Low-abundance Post-translational Modification Research Articles

Post-translational modifications of proteins in cardiovascular diseases examined by proteomic approaches.

Over 400 different types of post-translational modifications (PTMs) have been reported and over 200 various types of PTMs have been discovered using mass spectrometry (MS)-based proteomics. MS-based proteomics has proven to be a powerful method capable of global PTM mapping with the identification of modified proteins/peptides, the localization of PTM sites and PTM quantitation. PTMs play regulatory roles in protein functions, activities and interactions in various heart related diseases, such as ischemia/reperfusion injury, cardiomyopathy and heart failure. The recognition of PTMs that are specific to cardiovascular pathology and the clarification of the mechanisms underlying these PTMs at molecular levels are crucial for discovery of novel biomarkers and application in a clinical setting. With sensitive MS instrumentation and novel biostatistical methods for precise processing of the data, low-abundance PTMs can be successfully detected and the beneficial or unfavorable effects of specific PTMs on cardiac function can be determined. Moreover, computational proteomic strategies that can predict PTM sites based on MS data have gained an increasing interest and can contribute to characterization of PTM profiles in cardiovascular disorders. More recently, machine learning- and deep learning-based methods have been employed to predict the locations of PTMs and explore PTM crosstalk. In this review article, the types of PTMs are briefly overviewed, approaches for PTM identification/quantitation in MS-based proteomics are discussed and recently published proteomic studies on PTMs associated with cardiovascular diseases are included.

Abstract 5133: Optimized RAS top-down proteomic assay reveals expanded proteoform landscape in malignant cells

Abstract Traditional proteomic methods face an inherent challenge with the RAS family of GTPases (HRAS, NRAS, KRAS4A, KRAS4B). Expressed at low endogenous abundance, these four isoforms possess considerable sequence similarity, rendering the confident proteomic linkage of a given isoform with a specific mutation or post-translational modification (PTM) a formidable proposition outside of isoform-specific model cell lines. Conversely, top-down proteomic analysis (TDP), which measures intact protein molecules, can precisely identify modified protein forms, or proteoforms, and confidently localize both mutations and PTMs on each RAS isoform present. Previously, a method combining immunoprecipitation and subsequent TDP (IP-TDP) led to the identification of eleven KRAS4B proteoforms, including four mutations and two novel PTMs, within colorectal cancer cell lines and tumor samples†. These initial results demonstrated the great potential for proteoform-resolved measurements to further illuminate the role of KRAS4B mutations and modifications in human cancer. More recently, the NCI RAS Initiative has developed an enhanced RAS proteoform assay incorporating IP-TDP analysis on an Orbitrap Fusion Lumos mass spectrometer. By employing alternate antibodies, recombinant protein standards, and well-characterized model or malignant cell lines, we have obtained substantial improvements in both RAS proteoform detection and characterization, thus facilitating the identification and localization of low-abundance PTMs. Moreover, we have applied our optimized IP-TDP method to a diverse panel of malignant and RAS mutant cell lines with the goal of expanding our knowledge of the RAS proteoform landscape. In doing so, we have observed a wealth of novel RAS proteoforms, of far greater number and complexity than previously anticipated. We have also observed isoform-specific proteoform variations, most notably between KRAS4A and KRAS4B, and initial indications of proteoform context dependence, namely within a given mutation or tissue background. Our results further underscore the power of proteoform-resolved measurements and indicate that RAS-dependent signaling pathways in normal and cancer contexts may be far more complex than previously thought. † I Ntai et. al. “Precise characterization of KRAS4b proteoforms in human colorectal cells and tumors reveals mutation/modification crosstalk.” Proc Natl Acad Sci U S A. 2018 Apr 17; 115(16):4140-4145. Citation Format: Caroline DeHart, Kanika Sharma, Dominic Esposito, Anna Maciag, Dwight Nissley, Frank McCormick. Optimized RAS top-down proteomic assay reveals expanded proteoform landscape in malignant cells [abstract]. In: Proceedings of the Annual Meeting of the American Association for Cancer Research 2020; 2020 Apr 27-28 and Jun 22-24. Philadelphia (PA): AACR; Cancer Res 2020;80(16 Suppl):Abstract nr 5133.

Signature-Ion-Triggered Mass Spectrometry Approach Enabled Discovery of N- and O-Linked Glycosylated Neuropeptides in the Crustacean Nervous System

Crustaceans are commonly used model organisms to study neuromodulation. Despite numerous reported crustacean neuropeptide families and their functions, there has been no report on neuropeptide glycosylation. This is in part due to a lack of sensitive methods that enable deciphering this intricate low-abundance post-translational modification, even though glycosylation has been shown to play an important role in neuromodulation. Here, we describe the discovery of glycosylated neuropeptides with an enrichment-free approach, taking advantage of signature oxonium ions produced in higher-energy collision dissociation (HCD) MS/MS spectra. The detection of the oxonium ions in the HCD scans suggests glycan attachment to peptides, allowing electron-transfer/higher-energy collision dissociation (EThcD) to be performed to selectively elucidate structural information of glycosylated neuropeptides that are buried in nonglycosylated peptides. Overall, 4 N-linked and 14 O-linked glycosylated neuropeptides have been identified for the first time in the crustacean nervous system. In addition, 91 novel putative neuropeptides have been discovered based on the collected HCD scans. This hybrid approach, coupling a shotgun method for neuropeptide discovery and targeted strategy for glycosylation characterization, enables the first report on glycosylated neuropeptides in crustaceans and the discovery of additional neuropeptides simultaneously. The elucidation of novel glycosylated neuropeptides sheds light on the crustacean peptidome and offers novel insights into future neuropeptide functional studies.

Assessment of Quantification Precision of Histone Post-Translational Modifications by Using an Ion Trap and down To 50 000 Cells as Starting Material.

Histone post-translational modifications (PTMs) are fundamental players of chromatin regulation, as they contribute to editing histone chemical properties and recruiting proteins for gene transcription and DNA repair. Mass spectrometry (MS)-based proteomics is currently the most widely adopted strategy for high-throughput quantification of hundreds of histone PTMs. Samples such as primary tissues, complex model systems, and biofluids are hard to retrieve in large quantities. Because of this, it is critical to know whether the amount of sample available would lead to an exhaustive analysis if subjected to MS. In this work, we assessed the reproducibility in quantification of histone PTMs using a wide range of starting material, that is, from 5 000 000 to 50 000 cells. We performed the experiment using four different cell lines, that is, HeLa, 293T, human embryonic stem cells (hESCs), and myoblasts, and we quantified a list of 205 histone peptides using ion trap MS and our in-house software. Results highlighted that the relative abundance of some histone PTMs deviated as little as just 4% when comparing high starting material with histone samples extracted from 50 000 cells, for example, H3K9me2 (40% average abundance). Low abundance PTMs such as H3K4me2 (<3% average abundance) showed higher variability, but still ∼34%. This indicates that most PTMs, and especially abundant ones, are quantified with high precision starting from low cell counts. This study will help scientists to decide whether specific experiments are feasible and to plan how much sample should be reserved for histone analysis using MS.

Optimizing High-Resolution Mass Spectrometry for the Identification of Low-Abundance Post-Translational Modifications of Intact Proteins.

Intact protein analysis by liquid chromatography-mass spectrometry (LC-MS) is now possible due to the improved capabilities of mass spectrometers yielding greater resolution, mass accuracy, and extended mass ranges. Concurrent measurement of post-translational modifications (PTMs) during LC-MS of intact proteins is advantageous while monitoring critical proteoform status, such as for clinical samples or during production of reference materials. However, difficulties exist for PTM identification when the protein is large or contains multiple modification sites. In this work, analyses of low-abundance proteoforms of proteins of clinical or therapeutic interest, including C-reactive protein, vitamin D-binding protein, transferrin, and immunoglobulin G (NISTmAb), were performed on an Orbitrap Elite mass spectrometer. This work investigated the effect of various instrument parameters including source temperatures, in-source CID, microscan type and quantity, resolution, and automatic gain control on spectral quality. The signal-to-noise ratio was found to be a suitable spectral attribute which facilitated identification of low abundance PTMs. Source temperature and CID voltage were found to require specific optimization for each protein. This study identifies key instrumental parameters requiring optimization for improved detection of a variety of PTMs by LC-MS and establishes a methodological framework to ensure robust proteoform identifications, the first step in their ultimate quantification.

Relative quantitation of protein nitration by liquid chromatography–mass spectrometry using isotope-coded dimethyl labeling and chemoprecipitation

Protein nitration has been recognized as an important biomarker for nitroxidative stress associated with various diseases. While identification of protein targets for nitration is important, its quantitative profiling also is necessary to understand the biological impact of this low-abundance posttranslational modification. We have previously reported an efficient and straightforward enrichment method for nitropeptides to reduce sample complexity and permit unambiguous site-specific identifications by LC–MS analyses. This approach relies on two chemical derivatization steps: specifically reductive methylation of aliphatic amines and, then, conversion of nitrotyrosines to the corresponding aminotyrosines before their selective capture by a solid-phase reagent we introduced previously. Hence, the method inherently offers the opportunity for relative quantitation of nitropeptides by using isotopic variants of formaldehyde for reductive methylation. This simple method was tested via LC–MS analyses of differently N-methylated nitropeptides and nitroubiquitin as a model nitroprotein enriched from human serum albumin digest and from human plasma, respectively.

Selective Enrichment and Mass Spectrometric Identification of Nitrated Peptides Using Fluorinated Carbon Tags

Protein tyrosine nitration (PTN) is a post-translational modification that is related to several acute or chronic diseases. PTN introduces a nitro group in the ortho position of the phenolic hydroxyl group of tyrosine residues. PTN has been shown to be involved in the pathogenesis of inflammatory responses, cancers, and neurodegenerative and age-related disorders. Furthermore, it has been proposed that PTN regulates signal cascades related to nitric oxide (NO·) production and NO-mediated processes. Although nitrated proteins as markers of oxidative stress are confirmed by immunological assays in various affected cells or tissues, it is not known how many different types of proteins in living cells are nitrated. Since protein nitration is a low-abundance post-translational modification, development of an effective enrichment method for nitrated proteins is needed to detect nitrated peptides or proteins from the limited amount of pathophysiological samples. In the present study, we developed an enrichment method using specific chemical tagging. Nitroproteome profiling using chemical tagging and mass spectrometry was validated by model proteins. Furthermore, we successfully identified numerous nitrated proteins from the Huh7 human hepatoma cell line.

Chemical labeling and enrichment of nitrotyrosine-containing peptides

Protein tyrosine nitration (PTN) is a post-translational modification of proteins associated with a number of inflammatory diseases. While PTN is rather selective (not all proteins are modified and within a protein, only certain tyrosines are subject to nitration), no consensus sequence has been identified. Since PTN is a low-abundance post-translational modification, it is necessary to enrich modified proteins and/or to detect them with high selectivity and sensitivity. Until now this has been mostly accomplished with anti-nitrotyrosine antibodies in combination with two-dimensional gel electrophoresis and mass spectrometry. We propose a chemical labeling approach designed to allow enrichment of tyrosine-nitrated peptides independent of the sequence context, which is a potential shortcoming of antibody-based approaches. In this procedure, all amines are blocked by acetylation followed by conversion of nitrotyrosine to aminotyrosine and biotinylation of aminotyrosine. The entire reaction sequence is performed in a single buffer with no need for sample cleanup or pH changes thereby reducing sample loss. Free biotin is subsequently removed with a strong cation exchanger, the labeled peptides are enriched on an immobilized avidin column and the enriched peptides analyzed by LC–MS/MS. As a proof of concept, this method was successfully applied to the enrichment of tyrosine-nitrated angiotensin II in a tryptic digest of bovine serum albumin (BSA). The approach presented here is well adapted to peptide analysis, for instance in shotgun proteomics.

In-Solution Proteomic Workflow for Purification of Endogenous Sarcomeric Proteins and Identification of Distinct Charged Variants of Regulatory Light Chain

The molecular conformation of the myosin motor is modulated by intermolecular interactions with the light chains, C-protein and titin, and governed by post-translational modifications (PTMs). These PTMs are important in regulation of function in ejecting ventricles as mechanisms downstream of Ca2+ fluxes at the level of the sarcomere appear to dominate ejection and sustain ventricular elastance during systole. Therefore it is paramount to identify specific sites of PTMs. In-gel digestion has classically been used for PTM identification, however this approach is limited by protein size, pI, and difficulties in peptide extraction. We report a solution-based workflow for purifying endogenous sarcomeric proteins designed to enrich for peptides containing low-abundance PTMs. We focus particular attention on regulatory light chain (RLC), which was shown first by W.T. Perrie and S.V. Perry to be phosphorylated in vivo, but the specific sites have been unclear. Simplification of our sample with sub-cellular fractionation followed by OFFGEL electrophoresis (OGE) resulted in discriminatory purification of thick filament proteins including regulatory and essential light chains, myosin heavy chain, and myosin binding protein-C. Digestion and HPLC profiling of OGE-separated charge variants identified unique peptides suggestive of protein modifications, thus effectively enriching for endogenous PTMs which are low in abundance and have been historically difficult to identify with mass spectrometry. In addition, UV detection provided an additional unbiased quantitative analysis of peptides without having to explore more time-intensive quantitative MS methods. Using LC/MS/MS we unequivocally identified three distinct endogenous charge variants of cardiac RLC in unique OGE fractions, thus providing explanation for isoelectric point shifts observed, both in OGE and 2D-PAGE. The singly- versus doubly-phosphorylated RLC may evoke unique conformational states and thus may be functionally distinct in regulating cardiac contraction.

Enrichment and Analysis of Nonenzymatically Glycated Peptides: Boronate Affinity Chromatography Coupled with Electron-Transfer Dissociation Mass Spectrometry

Nonenzymatic glycation of peptides and proteins by d-glucose has important implications in the pathogenesis of diabetes mellitus, particularly in the development of diabetic complications. However, no effective high-throughput methods exist for identifying proteins containing this low-abundance post-translational modification in bottom-up proteomic studies. In this report, phenylboronate affinity chromatography was used in a two-step enrichment scheme to selectively isolate first glycated proteins and then glycated, tryptic peptides from human serum glycated in vitro. Enriched peptides were subsequently analyzed by alternating electron-transfer dissociation (ETD) and collision induced dissociation (CID) tandem mass spectrometry. ETD fragmentation mode permitted identification of a significantly higher number of glycated peptides (87.6% of all identified peptides) versus CID mode (17.0% of all identified peptides), when utilizing enrichment on first the protein and then the peptide level. This study illustrates that phenylboronate affinity chromatography coupled with LC-MS/MS and using ETD as the fragmentation mode is an efficient approach for analysis of glycated proteins and may have broad application in studies of diabetes mellitus.