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Keywords:

  • dyskeratosis congenita;
  • Hoyeraal-Hreidarsson syndrome;
  • telomerase;
  • enterocolitis

Summary

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

Defects in telomere maintenance genes cause pathological telomere shortening, and manifest in syndromes which have prominent phenotypes in tissues of high turnover: the skin and bone marrow. Because the gastrointestinal (GI) epithelium is highly proliferative, we sought to determine whether telomere syndromes cause GI disease, and to define its prevalence, spectrum, and natural history. We queried subjects in the Johns Hopkins Telomere Syndrome Registry for evidence of luminal GI disease. In sixteen percent of Registry subjects (6 of 38), there was a history of significant GI pathology, and 43 additional cases were identified in the literature. Esophageal stenosis, enteropathy, and enterocolitis were the recurrent findings. In the intestinal mucosa, there was striking villous atrophy, extensive apoptosis, and anaphase bridging pointing to regenerative defects in the epithelial compartment. GI disease was often the first and most severe manifestation of telomere disease in young children. These findings indicate that telomere dysfunction disrupts the epithelial integrity in the human GI tract manifesting in recognizable disease processes. A high index of suspicion should facilitate diagnosis and management.


Introduction

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

Gastrointestinal (GI) epithelium is highly proliferative and its integrity relies on the regenerative capacity of local stem cells (Barker et al., 2010). Telomeres are DNA-protein structures that protect chromosome ends. With cell division, telomeres shorten and short dysfunctional telomeres provoke apoptosis and/or senescence (Armanios & Blackburn, 2012). Telomerase synthesizes new telomere repeats to offset the loss that occurs during DNA replication(Greider & Blackburn, 1985, 1987). Mice that are null for telomerase show progressive telomere shortening and provide a model for understanding the consequences of telomere dysfunction (Armanios & Blackburn, 2012). In these mice, the highly proliferative tissues, such as the skin and bone marrow, display degenerative phenotypes due to stem-cell failure (Lee et al., 1998; Rudolph et al., 1999; Hao et al., 2005; Rossi et al., 2007). They also develop intestinal villous atrophy and enterocolitis, which contribute to their limited lifespan (Lee et al., 1998; Rudolph et al., 1999; Hao et al., 2005; Armanios et al., 2009). The question of how short telomeres affect the human GI tract has not been systematically examined.

Syndromes caused by mutant telomerase and telomere genes span the age spectrum, and their severity depends on the extent of telomere shortening (Armanios & Blackburn, 2012). Mutations in one of four genes account for the major subset (Armanios & Blackburn, 2012). Mutant telomerase core enzyme genes TERT, the telomerase reverse transcriptase, and TR, its RNA component, cause autosomal dominant disease. Mutations in DKC1, which encodes the telomerase-associated dyskerin protein, cause X-linked disease, and mutations in TINF2, which encodes the telomere protein TIN2, primarily cause de novo disease. In infancy, telomere-mediated disease is recognized as Hoyeraal-Hreidarsson (HH) syndrome, a rare disorder characterized by developmental delay, immunodeficiency, and cerebellar hypoplasia. In children, it is recognized as dyskeratosis congenita (DC) defined by a triad of oral leukoplakia, nail dystrophy and skin hyperpigmentation (Savage & Alter, 2009). Adult-onset telomere disease is heterogeneous and manifests as isolated or syndromic clustering of bone marrow failure, pulmonary fibrosis, and liver cirrhosis (Armanios, 2009). Because the clinical presentation of telomere syndromes is diverse, lymphocyte telomere length measurement is used diagnostically to identify affected individuals (Armanios & Blackburn, 2012). We sought to determine whether telomere syndromes cause GI disease. We show here that they manifest in discrete patterns, and report their prevalence, spectrum, and natural history.

The Johns Hopkins Telomere Syndrome Registry had 38 assessable individuals from 20 families (Methods S1). Of these, six (16%) required evaluation by a gastroenterologist and endoscopy. Clinical findings are summarized in Table 1 and Fig. 1, and the detailed histories are in Data S1. The DKC1, TERT, and TR mutations identified have been reported or shown to compromise telomerase activity (Knight et al., 2001; Marrone & Mason, 2003; Parry et al., 2011). In two cases, no mutations were identified. Lymphocyte telomere length was below the age-adjusted 1st percentile in the five assessable cases (Fig. 1A). Cases were on average 15 years (15 months-34 years), and the GI disease was most severe in the youngest subjects. A 15-month old presented with bloody diarrhea, was diagnosed with enterocolitis, and had severe B cell lymphopenia (Fig. 1B–D). The enterocolitis was refractory to immunosuppression, and she required colectomy and parenteral nutrition support. The GI symptoms persisted after bone marrow transplantation, and led to premature death within a year of diagnosis. A 3-year-old boy with severe swallowing difficulties was found to have a nearly obstructing proximal esophageal web. Three additional cases presented with difficulty gaining weight and abdominal pain, and two were diagnosed with celiac enteropathy based on profound villous atrophy and intraepithelial lymphocytosis (Fig. 1E–G). Case 6 presented with chronic dysphagia and had a proximal esophageal web (Fig. 1H,I).

Table 1. Clinical characteristics of Johns Hopkins Telomere Syndrome Registry subjects with GI disease
CaseAgeGenderClinical/ Genetic diagnosisTelomere phenotypesGI historyEsophageal and gastric findingsSmall and large bowel findings
  1. IUGR, intrauterine growth restriction; TPN, total parenteral nutrition; IEL, refers to intraepithelial lymphocytosis.

  2. a

    This biopsy was not centrally reviewed.

115 monthsFHoyeraal-Hreidarsson

IUGR

Developmental delay

Immunodeficiency

Failure to thrive

Diarrhea-bloody

Colectomy, TPN

Gastric lamina propria-mild fibrosis

Pancolitis, epithelial sloughing

[UPWARDS ARROW] Apoptosis

Gland dropout No plasma cells

23 yearsM

Hoyeraal-Hreidarsson

DKC1 c.472C[RIGHTWARDS ARROW]T

Arg158Trp

IUGR

Developmental Delay

Thrombocytopenia

Dysphagia-solidsEsophageal stenosis-CricopharynxNo data available
37 yearsMDyskeratosis congenita

Developmental Delay

Short stature

Failure to thrive

Abdominal pain post-prandial

Esophageal IEL

Villous blunting [UPWARDS ARROW] Apoptosis

Duodenal neutrophil infiltrates

Duodenal IEL

416 yearsF

Telomere syndrome

hTERT c.3075G[RIGHTWARDS ARROW]T

Val1025Phe

Aplastic Anemia

Immunodeficiency

Failure to thrive

Diarrhea-Watery

TPN

Esophagus- inflammatory changes

Normal duodenal biopsya

Colonic biopsy not performed

534 yearsF

Telomere syndrome

hTR 204C[RIGHTWARDS ARROW]G

Pancytopenia

Abdominal pain

Nausea

Early satiety

Schatzki's ring

Atrophic Gastritis

Esophageal IEL

Parietal Cell Dropout

Villous blunting

[UPWARDS ARROW] Apoptosis

Duodenal and colonic IEL

634 yearsM

Dyskeratosis congenita

DKC1 c.949C[RIGHTWARDS ARROW]T

Leu317Phe

Pancytopenia

Lacrimal duct stenosis

Urethral stenosis

Dysphagia-solids

Abdominal pain post-prandial

Esophageal stenosis-

Cervicothoracic junction

[UPWARDS ARROW] Apoptosis
image

Figure 1. Clinicopathologic findings in individuals with telomere-mediated gastrointestinal disease. (A) Lymphocyte telomere length is plotted relative to distribution of length in 400 controls. C1, C2….etc. refer to cases in Table 1. (B) Rectal endoscopy shows marked erythema with linear ulcerations and narrowing at the rectosigmoid junction (Case 1). (C) Colonic mucosa from Case 1 shows an expanded lamina propria with lymphoid cells and several crypts are completely absent or damaged resulting in mucosal atrophy. The mucosal surface itself is damaged and is partially sloughed off (original magnification, 20X). (D) Higher magnification of the colonic mucosa from Case 1 showing that although the lamina propria on the right side of the field is expanded with lymphoid cells, plasma cells are wholly absent, a finding typically associated with congenital immunodeficiency. The colonic crypt at the left side of the field shows an intraepithleial neutrophil infiltrate (focal acute colitis) at the 2:00 position in the crypt (original magnification 100X). (E) Although the mucosa in this image has the appearance of colonic mucosa, this biopsy was from the duodenum and shows villous atrophy and an expanded lamina propria containing lymphoplasmacytic cells (Case 5, original magnification 20X). (F) High magnification of colonic mucosa displaying striking crypt apoptosis with significant intraepithelial lymphocytosis (Case 5, original magnification 100X). Examples of apoptotic bodies are indicated by *. (G) High magnification of colon demonstrating an anaphase bridge at the center left portion of the field (Case 5, original magnification 125X). Inset of the anaphase bridging is shown in the right upper corner. (H) & (I) Still images from cineesophagopharyngogram demonstrating a tapered luminal defect in the cervical esophagus (Case 6). (J) & (K) Number of apoptotic bodies per 100 crypts in the duodenum and colon, respectively, is plotted relative to controls.

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GI mucosal biopsies in symptomatic cases revealed severe epithelial defects. In the case with enterocolitis, there was profound mucosal sloughing, crypt dropout, increased apoptosis, and absent plasma cells. In milder enteropathy cases, there was villous atrophy, intraepithelial lymphocytosis, and increased mitotic errors such as rings and anaphase bridges (Fig. 1G). There was also an increase in epithelial apoptotic bodies (Fig. 1F). We compared epithelial apoptotic bodies in cases and controls and found a significant increase in the duodenum [28.7 ± 7.2 SEM/100 crypts (n = 4) vs. 5.4 ± 1.3 SEM/100 crypts (n = 7), P < 0.01, unpaired t-test] and colon [70.0 ± 30.0 SEM (n = 2) vs. 6.0 ± 1.0 SEM/100 crypts (n = 8), P < 0.01, Fig. 1J,K]. Gastric epithelial apoptosis was seen in one case with parietal cell dropout.

To extend our findings, we reviewed 591 Pubmed entries, which fulfilled prespecified criteria (Methods S1), and identified 43 additional HH and DC cases with GI disease. Table S1 summarizes the 24 upper GI (Addison & Rice, 1965; Robledo Aguilar et al., 1974; Russo et al., 1990; Dokal et al., 1992; Paul et al., 1992; Sawant et al., 1994; Berezin et al., 1996; Herman et al., 1997; Krishnan et al., 1997; Baselga et al., 1998; Elliott et al., 1999; Ghavamzadeh et al., 1999; Knight et al., 1999; de Roux-Serratrice et al., 2000; Yaghmai et al., 2000; Arca et al., 2003; Sznajer et al., 2003; Kanegane et al., 2005; Utz et al., 2005; Handley & Ogden, 2006; Demirgunes et al., 2008; Sasa et al., 2012), and Table S2, the 23 lower GI cases (Steier et al., 1972; Kehrer et al., 1992; Paul et al., 1992; Berthet et al., 1994; Berezin et al., 1996; Knight et al., 1999; Cossu et al., 2002; Arca et al., 2003; Sznajer et al., 2003; Borggraefe et al., 2009; Touzot et al., 2010; Jyonouchi et al., 2011; Sasa et al., 2012). Dysphagia was the most common upper GI complaint, and esophageal stenosis the most prevalent diagnosis (23 of 24 cases, 96%). Mean age at diagnosis was 11.4 years (1 month–27 years). Strictures localized to the proximal esophagus (eight of nine, 89%), and symptoms improved after dilatation, but repeat procedure was at times required (Addison & Rice, 1965; Paul et al., 1992; Baselga et al., 1998). Stenosis was congenital in four cases with poor feeding history reported since birth (Russo et al., 1990; Knight et al., 1999; Yaghmai et al., 2000; Sznajer et al., 2003), while older children had milder long-standing swallowing difficulties. In most cases (21 of 24, 88%), DC was the underlying telomere disorder, indicating that esophageal stenosis may occur at higher frequency in this population.

Diarrhea due to severe enteropathy was the most common lower GI diagnosis (n = 14, 61%) presenting at a mean of 6.7 years (1 month–21 years). HH syndrome was the predominant underlying telomere disorder (17 of 23, 71%). Findings included pancolitis and atrophic mucosa, and pathology showed gland dropout, lamina propria fibrosis, intraepithelial lymphocytosis, and apoptosis, similar to one of our index cases. Esophageal stenosis preceded or followed lower GI disease at times (Berezin et al., 1996; Knight et al., 1999; Arca et al., 2003; Sznajer et al., 2003; Sasa et al., 2012). Intestinal disease presented earlier in HH than DC (mean 1.4 vs. 17 years, respectively). In all HH cases with intestinal disease, there was a concurrent B-cell lymphopenia and/or hypogammaglobulinemia (16 of 16, 100%). Intestinal disease caused significant morbidity in children requiring colectomy or parenteral nutrition support (Paul et al., 1992; Berthet et al., 1994; Knight et al., 1999; Cossu et al., 2002; Sznajer et al., 2003). Therefore, telomere-mediated intestinal disease can be life-threatening, especially in HH patients.

We show here that short telomere length disrupts GI mucosal integrity in telomere syndromes. Disease affected 16% of our Registry subjects and was at times the first and most severe presentation. The collective experience we report indicates nonmalignant telomere-mediated GI disease manifests in three discrete categories: esophageal stricture, enteropathy, and enterocolitis. Of these, enterocolitis is the most severe and occurs in young children with telomere-related B cell immunodeficiency. Enteropathy has a milder course and is associated with villous atrophy. Esophageal stenosis represents one of several luminal stenotic defects that occur in DC, such as lacrimal duct and urethral stenosis, and likely reflects developmental defects.

The convergence of findings in human telomere syndromes with those seen in telomerase null mice suggests the GI pathology we see is telomere-dependent. Villous atrophy in mice represents a telomere-mediated stem-cell failure (Rudolph et al., 1999), while the enterocolitis is thought to represent a compound defect in the epithelium-immune barrier (Armanios et al., 2009). Mice with short telomeres also develop intestinal microadenoma (Hao et al., 2005), and DC patients have an increased incidence of esophageal, rectal, and possibly gastric cancer, although the overall incidence is relatively low (Alter et al., 2009).

Our findings have clinical implications. A heightened index of suspicion for the GI processes described here in patients with known telomere syndromes, and conversely of telomere disorders in individuals with GI pathology can facilitate early diagnosis, prevent unnecessary work-up, and anticipate/avert complications. Telomere length testing in these cases can be a critical diagnostic tool. We note that the GI disease patterns we describe share features of poorly understood processes such as celiac and inflammatory bowel disease. It is possible that telomere length may be a relevant genetic modifier of disease severity in these disorders where the GI mucosa is disrupted. Because short telomere length is acquired with age, the processes we describe may also point to yet-unrecognized age-dependent disease patterns in the GI tract.

Acknowledgments

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

We are grateful to the subjects and families who participated in this research and to all their referring clinicians. We acknowledge helpful discussions and critical comments from Dr. Mark Donowitz, Dr. Frank Giardiello, and Dr. Maria Oliva-Hemker. The authors acknowledge support from the National Institutes of Health T32DK007632 (NL), RO1CA160433 (MA), and the Doris Duke Charitable Foundation (MA).

Author contributions

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

NLJ and MA conceived the idea and drafted the manuscript; NLJ, EAM, MA evaluated and analyzed clinical data; NG, JC provided important reagents/tools; all the authors reviewed the manuscript.

Potential competing interests

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

Dr. Califano is the Director of Research of the Milton J. Dance Head and Neck Endowment. The terms of this arrangement are being managed by the Johns Hopkins University in accordance with its conflict of interest policies. The other authors have no relevant financial conflict of interest to declare.

References

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information

Supporting Information

  1. Top of page
  2. Summary
  3. Introduction
  4. Acknowledgments
  5. Author contributions
  6. Potential competing interests
  7. References
  8. Supporting Information
FilenameFormatSizeDescription
acel12041-sup-0001-MethodsS1-DataS1-TableS1-S2.docWord document117K

Methods S1. Experimental Methods for the clinical and molecular studies as well as the literature review.

Data S1. Detailed clinical history of Johns Hopkins Registry subjects with gastrointestinal (GI) disease.

Table S1. Clinical findings of cases with upper GI pathology identified in literature review (n = 24).

Table S2. Clinical findings of cases with lower GI pathology (n = 23).

Please note: Wiley Blackwell is not responsible for the content or functionality of any supporting information supplied by the authors. Any queries (other than missing content) should be directed to the corresponding author for the article.