Project description:In top-down (TD) proteomics, fractionation prior to mass spectrometric (MS) analysis is a crucial step for the high confidence identification of proteoforms and increased sample depth. In addition to liquid phase separations, gas-phase fractionation strategies such as field asymmetric ion mobility spectrometry (FAIMS) have been shown to be highly beneficial in TD proteomics. However, the need for multiple injections using different compensation voltages (CV) leads to a huge increase in measurement time and the amount of sample required. Therefore, we here investigated for the first time the use of internal CV stepping for single shot TD analysis, i.e., the application of multiple CVs per acquisition. In addition, MS parameters were optimized for the individual CVs since different CVs target certain mass ranges. For example, small proteoforms identified mainly with lower CVs can be identified with a lower resolution and number of microscans than larger proteins identified mainly with higher CVs. We investigated the optimal combination and number of CVs for different gradient lengths and validated the optimized settings with the low molecular weight proteome of CaCo 2 cells obtained by different sample preparation techniques. Compared to measurements without FAIMS, both the number of identified protein groups (+60-94%) and proteoforms (+46-127%), and their confidence were significantly increased, while the measurement time remained identical. In total, we identified 684 protein groups and 2,675 proteoforms from CaCo-2 cells in less than 24 hours using the optimized multi-CV method.

Project description:Top-down proteomics (TDP) has made significant advances in the past, and a plethora of sample preparation workflows have been developed. Here, we systematically investigated the influence of different sample preparation steps on proteoform and protein identifications, including cell lysis, reduction and alkylation, proteoform enrichment, purification, and fractionation. We found that all steps in sample preparation influence the subset of proteoforms identified, e.g., their number, confidence, physicochemical properties, and artificially generated modifications. The various sample preparations resulted in complementary identifications, significantly increasing the depth of the analysis. Overall, 15,089 proteoforms from 2,780 protein accessions of human Caco-2 cells were identified, providing the most comprehensive dataset of this cell line up to now. The results from our study can serve as a guideline for designing and adapting TDP sample preparation strategies to particular research questions.

Project description:The heterogeneity and complexity of glycosylation hinder the depth of site-specific glycoproteomics analysis. High-field asymmetric-waveform ion-mobility spectrometry (FAIMS) has shown to improve the scope of bottom-up proteomics. The benefits of FAIMS for quantitative N-glycoproteomics have not been investigated yet. In this work, we optimized FAIMS settings for N-glycopeptide identification, with or without the tandem mass tag (TMT) label. The optimized FAIMS approach significantly increased the identification of site-specific N-glycopeptides derived from the purified IgM protein or human lymphoma cells. We explored in detail the changes in FAIMS mobility caused by N-glycopeptides with different characteristics, including TMT labeling, charge state, glycan type, peptide sequence, glycan size and precursor m/z. Importantly, FAIMS also improved multiplexed N-glycopeptide quantification, both with the standard MS2 acquisition method and with our recently developed Glyco-SPS-MS3 method. The combination of FAIMS and Glyco-SPS-MS3 provided the highest quantitative accuracy and precision. Our results demonstrate the advantages of FAIMS for improved mass-spectrometry-based qualitative and quantitative N-glycoproteomics.

Project description:While most nanoproteomics approaches for the analysis of low-input samples are based on bottom-up LC-MS workflows, top-down approaches enabling proteoform characterization are still underrepresented. Using mammalian cell proteomes, we here established a facile one-pot sample preparation protocol based on protein aggregation on magnetic beads and intact proteoform elution using 40% v/v formic acid. Performed on a digital microfluidics device, the workflow enabled sensitive analysis of single Caenorhabditis elegans nematodes, increasing the number of proteoform identifications compared to in-tube sample preparation by 46%. Label-free quantification of single nematodes grown under different conditions allowed to identify changes in abundance of proteoforms not distinguishable by bottom-up proteomics. The workflow presented here will help to elucidate cellular changes on the proteoform level in other samples of limited availability.

Project description:Short open reading frames (sORF) have the potential to encode small proteins in the human gut microbiome, but their role in this environment is rarely understood. These small proteins, known as sORF-encoded peptides (SEP), are less than or equal to 100 amino acids in length. Using bottom-up proteomics (BUP) and top-down proteomics (TDP) approaches, we aimed to identify SEP under various growth conditions and stress exposure in Blautia producta, a key species in mediating colonization resistance and dampening gut inflammation. After applying a rigorous filtering and validation procedure, we identified 45 SEP. Our findings indicate that in contrast to previous results the production of specific SEP is not restricted to direct bacterial interactions within the microbiome but rather depends on growth and stress conditions of the environment. Top-down analysis improved identification confidence and detected a number of full-length with and without N-terminal methionine excision (NME), N- or C-terminal truncated or post-translational modified proteoforms of SEP, indicating that these are common occurrences in B. producta. These findings highlight SEP as a ubiquitous class of non-annotated polypeptides that have been overlooked as a subset of proteins in B. producta.

Project description:Here we present a high-performance software for proteome analysis that combines different mass spectrometric approaches, such as, top-down for intact protein analyses and both bottom-up and middle-down, for proteolytic fragment characterization.

Project description:ADP-ribosylation (ADPr) is a posttranslational modification that is best studied using mass spectrometry. Method developments that are permissive to low inputs or baseline levels of protein ribosylation represent the next frontier in the field. High-field asymmetric waveform ion mobility spectrometry (FAIMS) reduces peptide complexity in gas phase, providing a means to achieve maximal ADPr peptide sequencing depth. We therefore investigated the extent to which FAIMS with or without traditional gas-phase fractionation/separation (GPS) can increase the number of ADPr peptides. We examined ADPr peptides enriched from mouse spleens. We gleaned additional insight by also reporting findings from the corresponding non-ADPr peptide contaminants, and the peptide inputs for ADPr peptide enrichment. At increasingly higher compensation voltages, ADPr peptides were more stable whereas the non-ADPr peptides were filtered out. A combination of 3 GPS survey scans, each with 8 compensation voltages resulted in 790 high-confidence ADPr peptides, compared to 90 with GPS alone. A simplified acquisition strategy requiring only two injections corresponding to two MS1 scan ranges coupled to optimized compensation voltage settings, provided 402 ADPr peptides corresponding to 234 ADPr proteins. We conclude that our combined gas phase separation strategy is a valuable addition to any ADP-ribosylome workflow.

Project description:Mass spectrometry is the premier tool for identifying and quantifying site-specific protein glycosylation globally. Analysis of intact glycopeptides often requires an enrichment step, after which the samples remain highly complex and exhibit a broad dynamic range of abundance. Here, we evaluated the analytical benefits of high-field asymmetric waveform ion mobility spectrometry (FAIMS) coupled to nano-liquid chromatography mass spectrometry (nLC-MS) for analyses of intact glycopeptide devoid of any enrichment step. We compared the effects of compensation voltage on the transmission of N- and O-glycopeptides derived from heterogeneous protein mixtures using two FAIMS devices. We comprehensively demonstrate the performance characteristics of the FAIMS device for glycopeptide analysis and recommend optimal electrode temperature and compensation voltage (CV) settings for N- and O-glycopeptide analysis. Under optimal CV settings, FAIMS-assisted gas-phase fractionation in conjunction with chromatographic reverse phase separation resulted in a 31% increase in the detection of both N- and O-glycopeptide compared to control experiments without FAIMS. Overall, our results demonstrate that FAIMS provides an alternative means to access glycopeptides without any enrichment providing an unbiased global glycoproteome landscape. In addition, our work provides the framework to verify ‘difficult-to-identify’ glycopeptide features.

Project description:Proteomic biomarker discovery using formalin-fixed paraffin-embedded (FFPE) tissue requires robust workflows to support the analysis of large cohorts of patient samples. It also requires finding a reasonable balance between achieving high proteomic depth and limiting overall analysis time. To this end, we evaluated the merits of online coupling of disposable trap column nano-flow liquid chromatography, high-field asymmetric-waveform ion-mobility spectrometry (FAIMS) and tandem mass spectrometry (nLC-FAIMS-MS/MS). The data shows that ≤ 600 ng of peptide digest should be loaded onto the chromatographic part of the system. Careful characterization of the FAIMS settings enabled the choice of optimal combinations of compensation voltages (CV) as a function of the employed LC gradient time. We found nLC-FAIMS-MS/MS to be on par with stage tip-based off-line high pH reversed phase fractionation in terms of proteomic depth and reproducibility of protein quantification (coefficient of variation ≤ 15% for 90 % of all proteins) but requiring 50% less sample and substantially reducing sample handling. Using FFPE material from lymph node, lung and prostate tissue as examples, we show that nLC-FAIMS-MS/MS can identify 5-6,000 proteins from the respective tissue within a total of 3 hours of analysis time.

Project description:The analysis of complex protein mixtures, such as FFPE tissue or plasma exosomes samples, is a challenge nowadays due to the low proteome coverage achieved by mass spectrometers nowadays. We have here investigated the benefits of FAIMS technology coupled to the Orbitrap Exploris 480 mass spectrometer for the TMT quantitative proteomics analyses of these complex samples, in comparison to easy-to-work cell protein extracts. A two-hours gradient LC-MS/MS without or with FAIMS and two compensation voltages (CV=-45 and CV=-60) was used for the analysis. Although a slightly increase in the number of identified and quantified proteins was associated to a decrease in the number of identified and quantified peptides with FAIMS in the cell protein extract TMT experiment, we observed a significant improvement (>100%) in the number of peptide and protein identifications and quantifications for the plasma exosomes and FFPE tissue samples TMT experiments with FAIMS in comparison to the LC-MS/MS analysis without FAIMS. Our results highlight the potential of mass spectrometry analyses with FAIMS to increase the depth into the proteome of complex samples as FFPE and plasma-derived exosomes, which might aid in the characterization of their proteome and proteoforms and in the identification of dysregulated proteins that could be used as biomarkers.