Flow cytometric measurement of telomere length (original) (raw)
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Cytometry, 2002
Telomeres containing noncoding DNA repeats at the end of the chromosomes are essential for chromosomal stability and are implicated in regulating the replication and senescence of cells. The gradual loss of telomere repeats in cells has been linked to aging and tumor development and methods to measure telomere length are of increasing interest. At least three methods for measuring the length of telomere repeats have been described: Southern blot analysis and quantitative fluorescence in situ hybridization using either digital fluorescence microscopy (Q-FISH) or flow cytometry (flow-FISH). Both Southern blot analysis and Q-FISH have specific limitations and are time-consuming, whereas the flow-FISH technique requires relatively few cells (10(5)) and can be completed in a single day. A further advantage of the flow-FISH method is that data on the telomere length from individual cells and subsets of cells (lymphocytes and granulocytes) can be acquired from the same sample. In order to ...
Anticancer research
The end of eukaryotic chromosomes terminates with nucleoprotein structures called telomeres. They insure several functions including capping the end of the chromosomes, ensuring their stability and protecting them from end-to-end fusion and preventing the activation of the DNA damage checkpoints. A flow-FISH methodology, i.e. quantitative fluorescence in situ hybridization (Q-FISH) in combination with flow cytometry, has been developed in our laboratory in order to estimate telomere length in three human cancer cell lines: K-562 (chronic myelogenous leukaemia), IM-9 (multiple myeloma) and 1301 (T cell lymphoblastic leukaemia). Telomeres were visualised after hybridisation with FITC-labelled PNA (Peptide Nucleic Acid) probes. We evaluated the most critical steps of the flow-FISH protocol to ensure reproducibility. Different methodological set ups were compared. Three fixation procedures (ethanol 80%, methanol 80% and formaldehyde 4%) were tested besides different fixation times (15 m...
The Journal of Pathology, 2003
Loss of telomere repeat sequences occurs after each cell division and telomere shortening has been implicated in cellular senescence. The measurement of telomere length might therefore assess the lifespan of a cell. The aim of this study was to set up and validate a technique enabling the assessment of telomere length on tissue sections. Quantitative fluorescence in situ hybridization (Q-FISH) with telomeric probes was performed on smears and sections from cell preparations or human tissues. The mean fluorescence intensity of telomere spots (FI/spot) was automatically quantified by image analysis. Telomeric restriction fragment (TRF) length was assessed by Southern blotting. There was a positive significant correlation between telomere length, as assessed by Q-FISH, and TRF length determined by Southern blotting in corresponding samples (p < 0.01, r = 0.6 for tissue and p < 0.01, r = 0.79 for cells). FI/spot was higher on smears than on sections, but pairwise comparison showed a significant correlation both for cells and for tissues (r = 0.77, p < 0.001 for cells and p ≤ 0.01, r = 0.64 for tissue). Finally, since telomere length is expected to shorten with age, FI/spot was assessed in liver samples according to the age of patients: a negative correlation was demonstrated (r = 0.76, p < 0.01). Inter-assay variation was 7% for Q-FISH performed on tissue sections and 12% on touch preparations. This study shows that Q-FISH can be performed with confidence on fixed frozen tissue sections in order to assess telomere length. It is an easy, accurate, and reproducible in situ method for assessing telomeres in the context of cell type and tissue architecture.
Robust measurement of telomere length in single cells
Proceedings of the National Academy of Sciences, 2013
Measurement of telomere length currently requires a large population of cells, which masks telomere length heterogeneity in single cells, or requires FISH in metaphase arrested cells, posing technical challenges. A practical method for measuring telomere length in single cells has been lacking. We established a simple and robust approach for single-cell telomere length measurement (SCT-pqPCR). We first optimized a multiplex preamplification specific for telomeres and reference genes from individual cells, such that the amplicon provides a consistent ratio (T/R) of telomeres (T) to the reference genes (R) by quantitative PCR (qPCR). The average T/R ratio of multiple single cells corresponded closely to that of a given cell population measured by regular qPCR, and correlated with those of telomere restriction fragments (TRF) and quantitative FISH measurements. Furthermore, SCT-pqPCR detected the telomere length for quiescent cells that are inaccessible by quantitative FISH. The reliability of SCT-pqPCR also was confirmed using sister cells from two cell embryos. Telomere length heterogeneity was identified by SCT-pqPCR among cells of various human and mouse cell types. We found that the T/R values of human fibroblasts at later passages and from old donors were lower and more heterogeneous than those of early passages and from young donors, that cancer cell lines show heterogeneous telomere lengths, that human oocytes and polar bodies have nearly identical telomere lengths, and that the telomere lengths progressively increase from the zygote, two-cell to four-cell embryo. This method will facilitate understanding of telomere heterogeneity and its role in tumorigenesis, aging, and associated diseases. single cell analysis | stem cell | cell senescence
Nature Protocols, 2010
In this protocol we describe a method to obtain telomere length parameters using Southern blots of terminal restriction fragments (TRFs). We use this approach primarily for epidemiological studies that examine leukocyte telomere length. However, the method can be adapted for telomere length measurements in other cells whose telomere lengths are within its detection boundaries. After extraction, DNA is inspected for integrity, digested, resolved by gel electrophoresis, transferred to a membrane, hybridized with labeled probes and exposed to X-ray film using chemiluminescence. Although precise and highly accurate, the method requires a considerable amount of DNA (3 μg per sample) and it measures both the canonical and noncanonical components of telomeres. The method also provides parameters of telomere length distribution in each DNA sample, which are useful in answering questions beyond those focusing on the mean length of telomeres in a given sample. A skilled technician can measure TRF length in ∼130 samples per week.
Biological Procedures Online, 2020
Background A large number of studies have suggested a correlation between the status of telomeres and disease risk. High-throughput quantitative fluorescence in situ hybridization (HT Q-FISH) is a highly accurate telomere measurement technique that can be applied to the study of large cell populations. Here we describe the analytical performance testing and validation of Telomere Analysis Technology (TAT®), a laboratory-developed HT Q-FISH-based methodology that includes HT imaging and software workflows that provide a highly detailed view of telomere populations. Methods TAT was developed for the analysis of telomeres in peripheral blood mononuclear cells (PBMCs). TAT was compared with Terminal Restriction Fragment (TRF) length analysis, and tested for accuracy, precision, limits of detection (LOD) and specificity, reportable range and reference range. Results Using 6 different lymphocyte cell lines, we found a high correlation between TAT and TRF for telomere length (R2 ≥ 0.99). T...
Cytometry. Part A : the journal of the International Society for Analytical Cytology, 2004
Telomeres are specialized nucleoprotein structures at chromosome ends that undergo dynamic changes after each cell cycle. Understanding the mechanisms of telomere dynamics is critically dependent on the ability to accurately measure telomere length in a cell population of interest. Techniques such as Southern blot, which measures average telomere length, and quantitative fluorescence in situ hybridization (Q-FISH), which can estimate telomere length in individual chromosomes, are limited in their capacity to determine the distribution of cells with differing telomere lengths in a given cell population. We employed flow-FISH to determine whether mouse and human cell lines exhibit subpopulations of cells with differing telomere lengths. Our analysis showed that at least one of four analyzed mouse cell lines had two subpopulations of cells with differing telomere lengths. Differences in telomere length between subpopulations of cells were significant, and we term this phenomenon TELEFL...
A quantitative PCR method for measuring absolute telomere length
Biological Procedures Online, 2011
We describe a simple and reproducible method to measure absolute telomere length (aTL) using quantitative realtime polymerase chain reaction (qPCR). This method is based on the Cawthon method for relative measurement of telomere length (TL) but modified by introducing an oligomer standard to measure aTL. The method describes the oligomer standards, the generation of the standard curve and the calculations required to calculate aTL from the qPCR data. The necessary controls and performance characteristics of the assay are described in detail and compared relative to other methods for measuring TL. Typical results for this assay for a variety of human tissue samples are provided as well as a troubleshooting schedule. This method allows high throughput measurement of aTL using small amounts of DNA making it amenable for molecular epidemiological studies. Compared to the traditional relative TL qPCR assays, the aTL method described in this protocol enables a more direct comparison of results between experiments within and between laboratories.
Cytometry Part A, 2016
Abnormal telomere lengths have been linked to cancer and other hematologic disorders. Determination of mean telomere content (MTC) is traditionally performed by Southern blotting and densitometry, giving a mean telomere restriction fragment (TRF) value for the total cell population studied. Here, we compared a quantitative Polymerase Chain Reaction approach (qPCR) and a flow cytometric approach, fluorescence in situ hybridization (Flow-FISH), to evaluate telomere content distribution in total patient peripheral blood mononuclear cells or specific cell populations. Flow-FISH is based on in situ hybridization using a fluorescein-labeled peptide nucleic acid (PNA) (CCCTAA) 3 probe and DNA staining with propidium iodide. We showed that both qPCR and Flow-FISH provide a robust measurement, with Flow-FISH measuring a relative content longer than qPCR at a single cell approach and that TRF2 fluorescence intensity did not correlate with MTC. Both methods showed comparable telomere content reduction with age, and the rate of relative telomere loss was similar.