Project description:Investigation of whole genome expression pattern of 60 and 72 hours post fertilization Danio Rerio embryos exposed to TMT and vehicle control Embryos were exposed to 10uM TMT or control from 48hpf to 60 or 72 hpf. Three replicates were collected for each time point. 40 embryos were pooled to comprise a replicate.

Project description:The rat pheochromocytoma cell line PC12 cells were cultured in complete DMEM till 80% confluence, then placed at 5000 cells per squared cm. Cells were then plated in 24-well plates for cell viability assay and in T75 flasks for RNA isolation. Medium was replaced with serum-free fresh medium for 12 hours prior to TMT treatment. Gene expression patterns were then analysed using Rat Expression Array 230A Experiment Overall Design: In this study we analize gene expression patterns in PC12 cells treated with Trimethyltin (TMT). We utilized control cells (untreated) and two different concentration (1 and 5) Experiment Overall Design: We used three biological replicates, for the three concentration tested, according to MIAME guidelines Experiment Overall Design: (total 9 chips were used in this study).

Project description:We used whole mouse genome microarrays to the effects of γ-TmT on global gene expression in the prostate TRAMP and age-matched C57BL/6 mice were administered either 600 mg/kg of γ-TmT or a control vehicle via oral gavage. Twelve hours after dosing, prostate tissues were collected for RNA extraction.

Project description:Isobaric labeling quantification by mass spectrometry (MS) has emerged as a powerful technology for multiplexed large-scale protein profiling, but measurement accuracy in complex mixtures is confounded by the interference from co-isolated ions, resulting in ratio compression. Here we report that the ratio compression can be essentially resolved by the combination of pre-MS peptide fractionation, MS2-based interference detection and post-MS computational interference correction. We pooled tandem mass tag (TMT) labeled E. coli peptides at 1 : 3 : 10 ratios, and added in ~20-fold more rat peptides as background, followed by the analysis of two dimensional liquid chromatography (LC)-MS/MS. The quantitative interference was systematic investigated and the interference in MS2 scans were estimated by the intensity of contaminated y1 product ions. An algorithm was thus developed to correct reporter ion ratios of tryptic peptides.

Project description:Isobaric chemical tag labeling (e.g., iTRAQ and TMT) is a commonly used approach in quantitative proteomics research. Typically, peptides are covalently labeled with isobaric chemical tags, and quantification is enabled through detection of low-mass reporter ions generated after MS2 fragmentation. Recently, we have introduced and optimized a platform for intact protein-level TMT labeling that demonstrated >90% labeling efficiency in complex sample with top-down proteomics. Higher-energy collisional dissociation (HCD) is a commonly utilized fragmentation method for peptide-level isobaric chemical tag labeling because it produces accurate reporter ion intensities and avoids the loss of low mass ions. HCD energies have been optimized for peptide-level isobaric chemical tag labeling; however, fragmentation energies have not been systematically evaluated for TMT-labeled intact proteins for both protein identification and quantitation. In this study, we report a systematic evaluation of normalized HCD fragmentation energies on TMT-labeled HeLa lysate with top-down proteomics. Our results suggested that reporter ions often require higher collisional energy for higher ion intensities while most of intact proteins fragment when normalized HCD energies are between 30% and 50%. We further demonstrated that a stepped HCD fragmentation scheme with energies between 30 and 50% resulted in the optimized quantitation and identification for TMT-labeled intact HeLa protein lysate by providing average reporter ion intensity as > 3.60 E4 and average PrSM as > 1000 PrSM counts with high confidence.

Project description:Alzheimer’s disease (AD) is characterized by an early, asymptomatic phase (AsymAD) in which individuals exhibit amyloid-beta (Aβ) plaque accumulation in the absence of clinically detectable cognitive decline. Here we report an unbiased multiplex quantitative proteomic and phosphoproteomic analysis using tandem mass tag (TMT) isobaric labeling of human post-mortem cortex (n=27) across pathology-free controls, AsymAD and symptomatic AD individuals. With off-line high-pH fractionation and liquid chromatography coupled to tandem mass spectrometry (LC-MS/MS) on an Orbitrap Lumos mass spectrometer, we identified 11,378 protein groups across three TMT 11-plex batches. Immobilized metal affinity chromatography (IMAC) was used to enrich for phosphopeptides from the same TMT-labeled cases and 51,736 phosphopeptides were identified. Of these, 48,992 were quantified by TMT reporter ions representing 33,652 unique phosphosites. Two reference standards in each TMT 11-plex were included to assess intra- and inter-batch variance at the protein and peptide level. This comprehensive human brain proteome and phosphoproteome dataset will serve as a valuable resource for the identification of biochemical, cellular and signaling pathways altered during AD progression.

Project description:Quantifying proteins based on peptide-coupled reporter-ions is a leading multiplexed quantitative strategy in proteomics that significantly alleviates the problem of ratio distortion caused by peptide co-fragmentation, as commonly observed in other reporter-ion based approaches, such as TMT and iTRAQ. Fueled by improvements in mass spectrometry and data processing, data-independent acquisition (DIA) is an attractive alternative to data dependent acquisition (DDA) due to its better reproducibility. While multiplexed labeling is widely used in DDA, it is rarely used in DIA, presumably because current approaches lead to more complex MS2 spectra or to a reduction in quantification accuracy and precision. Herein, we present a versatile acetyl-alanine-glycine (Ac-AG) tag which conceals quantitative information in isobarically labeled peptides and reveals it upon tandem MS in the form of peptide-coupled reporter-ions. Since the peptide-coupled reporter-ion is precursor-specific while fragment ions of the peptide backbone originating from different labeling channels are same, the Ac-AG tag is compatible with both the widely adopted DDA as well as with the DIA mode. By isolating the monoisotopic peak of the precursor ion in DDA, intensities of the peptide-coupled reporter-ions simply represent the relative ratios between constituent samples. While in DIA, the ratio can be inferred after deconvoluting peptide-coupled reporter-ions. The proteome quantification capability of the Ac-AG tag was demonstrated by triplex labeling of a yeast proteome spiked with bovine serum albumin (BSA) over a 10-fold dynamic range. Within a complex proteomics background, the BSA spiked at 1:5:10 ratios was detected at ratios of 1.00 : 4.87 : 10.13 in DDA and 1.16 : 5.20 : 9.64 in DIA.

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:The uploaded data are described within "Screen Identifies DYRK1B Network as Mediator of Transcription Repression on Damaged Chromatin". In short, peptides from RPE1 epithelial cells with either normal expression of DYRK1B, over expression, of knockout of the kinase were TMT11 plex labeled and enriched by tandem phosphopeptide enrichment.

Project description:Quantitative analysis of proteomes across multiple time points, organelles, and perturbations is essential for understanding both fundamental biology and disease states. The development of isobaric tags (e.g. TMT) have enabled the simultaneous measurement of peptide abundances across several different conditions. These multiplexed approaches are promising in principle because of advantages in throughput and measurement quality. However, in practice existing multiplexing approaches suffer from key limitations. In its simple implementation (TMT-MS2), measurements are distorted by chemical noise leading to poor measurement accuracy. The current state-of-the-art (TMT-MS3) addresses this, but requires specialized quadrupole-iontrap-Orbitrap instrumentation. The complement reporter ion approach (TMTc) produces high accuracy measurements and is compatible with many more instruments, like quadrupole-Orbitraps. However, the required deconvolution of the TMTc cluster leads to poor measurement precision. Here, we introduce TMTc+, which adds the modeling of the MS2-isolation step into the deconvolution algorithm. The resulting measurements are comparable in precision to TMT-MS3/MS2. The improved duty cycle, and lower filtering requirements make TMTc+ more sensitive than TMT-MS3 and comparable with TMT-MS2. At the same time, unlike TMT-MS2, TMTc+ is exquisitely able to distinguish signal from chemical noise even outperforming TMT-MS3. Lastly, we compare TMTc+ to quantitative label-free proteomics of total HeLa lysate and find that TMTc+ quantifies 7.8k versus 3.9k proteins in a 5-plex sample. At the same time the median coefficient of variation improves from 13% to 4%. Thus, TMTc+ advances quantitative proteomics by enabling accurate, sensitive, and precise multiplexed experiments on more commonly used instruments.