Project description:Limited sensitivity and depth of proteome sampling in experiments using Data-Dependent Acquisition (DDA) mass spectrometry are usually attributed to insufficient rate of fragmentation spectra acquisition relative to the number of co-eluting potential targets. Here we demonstrated that limited sensitivity and dynamic range of MS1 scans reduces the detection of low intensity ion, and thus their selection for fragmentation. As abundant ions occupy a large fraction of the ion accumulation capacity, we sought to improve MS1 detection of rare analytes by an easily implementable strategy based on gas-phase segmentation of the MS1 scan range, followed by co-accumulation and detection of all ions. The quadrupolar isolation windows used to segment the MS1 scan range are designed to transmit on average an equal number of charges, consistent with the parameter used by many recent mass spectrometers to regulate ion trap filling. This strategy, which we named High Dynamic Range MS1 (HDR-MS1), reduces the contribution of abundant ions to reaching the maximum ion capacity. As a result, HDR MS1 showed improved dynamic range and sensitivity compared to conventional full range scans, resulting in higher number of peptides and protein identifications under identical MS2 parameters, less redundant precursor ion sampling, and higher rate of quantified precursor ions. HDR MS1 scans are compatible with any DDA precursor selection filter and MS2 parameter, and the generated files can be analyzed using any software for peptide-spectral matching and quantification. This dataset contains files pertaining method parametrization and benchmarking.

Project description:Limited sensitivity and depth of proteome sampling in experiments using Data-Dependent Acquisition (DDA) mass spectrometry are usually attributed to insufficient rate of fragmentation spectra acquisition relative to the number of co-eluting potential targets. Here we demonstrated that limited sensitivity and dynamic range of MS1 scans reduces the detection of low intensity ion, and thus their selection for fragmentation. As abundant ions occupy a large fraction of the ion accumulation capacity, we sought to improve MS1 detection of rare analytes by an easily implementable strategy based on gas-phase segmentation of the MS1 scan range, followed by co-accumulation and detection of all ions. The quadrupolar isolation windows used to segment the MS1 scan range are designed to transmit on average an equal number of charges, consistent with the parameter used by many recent mass spectrometers to regulate ion trap filling. This strategy, which we named High Dynamic Range MS1 (HDR-MS1), reduces the contribution of abundant ions to reaching the maximum ion capacity. As a result, HDR MS1 showed improved dynamic range and sensitivity compared to conventional full range scans, resulting in higher number of peptides and protein identifications under identical MS2 parameters, less redundant precursor ion sampling, and higher rate of quantified precursor ions. HDR MS1 scans are compatible with any DDA precursor selection filter and MS2 parameter, and the generated files can be analyzed using any software for peptide-spectral matching and quantification. This experiments refer to the plasma analysis

Project description:We thoroughly characterize isobaric labeling (TMT)-associated reporter ion interference at the MS2 level using a defined two-proteome experimental system with known ground truth. We discover remarkably poor agreement between the apparent precursor purity in the isolation window and the actual level of observed reporter ion interference in MS2-scans - a discrepancy that we find resolved by considering co-fragmentation of peptide ions hidden within the spectral “noise” of the MS1 isolation window. On this basis, we establish a comprehensive regression modeling strategy for predicting accurate, feature-wise estimates of reporter ion interference. Finally, we demonstrate the utility of accurate ion purity estimates for accurate fold change estimation and unbiased PTM site-to-protein normalization.

Project description:This work aimed to improve sensitivity of targeted detection by orbitrap mass spectrometers. Co-isolation of contaminant ions was identified as the major factor limiting sensitivity, and LOD of both PRM and accumulated precursor ion scanning (AIM) was improved by increased chromatographic resolution.

Project description:Sensitivity and linear dynamic range of miRNA detection

Project description:We highlight the leap in performance made possible with new instrumentation in the Thermo Scientific Orbitrap Astral™ mass spectrometer. Integrated alongside a high-resolution accurate mass (HRAM) Orbitrap analyzer, the instrument introduces a fast-switching quadrupole mass filter congruent with downstream speeds of ion detection, a dual-pressure ion processor cell which fragments ions in the high-pressure cell before they are moved to the low-pressure cell for further accumulation and orthogonal extraction to the Astral analyzer, and a high dynamic range detector. Altogether, ions can be manipulated in five stages of the MS at once (Orbitrap, ion routing multipole, two ion processor stages, Astral analyzer), allowing for a high degree of parallelization which enables MS/MS scan speeds of 200 Hz while HRAM MS1 full scans are synchronously acquired in the Orbitrap analyzer. To provide such fast scan speeds, the Astral analyzer is capable of single-ion detection sensitivity like a linear ion trap, all while enabling resolving powers of 80,000 at m/z 524. Here, in triplicate 7-min microflow active LC gradients on the Orbitrap Astral MS, we report 7,852 protein groups from 94,267 peptides on average. When employing 15-, 30-, and 60-min active, nano-LC gradients, triplicate experiments yield an average of 9,831, 10,411, and 10,645 unique protein groups from 195,612, 234,406, and 245,754 unique peptides, respectively. These nanoflow methods delivered a median sequence coverage of 38%, 42.4% and 44.4% across identified proteins for each respective gradient length. Our 30-min method delivered approximately 347 proteins per minute. Finally, we applied our 30-min active gradient method to analyze a CRISPR-Cas9 knockout (KO) of the mitochondrial gene MGME1 in human HAP1 cells. There, we quantified an average of 10,353 proteins across three technical replicates and find 449 significantly up- or down-regulated proteins relative to wild-type (WT) HAP1 proteins. Proteins from the same sample quantified using a 61-min active gradient Orbitrap Ascend DIA method show strong fold-change correlations to and gene ontology (GO) term agreement with our results.Building upon the immense progress of the mass spectrometry and proteomics communities of the past ten years, here we report alongside other recent works, that the one-hour human proteome is now within reach.

Project description:<p>We have developed MetaboKit, a comprehensive software package for compound identification and relative quantification in mass spectrometry-based untargeted metabolomics analysis. In data dependent acquisition (DDA) analysis, MetaboKit constructs a customized spectral library with compound identities from reference spectral libraries, adducts, dimers, in-source fragments (ISF), MS/MS fragmentation spectra, and more importantly the retention time information unique to the chromatography system used in the experiment. Using the customized library, the software performs targeted peak integration for precursor ions in DDA analysis and for precursor and product ions in data independent acquisition (DIA) analysis. With its stringent identification algorithm requiring matches by both MS and MS/MS data, MetaboKit provides identification results with significantly greater specificity than the competing software packages without loss in sensitivity. The proposed MS/MS-based screening of ISFs also reduces the chance of unverifiable identification of ISFs considerably. MetaboKit's quantification module produced peak area values highly correlated with known concentrations in a DIA analysis of the metabolite standards at both MS1 and MS2 levels. Moreover, the analysis of Cdk1Liv-/- mouse livers showed that MetaboKit can identify a wide range of lipid species and their ISFs, and quantitatively reconstitute the well-characterized fatty liver phenotype in these mice. In DIA data, the MS1-level and MS2-level peak area data produced similar fold change estimates in the differential abundance analysis, and the MS2-level peak area data allowed for quantitative comparisons in compounds whose precursor ion chromatogram was too noisy for peak integration.</p><p><br></p><p><strong>Mouse liver assays</strong> are reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS1266' rel='noopener noreferrer' target='_blank'><strong>MTBLS1266</strong></a>.</p><p><strong>Standard mixture assay</strong> is reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS1311' rel='noopener noreferrer' target='_blank'><strong>MTBLS1311</strong></a>.</p>

Project description:<p>We have developed MetaboKit, a comprehensive software package for compound identification and relative quantification in mass spectrometry-based untargeted metabolomics analysis. In data dependent acquisition (DDA) analysis, MetaboKit constructs a customized spectral library with compound identities from reference spectral libraries, adducts, dimers, in-source fragments (ISF), MS/MS fragmentation spectra, and more importantly the retention time information unique to the chromatography system used in the experiment. Using the customized library, the software performs targeted peak integration for precursor ions in DDA analysis and for precursor and product ions in data independent acquisition (DIA) analysis. With its stringent identification algorithm requiring matches by both MS and MS/MS data, MetaboKit provides identification results with significantly greater specificity than the competing software packages without loss in sensitivity. The proposed MS/MS-based screening of ISFs also reduces the chance of unverifiable identification of ISFs considerably. MetaboKit's quantification module produced peak area values highly correlated with known concentrations in a DIA analysis of the metabolite standards at both MS1 and MS2 levels. Moreover, the analysis of Cdk1Liv-/- mouse livers showed that MetaboKit can identify a wide range of lipid species and their ISFs, and quantitatively reconstitute the well-characterized fatty liver phenotype in these mice. In DIA data, the MS1-level and MS2-level peak area data produced similar fold change estimates in the differential abundance analysis, and the MS2-level peak area data allowed for quantitative comparisons in compounds whose precursor ion chromatogram was too noisy for peak integration.</p><p><br></p><p><strong>Standard mixture assay</strong> is reported in the current study <a href='https://www.ebi.ac.uk/metabolights/MTBLS1311' rel='noopener noreferrer' target='_blank'><strong>MTBLS1311</strong></a>.</p><p><strong>Mouse liver assays</strong> are reported in <a href='https://www.ebi.ac.uk/metabolights/MTBLS1266' rel='noopener noreferrer' target='_blank'><strong>MTBLS1266</strong></a>.</p>

Project description:Data independent acquisition-mass spectrometry (DIA-MS) coupled with liquid chromatography is a promising approach for rapid, automatic sampling of MS/MS data in untargeted metabolomics. However, wide isolation windows in DIA-MS generate MS/MS spectra containing a mixed population of fragment ions together with their precursor ions. This precursor-fragment ion map in a comprehensive MS/MS spectral library is crucial for relative quantification of fragment ions uniquely representative of each precursor ion. However, existing reference libraries are not sufficient for this purpose since the fragmentation patterns of small molecules can vary in different instrument setups. Here we developed a bioinformatics workflow called MetaboDIA to build customized MS/MS spectral libraries using a user's own data dependent acquisition (DDA) data and to perform MS/MS-based quantification with DIA data, thus complementing conventional MS1-based quantification. MetaboDIA also allows users to build a spectral library directly from DIA data in studies of a large sample size. Using a marine algae data set, we show that quantification of fragment ions extracted with a customized MS/MS library can provide as reliable quantitative data as the direct quantification of precursor ions based on MS1 data. To test its applicability in complex samples, we applied MetaboDIA to a clinical serum metabolomics data set, where we built a DDA-based spectral library containing consensus spectra for 1829 compounds. We performed fragment ion quantification using DIA data using this library, yielding sensitive differential expression analysis. </br></br> Serum metabolome of 40 age-related macular degeneration patients and 20 control samples was analyzed using untargeted mass spectrometry. We used data dependent acquisition data to build a MS/MS spectral assay library for more than 1,000 compounds and performed targeted extraction of MS2 ion chromatograms from data independent acquisition analysis.

Project description:To improve the sensitivity and accuracy of label-free quantification and tandem mass tags (TMT) labeling in quantifying low-abundance proteins, multi-parameter optimization was carried out using a complex 2-proteome artificial sample mixture for a series of steps from sample preparation to data analysis, including the desalting of peptides, peptide injection amount for LC-MS/MS, MS1 resolution, the length of LC-MS/MS gradient, AGC targets, ion accumulation time, MS2 resolution, precursor co-isolation threshold, data analysis software, statistical calculation methods and protein fold changes. Five subprojects were included for this project.