Project description:As novel technologies allow for a substantial increase in the number of LC-MS run per day, proteomics sample preparation appears as new bottle-neck for throughput. To overcome this limitation, we introduce a novel strategy for positive pressure 96-well filter-aided sample preparation (PF96) on a commercial positive pressure solid-phase extraction unit allowing for a 5-fold reduction in lab-time. Similar as conventional FASP, PF96 allows for robust processing of protein amounts between 3 and 60 µg, with higher analyte recovery observed for higher protein loads (36-60 µg). Notably, even lower amounts can be processed reproducibly, but at the expense of loss of peptide signal intensity (~40 % of signal intensity for 3 µg compared to 60 µg ) - more pronounced for peptides of higher retention time (reversed phase) and higher share of the hydrophobic amino acids F, L, M, W. Processing of 40 technical replicates of mouse heart tissue lysate highlights its reproducibility with Pearson Product-Moment correlations of r=0.9992 and r=0.9891 on protein and peptide level, respectively, which is similar to the reproducibility of LC-MS for replicate injections of identical samples.

Project description:Here, we report the development of two RNA-seq library preparation protocols that increase the throughput and decrease the cost of converting RNA to cDNA libraries compatible for sequencing on high-throughput platforms. BaM-seq allows for early barcoding of samples such that many biological samples can be processed simultaneously. TBaM-seq allows for enrichment of target RNAs to decrease the required sequencing depth. Both methods are able to accurately measure gene expression changes with high technical reproducibility and agreement with gold standard, lower throughput approaches.

Project description:Here, we report the development of two RNA-seq library preparation protocols that increase the throughput and decrease the cost of converting RNA to cDNA libraries compatible for sequencing on high-throughput platforms. BaM-seq allows for early barcoding of samples such that many biological samples can be processed simultaneously. TBaM-seq allows for enrichment of target RNAs to decrease the required sequencing depth. Both methods are able to accurately measure gene expression changes with high technical reproducibility and agreement with gold standard, lower throughput approaches.

Project description:High-throughput has become a substantial need in many omics investigations. In proteomics the sample preparation workflow consists of multiple steps, whereby with each additional manual step more bias is added to the sample. Especially for label-free quantification experiments this drastically reduces the outcome. Here, a positive pressure workstation was evaluated to increase automation of sample preparation and decrease input time and consumables. The semi-automated workflow with the Resolvex A200 workstation including the sorbents Maestro and WWP2 performed equally well to the routinely conducted manual workflow, with similar technical variability in MSMS-based identifications of peptides and proteins. Both sorbents produced highly reproducible results within a range of 10-300 µg of peptide starting material. A direct, on-column sample preparation using the NBE columns - without conditioning and equilibration of the sorbents -works generally robust, whereby consumables and time are drastically reduced.

Project description:Reproducibility assessment is essential in extracting reliable scientific insights from high-throughput experiments. Inconsistency between technical replicates poses a challenge, particularly evident in NGS technologies based on immunoprecipitations, where the need for reproducibility in peak identification is a well-acknowledged limitation. While the Irreproducibility Discovery Rate (IDR) method has been instrumental in assessing reproducibility, its standard implementation is constrained to handling only two replicates. In the current era of steadly growing sample sizes, facilitated by multiplexing and reduced sequencing costs, highly performing methods that handle any number of replicates are desirable.

Project description:Major advances have been made to develop an automated universal 384-well plate sample preparation platform with high reproducibility and adaptability for extraction of proteins from cells within a culture plate. An in-solution digest strategy is employed to generate peptides from the extracted proteins for LC-MS analysis in the 384-well plate. Method evaluation utilized HeLa cells cultured in the 384-well plate ranging from 500 – 10,000 cells. Digestion efficiency was excellent in comparison to the commercial digest peptides standard with minimal sample loss while improving sample preparation throughput by 20 – 40 fold. Analysis of six human cell types, which included two primary cell samples identified and quantified approximately 4,000 proteins for each sample in a single LC-MS/MS injection with as little as 100 – 10,000 cells depending on cell type demonstrating universality of the platform. Implementation of the comprehensive 384-well format protocol for processing cells to clean digested peptides enables large-scale biomarker validation and compound screening through proteomic analysis.

Project description:Major advances have been made to improve the sensitivity of mass analyzers, spectral quality, and the speed of data processing enabling more comprehensive proteome discovery and quantitation. While focus has recently begun shifting toward robust proteomic sample preparation efforts, a high throughput proteomics sample preparation is still lacking. We report the development of a highly-automated universal 384-well plate sample preparation platform with high reproducibility and adaptability for extraction of proteins from cells within a culture plate. Digestion efficiency was excellent in comparison to a commercial digest peptide standard with minimal sample loss while improving sample preparation throughput by 20- to 40-fold (<1 min/sample for entire process from cells to clean peptides). Analysis of six human cell types, which included two primary cell samples, identified and quantified approximately 4,000 proteins for each sample in a single HPLC-MS/MS injection with only 100 -10,000 cells, thus demonstrating universality of the platform.

Project description:Five aliquots of the same RNA sample were labeled and hybridized in parallel to the L. vannamei microarray, in order to assess the technical reproducibility of the tool Keywords: technical validation

Project description:Global proteome analysis of paired colorectal cancer sample using LC-MS/MS

Project description:Hydrogel-based tissue expansion combined with mass spectrometry (MS) offers an emerging spatial proteomics approach. Here, we present a filter-aided expansion proteomics (FAXP) strategy for spatial proteomics analysis of archived formalin-fixed paraffin-embedded (FFPE) specimens. Compared to our previous ProteomEx method, FAXP employed a customized tip device to enhance both the stability and throughput of sample preparation, thus guaranteeing the reproducibility and robustness of the workflow. FAXP achieved a 14.5-fold increase in volumetric resolution. It generated over 8 times higher peptide yield and a 255% rise in protein identifications while reducing sample preparation time by 50%. We also demonstrated the applicability of FAXP using human colorectal FFPE tissue samples. Furthermore, for the first time, we achieved bona fide single-subcellular proteomics under image guidance by integrating FAXP with laser capture microdissection.