Project description:Tandem mass tag (TMT) mass spectrometry is a mainstream isobaric chemical labeling strategy for profiling proteomes. Here we present a 29-plex TMT method to combine the 11-plex and 18-plex labeling strategies. The 29-plex method was examined with a pooled sample composed of 1x, 3x and 10x E. coli peptides with 100x human background peptides, which generated two E. coli datasets (TMT11 and TMT18), displaying the distorted ratios of 1.0:1.7:4.2 and 1.0:1.8:4.9, respectively. This ratio compression from the expected 1:3:10 ratios was caused by co-isolated TMT-labeled ions (i.e., noise). Interestingly, the mixture of two TMT sets produced MS/MS spectra with unique features for the noise detection: (i) in TMT11-labeled spectra, TMT18-specific reporter ions (e.g., 135N) were shown as the noise; (ii) in TMT18-labeled spectra, the TMT11/TMT18-shared reporter ions (e.g., 131C) typically exhibited higher intensities than TMT18-specific reporter ions, due to contaminated TMT11-labeled ions in these shared channels. We further estimated the noise levels contributed by both TMT11- and TMT18-labeled peptides, and corrected reporter ion intensities in every spectrum. Finally, the anticipated 1:3:10 ratios were largely restored. This strategy was also validated using another 29-plex sample with 1:5 ratios. Thus the 29-plex method expands the TMT throughput and enhances the quantitative accuracy.

Project description:Systematically optimized the protocol for the newly developed 16-plex TMT Reported a novel 27-plex method to enhance the multiplexity for large-scale proteomic profiling, by combining two sets of distinct isobaric tags (11-plex and 16-plex TMT) based on their disparate mass shifts on modified peptides.

Project description:Isobaric labeling is the most widely used multiplexing quantitative approach in proteomic studies, enabling the comparison of up to 18 samples in a single MS analysis. Expanding the multiplexing capacity is of great necessity for high-throughput proteomic studies. Herein, we establish a novel TAG-TMTpro approach by introducing Ala or Gly residues to peptides prior to TMTpro labeling, which is able to triple the quantitative capacity of TMTpro. We systematically evaluated the Boc-Ala-OSu and Boc-Gly-OSu reaction and optimized the conditions for labeling, side-product elimination and Boc deprotection. We validated the identification and quantification performance using E. coli and HeLa cell lysates. We demonstrated that the TAG-TMTpro approach resulted in good identification reproducibility and reliable quantitative accuracy. The TAG-TMTpro is able to triple the multiplexing capacity of TMTpro reagents, and is a versatile quantitative approach for high-throughput proteomic studies.

Project description:Isobaric labeling empowers proteome-wide expression measurements simultaneously across multiple samples. Here, an expanded set of 16 isobaric reagents based on a proline backbone (TMTpro) is presented. These reagents have similar characteristics to existing TMT reagents but with increased fragmentation efficiency and signal. In a proteome-scale example dataset, we compared eight common cell lines with and without Torin1 treatment with three replicates, quantifying more than 8,800 proteins (mean of 7.5 peptides/protein) per replicate with an analysis time of only 67 min per proteome examined. Finally, we modified the powerful thermal stability assay to examine proteome-wide melting shifts after treatment with DMSO, 1 or 20 ������M staurosporine with five replicates. This new assay identified and dose-stratified the staurosporine binding to 228 cellular kinases in just one, 18-hr experiment. TMTpro reagents allow unprecedented complexity in experimental designs���������all with basically no missing values across the 16 samples and no loss in quantitative integrity.

Project description:Isobaric labeling empowers proteome-wide expression measurements simultaneously across multiple samples. Here, an expanded set of 16 isobaric reagents based on a proline backbone (TMTpro) is presented. These reagents have similar characteristics to existing TMT reagents but with increased fragmentation efficiency and signal. In a proteome-scale example dataset, we compared eight common cell lines with and without Torin1 treatment with three replicates, quantifying more than 8,800 proteins (mean of 7.5 peptides/protein) per replicate with an analysis time of only 67 min per proteome examined. Finally, we modified the powerful thermal stability assay to examine proteome-wide melting shifts after treatment with DMSO, 1 or 20 µM staurosporine with five replicates. This new assay identified and dose-stratified the staurosporine binding to 228 cellular kinases in just one, 18-hr experiment. TMTpro reagents allow unprecedented complexity in experimental designs—all with basically no missing values across the 16 samples and no loss in quantitative integrity.

Project description:Isobaric labeling empowers proteome-wide expression measurements simultaneously across multiple samples. Here, an expanded set of 16 isobaric reagents based on a proline backbone (TMTpro) is presented. These reagents have similar characteristics to existing TMT reagents but with increased fragmentation efficiency and signal. In a proteome-scale example dataset, we compared eight common cell lines with and without Torin1 treatment with three replicates, quantifying more than 8,800 proteins (mean of 7.5 peptides/protein) per replicate with an analysis time of only 67 min per proteome examined. Finally, we modified the powerful thermal stability assay to examine proteome-wide melting shifts after treatment with DMSO, 1 or 20 µM staurosporine with five replicates. This new assay identified and dose-stratified the staurosporine binding to 228 cellular kinases in just one, 18-hr experiment. TMTpro reagents allow unprecedented complexity in experimental designs—all with basically no missing values across the 16 samples and no loss in quantitative integrity.

Project description:Recurrent exertional rhabdomyolysis (RER) develops in 5-10% of Thoroughbred racehorses. High-stress environments, nervous temperament, and diet influence the presentation of RER. RER-susceptibility is associated with alterations in intramuscular Ca2+ regulation with detrimental effects on mitochondria. Our study aims to determine underlying molecular drivers influencing RER-susceptibility by comparing the muscle proteome of control, RER-susceptible, and RER horses treated with dantrolene. Animals used in this study were Thoroughbred mares in race training between episodes of RER.

Project description:Numerous hyperplexing approaches have been developed to meet the demand for large-scale basic and clinical analysis. Currently, the analysis capacity has expanded to up to 54 samples within a single experiment by utilizing different isotopic and isobaric reagent combinations. In this report, we propose a super multiplexed approach to enable the analysis of up-to 102-plex samples within a single experiment. by the combination of our recently developed TAG-TMTpro and TAG-IBT16 labeling. We systematically investigated the identification and quantification performance of the 102-plex approach using the mixtures of E. coli and HeLa peptides. Our results revealed that all analyses demonstrated accurate and reliable quanti-fication performance. The combination of TAG-TMTpro and TAG-IBT16 approaches expands the multiplexing capacity to 102-plex, providing a more multiplexed quantification method for even larger-scale proteomic analysis.

Project description:To investigate functional differences between pluripotent stem cells and somatic cells, we measured protein thermal stability and expression after transitions between cell types using allogenic cell lines. To this purpose, we reprogrammed hFF into human iPSCs and initiated undirected differentiation through formation of EBs during 21 days. We also included human embryonic stem cells (ESC) in order to validate our approach and colon cancer cell line RKO.

Project description:The design and synthesis of a novel proline-reporter-based isobaric Tandem Mass Tag 16 tag set (TMTpro) was carried out and the data uploaded here is a comparison of the performance of the new TMTpro tags with the current commercially available dimethylpiperidine-reporter-based TMT10/11 reagents. Data from 2 experiments are provided.