Project description:Analysis of HeLa cells at 24 hours after transfection with wild type miR-1, miR-124, miR-181 versus control transfected HeLa cells. Results were compared to protein down-regulation at 48 hours measured by SILAC-MS. Analysis of HeLa cells at 24 hours after transfection with wild type miR-1, miR-124, miR-181 versus control transfected HeLa cells. Results were compared to protein down-regulation at 48 hours measured by SILAC-MS.

Project description:Protein expression is regulated by production and degradation of mRNAs and proteins, but their specific relationships remain unknown. We combine measurements of protein production and degradation and mRNA dynamics to build a quantitative genomic model of the differential regulation of gene expression in LPS stimulated mouse dendritic cells. Changes in mRNA abundance play a dominant role in determining most dynamic fold changes in protein levels. Conversely, the preexisting proteome of proteins performing basic cellular functions is remodeled primarily through changes in protein production or degradation, accounting for over half of the absolute change in protein molecules in the cell. Thus, the proteome is regulated by transcriptional induction of novel cellular functions and remodeling of preexisting functions through the protein life cycle. Mouse primary dendritic cells were treated with LPS or mock stimulus and profiled over a 12-hour time course. Cells were grown in M-labeled SILAC media, which was replaced with H-labeled SILAC media at time 0. Aliquots were taken at 0, 0.5, 1, 2, 3, 4, 5, 6, 9, and 12 hours post-stimulation and added to equal volumes of a master mix of unlabeled (L) cells for the purpose of normalization. RNA-Seq was performed at 0, 1, 2, 4, 6, 9, and 12 hours post-stimulation.

Project description:Parallel reaction monitoring (PRM) on quadrupole-orbitrap mass spectrometers has a limited multiplexing capacity which depends heavily on the reproducibility of peptide retention times. To overcome these limitations, we aimed to establish a data acquisition mode that allows retention-time-independent massive multiplexing on quadrupole-orbitrap mass spectrometers. The presented method is based on data-dependent acquisition and is called pseudo-PRM. In principle, high-intensity stable isotope-labeled peptides are used to trigger the repeated fragmentation of the corresponding light peptides. In this way, pseudo-PRM data can be analyzed like normal PRM data with Skyline. We tested pseudo-PRM for the target detection from yeast, human cells, and serum, and assessed the quantification accuracy/precision and sensitivity. Moreover, we analyzed multiplexing of more than 1,000 targets in a single pseudo-PRM run. Finally, we applied pseudo-PRM to quantify vaccinia virus proteins during infection, verifying that pseudo-PRM presents an alternative method for multiplexed target profiling on quadrupole-orbitrap mass spectrometers.

Project description:Stable isotope labeling of peptides is the basis for numerous mass spectrometry-based quantification strategies. Isobaric tagging and metabolic labeling, namely TMT and SILAC, are among the most widely used techniques for relative protein quantification. Here we report an alternative, precursor-based quantification method using non-isobaric TMT variants: TMT0 (TMTzero) and shTMT (super-heavy TMT). We term this strategy mTMT (mass difference tandem mass tagging), as these TMT variants differ by 11 mass units; yet, peptides labeled with these reagents co-elute, analogous to SILAC-labeled sample analysis. As proof-of-concept, we profiled the proteomes of two cell lines that are frequently used in neuroscience studies, SH-SY5Y and SVGp12, using mTMT and standard SILAC-labeling approaches. We show similar numbers of quantified proteins and peptides using each method with highly correlated fold changes between workflows. We conclude that mTMT is a suitable alternative for precursor-based protein quantification.

Project description:THP-1 macrophages were infected with four strains of Mycobacterium tuberculosis to study the temporal dynamics of newly synthesized proteins in the secretome. Temporal snapshots of secretome reflect the macrophage response to pathogenicity which in combination with intracellular events, completes the disease picture. However, such studies are compromised by limitations of quantitative proteomics. Metabolic labeling by SILAC allows a 3-plex experiment while isobaric chemical labeling by iTRAQ/TMT allows up to 8 to 10-plex respectively. This makes studying temporal proteome dynamics an intangible and elusive proposition. We have developed a new variant of hyperplexing method, combining triplex SILAC with 6-plex iTRAQ to achieve 18-plex quantitation in a single MS run. THP-1 macrophages were infected with H37Ra, H37Rv, BND433 and JAL2287 and the newly synthesized secreted host proteins were studied over six temporal frame still 30 hours post infection, at a difference of 4 hours each. For quantitation, the strains were encoded with two sets of triple SILAC- H37Ra & H37Rv in one and BND433 & JAL2287 in another with a control in each. These sets were then iTRAQ labeled to encode for temporal profiles across six time points in 6-plex iTRAQ. Effectively a 36-plex design with 4 replicates of each set, these experiments were completed within few days on the mass spectrometer. Using MaxQuant and in house developed tools and pipelines, we have analysed the data to map the temporal and strain specific dynamics of newly synthesized proteins in host. Hyperplexing enables large scale spatio-temporal systems biology studies where large number of samples can be processed simultaneously and in quantitative manner.

Project description:This study identifies the transcriptomic effects of YBX3 depletion after 2 days of siRNA knockdown. Unspecific siRNA and untreated cells were used as controls. The cells were grown in SILAC media and the effects on protein levels were measured by mass spectrometry. Also an eCLIP (E-MTAB-5888) experiment was performed to identify RNA targets of YBX3.

Project description:Enzyme-catalyzed proximity labeling (PL) with biotin is a novel approach to map organelle compartmentalization and protein interaction networks in living cells. Here, we present a new method based on semi-permeabilized yeast cells and the enzyme APEX2, an engineered ascorbate peroxidase. Combined with stable isotope labeling by amino acids in cell culture (SILAC), we demonstrate proteomic mapping of a membrane-enclosed and a semi-open compartment, the mitochondrial matrix and the nucleus. APEX2 PL revealed nuclear proteins that were previously not identified by conventional techniques. One of these, the Yer156C protein, is highly conserved but of unknown function. In follow-up experiments using quantitative PL with Yer156C-APEX2 we discovered an array of Yer156C interactors. Thus, our approach establishes APEX2 PL as an effective and versatile tool that complements the powerful methods palette for the model system yeast.

Project description:These is a collection of chromatin proteomics experiments that make up the 80 "in-house" biological conditions covered by ProteomeHD (see publication for more details). All experiments use SILAC, resulting in 80 SILAC ratios comparing the impact of various drugs (estradiol, TSA, hydroxytamoxifen, etc.), growth factors (TNFalpha) or other treatments (ionizing radiation) on chromatin composition. For a more detailed description see the Supplementary Table S2 of the publication, which can also be downloaded from here.

Project description:The proteomic and phosphoproteomic characterization of bladder cancer samples was performed following a guanidine isothyocyanate method and using a super-SILAC spike-in standard for confident quantification. The phosphorylated peptides were enriched through a titanium dioxide protocol for the investigation of signaling cascades within cancer specimens.

Project description:In this study we use a SILAC based quantitative proteomics approach to examine the ERK-responsive phosphoproteome in mouse embryonic stem cells.