Project description:RATIONALE In spatial proteomics, matrix-assisted laser desorption/ionization (MALDI) imaging enables rapid and cost-effective peptide measurement. Yet, in situ peptide identification remains challenging. Therefore, this study aims to integrate the trapped ion mobility spectrometry (TIMS)-based parallel accumulation-serial fragmentation (PASEF) into MALDI imaging of peptides to enable multiplexed MS/MS imaging. METHODS An initial MALDI TIMS MS1 survey measurement is performed, followed by a manual generation of a precursor list containing mass over charge values and ion mobility windows. Inside the dual TIMS system, submitted precursors are trapped, separately eluted by their ion mobility and analyzed in a quadrupole time-of-flight device, thereby enabling multiplexed MALDI MS/MS imaging. Finally, precursors are identified by peptide to spectrum matching. RESULTS This study presents the first multiplexed MALDI TIMS MS/MS imaging (iprm-PASEF) of tryptic peptides. Its applicability is showcased on two histomorphologically distinct tissue specimens in a 4-plex and 5-plex setup. Precursors were successfully identified by the search engine MASCOT in one single MALDI imaging experiment for each respective tissue. Peptide identifications were corroborated by liquid-chromatography tandem mass spectrometry experiments and fragment colocalization analyses. CONCLUSIONS In the present study, we demonstrate the feasibility of TIMS-based MALDI MS/MS imaging for the multiplexed and rapid identification of tryptic peptides in a spatial manner. Hence, it represents a first step towards the integration of MALDI imaging into the emerging field of spatial proteomics. The datasets will be uploaded separately. This data set contains the PDX MS1 data. There are two tissues vissible on the.tif image. The relevant one is on the left side of the slide (away from the barcode).

Project description:RATIONALE In spatial proteomics, matrix-assisted laser desorption/ionization (MALDI) imaging enables rapid and cost-effective peptide measurement. Yet, in situ peptide identification remains challenging. Therefore, this study aims to integrate the trapped ion mobility spectrometry (TIMS)-based parallel accumulation-serial fragmentation (PASEF) into MALDI imaging of peptides to enable multiplexed MS/MS imaging. METHODS An initial MALDI TIMS MS1 survey measurement is performed, followed by a manual generation of a precursor list containing mass over charge values and ion mobility windows. Inside the dual TIMS system, submitted precursors are trapped, separately eluted by their ion mobility and analyzed in a quadrupole time-of-flight device, thereby enabling multiplexed MALDI MS/MS imaging. Finally, precursors are identified by peptide to spectrum matching. RESULTS This study presents the first multiplexed MALDI TIMS MS/MS imaging (iprm-PASEF) of tryptic peptides. Its applicability is showcased on two histomorphologically distinct tissue specimens in a 4-plex and 5-plex setup. Precursors were successfully identified by the search engine MASCOT in one single MALDI imaging experiment for each respective tissue. Peptide identifications were corroborated by liquid-chromatography tandem mass spectrometry experiments and fragment colocalization analyses. CONCLUSIONS In the present study, we demonstrate the feasibility of TIMS-based MALDI MS/MS imaging for the multiplexed and rapid identification of tryptic peptides in a spatial manner. Hence, it represents a first step towards the integration of MALDI imaging into the emerging field of spatial proteomics. All Datasets are uploaded separateley. This file contains the dataset for mouse kidney MS1 data. On the same slice a mouse liver was measured for a different experiment.

Project description:RATIONALE In spatial proteomics, matrix-assisted laser desorption/ionization (MALDI) imaging enables rapid and cost-effective peptide measurement. Yet, in situ peptide identification remains challenging. Therefore, this study aims to integrate the trapped ion mobility spectrometry (TIMS)-based parallel accumulation-serial fragmentation (PASEF) into MALDI imaging of peptides to enable multiplexed MS/MS imaging. METHODS An initial MALDI TIMS MS1 survey measurement is performed, followed by a manual generation of a precursor list containing mass over charge values and ion mobility windows. Inside the dual TIMS system, submitted precursors are trapped, separately eluted by their ion mobility and analyzed in a quadrupole time-of-flight device, thereby enabling multiplexed MALDI MS/MS imaging. Finally, precursors are identified by peptide to spectrum matching. RESULTS This study presents the first multiplexed MALDI TIMS MS/MS imaging (iprm-PASEF) of tryptic peptides. Its applicability is showcased on two histomorphologically distinct tissue specimens in a 4-plex and 5-plex setup. Precursors were successfully identified by the search engine MASCOT in one single MALDI imaging experiment for each respective tissue. Peptide identifications were corroborated by liquid-chromatography tandem mass spectrometry experiments and fragment colocalization analyses. CONCLUSIONS In the present study, we demonstrate the feasibility of TIMS-based MALDI MS/MS imaging for the multiplexed and rapid identification of tryptic peptides in a spatial manner. Hence, it represents a first step towards the integration of MALDI imaging into the emerging field of spatial proteomics. The datasets will be uploaded separately. This data set contains the PDX MSMS data. There are two tissues vissible on the.tif image. The relevant one is on the left side of the slide (away from the barcode).

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:MALDI imaging and LC-MS/MS-based fast, high-resolution spatial proteomics demonstrate cellular heterogeneity in situ

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 popular in mass spectrometry (MS)-based proteomics because they enable continuous acquisition of fragment spectra for all precursors simultaneously. However, these advantages come with the challenge of correctly reconstructing the precursor-fragment relationships in these highly convoluted 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 seamlessly and continuously follows the natural shape of the ion cloud in ion mobility and peptide precursor mass dimensions. Termed synchro-PASEF, it increases the detected fragment ion current several-fold at sub-second cycle times. Consecutive quadrupole selection windows move synchronously through the mass and ion mobility range. 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 relationships in ion mobility and mass dimensions and effectively deconvolutes the DIA fragment space. Importantly, the partitioned parts of the fragment ion transitions provide a further dimension of specificity via a lock and key mechanism. This is also advantageous for quantification, where signals from interfering precursors in the DIA selection window do not affect all partitions of the fragment ion, allowing to retain only the specific parts for quantification. Overall, we establish the defining features of synchro-PASEF and explore its potential for proteomic analyses.

Project description:LC-MS(/MS) and MALDI-(TIMS)-qTOF imaging MS(/MS) datasets for the fungal-fungal interaction between Penicillium sp. JBC and Diutina catenulata 135E/Brevibacterium linens JB5. MALDI-TIMS-qTOF MS/MS data for a purchased standard of sclerotigenin is included.

Project description:Matrix-assisted laser desorption/ionization imaging mass spectrometry (MALDI IMS) allows for highly multiplexed, unlabeled mapping of analytes from tissue sections. However, further work is needed to improve sensitivity and depth of coverage for protein and peptide IMS. Laser-based post-ionization MALDI-2 has been shown to increase sensitivity for several molecular classes but has not yet been reported for peptides. We demonstrate signal enhancement of proteolytic peptides from thin tissue sections of human kidney by conventional MALDI (termed MALDI-1), and conventional MALDI augmented using a second ionizing laser (termed MALDI-2). Proteins were digested in situ using trypsin prior to IMS analysis. For tentative identification of peptides and proteins, a tissue homogenate from the same tissue analyzed by IMS was analyzed by LC-MS/MS. These proteins were digested in silico to generate a database of theoretical peptides to then match to MALDI IMS datasets. Peptides were tentatively identified by matching the MALDI peak list to the database peptide list employing a 5 ppm error window. This resulted in 314 ± 45 (n=3) peptides and 1 112 ± 84 (n=3) peptides for MALDI-1 and MALDI-2, respectively. Protein identifications requiring two or more peptides per protein resulted in 55 ± 13 proteins identifications with MALDI-1 and 205 ± 10 with MALDI-2. These results demonstrate that MALDI-2 provides enhanced sensitivity for the spatial mapping of tryptic peptides and significantly increases the number of proteins identified in IMS experiments.

Project description:LC-MS(/MS) and MALDI-(TIMS)-qTOF imaging MS(/MS) datasets for the fungal-fungal interaction between Penicillium sp. JBC and Diutina catenulata 135E/Brevibacterium linens JB5. MALDI-TIMS-qTOF MS/MS data for a purchased standard of sclerotigenin is included.