Direct comparison of flow-FISH and qPCR as diagnostic tests for telomere length measurement in humans.

Telomere length measurement is an essential test for the diagnosis of telomeropathies, which are caused by excessive telomere erosion. Commonly used methods are terminal restriction fragment (TRF) analysis by Southern blot, fluorescence in situ hybridization coupled with flow cytometry (flow-FISH), and quantitative PCR (qPCR). Although these methods have been used in the clinic, they have not been comprehensively compared. Here, we directly compared the performance of flow-FISH and qPCR to measure leukocytes' telomere length of healthy individuals and patients evaluated for telomeropathies, using TRF as standard. TRF and flow-FISH showed good agreement and correlation in the analysis of healthy subjects (R(2) = 0.60; p<0.0001) and patients (R(2) = 0.51; p<0.0001). In contrast, the comparison between TRF and qPCR yielded modest correlation for the analysis of samples of healthy individuals (R(2) = 0.35; p<0.0001) and low correlation for patients (R(2) = 0.20; p = 0.001); Bland-Altman analysis showed poor agreement between the two methods for both patients and controls. Quantitative PCR and flow-FISH modestly correlated in the analysis of healthy individuals (R(2) = 0.33; p<0.0001) and did not correlate in the comparison of patients' samples (R(2) = 0.1, p = 0.08). Intra-assay coefficient of variation (CV) was similar for flow-FISH (10.8 ± 7.1%) and qPCR (9.5 ± 7.4%; p = 0.35), but the inter-assay CV was lower for flow-FISH (9.6 ± 7.6% vs. 16 ± 19.5%; p = 0.02). Bland-Altman analysis indicated that flow-FISH was more precise and reproducible than qPCR. Flow-FISH and qPCR were sensitive (both 100%) and specific (93% and 89%, respectively) to distinguish very short telomeres. However, qPCR sensitivity (40%) and specificity (63%) to detect telomeres below the tenth percentile were lower compared to flow-FISH (80% sensitivity and 85% specificity). In the clinical setting, flow-FISH was more accurate, reproducible, sensitive, and specific in the measurement of human leukocyte's telomere length in comparison to qPCR. In conclusion, flow-FISH appears to be a more appropriate method for diagnostic purposes.

p53 pathway activation by telomere attrition in X-DC primary fibroblasts occurs in the absence of ribosome biogenesis failure and as a consequence of DNA damage.

BACKGROUND: Dyskeratosis congenita (DC) is a rare inherited bone marrow failure syndrome with high clinical heterogeneity. Various mutations have been reported in DC patients, affecting genes that code for components of H/ACA ribonucleoproteins, proteins of the telomerase complex and components of the shelterin complex. OBJECTIVES: We aim to clarify the role of ribosome biogenesis failure in senescence induction in X-DC since some studies in animal models have reported a decrease in ribosome biogenesis as a major role in the disease. METHODS: Dyskerin was depleted in normal human fibroblasts by expressing two DKC1 shRNAs. Common changes in gene expression profile between these dyskerin-depleted cells and X-DC fibroblasts were analyzed. RESULTS: Dyskerin depletion induced early activation of the p53 pathway probably secondary to ribosome biogenesis failure. However, the p53 pathway in the fibroblasts from X-DC patients was activated only after an equivalent number of passes to AD-DC fibroblasts, in which telomere attrition in each division rendered shorter telomeres than control fibroblasts. Indeed, no induction of DNA damage was observed in dyskerin-depleted fibroblasts in contrast to X-DC or AD-DC fibroblasts suggesting that DNA damage induced by telomere attrition is responsible for p53 activation in X-DC and AD-DC fibroblasts. Moreover, p53 depletion in senescent DC fibroblasts rescued their proliferative capacity and reverted the morphological changes produced after prolonged culture. CONCLUSIONS: Our data indicate that ribosome biogenesis do not seem to play an important role in dyskeratosis congenita, conversely increasing DNA damage and activation of p53 pathway triggered by telomere shortening is the main activator of cell senescence.

Defects in mTR stability and telomerase activity produced by the Dkc1 A353V mutation in dyskeratosis congenita are rescued by a peptide from the dyskerin TruB domain.

BACKGROUND: The predominant X-linked form of dyskeratosis congenita results from mutations in dyskerin, a protein required for ribosomal RNA modification that is also a component of the telomerase complex. We have previously found that expression of an internal fragment of dyskerin (GSE24.2) rescues telomerase activity in X-linked dyskeratosis congenita (X-DC) patient cells. MATERIALS AND METHODS: Here, we have generated F9 mouse cell lines expressing the most frequent mutation found in X-DC patients, A353V and study the effect of expressing the GSE24.2 cDNA or GSE24.2 peptide on telomerase activity by TRAP assay, and mTERT and mTR expression by Q-PCR. Point mutation in GSE24.2 residues were generated by site-directed mutagenesis. RESULTS: Expression of GSE24.2 increases mTR and to a lesser extent mTERT RNA levels, and leads to recovery of telomerase activity. Point mutations in GSE24.2 residues known to be highly conserved and crucial for the pseudouridine-synthase activity of dyskerin abolished the effect of the peptide. Recovery of telomerase activity and increase in mTERT levels were found when the GSE24.2 peptide purified from bacteria was introduced into the cells. Moreover, mTR stability was also rescued by transfection of the peptide GSE24.2. DISCUSSION: These data indicate that supplying GSE24.2, either from a cDNA vector, or as a peptide, can reduces the pathogenic effects of Dkc1 mutations and could form the basis of a novel therapeutic approach.