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.

Project description:Data-independent acquisition (DIA) methods have become increasingly attractive in mass spectrometry (MS)-based proteomics, because they enable high data completeness and a wide dynamic range. Recently, we combined DIA with parallel accumulation – serial fragmentation (dia-PASEF) on a Bruker trapped ion mobility separated (TIMS) quadrupole time-of-flight (TOF) mass spectrometer. This requires alignment of the ion mobility separation with the downstream mass selective quadrupole, leading to a more complex scheme for dia-PASEF window placement compared to DIA. To achieve high data completeness and deep proteome coverage, here we employ variable isolation windows that are placed optimally depending on precursor density in the m/z and ion mobility plane. This Automatic Isolation Design procedure is implemented in the freely available py_diAID package. In combination with in-depth project-specific proteomics libraries and the Evosep LC system, we reproducibly identified over 7,700 proteins in a human cancer cell line in 44 minutes with quadruplicate single-shot injections at high sensitivity. Even at a throughput of 100 samples per day (11 minutes LC gradients), we consistently quantified more than 6,000 proteins in mammalian cell lysates by injecting four replicates. We found that optimal dia-PASEF window placement facilitates in-depth phosphoproteomics with very high sensitivity, quantifying more than 35,000 phosphosites in a human cancer cell line stimulated with an epidermal growth factor (EGF) in triplicate 21 minutes runs. This covers a substantial part of the regulated phosphoproteome with high sensitivity, opening up for extensive systems-biological studies.

Project description:Data independent acquisition methods have become increasingly popular in mass spectrometry (MS)-based proteomics because they enable parallel and continuous acquisition of fragment spectra. However, these advantages come with the challenge of correctly reconstructing the precursor-fragment relationship in these highly multiplexed spectra for reliable identification and quantification. Here we introduce a scan mode for the combination of trapped ion mobility spectrometry (TIMS) with parallel accumulation – serial fragmentation (PASEF) that naturally and continuously follows the ion cloud in ion mobility and peptide mass dimensions as opposed to the step functions we employed before. Termed synchro-PASEF, it increases fragment yield several fold at sub-second cycle times. The quadrupole selection window moves synchronously through the mass and ion mobility range, deconvoluting the DIA spectra and defining precursor-quadrupole relationships. In this process, the quadrupole slices through the peptide precursors, which separates fragment ion signals of each precursor into adjacent synchro-PASEF scans. This precisely defines precursor – fragment relationship in ion mobility and mass dimensions. Importantly, the two parts of the fragment ion transitions in synchro-PASEF provide a further dimension of specificity via a lock and key mechanism. This is especially advantageous for quantification, where signals from interfering precursors in the dia selection window only affect the top or bottom part of the fragment ion, allowing them to be filtered out. In this paper, we establish the defining features of synchro-PASEF and explore its potential for proteomics analyses.

Project description:Neutrophils, crucial player in inflammation, present a significant challenge in comprehensive molecular characterization due to limited availability (~1,000 cells) in inflamed sites like steady state infiltration. Prior proteomic studies typically required millions of neutrophils, posing difficulties when dealing with limited samples. This study introduces a ‘low-cell proteome’ workflow for neutrophils, integrating S-trap micro column-based digestion with DIA PASEF to investigate their functional dynamics within individual inflamed site.This method enable protein profiling of 1,000 isoated resting circulatory neutrophils with broad dynamic range in a reproducible manner.Furthermore, we applied this integrated approach to investigate the change in neutrophil proteome under different physiological and pathological conditions, including brain infiltration following stroke in mice and transmigration to the oral cavity post-treatment with tabasco in humans. Our comprehensive proteomic analysis provides insights into the distinct behavioral responses of neutrophils in these inflammatory contexts compared to their circulating counterparts.

Project description:dia-PASEF analysis of human amygdala in Parkinson’s disease

Project description:dia-PASEF analysis of human amygdala in Alzheimer’s disease

Project description:In bottom-up proteomics, peptides are separated by liquid chromatography with elution peak widths in the range of seconds, while mass spectra are acquired in about 100 microseconds with time-of-fight (TOF) instruments. This allows adding ion mobility as a third dimension of separation. Among several formats, trapped ion mobility spectrometry (TIMS) is attractive due to its small size, low voltage requirements and high efficiency of ion utilization. We have recently demonstrated a scan mode termed parallel accumulation – serial fragmentation (PASEF), which multiplies the sequencing speed without any loss in sensitivity (Meier et al., PMID: 26538118). Here we introduce the timsTOF Pro instrument, which optimally implements online PASEF. It features an orthogonal ion path into the ion mobility device, limiting the amount of debris entering the instrument and making it very robust in daily operation. We investigate different precursor selection schemes for shotgun proteomics to optimally allocate in excess of 100 fragmentation events per second. More than 800,000 fragmentation spectra in standard 120 min LC runs are easily achievable, which can be used for near exhaustive precursor selection in complex mixtures or re-sequencing weak precursors. MaxQuant identified more than 6,000 proteins in single run HeLa analyses without matching to a library, and with high quantitative reproducibility (R > 0.97). Online PASEF achieves a remarkable sensitivity with more than 2,000 proteins identified in 30 min runs of only 10 ng HeLa digest. We also show that highly reproducible collisional cross sections can be acquired on a large scale (R > 0.99). PASEF on the timsTOF Pro is a valuable addition to the technological toolbox in proteomics, with a number of unique operating modes that are only beginning to be explored.

Project description:Opportunistic infections of the respiratory tract often succeed under a weakened immune response caused by an underlying illness or hospitalization. The human fungal pathogen, Cryptococcus neoformans, and the bacterial pathogen, Klebsiella pneumoniae, are both well-characterized microbes that cause severe infections within immunocompromised individuals. In this study, we simulate a concentration-dependent pulmonary coinfection of a bacterial and fungal pathogen, and profile the proteomic changes by DDA vs. DIA. Dual perspective profiling provides new insights into host defense regulation of infection and pathogenic mechanisms of invasion.

Project description:High resolution mass spectrometry-based proteomics generates large amounts of data, even in the standard liquid chromatography (LC) – tandem mass spectrometry configuration. Adding an ion mobility dimension vastly increases the acquired data volume, challenging both analytical processing pipelines and especially data exploration by scientists. This has necessitated data aggregation, effectively discarding much of the information present in these rich data sets. Taking trapped ion mobility spectrometry (TIMS) on the quadrupole time of flight platform (Q-TOF) as an example, we developed an efficient indexing scheme that represents all data points as detector arrival times on scales of seconds (LC), milliseconds (TIMS) and microseconds (TOF). In our open source AlphaTims package, data are indexed, accessed and visualized by a combination of tools of the scientific Python ecosystem. We interpret unprocessed data as a sparse 4D matrix and use just in time compilation to machine code with Numba, accelerating our computational procedures by several orders of magnitude while keeping to familiar indexing and slicing notations. For samples with more than six billion detector events a modern laptop can load and index raw data in about a minute. Loading is even faster when AlphaTims has already saved indexed data in a HDF5 file, a portable scientific standard used in extremely large-scale data acquisition. Subsequently, data accession along any dimension and interactive visualization happen in milliseconds. We have found AlphaTims to be a key enabling tool to explore high dimensional LC-TIMS-Q-TOF data and have made it freely available as an open-source Python package with a stand-alone graphical user interface at https://github.com/MannLabs/alphatims or as part of the AlphaPept framework.

Project description:Fast photochemical oxidation of proteins (FPOP) is a modern technique for studying protein folding, conformations, interactions, etc. In this work, timsTOF Pro mass spectrometer coupled with trapped ion mobility spectrometry was used for identification of oxidative modifications in a model protein. Multiple modifications on the same residues, including six modifications of histidine, were successfully resolved. Moreover, PASEF technology allows successful sequencing even minor populations of modified peptides.