Lung Tissue Storage: Optimizing Conditions for Future Use in Molecular Research (original) (raw)
Related papers
2009
Background: The reliability of gene expression profiling-based technologies to detect transcriptional differences representative of the original samples is affected by the quality of the extracted RNA. It strictly depends upon the technique that has been employed. Hence, the present study aimed at systematically comparing silica-gel column (SGC) and guanidine isothiocyanate (GTC) techniques of RNA isolation to answer the question which technique is preferable when frozen, long-term stored or fresh lung tissues have to be evaluated for the downstream molecular analysis. Methods: Frozen lungs (n = 3) were prepared by long-term storage (2.5 yrs) in-80°C while fresh lungs (n = 3) were harvested and processed immediately. The purity and quantification of RNA was determined with a spectrophotometer whereas the total amounted copy numbers of target sequences were determined with iCycler detection system for assessment of RNA intactness (28S and 18S) and fragment sizes, i.e. short (GAPDH-3' UTR), medium (GAPDH), and long (PBGD) with 200 bp, 700 bp, and 1400 bp distance to the 3'ends of mRNA motif, respectively. Results: Total yield of RNA was higher with GTC than SGC technique in frozen as well as fresh tissues while the purity of RNA remained comparable. The quantitative reverse transcriptase-polymerase chain reaction data revealed that higher mean copy numbers of 28S and a longer fragment (1400 bp) were obtained from RNA isolated with SGC than GTC technique using fresh as well as frozen tissues. Additionally, a high mean copy number of 18S and medium fragment (700 bp) were obtained in RNA isolated with SGC technique from fresh tissues, only. For the shorter fragment, no significant differences between both techniques were noticed. Conclusion: Our data demonstrated that although the GTC technique has yielded a higher amount of RNA, the SGC technique was much more superior with respect to the reliable generation of an intact RNA and effectively amplified longer products in fresh as well as in frozen tissues.
Assessing Gene Expression in Lung Subcompartments Utilizing In Situ RNA Preservation
Toxicological Sciences, 2003
The mechanisms of toxicant-mediated lung injury and repair are influenced by the considerable spatial heterogeneity that exists within the conducting airways of the lungs. As a result of this heterogeneity, significant differences and similarities in gene expression are observed throughout lung subcompartments. RNAbased technologies such as real-time reverse transcription polymerase chain reaction (real-time RT-PCR) and cDNA microarray analysis of gene expression provide valuable clues to understanding the mechanisms of toxicant-induced injury. Isolating RNA from lung subcompartments has previously involved considerable time and labor-intensive processes that limit the number of animals that could be processed in a day. The aim of this study was to determine if intact, high-quality RNA could be preserved in situ over a period of time to delay the need to immediately perform site-specific lung subcompartment microdissections and RNA isolations. Two hours after 1-nitronaphthalene treatment, rat lungs were inflated with and stored in RNA preservation solution and stored at 4°C for 7 days. RNA was isolated from the lung subcompartments isolated by microdissection. After 7 days of storage, the RNA was intact, of high quality, and could be used for real-time RT-PCR to examine heterogeneous gene expression in the lung subcompartments. In summary, this simplified technique of in situ RNA preservation and site-specific lung subcompartment microdissection allows the isolation of intact, high-quality RNA that may be used with molecular RNA-based technologies that will significantly accelerate our understanding of pulmonary injury and repair mechanisms.
RNA isolation from precision-cut lung slices (PCLS) from different species
BMC Research Notes, 2017
Background: Functional 3D organ models such as precision-cut lung slices (PCLS) have recently captured the attention of biomedical research. To enable wider implementation in research and development, these new biologically relevant organ models are being constantly refined. A very important issue is to improve the preparation of high-quality RNA (ribonucleic acid) from PCLS for drug discovery and development of new therapies. Gene expression analysis at different levels is used as an important experimental readout. Genome-wide analysis using microarrays is mostly applied for biomarker selection in disease models or in comprehensive toxicological studies. Specific biomarker testing by reverse transcriptase quantitative polymerase chain reaction (RTqPCR) is often used in efficacy studies. Both applications require high-quality RNA as starting material for the generation of reliable data. Additionally, a small number of slices should be sufficient for satisfactory RNA isolation to allow as many experimental conditions as possible to be covered with a given tissue sample. Unfortunately, the vast amount of agarose in PCLS impedes RNA extraction according to the standard procedures. Results: We established an optimized protocol for RNA isolation from PCLS from humans, rats, mice, marmosets, and rhesus macaques based on the separation of lysis and precipitation steps and a magnetic-bead cleanup procedure. The resulting RNA is of high purity and possesses a high degree of integrity. There are no contaminations affecting RTqPCR efficiency or any enzymatic step in sample preparation for microarray analysis. Conclusions: In summary, we isolated RNA from PCLS from different species that is well suited for RTqPCR and for microarray analysis as downstream applications.
Postmortem RNA and Protein Stability in Perinatal Human Lungs
Diagnostic Molecular Pathology, 2002
The availability of fetal and neonatal lung tissue is an invaluable resource to elucidate the molecular regulation of human lung development. In this study, we have investigated the mRNA and protein stability of perinatal lung tissues treated with RNAlater (Ambion Inc., Austin, TX) or snap frozen in liquid nitrogen (LN 2). Lung samples were obtained from 25 consecutive perinatal autopsies of live-born and stillborn infants (median gestational age, 23 weeks) with various clinical presentations. Treatment of lung tissue with RNAlater yielded more total RNA and protein than LN 2 freezing. The integrity of RNA, assessed by spectrophotometry and gel electrophoresis, was equivalent between both tissue preservation methods, and both methods produced RNA suitable for reverse transcriptasepolymerase chain reaction analysis of representative genes (actin and surfactant protein-B [SP-B]). Similarly, the protein integrity of RNAlater-treated tissues was equivalent to that of LN 2-frozen tissues, as judged by Western blot analysis of SP-B/actin protein expression. Although the total yield was similar in live-born, nonmacerated stillborn and macerated stillborn infants, only RNA and protein from live-born or nonmacerated stillborn infants was suitable for subsequent molecular analyses. Within the 41-hour range studied, the duration of the postmortem interval did not affect the yield or integrity of RNA and protein with either tissue preservation method. In summary, high-quality RNA and protein, suitable for routine molecular analyses, can be obtained from postmortem lung tissue from live-born and nonmacerated stillborn infants, even with prolonged postmortem intervals. RNAlater is equivalent, if not superior, to LN 2 for preservation of postmortem RNA and protein in developing human lungs.
Impact of Collection and Storage of Lung Tumor Tissue on Whole Genome Expression Profiling
The Journal of Molecular Diagnostics, 2012
Gene expression profiling could assist in revealing biomarkers of lung cancer prognosis and progression. The handling of biological samples may strongly influence global gene expression, a fact that has not been addressed in many studies. We sought to investigate the changes in gene expression that may occur as a result of sample processing time and conditions. Using Illumina Human WG-6 arrays, we quantified gene expression in lung carcinoma samples from six patients obtained at chest opening before and immediately after lung resection with storage in RNAlater [T1a (CO) and T1b (LR) ], after receipt of the sample for histopathology, placed in RNAlater [T2a (HP) ]; snap frozen [T2b (HP.SF) ]; or snap frozen and stored for 1 week [T2c (HP.SFA) ], as well as formalin-fixed, paraffin-embedded (FFPE) block samples. Sampling immediately after resection closely represented the tissue obtained in situ, with only 1% of genes differing more than twofold [T1a (CO) versus T1b (LR) ]. Delaying tissue harvest for an average of 30 minutes from the operating theater had a significant impact on gene expression, with approximately 25% of genes differing between T1a (CO) and T2a (HP) . Many genes previously identified as lung cancer biomarkers were altered during this period. Examination of FFPE specimens showed minimal correlation with fresh samples. This study shows that tissue collection immediately after lung resection with conservation in RNAlater is an optimal strategy for gene expression profiling.
PubMed, 1996
The lung is composed of a complex assemblage of more than 40 different cell types. Therefore, investigative techniques that rely on samples derived from whole lung homogenates, whether for biochemical measurements of metabolism or the analysis of gene expression, are inherently insensitive to cell type or region-specific differences. Microdissection has previously been successful for defining region-specific metabolic activity in the lung. Tissues obtained by this technique exhibit good viability and permit reproducible enzyme activity measurements. In this paper, a technique for isolating RNA from lung subcompartments obtained by microdissection is described. The method is straight forward and results in high quality RNA that can be used to quantify specific mRNAs in microscopically selected lung subcompartments by complementary DNA or RNA hybridization techniques. This technique provides a significant increase in sensitivity over techniques based on whole lung homogenates because RNA contributed by relevant lung subcompartments is enriched. The high sensitivity of the method makes it feasible to compare differences in mRNA expression 1) within different regions of the lung in the same animal, 2) in the same region in different animals and between different species, and 3) between susceptible and nonsusceptible sites in conditions of focal lung injury.
BMC research notes, 2014
Establishing methods for secure long term storage of RNA is critical to realizing the promise of biobanks in biomedical research. Here, we describe the results of yearly analyses of the same set of umbilical cord and adult whole blood RNA collected in Tempus Blood RNA tubes and stored at -80 °C, over a period of up to six years. We systematically investigated the effects of long-term storage of samples (75 Tempus tubes form three adult donors and 30 Tempus tubes from three cord blood donors) on the RNA quality and transcript stability of six selected genes (CDKN1A, FOS, IL1B, IL8, MYC and TP53). This is the first systematic study of both cord and adult blood samples stored for many years. The RNA purity and integrity, expressed as RIN-values, were stable up to six years of storage, and there were no storage-related deleterious effects on RNA purity. There were limited intra- and inter-individual variations in RNA yields; however, no consistent trend of decreasing RNA yield was obser...
Journal of Histochemistry & Cytochemistry, 2006
Microarrays have been used to simultaneously monitor the expression of thousands of genes from biological samples, an approach that can potentially uncover previously unrecognized functions of genes. Microarray analyses can rarely be conducted retrospectively because of the requirement for RNA to be obtained from fresh or unfixed frozen tissues. Archived pathology specimens would need to be used for retrospective analyses, and these are typically preserved as formalin-fixed, paraffin-embedded (FFPE) tissue. Formalin-fixed tissues have been shown to yield compromised RNA compared with that obtained from frozen tissue. To begin to assess the performance of RNA extracted from FFPE samples on a microarray format, we compared RNA from a model system of pelleted lipopolysaccharidestimulated human bone marrow stromal cells that were snap frozen with RNA from FFPE cells. RNA integrity and Affymetrix quality control parameters were assessed, and differentially regulated genes were analyzed w...
Quality assessment of RNA in long-term storage: The All Our Families biorepository
PLOS ONE, 2020
Background The All Our Families (AOF) cohort study is a longitudinal population-based study which collected biological samples from 1948 pregnant women between May 2008 and December 2010. As the quality of samples can decline over time, the objective of the current study was to assess the association between storage time and RNA (ribonucleic acid) yield and purity, and confirm the quality of these samples after 7–10 years in long-term storage. Methods Maternal whole blood samples were previously collected by trained phlebotomists and stored in four separate PAXgene Blood RNA Tubes (PreAnalytiX) between 2008 and 2011. RNA was isolated in 2011 and 2018 using PAXgene Blood RNA Kits (PreAnalytiX) as per the manufacturer’s instruction. RNA purity (260/280), as well as RNA yield, were measured using a Nanodrop. The RNA integrity number (RIN) was also assessed from 5–25 and 111–130 months of storage using RNA 6000 Nano Kit and Agilent 2100 BioAnalyzer. Descriptive statistics, paired t-test...