Use of formalin-fixed paraffin-embedded tumor tissue as a DNA source in molecular epidemiological studies of pediatric CNS tumors

DNA isolated from formalin-fixed paraffin-embedded healthy tissue after 30 years of storage can be used for forensic studies

Tissue formalin fixation and paraffin embedding (FFPE) is a standard method for long-term preservation and morphological and molecular analysis. The aim of this study was to analyze the effect of storage time on the integrity of DNA isolated from three different healthy FFPE tissues. DNA was isolated from FFPE heart, liver and brain tissues obtained from autopsy and archived from 1988 to 2017 using two different methods of DNA isolation: phenol-chloroform-isoamyl alcohol (PCI) and PureLink Genomic DNA Kit. The quantification and purity of DNA was measured spectrophotometrically at 260 nm and 280 nm. The quality of isolated DNA was evaluated by PCR amplification of GPD1 (150 bp), ACTB (262 bp) and RPL4 (407 bp) genes. The histomorphological characteristics of FFPE tissues were not significantly changed during 30 years of storage. Higher yield (272.9 ± 10.3 µg) and purity (A260/280 = 2.05) of DNA was obtained using the PCI method for DNA isolation from FFPE liver tissue. The PCI extraction method showed reproducible and consistent results in PCR amplification of all of three examined genes. The GPD1 gene can be amplified up to 30 years, the ACTB gene in the same samples up to 26 years and the RPL4 gene up to 6 years of storage in FFPE blocks. Although the best yield and purity of isolated DNA (using both isolation methods) was obtained from FFPE liver tissue, the DNA with the most preserved integrity was obtained from brain tissue archived up to 30 years. This is the first report using long-term archived healthy FFPE tissues (up to 30 years) that shows that the DNA isolated from these tissues is of preserved integrity and can be used in molecular autopsy.

Accuracy of Molecular Data Generated with FFPE Biospecimens: Lessons from the Literature

Formalin-fixed and paraffin-embedded (FFPE) tissue biospecimens are a valuable resource for molecular cancer research. Although much can be gained from their use, it remains unclear whether the genomic and expression profiles obtained from FFPE biospecimens accurately reflect the physiologic condition of the patient from which they were procured, or if such profiles are confounded by biologic effects from formalin fixation and processing. To assess the physiologic accuracy of genomic and expression data generated with FFPE specimens, we surveyed the literature for articles investigating genomic and expression endpoints in case-matched FFPE and fresh or frozen human biospecimens using the National Cancer Institute's Biospecimen Research Database (http://biospecimens.cancer.gov/brd). Results of the survey revealed that the level of concordance between differentially preserved biospecimens varied among analytical parameters and platforms but also among reports, genes/transcripts of interest, and tumor status. The identified analytical techniques and parameters that resulted in strong correlations between FFPE and frozen biospecimens may provide guidance when optimizing molecular protocols for FFPE use; however, discrepancies reported for similar assays also illustrate the importance of validating protocols optimized for use with FFPE specimens with a case-matched fresh or frozen cohort for each platform, gene or transcript, and FFPE processing regime. On the basis of evidence published to date, validation of analytical parameters with a properly handled frozen cohort is necessary to ensure a high degree of concordance and confidence in the results obtained with FFPE biospecimens.

Technical reproducibility of single-nucleotide and size-based DNA biomarker assessment using DNA extracted from formalin-fixed, paraffin-embedded tissues

DNA extracted from formalin-fixed, paraffin-embedded (FFPE) tissues has been used in the past to analyze genetic polymorphisms. We evaluated the technical reproducibility of different types of assays for gene polymorphisms using DNA extracted from FFPE material. By using the MassARRAY iPLEX system, we investigated polymorphisms in DPYD (rs1801159 and rs3918290), UMPS (rs1801019), ERCC1 (rs11615), ERCC1 (rs3212986), and ERCC2 (rs13181) in 56 FFPE DNA samples. By using PCR, followed by size-based gel electrophoresis, we also examined TYMS 5' untranslated region 2R/3R repeats and GSTT1 deletions in 50 FFPE DNA samples and 34 DNAs extracted from fresh-frozen tissues and cell lines. Each polymorphism was analyzed by two independent runs. We found that iPLEX biomarker assays measuring single-nucleotide polymorphisms provided consistent concordant results. However, by using FFPE DNA, size-based PCR biomarkers (GSTT1 and TYMS 5' untranslated region) were discrepant in 32.7% (16/49, with exact 95% CI, 19.9%-47.5%; exact binomial confidence limit test) and 4.2% (2/48, with exact 95% CI, 0.5%-14.3%) of cases, respectively, whereas no discrepancies were observed using intact genomic DNA. Our findings suggest that DNA from FFPE material can be used to reliably test single-nucleotide polymorphisms. However, results based on size-based PCR biomarkers, and particularly GSTT1 deletions, using FFPE DNA need to be interpreted with caution. Independent repeated assays should be performed on all cases to assess potential discrepancies.