• Telomerase variants in patients with bone marrow failure syndromes are difficult to categorize as disease-causing or otherwise.

  • DC can derive from triallelic mutations in 2 telomerase genes and epigenetic-like inheritance of short telomeres.

Dyskeratosis congenita (DC) and related diseases are a heterogeneous group of disorders characterized by impaired telomere maintenance, known collectively as the telomeropathies. Disease-causing variants have been identified in 10 telomere-related genes including the reverse transcriptase (TERT) and the RNA component (TERC) of the telomerase complex. Variants in TERC and TERT can impede telomere elongation causing stem cells to enter premature replicative senescence and/or apoptosis as telomeres become critically short. This explains the major impact of the disease on highly proliferative tissues such as the bone marrow and skin. However, telomerase variants are not always fully penetrant and in some families disease-causing variants are seen in asymptomatic family members. As a result, determining the pathogenic status of newly identified variants in TERC or TERT can be quite challenging. Over a 3-year period, we have identified 26 telomerase variants (16 of which are novel) in 23 families. Additional investigations (including family segregation and functional studies) enabled these to be categorized into 3 groups: (1) disease-causing (n = 15), (2) uncertain status (n = 6), and (3) bystanders (n = 5). Remarkably, this process has also enabled us to identify families with novel mechanisms of inheriting human telomeropathies. These include triallelic mutations, involving 2 different telomerase genes, and an epigenetic-like inheritance of short telomeres in the absence of a telomerase mutation. This study therefore highlights that telomerase variants have highly variable functional and clinical manifestations and require thorough investigation to assess their pathogenic contribution.

The telomeropathies are a collection of disorders characterized by impaired telomere maintenance.1,2  The classic example of this is the inherited bone marrow failure (BMF) syndrome dyskeratosis congenita (DC).3  In this disease, patients are diagnosed by the presence of a characteristic triad of mucocutaneous features (abnormal skin pigmentation, nail dystrophy, and oral leukoplakia) which is often seen alongside BMF and other constitutional features which can affect all body systems. The Hoyeraal-Hreidarsson syndrome (HHS) is a particularly severe form of DC characterized by aplastic anemia (AA), immune deficiency, growth retardation, microcephaly, and cerebellar hypoplasia.4 

DC and HHS patients usually have abnormally short telomeres due to variants in genes encoding proteins and an RNA molecule responsible for telomere extension and maintenance.5,6  Human telomeres are composed of thousands of repeats of the hexameric sequence TTAGGG. These chromosomal caps serve to protect genomic DNA from attrition during cell division due to the “end replication problem,”7  which results in the loss of 50 to 100 bp of telomeric DNA during each cycle. When telomeres become critically short, replicative senescence is triggered, halting further divisions of the cell.8  In some stem cells and in the germline, telomere shortening can be compensated by the action of telomerase.9  This ribonucleoprotein complex is composed of 2 key components, the reverse transcriptase (TERT) and the RNA component (TERC). TERT is responsible for lengthening telomeres using the RNA template provided by TERC. In association with proteins of the shelterin complex, telomeres also prevent the chromosome ends from being recognized as a double-strand breaks and being inappropriately subjected to DNA damage repair mechanisms.10 

Genetic variants in TERC and TERT are frequently seen in DC patients, accounting for ∼10% of cases.11  Typically, TERC variants are heterozygous, resulting in dominantly inherited disease with heterogeneous disease presentation. Alongside the typical mucocutaneous and BMF features of DC,12  patients have also been observed presenting with AA, myelodysplasia (MDS),13  pulmonary fibrosis,14  and/or liver disease.15  Similarly, dominantly inherited variants in TERT have been identified in DC patients16,17  as well as in patients with idiopathic or familial AA,18  pulmonary fibrosis,14,19  liver disease,20  and familial MDS/acute myeloid leukemia (AML).15,21 

Although TERC and TERT variants are associated with a number of disease phenotypes, the investigation of telomerase variants is further complicated by variable penetrance within families, late onset of disease, subclinical features, and disease anticipation due to progressive telomere shortening through successive generations.17,22  Furthermore, next-generation sequencing has increased our awareness of the number of genetic variants in healthy individuals, with ∼100 novel, heterozygous coding variants being described in each person. Data from the Exome Aggregation Consortium (ExAC, http://exac.broadinstitute.org/) indicates that 1 in ∼120 people carry a rare missense or loss-of-function (LOF) variant (allele frequency <1/10 000) in the TERT gene. The ExAC database shows genetic variants reported in 60 706 unrelated individuals, sequenced as part of various disease-specific and population genetic studies. This underlies the importance of investigating novel variants in order to assign their pathogenic status.

Here, we report on 23 families with DC or DC-like disease in which we have identified 26 telomerase variants, 16 of which are novel. From analyzing each variant, we have predicted their impact and placed them into 3 different categories: disease-causing, status uncertain, and bystander. We provide an algorithm which will assist in categorizing new telomerase variants and report on 2 novel inheritance mechanisms at play in causing telomeropathies.

Patient selection

The majority of patients included in this study come from the DC registry (DCR) in London, which currently comprises 417 families with 618 affected individuals from 42 different countries. The criteria for admission to the DCR has been described previously.23  In addition to these patients, we have also studied samples from patients who have clinical features that overlap DC, but not enough to fulfill a definitive diagnosis, as well as patients who present with AA, with or without additional constitutional features (CAA). Informed consent was provided from all patients and family members in accordance with the Declaration of Helsinki. These studies have received approval from the East London and The City Research Ethics Committee.

Identification of telomerase variants

Telomerase variants were identified in patients recruited over the past 3 years using 3 different methods: (1) all BMF patients referred to our laboratory (n = 338) were routinely screened for TERC variants by polymerase chain reaction (PCR) amplification and direct Sanger sequencing using a BigDye Terminator Cycle Sequencing V3.1 kit followed by capillary electrophoresis on a 3130xl Genetic Analyzer (Applied Biosystems). (2) Screening for TERT variants was performed on a selected group of patients (n = 39) whose clinical presentation had features indicative of a telomerase variant, including DC and BMF with autosomal-dominant inheritance, pulmonary fibrosis, and/or liver disease. The 16 exons of TERT were amplified on 18 different fragments by PCR and scanned for mutation by denaturing high-performance liquid chromatography (HPLC) on a WAVE DNA fragment analysis system (Transgenomic), as described previously.16  If a sample gave an abnormal elution pattern, the appropriate fragment was reamplified and sequenced as for the TERC fragment above. (3) In another group of DC patients, or patients with DC-like features (n = 75), we have performed whole-exome sequencing as described elsewhere.24  Briefly, library preparation and exon capture was performed using the TruSeq Exome enrichment kit (Illumina). Samples were sequenced on the Illumina HighSequation 2000 following the on-system generation of 100-bp paired-end reads and variants were called with the Genome Analysis Toolkit (GATK) version 2.7.4.

Telomere length measurement

Patient telomere lengths (TLs) were measured using a monochrome multiplex quantitative PCR method.25  This approach compares the amount of PCR product generated from the telomere (T) to a single-copy gene (S) to obtain a T:S ratio, which is proportional to TL. In brief, 30 nM of telomere-specific primers and 6 nM of primers specific to human β-globin were used, 10 ng of genomic DNA was input per sample (extracted from whole peripheral blood), and all samples were measured in triplicate. Reactions were analyzed on a Roche LightCycler 480 real-time thermal cycler (Roche Applied Science). Standard curves for telomere and human β-globin amplification were established by titration of a reference DNA sample. T:S ratios were determined from these curves and normalized to the T:S ratio of a second reference sample run on each plate. Selected samples also had TL measured by flow–fluorescence in situ hybridization (FISH; Repeat Diagnostics).

Cell culture and plasmids

Telomerase-negative WI38-VA13 cells were maintained in Dulbecco modified Eagle medium (Invitrogen) supplemented with 10% fetal bovine serum, 2 mM glutamine, 1 mM sodium pyruvate, 100 μg/mL streptomycin, and 100 U/mL penicillin in an atmosphere of 5% CO2. Wild-type pcDNA3.1+TERC or pcDNA3.1+TERT plasmids have been previously reported.21  Site-directed mutagenesis was carried out in order to introduce single-nucleotide variants into these plasmids using Phusion High-Fidelity DNA Polymerase (Thermo Scientific). The fidelity of all constructs was verified by DNA sequencing.

Analysis of telomerase activity

The effect of TERC and TERT variants on telomerase activity was measured using the TRAPeze RT Telomerase Detection kit (Millipore) according to the manufacturer’s guidelines. The telomerase-negative human fibroblast cell line WI-38 and plasmids pcDNA3.1+TERT and pcDNA3.1+TERC were used. Briefly, 1 × 105 WI-38 cells were transfected with 0.8 µg of DNA (0.4 µg of each pcDNA3.1-TERT and pcDNA3.1-TERC) using Lipofectamine 2000 (Invitrogen) and harvested 24 hours later. The telomerase activity of 3000 cells was measured in duplicate in 2 independent experiments. Plasmid expression was confirmed as described previously.21 

Identification of telomerase variants

Direct sequencing of the TERC gene has revealed 9 variants of interest among the 338 patients screened in this study, 5 of which have not been observed previously. Scanning of the TERT gene by denaturing HPLC has identified 7 cases with heterozygous variants from a selected cohort of 39 patients. Whole-exome sequencing, performed on a total of 75 patients, has revealed 9 additional TERT variants to give a total of 16 TERT variants and 9 TERC variants in 23 different families (Figure 1; Table 1). We have also obtained updated clinical information from a family with a TERT variant that we have previously reported,16  and this will be discussed further.

Figure 1

Twenty-three families identified with telomerase variants. Open circles and squares indicate unaffected females and males; black circles and squares, affected females and males; gray circles and squares, females and males with few disease features; diamond, gender unknown; line through, deceased. Arrows indicate the index cases in each family. Where known, the genotype is indicated below each individual. Individuals who have undergone exome sequencing are denoted with an asterisk (*).

Figure 1

Twenty-three families identified with telomerase variants. Open circles and squares indicate unaffected females and males; black circles and squares, affected females and males; gray circles and squares, females and males with few disease features; diamond, gender unknown; line through, deceased. Arrows indicate the index cases in each family. Where known, the genotype is indicated below each individual. Individuals who have undergone exome sequencing are denoted with an asterisk (*).

Close modal
Table 1

Twenty-six telomerase variants in 23 families

FamilySexAge at report, yGeneNucleotide changeAmino acid substitutionZygosityTRAP, %Frequency on ExACStatus
Female 48 TERC r.72C>G N/A Het 5* NR 
Female 32 TERC r.180C>T N/A Het 25* NR 
Female 53 TERC r. 212C>G N/A Het 1* NR 
Male 37 TERT c.1710G>C p. Lys570Asn Het 1-2* NR 
Female 64 TERT c.1892G>A p.Arg631Gln Het 2.7 NR 
Male 42 TERC r.95G>C N/A Het 1.7 NR 
Male 54 TERC r.205C>T N/A Het 4.7 NR 
Male 12 TERC r.448A>G N/A Het 2.7 NR 
Female 39 TERT c.1769+1G>A Splicing Het NA NR 
10 Male TERT c.1336_1337insC p.Arg446Profs*93 C. het NA NR 
11 Female 25 TERT c.1743delG p.Trp581* C. het NA NR 
12 Male 11 TERC c. 129_140delinsGT N/A Het NA NR 
10 Male TERT c.329G>C p.Gly110Ala C. het NA NR 
13 Male TERT c.1141C>T p.Arg381Cys Het 66 NR 
14 Male 49 TERT c.355G>A p.Val119Met Het 140 NR 
15 Male 29 TERT c.2318T>C p.Met773Thr Het NA NR 
16 Male 45 TERT c.2329G>A p.Val777Leu Het NA NR 
17 Male 40 TERT c.2474A>G p.Tyr825Cys Het NA NR 
18 Female 58 TERC r.202T>G N/A Hom 92 NR 
11 Female 25 TERT c.1589C>T p.Pro530Leu C. het NA 2/121934 
19 Male TERT c.2936G>A p.Arg979Gln Het 35 1/122330 
20 Female 14 TERC r.93G>C N/A Het NA 2/112256 
21 Female TERT c.2113G>C p.Glu705Gln Het 38 NR 
22 Female TERT c.3379T>C p.Phe1127Leu Het 100 NR 
Male 54 TERT c.3150G>C p.Lys1050Asn Hom 56 10/114130 
23 Male 17 TERT c.1141C>G p.Arg381Gly Het 51 NR 
FamilySexAge at report, yGeneNucleotide changeAmino acid substitutionZygosityTRAP, %Frequency on ExACStatus
Female 48 TERC r.72C>G N/A Het 5* NR 
Female 32 TERC r.180C>T N/A Het 25* NR 
Female 53 TERC r. 212C>G N/A Het 1* NR 
Male 37 TERT c.1710G>C p. Lys570Asn Het 1-2* NR 
Female 64 TERT c.1892G>A p.Arg631Gln Het 2.7 NR 
Male 42 TERC r.95G>C N/A Het 1.7 NR 
Male 54 TERC r.205C>T N/A Het 4.7 NR 
Male 12 TERC r.448A>G N/A Het 2.7 NR 
Female 39 TERT c.1769+1G>A Splicing Het NA NR 
10 Male TERT c.1336_1337insC p.Arg446Profs*93 C. het NA NR 
11 Female 25 TERT c.1743delG p.Trp581* C. het NA NR 
12 Male 11 TERC c. 129_140delinsGT N/A Het NA NR 
10 Male TERT c.329G>C p.Gly110Ala C. het NA NR 
13 Male TERT c.1141C>T p.Arg381Cys Het 66 NR 
14 Male 49 TERT c.355G>A p.Val119Met Het 140 NR 
15 Male 29 TERT c.2318T>C p.Met773Thr Het NA NR 
16 Male 45 TERT c.2329G>A p.Val777Leu Het NA NR 
17 Male 40 TERT c.2474A>G p.Tyr825Cys Het NA NR 
18 Female 58 TERC r.202T>G N/A Hom 92 NR 
11 Female 25 TERT c.1589C>T p.Pro530Leu C. het NA 2/121934 
19 Male TERT c.2936G>A p.Arg979Gln Het 35 1/122330 
20 Female 14 TERC r.93G>C N/A Het NA 2/112256 
21 Female TERT c.2113G>C p.Glu705Gln Het 38 NR 
22 Female TERT c.3379T>C p.Phe1127Leu Het 100 NR 
Male 54 TERT c.3150G>C p.Lys1050Asn Hom 56 10/114130 
23 Male 17 TERT c.1141C>G p.Arg381Gly Het 51 NR 

B, bystander; C.het, compound heterozygous; D, disease-causing; Het, heterozygous; Hom, homozygous; N/A, not applicable; NA, not available; NR, not reported; TRAP, telomerase repeat amplification assay (% wild type); U, uncertain status.

*

Reported elsewhere.

The TLs of all patients were measured (Figure 2A) except for the index in family 17 who was excluded as the DNA was not of sufficient quality. With the exception of family 21, all probands had short telomeres (below the 10th centile) and 18 had very short telomeres (below the first centile). Although this is indicative of a telomeropathy (as demonstrated previously21,26-28 ), we examined each family further, and find that it is not always easy to definitively assign pathogenic status to the telomerase variants we identified.

Figure 2

Telomere lengths of patients and telomerase activity of selected variants. (A) Telomere lengths were measured by MM-qPCR and expressed as a T:S ratio for probands and 99 normal controls. Percentiles for the normal controls are indicated. All samples were normalized to a reference. (B) Telomerase activity was measured in WI38-VA13 cells ectopically expressing the stated telomerase variant. Activity was calculated as a percentage of wild-type levels, measured using the TRAP. Less than 5% activity is considered LOF. RT-PCR products demonstrate expression of wild-type and mutant TERC and TERT mRNA. Bars show standard error of mean of duplicate readings from 2 independent experiments. MM-qPCR, monochrome multiplex quantitative PCR; mRNA, messenger RNA; NTC, no template control; RT-PCR, reverse transcription PCR.

Figure 2

Telomere lengths of patients and telomerase activity of selected variants. (A) Telomere lengths were measured by MM-qPCR and expressed as a T:S ratio for probands and 99 normal controls. Percentiles for the normal controls are indicated. All samples were normalized to a reference. (B) Telomerase activity was measured in WI38-VA13 cells ectopically expressing the stated telomerase variant. Activity was calculated as a percentage of wild-type levels, measured using the TRAP. Less than 5% activity is considered LOF. RT-PCR products demonstrate expression of wild-type and mutant TERC and TERT mRNA. Bars show standard error of mean of duplicate readings from 2 independent experiments. MM-qPCR, monochrome multiplex quantitative PCR; mRNA, messenger RNA; NTC, no template control; RT-PCR, reverse transcription PCR.

Close modal

Disease-causing variants

We consider a variant to be disease-causing if it has been previously reported as disease-associated. This is true for 3 of the TERC variants (r.72C>G, r.180C>T, and r.212C>G) and 2 of the TERT variants (Lys570Asn and p.Arg631Gln) that we have identified in families 1 through 5. Arg631Gln in family 5 is worthy of special mention as it has been reported previously on 4 different occasions, segregating with a variety of phenotypes including DC-like disease, familial MDS/AML, and idiopathic pulmonary fibrosis.21,29-31  It is also 1 of the few TERT variants that, in our hands, gives telomerase activity of <10% in the telomerase repeat amplification protocol (TRAP) assay, which we have confirmed in this study (Figure 2B). For the other variants, the fact that they are recurring in affected individuals strengthens the case that they are disease-causing.

We also consider LOF variants to be disease-causing as these will certainly result in haploinsufficiency which is a well-established disease mechanism with telomerase variants.18,32-34  We suggest that a telomerase activity of < 5% of wild-type levels in a TRAP assay represents LOF. This is true for 3 novel TERC variants (r.95G>C, r.205C>T, and r.448A>G) identified in families 6 through 8. Interestingly, apart from p.Arg631Gln, none of the TERT missense variants that we have studied here display low TRAP activity (Figure 2B). However, we have identified 3 TERT variants in families 9 through 11 that are predicted to result in LOF in that they are splicing, frameshift, or nonsense variants (c.1769+1G>A, p.Arg446Profs*93, and p.Trp581*, respectively).35  In family 12, we have identified a TERC variant (r.129_140delinsGT) that is also predicted to cause LOF due to its impact on the pseudoknot domain.

The index case in family 10 presented with severe features resembling HHS, including microcephaly and cerebellar atrophy (Table 2). In addition to the LOF TERT variant (p.Arg446Profs*93) inherited from his asymptomatic mother, he also inherited a novel missense variant from his asymptomatic father (p.Gly110Ala). This situation is very reminiscent of previous reports of a severe phenotype being associated with biallelic inheritance of TERT variants36,37  and we therefore consider it likely that both of these variants are contributing to the disease. Furthermore, exome sequencing did not reveal rare variants in any other gene known to cause DC, or to be involved in telomere biology.

Table 2

Clinical features of probands and affected family members

FamilyIndividualHematologic featuresMucocutaneous featuresOther abnormalities
Index MDS  FH ovarian and prostate cancer 
Index BMF  FH macrocytic anemia 
Index BMF   
Brother BMF  LD, finger clubbing 
Brother BMF  Premature greying, hair loss 
Sister Low wbc  PF 
Index BMF  LD, PF, premature greying, hair loss 
Index  ND, SP PF, premature greying 
Father BMF  LD, premature greying 
Sister BMF  COPD, premature greying 
Index BMF   
Index BMF ND, SP Dental, renal failure 
Sister BMF ND  
Father  ND  
Index BMF  CH, MC, ataxia 
Sister   CH, MC 
Index AML ND Hair loss 
10 Index BMF ND, LP CH, MC 
11 Index BMF LP Dental, aseptic necrosis, tongue cancer 
12 Index BMF   
12 Mother BMF   
13 Index BMF ND, LP Low birth weight 
14 Index BMF  LD, PF, dental 
14 Brother   LD, PF 
14 Mother   PF 
15 Index BMF  Premature greying 
15 Sister   Premature greying 
16 Index   LD, PF 
17 Index BMF   
17 Mother   Premature greying 
18 Index  ND, SP, LP PF, dental 
18 Sister  ND, SP, LP PF 
19 Index BMF LP CH, MC, low birth weight, scoliosis 
20 Index MDS   
21 Index ID SP café au lait spot MC, low birth weight 
22 Index BMF LP CH 
22 Sister   CH 
22 Father BMF ND, SP, LP Hair loss, premature greying 
23 Index BMF ND, SP, LP  
23 Brother  LP  
FamilyIndividualHematologic featuresMucocutaneous featuresOther abnormalities
Index MDS  FH ovarian and prostate cancer 
Index BMF  FH macrocytic anemia 
Index BMF   
Brother BMF  LD, finger clubbing 
Brother BMF  Premature greying, hair loss 
Sister Low wbc  PF 
Index BMF  LD, PF, premature greying, hair loss 
Index  ND, SP PF, premature greying 
Father BMF  LD, premature greying 
Sister BMF  COPD, premature greying 
Index BMF   
Index BMF ND, SP Dental, renal failure 
Sister BMF ND  
Father  ND  
Index BMF  CH, MC, ataxia 
Sister   CH, MC 
Index AML ND Hair loss 
10 Index BMF ND, LP CH, MC 
11 Index BMF LP Dental, aseptic necrosis, tongue cancer 
12 Index BMF   
12 Mother BMF   
13 Index BMF ND, LP Low birth weight 
14 Index BMF  LD, PF, dental 
14 Brother   LD, PF 
14 Mother   PF 
15 Index BMF  Premature greying 
15 Sister   Premature greying 
16 Index   LD, PF 
17 Index BMF   
17 Mother   Premature greying 
18 Index  ND, SP, LP PF, dental 
18 Sister  ND, SP, LP PF 
19 Index BMF LP CH, MC, low birth weight, scoliosis 
20 Index MDS   
21 Index ID SP café au lait spot MC, low birth weight 
22 Index BMF LP CH 
22 Sister   CH 
22 Father BMF ND, SP, LP Hair loss, premature greying 
23 Index BMF ND, SP, LP  
23 Brother  LP  

AML, acute myeloid leukemia; BMF, bone marrow failure; CH, cerebellar hypoplasia; COPD, chronic obstructive pulmonary disease; FH, family history; ID, immune deficiency; LD, liver disease; LP, leukoplakia; MC, microcephaly; MDS, myelodysplastic syndrome; ND, nail dystrophy; PF, pulmonary fibrosis; SP, abnormal skin pigmentation; wbc, white blood cell count.

Variants of uncertain status

We have identified 6 variants which, with all the currently available data, remain of uncertain status (Figure 1; Table 1; families 13-18). One of the problems encountered in trying to assign pathogenic status to a variant is that the details of the patient’s family history are often limited. We have therefore classed a variant as having uncertain status if it does not cause LOF and the patient either has (1) no other family members with disease features (or their phenotype is unknown) or (2) family members with disease features but segregation of the variant is unknown.

This applies to 5 of the TERT variants that we have identified. In 1 of these, a boy with early onset DC (family 13), had inherited p.Arg381Cys from his asymptomatic father (Table 1), a variant that gave 66% wild-type activity in a TRAP assay (Figure 2B). In 4 other cases with previously unreported variants (p.Val119Met, p.Met773Thr, p.Val777Leu, and p.Tyr825Cys), the clinical presentation and family history is typical of patients with disease-causing TERT variants. These features include BMF, liver disease, pulmonary fibrosis, and/or apparent autosomal-dominant inheritance (Table 2). However, in each case, other family members are unavailable and segregation cannot be established. In addition, the TRAP data are either unavailable (which is the case in a diagnostic setting) or show >100% wild-type activity (Figure 2B). We note that an in vitro TRAP assay may reveal a variant has normal telomerase activity, yet it could still be pathogenic due to errors in recruitment or assembly. These variants therefore have to remain of uncertain status.

Family 18 is particularly interesting as a TERC variant (r.202T>G) is seen in a homozygous state in the index case and her affected sister (Figure 1). To our knowledge, this is the first report of a homozygous variant in TERC. The proband is a 58-year-old women with dental abnormalities and both her and her affected sister have pulmonary fibrosis and mucocutaneous features (Table 2). The TRAP assay revealed a telomerase activity of 92% wild-type (Figure 2B) which does not denote LOF. Although 3 additional family members have disease features, the segregation of the variant among these individuals, as well as unaffected siblings and parents, remains unknown. We therefore class this variant as status uncertain due to the limited information available from family members.

Variants that are bystanders

Somewhat surprisingly, we have identified 5 variants which we believe are likely to be bystanders (Figure 1; Table 1; families 11 and 19-22). We consider a heterozygous variant to be a bystander if it has been reported on the ExAC database. This is true of TERT variants p.Pro530Leu (identified in conjunction with the LOF variant in family 11) and p.Arg979Gln (identified in family 19). If a variant has been previously reported at a frequency of ∼1 in 100 000 it is unlikely to cause a rare disorder. The TERC variant in family 20 (r.93G>C), who presented with MDS at the age of 14 and was found to be heterozygous in both parents, is also present on the ExAC database.

The TERT variant identified in family 21 (p.Glu705Gln) is also likely to be a bystander because variants in a different disease gene have been identified in this patient, who presented with immune deficiency alongside a café au lait spot, low birth weight, and microcephaly. She stands out as her telomeres were above the 50th centile (Figure 2A), which suggested that telomere maintenance was not the cause of pathology. She was subsequently found to have compound heterozygous LOF variants in LIG4, which cause the immune-deficiency disorder ligase IV syndrome (LIG4 syndrome, OMIM 601837).

We have previously described family 22 with the TERT variant p.Phe1127Leu, which was shown to be inherited by the index case from her asymptomatic mother.16  The proband had a severe HHS-like phenotype (Table 2) and it was noted that her mother may be asymptomatic due to an extreme case of anticipation. However, functional analysis later showed the substitution gave ∼100% wild-type telomerase activity, suggesting it did not have a negative impact.38  Since this original report, the proband’s father, who is wild type for TERT, developed features of disease (Table 2). This TERT variant therefore turns out to be a bystander, as it is not present in the affected father.

Categorization of telomerase variants

In order to aid the assignment of pathogenic status, we have established a diagnostic algorithm to characterize the likely impact of telomerase variants (Figure 3). This groups the variants into categories of (1) disease-causing, (2) status uncertain, and (3) bystander, as described in this article. The algorithm considers whether a variant has been reported previously in disease, the nature of the variant (ie, if it causes LOF), its frequency of the variant in a general population, the presence of variants in other known disease genes, and the family history of the patient (where available). The algorithm acknowledges that details of a patient’s family history are often incomplete and does not rely on TL to predict the impact of a variant. This is because short telomeres alongside a telomerase variant may not mean the variant is disease-causing.

Figure 3

Diagnostic algorithm for the characterization of telomerase variants. Variants are considered disease-causing if they have been reported in other unrelated patients or cause LOF. Conversely, variants are considered bystanders if they appear on ExAC or if a different disease gene has been identified. Additionally, a variant is classed as a bystander if it does not segregate with all affected members of a family. If segregation of the variant is unknown (or if a patient is a sporadic case) and if TRAP activity is >5% or unknown, a variant should be considered as status uncertain.

Figure 3

Diagnostic algorithm for the characterization of telomerase variants. Variants are considered disease-causing if they have been reported in other unrelated patients or cause LOF. Conversely, variants are considered bystanders if they appear on ExAC or if a different disease gene has been identified. Additionally, a variant is classed as a bystander if it does not segregate with all affected members of a family. If segregation of the variant is unknown (or if a patient is a sporadic case) and if TRAP activity is >5% or unknown, a variant should be considered as status uncertain.

Close modal

Families with novel disease mechanisms: triallelic inheritance in the index case

The TERT variant p.Lys1050Asn identified in family 7, which shows intermediate telomerase activity in the TRAP assay (56%, Figure 2B), has been reported on the ExAC database in 10 of 114 130 alleles. However, in this family, it was found in a homozygous state in the index case and his sister, who both have BMF and nail dystrophy, with the index case additionally presenting with abnormal skin pigmentation, dental abnormalities, and renal failure (Figure 1; Tables 1-2). The family are Ashkenazi Jews and this variant may be enriched due to a founder effect in this population. Remarkably, the index case in this family also has the novel TERC variant r.205C>T which has low telomerase activity (4.7%, Figure 2B). However, his affected sister is wild type for TERC. Thus, the index case, who has a more severe clinical phenotype and shorter telomeres than his sister (supplemental Figure 1, available on the Blood Web site), has both a homozygous TERT variant as well as a heterozygous TERC variant. His sister, with a less severe clinical phenotype, only has the homozygous TERT variant. The exome data from the proband was extensively analyzed and no other variants were identified in known disease genes or genes known to be involved in telomere biology. We therefore propose a triallelic model of inheritance in this index case.

Disease phenotype in individuals arising from inherited short telomeres in presence of normal telomerase

In family 8, the proband has a severe HHS phenotype, with BMF, cerebellar hypoplasia, microcephaly, and ataxia (Table 2). He has the TERC variant r.448A>G, inherited from his asymptomatic father. This variant impacts on the ACA box of TERC and reduces telomerase activity to 2.2% of wild-type levels (Figure 2B). However, his sister, who also has microcephaly and cerebellar hypoplasia, is wild type for TERC. TLs in this family were measured by flow-FISH, showing that the father and both siblings had very short telomeres (Figure 4). Fifty-two genes linked to inherited BMF were sequenced in the proband (as part of a previous study28 ) and no novel variants were revealed. Although we cannot rule out the contribution of a variant in another gene, we propose that the inheritance of short telomeres, alongside the TERC variant, has caused the severe disease phenotype observed in the proband. His sister, on the other hand, presents with fewer disease features due to the inheritance of short telomeres through the germline while being wild type for TERC.

Figure 4

Telomere lengths in families 8 and 23. (A) Lymphocyte telomere lengths in family 8 measured by flow-FISH. (i) Father of the index, asymptomatic with TERC variant r.448A>G; (ii) mother of the index, asymptomatic, wild type for TERC; (iii) index case with TERC variant r.448A>G; (iv) sister of the index, affected, wild type for TERC. Curved lines represent 99th, 90th, 50th, 10th, and first percentiles. (B) Telomere lengths of family 23 measured by MM-qPCR. Telomere lengths are expressed as a T:S ratio for the index case, his mother (heterozygous for TERT variant) and his brother (wild type for TERT). These are compared with 99 normal controls (as in Figure 2A). Percentiles for the normal controls are indicated. All samples were normalized to a reference.

Figure 4

Telomere lengths in families 8 and 23. (A) Lymphocyte telomere lengths in family 8 measured by flow-FISH. (i) Father of the index, asymptomatic with TERC variant r.448A>G; (ii) mother of the index, asymptomatic, wild type for TERC; (iii) index case with TERC variant r.448A>G; (iv) sister of the index, affected, wild type for TERC. Curved lines represent 99th, 90th, 50th, 10th, and first percentiles. (B) Telomere lengths of family 23 measured by MM-qPCR. Telomere lengths are expressed as a T:S ratio for the index case, his mother (heterozygous for TERT variant) and his brother (wild type for TERT). These are compared with 99 normal controls (as in Figure 2A). Percentiles for the normal controls are indicated. All samples were normalized to a reference.

Close modal

In family 23, the index case manifests a full DC phenotype and has the heterozygous TERT variant, p.Arg381Gly. This variant has intermediate telomerase activity based on the TRAP assay (51%, Figure 2B). His brother is wild type for TERT but has leukoplakia. Exome sequencing in the proband failed to reveal any other likely disease-causing variants. As in family 8, it is likely that the inheritance of short telomeres alongside the TERT variant has caused more severe phenotype in the index case, whereas the younger brother has inherited short telomeres (Figure 4), but is wild type for TERT, leading to a milder phenotype.

We therefore propose that in these 2 families, the inheritance of short telomeres exacerbates the disease in the probands who harbor telomerase variants, consistent with previous observations of disease anticipation. However, we now also suggest that the inheritance of short telomeres alone is sufficient to cause the disease phenotypes observed in affected siblings, in the absence of a telomerase variant.

To date, we are aware of 75 TERT and 49 TERC disease-associated variants, listed in the Telomerase Database (http://telomerase.asu.edu/) as well as other published sources.11  Here, we have reported on 26 telomerase variants (17 in TERT and 9 in TERC) in 23 different families. Reviewing each 1, we have found it helpful to place them into 1 of 3 different categories: (1) disease-causing, (2) status uncertain, and (3) bystander. In doing so, this study highlights the difficulties in assigning pathogenic status to telomerase variants. We have therefore established an algorithm, which we present here, that will help to objectively categorize telomerase variants. It considers 5 key factors: (1) the reoccurrence of a variant within the disease population, (2) the type of variant and its functional impact, (3) the frequency of the variant in a general population, (4) the presence of variants in other known disease genes, and (5) the family history of disease and segregation of the variant among affected individuals.

We believe that variants reported on the ExAC database are unlikely to be disease-causing in the heterozygous state because DC is a very rare disease. However, other disease phenotypes associated with telomerase variants are more common, notably idiopathic pulmonary fibrosis which has an estimated prevalence of between 14 and 42.7 in 100 000.39  We therefore suggest that if a TERT variant in a patient with pulmonary fibrosis appears on ExAC it should not be ruled out as a bystander without further investigation.

All of the patients reported in this series had short or very short telomeres, bar 1. On its own, therefore, the presence of short telomeres does not demonstrate that the telomerase variant identified is disease-causing. We considered variants that significantly reduced telomerase activity (<5% of wild type) were disease-causing. However, interpreting intermediate TRAP levels can be difficult because there is no designated “cutoff” describing a level of activity needed for normal telomerase function. Xin et al have grouped variants, giving TRAP scores between 20% and 100% of wild-type levels as within a normal range,38  whereas Zaug et al, using a direct telomerase assay, described 10% to 50% as “substantially reduced activity.”40  Surprisingly, these authors found that a significant number of disease-associated TERT variants showed normal telomerase activities in their direct assay. It is possible that alternative methods that directly measure telomerase processivity41  or telomerase recruitment42,43  would further help to characterize these variants.

Remarkably, we have identified 3 families that appear to display novel mechanisms in the inheritance of telomere disorders. In 1 family (family 7), we describe an affected case with a severe phenotype associated with mutations in 2 different telomerase genes (homozygous variant in TERT and heterozygous variant in TERC). This individual therefore has 3 mutant telomerase alleles, representing a triallelic disease model. It is notable that studies in Saccharomyces cerevisiae have demonstrated a similar effect called “additive haploinsufficiency.” Diploid organisms with heterozygous deletions in 2 telomerase genes were shown to have an enhanced phenotype (telomere shortening and an accelerated onset of senescence in haploid progeny that inherit a deletion in a single telomerase gene) compared with strains carrying only 1 mutation.44,45  In human disease, a similar triallelic phenomenon has been documented previously in the heterogeneous disorder Bardet-Biedl syndrome.46 

In 2 other families (families 8 and 23), we find that the index cases have a more severe phenotype because of the inheritance of short telomeres from a parent in association with a telomerase variant whereas a corresponding affected sibling has mild disease due to the inheritance of short telomeres but with normal telomerase. This is the first observation in humans of the generation of a clinical phenotype due solely to the inheritance of short telomeres from a parent, although this phenomenon has been documented previously in mice.47,48  Although this represents an epigenetic-like mechanism of inheritance, it is not dissimilar to the effect that short telomeres have in hastening disease in people who are heterozygous for telomerase mutations, which is thought to be the mechanism underlying the observed disease anticipation in these disorders. It has also been proposed that this atypical, epigenetic-like mechanism of TL inheritance may account for a significant proportion of the heritability of TL in the general population.49 

In summary, this study highlights the complexity in categorizing telomerase variants, documents new mechanisms involved in generating human telomeropathies, and demonstrates that thorough investigation is necessary to assess the pathogenic contribution of newly identified telomerase variants. This will become increasingly important and difficult as exome-based diagnostic reports are generated without reference to the many nuances that may be encountered.

The online version of this article contains a data supplement.

The publication costs of this article were defrayed in part by page charge payment. Therefore, and solely to indicate this fact, this article is hereby marked “advertisement” in accordance with 18 USC section 1734.

The authors thank Charles Mein, Anna Terry, and Monika Bozek of the Barts and The London Genome Centre for their help with DNA sequencing; Vincent Plagnol for variant calling of the exome data; and all of the patients and clinicians who entered samples into this study.

This work was supported by the Medical Research Council (MRC; UK) and Children with Cancer.

Contribution: L.C.C. performed research and wrote the paper; A.J.W., S.C., A.J.Y.V.L., T.L., R.K., and H. Tummala performed research; J.d.l.F., M.M., H. Toriello, and H. Tamary provided clinical samples; and T.J.V. and I.D. designed the research and wrote the paper.

Conflict-of-interest disclosure: The authors declare no competing financial interests.

Correspondence: Thomas J. Vulliamy, Centre for Genomics and Child Health, Blizard Institute, Barts and The London School of Medicine and Dentistry, Queen Mary University of London, 4 Newark St, London E1 2AT, United Kingdom; e-mail: t.vulliamy@qmul.ac.uk.

1
Calado
 
R
Young
 
N
Telomeres in disease.
F1000 Med Rep
2012
, vol. 
4
 pg. 
8
 
2
Armanios
 
M
Blackburn
 
EH
The telomere syndromes.
Nat Rev Genet
2012
, vol. 
13
 
10
(pg. 
693
-
704
)
3
Dokal
 
I
Dyskeratosis congenita.
Hematology Am Soc Hematol Educ Program
2011
, vol. 
2011
 (pg. 
480
-
486
)
4
Knight
 
SW
Heiss
 
NS
Vulliamy
 
TJ
et al. 
Unexplained aplastic anaemia, immunodeficiency, and cerebellar hypoplasia (Hoyeraal-Hreidarsson syndrome) due to mutations in the dyskeratosis congenita gene, DKC1.
Br J Haematol
1999
, vol. 
107
 
2
(pg. 
335
-
339
)
5
Alter
 
BP
Baerlocher
 
GM
Savage
 
SA
et al. 
Very short telomere length by flow fluorescence in situ hybridization identifies patients with dyskeratosis congenita.
Blood
2007
, vol. 
110
 
5
(pg. 
1439
-
1447
)
6
Savage
 
SA
Alter
 
BP
Dyskeratosis congenita.
Hematol Oncol Clin North Am
2009
, vol. 
23
 
2
(pg. 
215
-
231
)
7
Harley
 
CB
Futcher
 
AB
Greider
 
CW
Telomeres shorten during ageing of human fibroblasts.
Nature
1990
, vol. 
345
 
6274
(pg. 
458
-
460
)
8
Allsopp
 
RC
Vaziri
 
H
Patterson
 
C
et al. 
Telomere length predicts replicative capacity of human fibroblasts.
Proc Natl Acad Sci USA
1992
, vol. 
89
 
21
(pg. 
10114
-
10118
)
9
Shay
 
JW
Bacchetti
 
S
A survey of telomerase activity in human cancer.
Eur J Cancer
1997
, vol. 
33
 
5
(pg. 
787
-
791
)
10
de Lange
 
T
Shelterin: the protein complex that shapes and safeguards human telomeres.
Genes Dev
2005
, vol. 
19
 
18
(pg. 
2100
-
2110
)
11
Dokal
 
I
Vulliamy
 
T
Mason
 
P
Bessler
 
M
Clinical utility gene card for: dyskeratosis congenita - update 2015.
Eur J Hum Genet
2015
, vol. 
23
 
4
12
Vulliamy
 
T
Marrone
 
A
Goldman
 
F
et al. 
The RNA component of telomerase is mutated in autosomal dominant dyskeratosis congenita.
Nature
2001
, vol. 
413
 
6854
(pg. 
432
-
435
)
13
Yamaguchi
 
H
Baerlocher
 
GM
Lansdorp
 
PM
et al. 
Mutations of the human telomerase RNA gene (TERC) in aplastic anemia and myelodysplastic syndrome.
Blood
2003
, vol. 
102
 
3
(pg. 
916
-
918
)
14
Armanios
 
MY
Chen
 
JJ
Cogan
 
JD
et al. 
Telomerase mutations in families with idiopathic pulmonary fibrosis.
N Engl J Med
2007
, vol. 
356
 
13
(pg. 
1317
-
1326
)
15
Calado
 
RT
Regal
 
JA
Hills
 
M
et al. 
Constitutional hypomorphic telomerase mutations in patients with acute myeloid leukemia.
Proc Natl Acad Sci USA
2009
, vol. 
106
 
4
(pg. 
1187
-
1192
)
16
Vulliamy
 
TJ
Walne
 
A
Baskaradas
 
A
Mason
 
PJ
Marrone
 
A
Dokal
 
I
Mutations in the reverse transcriptase component of telomerase (TERT) in patients with bone marrow failure.
Blood Cells Mol Dis
2005
, vol. 
34
 
3
(pg. 
257
-
263
)
17
Armanios
 
M
Chen
 
JL
Chang
 
YP
et al. 
Haploinsufficiency of telomerase reverse transcriptase leads to anticipation in autosomal dominant dyskeratosis congenita.
Proc Natl Acad Sci USA
2005
, vol. 
102
 
44
(pg. 
15960
-
15964
)
18
Yamaguchi
 
H
Calado
 
RT
Ly
 
H
et al. 
Mutations in TERT, the gene for telomerase reverse transcriptase, in aplastic anemia.
N Engl J Med
2005
, vol. 
352
 
14
(pg. 
1413
-
1424
)
19
Tsakiri
 
KD
Cronkhite
 
JT
Kuan
 
PJ
et al. 
Adult-onset pulmonary fibrosis caused by mutations in telomerase.
Proc Natl Acad Sci USA
2007
, vol. 
104
 
18
(pg. 
7552
-
7557
)
20
Calado
 
RT
Brudno
 
J
Mehta
 
P
et al. 
Constitutional telomerase mutations are genetic risk factors for cirrhosis.
Hepatology
2011
, vol. 
53
 
5
(pg. 
1600
-
1607
)
21
Kirwan
 
M
Vulliamy
 
T
Marrone
 
A
et al. 
Defining the pathogenic role of telomerase mutations in myelodysplastic syndrome and acute myeloid leukemia.
Hum Mutat
2009
, vol. 
30
 
11
(pg. 
1567
-
1573
)
22
Vulliamy
 
T
Marrone
 
A
Szydlo
 
R
Walne
 
A
Mason
 
PJ
Dokal
 
I
Disease anticipation is associated with progressive telomere shortening in families with dyskeratosis congenita due to mutations in TERC.
Nat Genet
2004
, vol. 
36
 
5
(pg. 
447
-
449
)
23
Vulliamy
 
TJ
Marrone
 
A
Knight
 
SW
Walne
 
A
Mason
 
PJ
Dokal
 
I
Mutations in dyskeratosis congenita: their impact on telomere length and the diversity of clinical presentation.
Blood
2006
, vol. 
107
 
7
(pg. 
2680
-
2685
)
24
Tummala
 
H
Kirwan
 
M
Walne
 
AJ
et al. 
ERCC6L2 mutations link a distinct bone-marrow-failure syndrome to DNA repair and mitochondrial function.
Am J Hum Genet
2014
, vol. 
94
 
2
(pg. 
246
-
256
)
25
Cawthon
 
RM
Telomere length measurement by a novel monochrome multiplex quantitative PCR method.
Nucleic Acids Res
2009
, vol. 
37
 
3
pg. 
e21
 
26
Walne
 
AJ
Dokal
 
A
Plagnol
 
V
et al. 
Exome sequencing identifies MPL as a causative gene in familial aplastic anemia.
Haematologica
2012
, vol. 
97
 
4
(pg. 
524
-
528
)
27
Walne
 
AJ
Vulliamy
 
T
Kirwan
 
M
Plagnol
 
V
Dokal
 
I
Constitutional mutations in RTEL1 cause severe dyskeratosis congenita.
Am J Hum Genet
2013
, vol. 
92
 
3
(pg. 
448
-
453
)
28
Collopy
 
LC
Walne
 
AJ
Vulliamy
 
TJ
Dokal
 
IS
Targeted resequencing of 52 bone marrow failure genes in patients with aplastic anemia reveals an increased frequency of novel variants of unknown significance only in SLX4.
Haematologica
2014
, vol. 
99
 
7
(pg. 
e109
-
e111
)
29
Basel-Vanagaite
 
L
Dokal
 
I
Tamary
 
H
et al. 
Expanding the clinical phenotype of autosomal dominant dyskeratosis congenita caused by TERT mutations.
Haematologica
2008
, vol. 
93
 
6
(pg. 
943
-
944
)
30
Diaz de Leon
 
A
Cronkhite
 
JT
Katzenstein
 
AL
et al. 
Telomere lengths, pulmonary fibrosis and telomerase (TERT) mutations.
PLoS ONE
2010
, vol. 
5
 
5
pg. 
e10680
 
31
Fernandez
 
BA
Fox
 
G
Bhatia
 
R
et al. 
A Newfoundland cohort of familial and sporadic idiopathic pulmonary fibrosis patients: clinical and genetic features.
Respir Res
2012
, vol. 
13
 
64
(pg. 
64
-
74
)
32
Liu
 
Y
Snow
 
BE
Hande
 
MP
et al. 
The telomerase reverse transcriptase is limiting and necessary for telomerase function in vivo.
Curr Biol
2000
, vol. 
10
 
22
(pg. 
1459
-
1462
)
33
Liu
 
Y
Kha
 
H
Ungrin
 
M
Robinson
 
MO
Harrington
 
L
Preferential maintenance of critically short telomeres in mammalian cells heterozygous for mTert.
Proc Natl Acad Sci USA
2002
, vol. 
99
 
6
(pg. 
3597
-
3602
)
34
Erdmann
 
N
Liu
 
Y
Harrington
 
L
Distinct dosage requirements for the maintenance of long and short telomeres in mTert heterozygous mice.
Proc Natl Acad Sci USA
2004
, vol. 
101
 
16
(pg. 
6080
-
6085
)
35
MacArthur
 
DG
Balasubramanian
 
S
Frankish
 
A
et al. 
1000 Genomes Project Consortium
A systematic survey of loss-of-function variants in human protein-coding genes.
Science
2012
, vol. 
335
 
6070
(pg. 
823
-
828
)
36
Marrone
 
A
Walne
 
A
Tamary
 
H
et al. 
Telomerase reverse-transcriptase homozygous mutations in autosomal recessive dyskeratosis congenita and Hoyeraal-Hreidarsson syndrome.
Blood
2007
, vol. 
110
 
13
(pg. 
4198
-
4205
)
37
Du
 
HY
Pumbo
 
E
Manley
 
P
et al. 
Complex inheritance pattern of dyskeratosis congenita in two families with 2 different mutations in the telomerase reverse transcriptase gene.
Blood
2008
, vol. 
111
 
3
(pg. 
1128
-
1130
)
38
Xin
 
ZT
Beauchamp
 
AD
Calado
 
RT
et al. 
Functional characterization of natural telomerase mutations found in patients with hematologic disorders.
Blood
2007
, vol. 
109
 
2
(pg. 
524
-
532
)
39
Raghu
 
G
Weycker
 
D
Edelsberg
 
J
Bradford
 
WZ
Oster
 
G
Incidence and prevalence of idiopathic pulmonary fibrosis.
Am J Respir Crit Care Med
2006
, vol. 
174
 
7
(pg. 
810
-
816
)
40
Zaug
 
AJ
Crary
 
SM
Jesse Fioravanti
 
M
Campbell
 
K
Cech
 
TR
Many disease-associated variants of hTERT retain high telomerase enzymatic activity.
Nucleic Acids Res
2013
, vol. 
41
 
19
(pg. 
8969
-
8978
)
41
Zhong
 
FL
Batista
 
LF
Freund
 
A
Pech
 
MF
Venteicher
 
AS
Artandi
 
SE
TPP1 OB-fold domain controls telomere maintenance by recruiting telomerase to chromosome ends.
Cell
2012
, vol. 
150
 
3
(pg. 
481
-
494
)
42
Nandakumar
 
J
Bell
 
CF
Weidenfeld
 
I
Zaug
 
AJ
Leinwand
 
LA
Cech
 
TR
The TEL patch of telomere protein TPP1 mediates telomerase recruitment and processivity.
Nature
2012
, vol. 
492
 
7428
(pg. 
285
-
289
)
43
Vulliamy
 
TJ
Kirwan
 
MJ
Beswick
 
R
et al. 
Differences in disease severity but similar telomere lengths in genetic subgroups of patients with telomerase and shelterin mutations.
PLoS ONE
2011
, vol. 
6
 
9
pg. 
e24383
 
44
Lendvay
 
TS
Morris
 
DK
Sah
 
J
Balasubramanian
 
B
Lundblad
 
V
Senescence mutants of Saccharomyces cerevisiae with a defect in telomere replication identify three additional EST genes.
Genetics
1996
, vol. 
144
 
4
(pg. 
1399
-
1412
)
45
Hughes
 
TR
Evans
 
SK
Weilbaecher
 
RG
Lundblad
 
V
The Est3 protein is a subunit of yeast telomerase.
Curr Biol
2000
, vol. 
10
 
13
(pg. 
809
-
812
)
46
Katsanis
 
N
Ansley
 
SJ
Badano
 
JL
et al. 
Triallelic inheritance in Bardet-Biedl syndrome, a Mendelian recessive disorder.
Science
2001
, vol. 
293
 
5538
(pg. 
2256
-
2259
)
47
Hao
 
LY
Armanios
 
M
Strong
 
MA
et al. 
Short telomeres, even in the presence of telomerase, limit tissue renewal capacity.
Cell
2005
, vol. 
123
 
6
(pg. 
1121
-
1131
)
48
Armanios
 
M
Alder
 
JK
Parry
 
EM
Karim
 
B
Strong
 
MA
Greider
 
CW
Short telomeres are sufficient to cause the degenerative defects associated with aging.
Am J Hum Genet
2009
, vol. 
85
 
6
(pg. 
823
-
832
)
49
De Meyer
 
T
Vandepitte
 
K
Denil
 
S
De Buyzere
 
ML
Rietzschel
 
ER
Bekaert
 
S
A non-genetic, epigenetic-like mechanism of telomere length inheritance?
Eur J Hum Genet
2014
, vol. 
22
 
1
(pg. 
10
-
11
)

Author notes

T.J.V. and I.D. are joint senior authors.

Sign in via your Institution