Premature loss of telomere repeats underlies the pathologies of inherited bone marrow failure syndromes. Over the past decade, researchers have mapped genetic lesions responsible for the accelerated loss of telomere repeats. Haploinsufficiencies in the catalytic core components of the telomere maintenance enzyme telomerase, as well as genetic defects in telomerase holoenzyme components responsible for enzyme stability, have been linked to hematopoietic failure pathologies. Frequencies of these disease-associated alleles in human populations are low. Accordingly, the diseases themselves are rare. On the other hand, single nucleotide polymorphisms of telomerase enzyme components are found with much higher frequencies, with several non-synonymous SNP alleles observed in 2-4% of the general population. Importantly, recent advents of molecular diagnostic techniques have uncovered links between telomere length maintenance deficiencies and an increasing number of pathologies unrelated to the hematopoietic system. In these cases, short telomere length correlates to tissue renewal capacities and predicts clinical progression and disease severity. To the authors of this review, these new discoveries imply that even minor genetic defects in telomere maintenance can culminate in the premature failure of tissue compartments with high renewal rates. In this review, we discuss the biology and molecules of telomere maintenance, and the pathologies associated with an accelerated loss of telomeres, along with their etiologies. We also discuss single nucleotide polymorphisms of key telomerase components and their association with tissue renewal deficiency syndromes and other pathologies. We suggest that inter-individual variability in telomere maintenance capacity could play a significant role in chronic inflammatory diseases, and that this is not yet fully appreciated in the translational research of pharmacogenomics and personalized medicine.
Chronic obstructive pulmonary disease (COPD) is a disorder of accelerated lung aging. Multiple pieces of evidence support that the aging biomarker short telomeres, which can be caused by mutations in telomerase reverse transcriptase (TERT), contribute to COPD pathogenesis. We hypothesized that short telomere risk-associated single nucleotide polymorphisms (SNPs) in TERT, while not able to drive COPD development, nonetheless modify the disease presentation. We set out to test the SNP carrying status in a longitudinal study of smokers with COPD and found that rapid decline of FEV1 in lung function was associated with the minor allele of rs61748181 (adjusted odds ratio 2.49, p = 0.038). Biochemical evaluation of ex vivo engineered human cell models revealed that primary cells expressing the minor allele of rs61748181 had suboptimal telomere length maintenance due to reduced telomerase catalytic activity, despite having comparable cell growth kinetics as WT-TERT expressing cells. This ex vivo observation translated clinically in that shorter telomeres were found in minor allele carriers in a sub-population of COPD patients with non-declining lung function, over the 5-year period of the longitudinal study. Collectively, our data suggest that functional TERT SNPs with mild catalytic defects are nonetheless implicated in the clinical presentation of COPD.
Telomere biology disorders (TBDs) refer to a spectrum of tissue degenerative disorders caused by genetic mutations in telomere biology genes. Most patients with TBDs suffer from telomere maintenance defects secondary to telomerase deficiency. While the highly penetrant mutations in the telomerase reverse transcriptase (TERT) gene that drive disease onset and progression of TBDs are relatively rare, there exist several single nucleotide polymorphisms (SNPs) in TERT that have been linked to various diseases in the TBD spectrum. In this study, we investigated the biochemical properties of five TERT variants. In an ex vivo cell model, we found that primary human fibroblasts expressing nonsynonymous TERT SNPs had comparable cell growth kinetics to primary cells expressing WT-TERT, while a parallel vector control expressing-cell line entered replicative senescence. At the molecular level, primary cells expressing the minor alleles of two of the five TERT variants (A279T, ΔE441) had replication-dependent loss of telomere length. In an in vitro primer extension assay, these two variants showed reduced telomerase nucleotide addition processivity. Together, our data suggested that selective, common TERT variants could be revealed to harbour telomere maintenance defects, leading to a plausible explanation for their observed associations to telomere biology disorders.
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