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:Gas phase fractionation techniques have become popular in the field of mass spectrometry to improve results without using more sample. High field asymmetric waveform ion mobility spectrometry (FAIMS) coupled to liquid chromatography-mass spectrometry (LC-MS) has been shown to increase peptide and protein detections compared to LC-MS/MS alone. However, FAIMS has not been compared to other methods of gas phase fractionation, such as quadrupole gas phase fractionation, which leaves uncertainty about the mechanisms of improvement. The goal of this work was to assess whether FAIMS improves peptide identifications because 1) gas phase fractionation enables the analysis of less abundant signals by excluding more abundant precursors from filling the ion trap, 2) the use of FAIMS reduces co-isolation of peptides during the MS/MS process resulting in a reduction of chimeric spectra, or 3) a combination of both. To investigate these hypotheses, pooled human brain tissue samples were measured in triplicate using FAIMS gas phase fractionation, quadrupole gas phase fractionation, or no gas phase fractionation. To confirm the results, the experiment was reproduced on another instrument. On both instruments, FAIMS gas phase fractionation reduced co-isolation of peptides and generated fewer chimeric spectra even though it was less efficient at transmitting ions than quadrupole gas phase fractionation. This suggests that improvements can be made to the DDA acquisition process by excluding peptides for MS/MS that have more than one peptide isotope distribution in the isolation window.

Project description:We performed an extensive qualitative characterization of the platelet granule proteome using subcellular fractionation followed by mass spectrometry analysis and functional annotation. Platelets were isolated from whole blood by centrifugation and their level of purity was tested by microscopic inspection, western blot and Leucocount kit. Subcellular fractionation based on sucrose gradient was used to enrich sample in secretory granules. Then sample quality was assessed by western blot and electronic microscopy, prior proteomic study. Samples were trypsin digested and analyzed using an Orbitrap Velos in a gas-phase fractionation mode. The m/z ranges for the selection of precursor ions were 400-521, 516-690, 685-986 and 963-2000 Thomsons. The 2 technical replicates were analyzed by a GPF series of injections. Protein identification was performed using the EasyProt resource. The module EasyProtConv was used to generate the MGF file from the raw data. The peaklist files were searched against the UniProt database (2011_02 of 08-Feb-2011) using EasyProt. Eight-hundred-and-twenty-seven proteins were identified, most of them being associated to granules and to the granule’s secretory machinery.

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:Applications of notched injection waveforms for more uniform gas-phase fractionation

Project description:In this study, we investigated the benefits of adding high-field asymmetric ion mobility spectrometry (FAIMS) separation prior to data dependent acquisition (DDA) and gas phase fractionation (GPF) prior to data independent acquisition (DIA) LC-MS/MS analysis. Native digestion followed by LC-MS/MS with FAIMS allowed the identification of 221 HCPs among which 158 were reliably quantified for a global amount of 880 ng/mg of NIST mAb Reference Material. Our methods have also been applied to commercial DPs and demonstrate their ability to dig deeper into the HCP landscape with the identification of 60 and 67 HCPs, and accurate quantification of 29 and 31 of these impurities in nivolumab and trastuzumab respectively, with sensitivity down to the sub-ng/mg of mAb level.

Project description:In this study, we investigated the benefits of adding high-field asymmetric ion mobility spectrometry (FAIMS) separation prior to data dependent acquisition (DDA) and gas phase fractionation (GPF) prior to data independent acquisition (DIA) LC-MS/MS analysis. Native digestion followed by LC-MS/MS with FAIMS allowed the identification of 221 HCPs among which 158 were reliably quantified for a global amount of 880 ng/mg of NIST mAb Reference Material. Our methods have also been applied to commercial DPs and demonstrate their ability to dig deeper into the HCP landscape with the identification of 60 and 67 HCPs, and accurate quantification of 29 and 31 of these impurities in nivolumab and trastuzumab respectively, with sensitivity down to the sub-ng/mg of mAb level

Project description:GAS strains were grown in THY broth to early exponential phase and RNA extracted. cDNA was generated and the expression profiles were determined using the RMLgenechip. Comparisons between the sample groups allow the identification of genes differentially expressed between strains. This experiment compared pre- and post- mouse passaged GAS strains. Keywords: GAS comparison

Project description:We used RNA-Seq to assess how RocA regulates gene expression in stationary phase cultures of serotype M1 GAS