Project description:Mass spectrometry is the most effective method to directly identify peptides presented on HLA molecules. However, current standard approaches often require billions of cells for input material to achieve high coverage of the immunopeptidome and are therefore not compatible with the often limiting amounts of tissue available from clinical tumor samples. Here, we evaluated microscaled basic reversed-phase fractionation to separate HLA peptide samples off-line followed by ion mobility coupled to LC-MS/MS for analysis. The combination of these two separation methods enabled identification of 20% to 50% more peptides compared to samples analyzed without either prior fractionation or use of ion mobility. We demonstrate coverage of HLA immunopeptidomes with up to 8,107 distinct peptides starting with as few as 50 million cells or 150 milligrams of wet weight tumor tissue. This increased sensitivity can improve HLA binding prediction algorithms and enable detection of clinically relevant epitopes such as neoantigens

Project description:Phulphagar K, Ctortecka C, Vaca Jacome AS, Klaeger S, Verzani E, Hernandez G, Udeshi ND, Clauser KR, Abelin JG, Carr SA. 2023. Comprehensive, in-depth identification of the human leukocyte antigen HLA-I and HLA-II tumor immunopeptidome can inform the development of cancer immunotherapies. Mass spectrometry (MS) is a powerful state-of-the-art technology for direct identification of HLA peptides from patient derived tumor samples or cell lines. However, achieving sufficient coverage to detect rare, clinically relevant antigens requires highly sensitive MS-based acquisition methods and large amounts of samples. Immunopeptidome depth can be increased through biochemical fractionation, which can be impeded by the limited amounts of primary tissue biopsies. To address this challenge, we developed and applied a high throughput, sensitive, single-shot MS-based immunopeptidomics workflow that leverages trapped ion mobility time-of-flight mass spectrometry on the Bruker timsTOF SCP. We demonstrate >2-fold improved coverage of HLA immunopeptidomes with up to 15,000 distinct HLA-I and HLA-II peptides from 4e7 cells. Our optimized single-shot MS acquisition method on the SCP maintains high coverage, eliminates the need for biochemical fractionation and reduces input requirements to 1e7 cells for > 800 distinct HLA-I peptides. Moreover, we find that the binding motifs of specific HLA alleles can influence peptide fragmentation patterns, and that optimized collision energies can result in complementary b/y ion sequence coverage. Our optimized single-shot SCP acquisition methods enable sensitive, high throughput and reproducible immunopeptidome profiling and the detection of peptides from non-canonical open reading frames and clinically relevant cancer-testis antigens from less than 4e7 cells or 15 mg wet weight tissue.

Project description:The sensitivity and depth of proteomic analyses is limited by isobaric ions and interferences that preclude the identification of low abundance peptides. Extensive sample fractionation is often required to extend proteome coverage when sample amount is not a limitation. Ion mobility devices provide a viable alternate approach to resolve confounding ions, improve peak capacity and mass spectrometry (MS) sensitivity. Here, we report the integration of differential ion mobility with segmented ion fractionation (SIFT) to enhance the comprehensiveness of proteomic analyses. The combination of differential ion mobility and SIFT, where narrow windows of ~ m/z 100 are acquired in turn, is found particularly advantageous in the analysis of protein digests, and typically provided 70% gain in identification compared to conventional single-shot LC-MS/MS. The application of this approach is further demonstrated for the analysis of tryptic digests from different colorectal cancer cell lines where the enhanced sensitivity enabled the identification of single amino acid variants that were correlated with the corresponding transcriptomic datasets.

Project description:Data independent acquisition (DIA or DIA/SWATH ) mass spectrometry has emerged as a primary measurement strategy in the field of quantitative proteomics. diaPASEF is a recent adaptation that leverages trapped ion mobility spectrometry (TIMS) to improve selectivity and increase sensitivity. The complex fragmentation spectra generated by co-isolation of peptides in DIA mode are most typically analyzed with reference to prior knowledge in the form of spectral libraries. The best established method for generating libraries uses data dependent acquisition (DDA) mode, or DIA mode if appropriately deconvoluted, often including offline fractionation to increase depth of coverage,to create spectral libraries. More recently strategies for spectral library generation based on gas phase fractionation (GPF), where a representative sample is injected serially using narrow window DIA methods designed to cover different slices of the precursor space, have been introduced and performed comparably to deep offline fractionation-based libraries for DIA data analysis. Here, we investigated whether an analogous GPF-based library building approach that accounts for the ion mobility (IM) dimension is useful for the analysis of diaPASEF data and can remove the need for offline fractionation. To enable a rapid library development approach for diaPASEF we designed a GPF acquisition scheme covering the majority of multiply charged precursors in the m/z vs 1/K0 space requiring 7 injections of a representative sample and compared this with libraries generated by direct deconvolution-based analysis of diaPASEF data or by deep offline fractionation and ddaPASEF. . We found that the GPF based library outperformed library generation by direct deconvolution of the diaPASEF data, and performed comparably to deep offline fractionation libraries, when analysing diaPASEF data acquired from 200ng of commercial HeLa digest. With the ion mobility integrated GPF scheme we establish a pragmatic approach to rapid and comprehensive library generation for the analysis of diaPASEF data.

Project description:Data independent acquisition (DIA or DIA/SWATH ) mass spectrometry has emerged as a primary measurement strategy in the field of quantitative proteomics. diaPASEF is a recent adaptation that leverages trapped ion mobility spectrometry (TIMS) to improve selectivity and increase sensitivity. The complex fragmentation spectra generated by co-isolation of peptides in DIA mode are most typically analyzed with reference to prior knowledge in the form of spectral libraries. The best established method for generating libraries uses data dependent acquisition (DDA) mode, or DIA mode if appropriately deconvoluted, often including offline fractionation to increase depth of coverage,to create spectral libraries. More recently strategies for spectral library generation based on gas phase fractionation (GPF), where a representative sample is injected serially using narrow window DIA methods designed to cover different slices of the precursor space, have been introduced and performed comparably to deep offline fractionation-based libraries for DIA data analysis. Here, we investigated whether an analogous GPF-based library building approach that accounts for the ion mobility (IM) dimension is useful for the analysis of diaPASEF data and can remove the need for offline fractionation. To enable a rapid library development approach for diaPASEF we designed a GPF acquisition scheme covering the majority of multiply charged precursors in the m/z vs 1/K0 space requiring 7 injections of a representative sample and compared this with libraries generated by direct deconvolution-based analysis of diaPASEF data or by deep offline fractionation and ddaPASEF. . We found that the GPF based library outperformed library generation by direct deconvolution of the diaPASEF data, and performed comparably to deep offline fractionation libraries, when analysing diaPASEF data acquired from 200ng of commercial HeLa digest. With the ion mobility integrated GPF scheme we establish a pragmatic approach to rapid and comprehensive library generation for the analysis of diaPASEF data.

Project description:<p>The metabolome includes not just known but also unknown metabolites; however, metabolite annotation remains the bottleneck in untargeted metabolomics. Ion mobility – mass spectrometry (IM-MS) has emerged as a promising technology by providing multi-dimensional characterizations of metabolites. Here, we curated an ion mobility CCS atlas, namely AllCCS, and developed an integrated strategy for metabolite annotation using known or unknown chemical structures. The AllCCS atlas covers vast chemical structures with &gt;5000 experimental CCS records and ~12 million calculated CCS values for &gt;1.6 million small molecules. We demonstrated the high accuracy and wide applicability of AllCCS with medium relative errors of 0.5-2% for a broad spectrum of small molecules. AllCCS combined with in-silico MS/MS spectra facilitated multi-dimensional match and substantially improved the accuracy and coverage of both known and unknown metabolite annotation from biological samples. Together, AllCCS is a versatile resource that enables confident metabolite annotation, revealing comprehensive chemical and metabolic insights towards biological processes.</p><p><br></p><p><strong>Known Metabolite Annotation in Different Biological Samples assays</strong> are reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS1693' rel='noopener noreferrer' target='_blank'><strong>MTBLS1693</strong></a>.</p><p><strong>Unknown Metabolite Annotation in Mouse Aging assay</strong> is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS1622' rel='noopener noreferrer' target='_blank'><strong>MTBLS1622</strong></a>.</p>

Project description:<p>The metabolome includes not just known but also unknown metabolites; however, metabolite annotation remains the bottleneck in untargeted metabolomics. Ion mobility – mass spectrometry (IM-MS) has emerged as a promising technology by providing multi-dimensional characterizations of metabolites. Here, we curated an ion mobility CCS atlas, namely AllCCS, and developed an integrated strategy for metabolite annotation using known or unknown chemical structures. The AllCCS atlas covers vast chemical structures with &gt;5000 experimental CCS records and ~12 million calculated CCS values for &gt;1.6 million small molecules. We demonstrated the high accuracy and wide applicability of AllCCS with medium relative errors of 0.5-2% for a broad spectrum of small molecules. AllCCS combined with in-silico MS/MS spectra facilitated multi-dimensional match and substantially improved the accuracy and coverage of both known and unknown metabolite annotation from biological samples. Together, AllCCS is a versatile resource that enables confident metabolite annotation, revealing comprehensive chemical and metabolic insights towards biological processes.</p><p><br></p><p><strong>Unknown Metabolite Annotation in Mouse Aging assay</strong> is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS1622' rel='noopener noreferrer' target='_blank'><strong>MTBLS1622</strong></a>.</p><p><strong>Known Metabolite Annotation in Different Biological Samples assays</strong> are reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS1693' rel='noopener noreferrer' target='_blank'><strong>MTBLS1693</strong></a>.</p>

Project description:Data independent acquisition modes isolate and concurrently fragment populations of different precursors by cycling through segments of a predefined precursor m/z range. Although these selection windows collectively cover the entire m/z range, overall only a few percent of all incoming ions in each window are sampled. Making use of the correlation of molecular weight and ion mobility in a trapped ion mobility device (timsTOF Pro), we here devise a novel scan mode that samples up to 100% of the peptide precursor ion current in m/z and mobility windows. We extend an established targeted data extraction workflow by including the ion mobility dimension for both signal extraction and scoring, thereby increasing the specificity for precursor identification. Data acquired from whole proteome digests and mixed organism samples demonstrate deep proteome coverage and a very high degree of reproducibility as well as quantitative accuracy, even from 10 ng sample amounts.

Project description:Circulating antibodies provide valuable information about an individual’s immune status and constitute a significant portion of the human plasma proteome. Proteomic analysis of plasma is challenged by the large dynamic concentration range of plasma proteins, including antibodies. Peptide fractionation prior to data-independent (shotgun) proteomics has the potential to overcome this obstacle and enable increased coverage of plasma proteins. In this work, we evaluated the detection of tryptic immunoglobulin variable region peptides using multidimensional chromatography (high-pH preparative LC) or gas-phase ion mobility spectrometry (FAIMS). Typical digests of eight serum samples were obtained by (a) direct LC-MS (without prior fractionation, 1D), (b) LC-FAIMS-MS, and (c) high-pH reversed-phase fractionation into 24 fractions and subsequent measurement of each fraction. As de novo search is an essential step in antibody variable region peptide identification, all MS/MS spectra were acquired in high resolution Orbitrap mode.

Project description:Data provided report the use of trapped ion mobility spectrometry (TIMS) to fractionate ions in the gas phase based on their ion mobility (V⋅s/cm2) followed by parallel accumulation serial fragmentation (PASEF) in a quadrupole time-of-flight instrument. TIMS fractionation coupled to DDA-PASEF allowed for the detection of approximately 7,000 proteins and over 70,000 peptides per overall run from 200ng of human (HeLa) cell lysate per injection using a commercial UPLC column with a 90-minute gradient. This project also explored the utility of TIMS fractionation to generate a DDA library for downstream DIA analysis using shorter LC gradients (20 minutes) as well as lower sample input. Using a 20min gradient, we identified 4,092 and 6,654 proteins on average per run, respectively, from 10ng and 200ng of human (HeLa) cell lysate input based on a TIMS-fractionated library consisting of 82,214 peptides derived from 7,615 proteins.