Project description:Formalin-fixed, paraffin-embedded (FFPE) tissue samples are an invaluable resource to study the underlying molecular mechanisms of the diseases and when coupled with laser capture microdissection (LCM, isolation of sub histological regions of the tissue sections is readily obtained for further analysis. LCM-based FFPE tissue proteomics is gaining clinicopathological significance particularly in biomarker discovery driven research, beyond its conventional morphology-based application in laboratory diagnosis. Processing of laser capture microdissected tissue sections can be challenging for quantitative proteomic analysis due to lower amount of protein retrieved and losses during the sample processing. A robust, streamlined and automated sample preparation workflow for efficient processing of large cohort of LCM samples which is a primary requisite for biomarker type of studies is needed. Here, we propose a new sample processing workflow for processing of FFPE samples and enable scalable, automated extraction of clean peptides from unprocessed or H&E-stained FFPE tissue sections for deep bottom-up protein profiling and quantification.

Project description:Most human tumor tissues that are obtained for pathology and diagnostic purposes are forma-lin-fixed and paraffin embedded (FFPE). To perform quantitative proteomics of FFPE samples, paraffin has to be removed and formalin-induced crosslinks have to be reversed prior to prote-olytic digestion. A central component of almost all deparaffinization protocols is xylene, a toxic and highly flammable solvent that has been reported to negatively affect protein extraction and quantitative proteome analysis. Here, we present a ‘green’ xylene-free protocol for accel-erated sample preparation of FFPE tissues based on paraffin-removal with hot water. Com-bined with tissue homogenization using disposable micropestles and a modified protein aggre-gation capture (PAC) digestion protocol, our workflow enables streamlined and reproducible quantitative proteomic profiling of FFPE tissue. Label free quantitation of FFPE cores from human ductal breast carcinoma in-situ (DCIS) xenografts with a volume of only 0.79 mm3 showed a high correlation between replicates (r2=0.992) with a median %CV of 16.9%. Im-portantly, this small volume is amenable to tissue micro array (TMA) cores and core needle bi-opsies, while our results and the easy-of-use indicate that a further downsizing is feasible. Fi-nally, our FFPE workflow does not require costly equipment and can be established in every standard clinical laboratory.

Project description:Formalin-fixed, paraffin-embedded (FFPE) tissues are an invaluable resource for retrospective studies but protein extraction and subsequent sample processing steps have shown to be challenging for mass spectrometry (MS) analysis. Streamlined high-throughput sample preparation workflows are essential for efficient peptide extraction from complex clinical specimens such as fresh frozen tissues or FFPE. Overall, proteome analysis has gained significant improvements in the instrumentation, acquisition methods, sample preparation workflows and analysis pipelines yet even the most recent FFPE workflows remain complex and are not readily scalable. Here, we present an optimized workflow for Automated Sonication-free Acid-assisted Proteome (ASAP) extraction from FFPE sections. ASAP enables efficient protein extraction from FFPE specimens achieving similar proteome coverage as established methods using time in equipment-heavy sonication-based methods at reduced sample processing time. The broad applicability of ASAP on archived pediatric tumor FFPE specimens resulted in high-quality data with increased proteome coverage and quantitative reproducibility. Our study demonstrates the practicality and superiority of the ASAP workflow as a streamlined, time and cost-effective pipeline for high-throughput FFPE proteomics of clinical specimens.

Project description:We performed Visium CytAssist (10X), GeoMx DSP (Nanostring) and Chromium Flex (10X Genomics) full transcriptome profiling on Breast Cancer (BC), Lung Cancer (LC) and diffuse large B cell lymphoma (DLBCL) samples from archival FFPE blocks. We explore the data quality across blocks with different storage times and DV200 values for all the three methods. We compared the cell type signature purity between ST methods Visium and GeoMx by utilising pathology annotations and scRNAseq. For the Visium and Chromium methods with a large number of data points we explored the heterogeneity between tissues. Finally, we demonstrate the discovery of patient-specific tumor-TME interactions across all three methods.

Project description:Pathology archives contain vast resources of clinical material in the form of formalin-fixed paraffin embedded (FFPE) tissue samples. Due to the methods of tissue fixation and storage, the integrity of DNA and RNA available from FFPE tissue is compromised, meaning obtaining informative data regarding epigenetic, genomic and expression alterations can be challenging. Here we have investigated the utility of repairing damaged DNA derived from FFPE tumours prior to single nucleotide polymorphism (SNP) arrays for whole genome DNA copy number analysis. To investigate whether repairing the DNA might improve performance in SNP array assay, we used the DNA Restore protocol from Illumina as a pre-treatment step prior to applying the DNA to the Infinium assay using the Human CytoSNP FFPE-12v2.1 arrays. DNA was extracted from FFPE samples spanning five decades involving tumor material obtained from surgical specimens and post-mortems. Various aspects of the protocol were assessed, including the method of DNA extraction, the role of Quality Control quantitative PCR in predicting sample success and the effect of DNA restoration on assay performance, data quality and the prediction of copy number aberrations (CNAs). In total 8 cases were analysed in this experiment, involving 43 SNP arrays of tumour and matched normal DNA samples, replicates and other control arrays.

Project description:High-throughput and streamlined workflows are essential in clinical proteomics for standardized processing of samples originating from a variety of sources, including frozen tissue, FFPE tissue, or blood. To reach this goal, we have implemented single-pot solid-phase-enhanced sample preparation (SP3) on a liquid handling robot for automated processing (autoSP3) of tissue lysates in a 96-well format, performing unbiased protein purification and digestion delivering peptides that can be directly analyzed by LCMS. AutoSP3 eliminates hands-on time and minimizes the risk of error, and we show it reduces the protein quantification variability, and improves longitudinal performance and reproducibility. We demonstrate the distinguishing ability of autoSP3 to process low-input samples, reproducibly quantifying 500-1000 proteins from 100-1000 cells (<100 ng protein). Furthermore we applied it to process a cohort of clinical FFPE pulmonary adenocarcinoma (ADC) samples, and recapitulate their separation into known histological growth patterns based on proteome profiles. Collectively, autoSP3 provides a generic, scalable, and cost-effective pipeline for routine and standardized proteomic sample processing that should enable reproducible proteomics in broad range of clinical and non-clinical applications.

Project description:We performed Visium CytAssist (10X), GeoMx DSP (Nanostring) and Chromium Flex (10X Genomics) full transcriptome profiling on Breast Cancer (BC), Lung Cancer (LC) and diffuse large B cell lymphoma (DLBCL) samples from archival FFPE blocks. We explore the data quality across blocks with different storage times and DV200 values for all the three methods. We compared the cell type signature purity between ST methods Visium and GeoMx by utilising pathology annotations and scRNAseq. For the Visium and Chromium methods with a large number of data points we explored the heterogeneity between tissues. Finally, we demonstrate the discovery of patient-specific tumor-TME interactions across all three methods.

Project description:In recent years, the use of FFPE tissue in gene expression microarray (GEM) studies has become a topic of increased interest, because pathology departments worldwide contain an invaluable source of biological disease-specific FFPE- tissue material. Thus far, some published studies on FFPE tissue consider the processed tissue amenable, whereas other studies assert that the tissue is not useful in GEM. In general, pancreatic tissue is known to contain large amounts of nucleases, leading to high turnover rates and degradation of RNA in the tissue. This characteristic, in combination with FFPE processing time and its effect on the tissue, does not make FFPE pancreatic tissue the obvious choice for GEM. The basis for using FFPE pancreatic tissue in RNA-based assays seems suboptimal. Previous GEM studies have used different FFPE tissue types, but GEM studies on FFPE pancreatic tissue have not been published. In most studies, the tissue was specially processed for use with GEMs. Here we demonstrate the usefulness of randomly archived FFPE pancreatic tissues for GEMs. For this purpose we included FFPE pancreatic tissue from patients with congenital hyperinsulinism or insulinoma; In these patients, pancreas resection is performed when medical treatment is not adequate to prevent hyperinsulinemic hypoglycemia or when patients do not respond to medical treatment. Although ribonuclease-rich, we obtained biologically relevant and disease-specific, significant genes; cancer-related genes and genes involved in a) the regulation of insulin secretion and synthesis, b) amino acid metabolism, and c) calcium ion homeostasis. This application may extend the possibilities of gene expression studies to many tissue types, especially in rare diseases, for which fresh frozen tissue is not readily available.

Project description:FFPE tissue samples have long been considered challenging for sc-/sn-RNA sequencing assays. In this study, we developed a novel snRNA-seq workflow, snPATHO-seq, for FFPE tissue samples utilising isolated high-quality nuclei from FFPE samples and 10X Genomics FLEX chemistry. The snPATHO-seq demonstrated consistent performance with the established 10X Genomics 3' assay. In addition, it allows more accurate single-nucleus and spatial transcriptomics integration with the FFPE Visium dataset generated from the same FFPE block. We envision this new protocol can facilitate the transcriptomic interpretation of millions of FFPE archives generated and simplify the sample collection process and data generation.

Project description:FFPE tissue samples have long been considered challenging for sc-/sn-RNA sequencing assays. In this study, we developed a novel snRNA-seq workflow, snPATHO-seq, for FFPE tissue samples utilising isolated high-quality nuclei from FFPE samples and 10X Genomics FLEX chemistry. The snPATHO-seq demonstrated consistent performance with the established 10X Genomics 3' assay. In addition, it allows more accurate single-nucleus and spatial transcriptomics integration with the FFPE Visium dataset generated from the same FFPE block. We envision this new protocol can facilitate the transcriptomic interpretation of millions of FFPE archives generated and simplify the sample collection process and data generation.