, as well as instability of the canonical ionic interaction to Asp¹⁴⁷, could explain its very low MOR affinity.

Dual-Stage Neutral Loss Tandem Mass Spectrometric Strategy for Confident Identification of Protein Prenylation

Protein prenylation is an important post-translational modification that regulates protein interactions, localizations, and signaling pathways in normal functioning of eukaryotic cells. It is also a critical step in the oncogenic developments of various cancers. Direct identification of native protein prenylation by mass spectrometry (MS) has been challenging due to high hydrophobicity and the lack of an efficient enrichment technique. Prior MS studies of prenylation revealed that prenyl peptides readily generate high-intensity fragments after neutral loss of the prenyl group (R group), and more recent investigation of oxidized prenyl peptides discovered more consistent neutral loss of the oxidized prenyl group (RSOH group). Here, a dual-stage neutral loss MS³ (DS-NLMS3)-based strategy is therefore developed by combining both gas-phase cleavable properties of the prenyl thioether bond and mono-oxidized thioether to improve the large-scale identification of prenylation. Both neutral losses can individually and distinctively confirm the prenylation type in MS² and the sequence of the prenyl peptide upon targeted MS³ fragmentation. This dual-faceted NLMS3 strategy significantly improves the confidence in the identification of protein prenylation from large-scale samples, which enables the unambiguous identification of prenylated sites of the spiked low-abundance farnesyl peptide and native prenyl proteins from mouse macrophage cells, even without prior enrichment during sample preparation. The ease of incorporating this strategy into the prenylation study workflow and minimum disruption to the biological lipidome are advantageous for unraveling unknown native protein prenylation and further developments in profiling and quantifying prenylome.

Basic pH reversed-phase liquid chromatography (bRPLC) in combination with tip-based strong cation exchange (SCX-Tip), ReST, an efficient approach for large-scale cross-linked peptide analysis

Chemical cross-linking in combination with mass spectrometry (XL-MS) has emerged as a useful method for structural elucidation of proteins and protein complexes. Due to the low stoichiometry of cross-linked peptides, a specific enrichment method is always necessary prior to LC-MS/MS analysis, especially for complex samples. Currently, strong cation exchange chromatography (SCX), size exclusion chromatography (SEC), and affinity tag-based enrichment are among the widely used enrichment strategies. Herein, we present a two-dimensional strategy combining basic pH reversed-phase liquid chromatography (bRPLC) fractionation and tip-based SCX (SCX-Tip) enrichment, termed ReST, for the characterization of cross-linked peptides. We revealed the unbiased separation effects of the bRPLC in the cross-linked peptide fractionation. We optimized the enrichment conditions of SCX-Tip using well-designed cross-linked peptides. Taking advantage of the high resolution of bRPLC separation and the high enrichment efficiency of SCX-Tip, we were able to identify 43.6% more cross-linked peptides than the conventional SCX approach. The presented ReST is a simple and efficient approach for proteome-scale protein-protein interaction studies.

A supramolecular cavitand for selective chromatographic separation of peptides using LC-MS/MS: a combined in silico and experimental approach

The chromatographic separation of proteomic standards via a silica immobilized pillararene cavitand has been designed in silico using host–guest binding energy studies and realized experimentally to selectively interact with peptides.

Evaluating the performance of an ETD-cleavable cross-linking strategy for elucidating protein structures

Chemical cross-linking is a powerful strategy for elucidating the structures of protein or protein complexes. The distance constraints obtained from cross-linked peptides represent the three-dimensional structures of the protein complexes. Unfortunately, structural analysis using cross-linking approach demands a significant amount of data to elucidate protein structures. This requires the development of several cleavable cross-linkers with different range of spacer chains. An Electron Transfer Dissociation (ETD) tandem mass spectrometry cleavable bond hydrazone was reported. Its fragmentation with conjugated peptides showed promise for the development of a new ETD cleavable cross-linker. However, no cross-linker was developed utilizing this ETD cleavable bond. For the first time, we attempted to develop an ETD cleavable cross-linker utilizing a hydrazone bond. We overcome the pitfall for the synthesis of this cross-linker and an easy synthesis scheme is reported. In this report, we evaluated the performance of this cross-linker called Hydrazone Incorporated ETD cleavable cross-linker (HI-ETD-XL) in model peptides and proteins. The characteristic fragmentation behavior of HI-ETD-XL during electron transfer dissociation and subsequent sequence identification of the peptide fragment ions by tandem mass spectrometry allowed the identification of cross-linked peptides unambiguously. We believe the availability of this ETD cleavable cross-linker will advance structural proteomics research significantly. SIGNIFICANCE: Many cellular processes rely on the structural dynamics of protein complexes. The detailed knowledge of the structure and dynamics of protein complexes is crucial for understanding their biological functions and regulations. However, most of the structure of these multiprotein entities remain uncharacterized and sometimes is very challenging to reveal with biophysical techniques alone. Chemical cross-linking combined with mass spectrometry (MS) has proven to be a dependable strategy in structural proteomics field. However, data complexity and false identifications are significant hindrances for unambiguous identification of cross-linked peptides. Confident identifications demand structural studies with cross-linkers with different properties and variable spacer chain lengths. This new ETD cleavable cross-linking workflow will provide additional confidence to overcome these drawbacks and allow us to pinpoint cross-linked peptides confidently.

High Confidence Identification of Cross-Linked Peptides by an Enrichment-Based Dual Cleavable Cross-Linking Technology and Data Analysis tool Cleave-XL

Cleavable cross-linking technology requires further MS/MS of the cleavable fragments for unambiguous identification of cross-linked peptides. These spectra are sometimes very ambiguous due to the sensitivity and complex fragmentation pattern of the peptides with the cross-linked residues. We recently reported a dual cleavable cross-linking technology (DUCCT), which can enhance the confidence in the identification of cross-linked peptides. The heart of this strategy is a novel dual mass spectrometry cleavable cross linker that can be cleaved preferentially by two differential tandem mass spectrometry methods, collision induced dissociation and electron transfer dissociation (CID and ETD). Different signature ions from two different mass spectra for the same cross-linked peptide helped identify the cross-linked peptides with high confidence. In this study, we developed an enrichment-based photocleavable DUCCT (PC-DUCCT-biotin), where cross-linked products were enriched from biological samples using affinity purification, and subsequently, two sequential tandem (CID and ETD) mass spectrometry processes were utilized. Furthermore, we developed a prototype software called Cleave-XL to analyze cross-linked products generated by DUCCT. Photocleavable DUCCT was demonstrated in standard peptides and proteins. Efficiency of the software tools to search and compare CID and ETD data of photocleavable DUCCT biotin in standard peptides and proteins as well as regular DUCCT in protein complexes from immune cells were tested. The software is efficient in pinpointing cross-linked sites using CID and ETD cross-linking data. We believe this new DUCCT and associated software tool Cleave-XL will advance high confidence identification of protein cross-linking sites and automated identification of low-resolution protein structures.