Project description:Background Mass spectrometry-based proteomics has become a powerful tool for the identification and quantification of proteins from a wide variety of biological specimens. To date, the majority of studies utilizing tissue samples have been carried out on prospectively collected fresh frozen or optimal cutting temperature (OCT) embedded specimens. However, such specimens are often difficult to obtain, in limited in supply, and clinical information and outcomes on patients are inherently delayed as compared to banked samples. Annotated formalin fixed, paraffin embedded (FFPE) tumor tissue specimens are available for research use from a variety of tissue banks, such as from the surveillance, epidemiology and end results (SEER) registries' residual tissue repositories. Given the wealth of outcomes information associated with such samples, the reuse of archived FFPE blocks for deep proteomic characterization with mass spectrometry technologies would provide a valuable resource for population-based cancer studies. Further, due to the widespread availability of FFPE specimens, validation of specimen integrity opens the possibility for thousands of studies that can be conducted worldwide. Methods To examine the suitability of the SEER repository tissues for proteomic and phosphoproteomic analysis, we analyzed 60 SEER patient samples, with time in storage ranging from 7 to 32 years; 60 samples with expression proteomics and 18 with phosphoproteomics, using isobaric labeling. Linear modeling and gene set enrichment analysis was used to evaluate the impacts of collection site and storage time. Results All samples, regardless of age, yielded suitable protein mass after extraction for expression analysis and 18 samples yielded sufficient mass for phosphopeptide analysis. Although peptide, protein, and phosphopeptide identifications were reduced by 50, 20 and 76% respectively, from comparable OCT specimens, we found no statistically significant differences in protein quantitation correlating with collection site or specimen age. GSEA analysis of GO-term level measurements of protein abundance differences between FFPE and OCT embedded specimens suggest that the formalin fixation process may alter representation of protein categories in the resulting dataset. Conclusions These studies demonstrate that residual FFPE tissue specimens, of varying age and collection site, are a promising source of protein for proteomic investigations if paired with rigorously verified mass spectrometry workflows. <ul><li>Dataset imported into MassIVE from <a href="https://cptac-data-portal.georgetown.edu/study-summary/S042">https://cptac-data-portal.georgetown.edu/study-summary/S042</a> on 12/08/21</li></ul>

Project description:This experiment contains the RNA-Seq samples only. Formalin-fixed, paraffin-embedded (FFPE) tissues are an invaluable resource for clinical research. However, nucleic acids extracted from FFPE tissues are fragmented and chemically modified making them challenging to use in molecular studies. We analysed 23 fresh-frozen (FF), 35 FFPE and 38 paired FF/FFPE specimens, representing six different human tissue types (bladder, prostate and colon carcinoma; liver and colon normal tissue; reactive tonsil) in order to examine the potential use of FFPE samples in next-generation sequencing (NGS) based retrospective and prospective clinical studies. Two methods for DNA and three methods for RNA extraction from FFPE tissues were compared and were found to affect nucleic acid quantity and quality. DNA and RNA from selected FFPE and paired FF/FFPE specimens were used for exome and transcriptome analysis. Preparations of DNA Exome-Seq libraries was more challenging (29.5 % success) than that of RNA-Seq libraries, presumably because of modifications to FFPE tissue-derived DNA. Libraries could still be prepared from RNA isolated from two-decade old FFPE tissues. Data were analysed using the CLC Bio Genomics Workbench and revealed systematic differences between FF and FFPE tissue-derived nucleic acid libraries. In spite of this, pairwise analysis of DNA Exome-Seq data showed concordance for 70-80 % of variants in FF and FFPE samples stored for fewer than three years. RNA-Seq data showed high correlation of expression profiles in FF/FFPE pairs (Pearson Correlations of 0.90 +/- 0.05), irrespective of storage time (up to 244 months) and tissue type. A common set of 1,494 genes was identified with expression profiles that were significantly different between paired FF and FFPE samples irrespective of tissue type. Our results are promising and suggest that NGS can be used to study FFPE specimens in both prospective and retrospective archive-based studies in which FF specimens are not available.

Project description:Archival Formalin-Fixed Paraffin Embedded (FFPE) tissue represents an abundant and more easily transferable source of patient tissue than live specimens. Furthermore cancer FFPE tissue deposited at major cancer research institutes is often paired with survival data increasing the value of biomarker and prediction based research from these samples. However the known fragility of RNA and artifacts introduced through the processes of tissue preservation and storage introduce the possibility of unfaithful RNA expression signatures from these sources. To evaluate this we established an RNA isolation, library prepration and data analysis pipeline at Oregon Health and Science University to evaluate the fidelity of RNA expression profiles from FFPE tissues utilizing gene and pathway expression comparisons between ER positive and ER negative samples in archival FFPE specimens compared to those obtained from public available data sets of fresh specimens.

Project description:<p>The Biospecimen Pre-analytical Variables (BPV) Program is a National Cancer Institute-sponsored study to systematically assess the effects of pre-analytical factors on the molecular profile of biospecimens. A robust biospecimen collection infrastructure was established to prospectively collect biospecimens using rigorous standard operating procedures to control for most variables while introducing experimental conditions to study specific biospecimen handling issues, including the cold ischemic time (delay to formalin fixation), time in formalin, freezing methods, and storage temperatures and durations. RNA and DNA from biospecimens collected under these conditions was analyzed on multiple molecular platforms. The potential effects of these pre-analytical conditions on protein integrity and detection of metabolites were also examined. Data from this study will be used to develop evidence-based biospecimen standard operating procedures and best practices for fit-for-purpose collection, processing, and storage of biospecimens.</p> <p>The BPV Cohort is utilized in the following dbGaP substudies. To view genotypes, analysis, expression data, other molecular data, and derived variables collected in these substudies, please click on the following sub-studies below or in the &#34;Substudies&#34; box located on the right hand side of this top-level study page phs001304 BPV Cohort. The substudy links will be active once they are released by dbGaP.</p> <p> <ol> <li>Preanalytical Impacts on Global Metabolite Profiling - plasma (MassSpec by Metabolon) This study was to evaluate the impact of the storage temperature (s) (-80&#176;C and LN2 vapor) and the length of storage on human plasma quality using LC-MS/MS (liquid-chromatography-mass spectrometry/mass spectrometry) based global metabolite profiling. The study includes 240 plasma samples collected from 40 donors.</li> <li>Investigate the effect of the delay to fixation on the proteome and phosphoproteome -FFPE (MassSpec by Caprion). The study is to do proteome and phosphoproteome analysis on Delay to fixation was carried out using FFPE tumor samples from colon and ovarian cancer patients comparing 2, 3, and 12hr delay to fixation to the 1hr time point. The study includes 100 samples 20 donors.</li> <li>Investigate the effect of storage conditions of tumor specimens on the proteome and phosphoproteome profiling- Frozen tissue and plasma (MassSpec by Caprion). The study was to evaluate the effects of storage conditions on tumor specimens. Plasma samples from 40 cancer patients stored at two different temperatures (-80&#176;C and LN2) for a given period (0-2, 6-8, and 12-14 months) were evaluated. Frozen kidney tumor samples from 20 patients were compared for effects of different snap frozen (dry ice vs. LN2) and storage temperatures (-80&#176;C and LN2). The study includes 100 tissue and 240 plasma samples from 60 donors.</li> <li>Preanalytical Impacts on Genomic Sequencing by Next Generation Sequencing (NGS) technology (mRNA/miRNA and WES by Expression Analysis). The goal of the study is to determine the effects of cold ischemic delay-to-fixation (4 time points) and formalin preservation (FFPE) on the nature and quality of genomic profiles using the matched freshly frozen sample as the gold standard, which including WES, RNAseq. The study includes 395 samples from 37 donors.</li> <li>Preanalytical Impacts on Copy Number Variation (CNV) Detection by aCGH technology (aCGH by Georgetown University). This study was to use aCGH to evaluate the effect of variation in cold ischemia time and time in formalin fixation on CNV in DNA extracted from kidney cancer specimens. The study includes 235 samples from 40 donors.</li> <li>Evaluation of frozen conditions on mRNA profiling by TaqMan assay (mRNA expression by Georgetown University). This study was to utilize gene expression profiling, using custom TaqMan arrays, to compare the molecular profiles of RNA from frozen tumor samples collected using two freezing methods (dry ice or LN2), two storage temperatures (-80&#176;C or LN2 vapor), as well as Optimal Cutting Temperature (OCT) compound and non-OCT embedded. The study includes 100 samples from 20 donors.</li> <li>mRNA signature for stratification by cold ischemia time (mRNA expression by IBBL). The study was to determine the effects of cold ischemic time (delay-to-fixation) and formalin preservation (FFPE) on mRNA detection by Taqman assay using tumor tissue specimens from kidney, colon and ovarian cancer patients. There are160 samples from 40 donors.</li> </ol> </p> <p><b>The Biospecimen PV cohort is utilized in the following dbGaP individual studies.</b> To view molecular data, and derived variables collected in these individual studies, please click on the following individual studies below or in the "Sub-studies" box located on the right hand side of this top-level study page <a href="study.cgi?study_id=phs001304">phs001304</a> Biospecimen PV cohort. <ul> <li><a href="study.cgi?study_id=phs001634">phs001634</a> CIT mRNA</li> <li><a href="study.cgi?study_id=phs001635">phs001635</a> CNV aCGH</li> <li><a href="study.cgi?study_id=phs001636">phs001636</a> Fixation Delay</li> <li><a href="study.cgi?study_id=phs001637">phs001637</a> Global Metabolite Profiling</li> <li><a href="study.cgi?study_id=phs001638">phs001638</a> mRNA TaqMan</li> <li><a href="study.cgi?study_id=phs001639">phs001639</a> NGS</li> <li><a href="study.cgi?study_id=phs001640">phs001640</a> Tumor Storage</li> </ul> </p>

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:Purpose: Only a limited number of genetic studies have been performed in primary central nervous system lymphomas (PCNSL), partly due to the rarity of the tumors and the very limited amount of available tissue. In this report, we present the first molecular characterization of copy-number abnormalities (CNA) of newly diagnosed PCNSL by array-based comparative genomic hybridization in formalin fixed paraffin embedded (FFPE) specimens and compare the results with matched frozen tumor specimens. Experimental design: We performed array-based comparative genomic hybridization (aCGH) in FFPE tissues from PCNSL. Results were compared with matched paired frozen tumors. Results: Our analysis confirmed the good to fair quality and reliability of the data generated from limited amounts of tumoral FFPE tissue. Overall, all PCNSL cases were characterized by highly complex karyotypes with a median of 23 copy-number abnormalities (CNA) per patient (range 17-47). Overall, 20 chromosomal regions were recurrently found in more than 40% of cases. Deletions of 6p21, 6q, 9p21.3 and gain of 12q12-q24.33 were the commonest CNA. Other minimal affected regions were defined, and novel recurrent CNAs affecting single genes were identified in 3q26.32 (TBL1XR1) and 8q12.1 (TOX). Conclusions: The results obtained are encouraging. Larger archival tissue collections can now be analyzed in order to complement the still fragmented knowledge we have of the genetic basis of the PCNSL. We included samples from 7 PCNSL patients. In 6 out of these 7 PCNSL patients (cases B – G), aCGH experiments were performed in DNA samples obtained from both snap-frozen and FFPE tissues for assay quality comparative purposes. In the remaining sample (case A), only frozen sample was analyzed.

Project description:Background and Aims Formalin-fixed, paraffin-embedded (FFPE) tissue is the most commonly available form of archived clinical specimens, which are often stored as thin sections on glass slides. RNA isolated from such archived section (AS) of FFPE tissue is more degraded compared to freshly cut (FC) FFPE section because of prolonged air exposure. In this study, we evaluated performance of transcriptome profiling-based disease classification in AS-FFPE tissue. Methods Genome-wide gene-expression profiles of AS-FFPE tissues of 83 hepatocellular carcinoma (HCC) and 47 liver cirrhosis samples were generated by using whole-genome DASL assay (Illumina), and compared with the profiles previously produced by using FC tissue sections from the same FFPE blocks. Quality of the profiles and performance of gene signature-based class prediction were systematically evaluated. Results RNA quality and assay reproducibility of AS-FFPE RNA were comparable to intermediate ~ poor quality FC-FFPE samples (R2 as high as 0.93). Gene-expression signal was detected in lower number of probes in AS FFPE samples compared to FC-FFPE samples (proportion of probes with present signal (%P-call): 10%~60% and 70%~90% in AS- and FC-FFPE profiles, respectively). Based on %P-call quality threshold of 20%, 64/88 (77%) HCC and 37/48 (77%) liver profiles were judged as having relatively good quality data with comparable inter-sample correlation. Inter-sample correlation coefficient, as a measure to detect outlier profiles due to poor RNA quality, was also lower in AS-FFPE (0.4~0.9) compared to FC-FFPE (0.6~1.0). In the genome-wide profiling analysis, previously identified molecular subclasses of HCC tumors were reproduced in 67/83 (81%) samples, which was improved to 43/48 (90%) samples when we focused on statistically confident predictions (p<0.05). A 186-gene prognostic signature in liver cirrhosis was reproduced in 32/47 (68%) samples, which was slightly improved to 11/16 (69%) when focused on statistically significant predictions. Conclusions We observed decay of genome-wide transcriptional profiles in AS-FFPE tissues in quantitative manner. However, disease classification was still possible, which suggests potential of AS-FFPE material for clinical diagnosis and prognosis.

Project description:Meningiomas are the most commonly reported primary intracranial tumor in dogs and humans. Canine meningiomas closely resemble human meningiomas in histological appearance as well as biological behavior. Because of the similarities between canine and human meningiomas, dogs have been proposed as models and surrogates for studying and treating human cancers including meningioma. However, little is known about specific pathways and individual genes that are involved in the development and progression of canine meningioma. In addition, there is a paucity of suitable fresh material available for studies of differential expression (DE) of genes in cases of veterinary neoplasia. We report here the use of formalin-fixed paraffin embedded (FFPE) specimens as much as a decade old, to provide RNA suitable for transcriptome analysis using next-generation sequencing (NGS). RNA was extracted from 13 canine meningiomas – 12 from (FFPE) and one flash-frozen. These represented 6 grade I and 7 grade II/III. RNA was also collected from flash-frozen meningeal tissue (arachnoid) from 3 control dogs. RNA from FFPE was of sufficient quality to successfully identify 125 significantly DE genes, the majority of which were related to oncogenic processes. 12 genes (AQP1, BMPER, FBLN2, FRZB, MEDAG, MYC, PAMR1, PDGFRL, PDPN, PECAM1, PERP, ZC2HC1Cc) were validated using qPCR. Among the DE genes were oncogenes, tumor suppressors, transcription factors, VEGF-related genes, and members of the WNT pathway. Our work demonstrates that RNA of sufficient quality can be extracted from FFPE samples to provide biologically relevant transcriptome analyses using a NGS technique, such as RNA-seq.

Project description:ER-positive tumor data was derived by RNA-sequencing of formalin-fixed paraffin-embedded specimens (FFPE) collected from 44 women diagnosed with ER+ and progesterone receptor-positive but HER2 negative (ER+/PR+/HER2-) breast cancer at the Karmanos Cancer Institute. According to a pathologist review, all tumor specimens were invasive cancer with 70% or greater cancer cell content. Patients had not received neoadjuvant cancer therapy, nor were they treated for diabetes with systemic drugs (e.g., metformin) before surgical resec- tion. Following manufacturer instructions, the Recoverall Nucleic Acid Isolation Kit for FFPE Tissue (Ambion, Austin, TX) was used to isolate RNA. Quantitation and fragmentation analysis were performed using the NanoDrop 2000 spectrophotometer (Thermo Fisher Scientific, Waltham, MA) and Bioanalyzer 2100 and RNA 6000 Nano kit (Agilent Technologies, Santa Clara, CA). A Qubit fluorometric assay (Thermo Fisher Scientific) was used to quantitate and equalize dsDNA prepared using the Truseq RNA Access library preparation kit (Illu- mina, San Diego, CA). Libraries were randomized, indexed, multiplexed, and paired end sequenced (200 cycles total) on an Illumina Nextseq500. Bioinformatic quality control was done using the FastQC software (v0.11.4), adapter and low-quality reads were removed using Trimmomatic v0.36. FPKM normalization and aligning were done using TopHat v2.1.1.

Project description:The majority of clinical cancer specimens are preserved as formalin-fixed paraffin-embedded (FFPE) samples. In order for clinical molecular tests to have wide reaching impact, they must be applicable to FFPE material. Accurate quantitative measurements of RNA derived from FFPE specimens is challenging due to low yields and high amounts of degradation. Here we present FFPEcap-seq, a method specifically designed for sequencing capped 5’ ends of RNA derived from FFPE samples. FFPEcap-seq combines enzymatic enrichment of 5’ capped RNAs with template switching to create sequencing libraries. We find that FFPEcap-seq can faithfully capture mRNA expression levels in FFPE specimens while also detecting enhancer RNAs that arise from distal regulatory regions. FFPEcap-seq is a fast and straightforward method for making high quality 5’ end RNA-seq libraries from FFPE-derived RNA.