a Department of Pediatrics, I.R.C.C.S. Burlo Garofolo, Trieste, Italy
b Department of Cardiology, I.R.C.C.S. Policlinico San Matteo, Pavia, Italy
c Department of Biology, University of Trieste, Trieste, Italy
d Department of Cardiology, Ospedali Riuniti, Bergamo, Italy
e Gastroenterology, University Unit I.R.C.C.S. Policlinico San Matteo, Pavia, Italy
f Molecular Diagnostics, Cardiovascular and Transplant Pathology Laboratory, Transplant Research Area, I.R.C.C.S. Policlinico San Matteo, Pavia, Italy
* Correspondence to: Eloisa Arbustini, MD, Molecular Diagnostic, Cardiovascular and Transplant Pathology Laboratory, Transplant Research Area, I.R.C.C.S. Policlinico San Matteo, Via Forlanini 16, 27100 Pavia, Italy. Tel: +39 0382 503829; fax: +39 0382 525866
E-mail address: e.arbustini{at}smatteo.pv.it
Received 12 December 2002; revised 15 May 2003; accepted 21 May 2003
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Abstract |
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Methods and results We screened anti-human-tissue-transglutaminase (IgA and IgG anti-h-tTG) and anti-endomysial antibodies (AEAs) in 238 consecutive adult patients with inherited or sporadic dilated cardiomyopathy (DCM), 418 relatives, and 2000 healthy blood donors. HLADQ2-DQ8 was tested in tTG-positive subjects. The IgA-tTG-positive patients with cardiomyopathy underwent duodenal biopsy. Twenty-six subjects were tTG-positive: five DCM patients (2.1%), two of 28 (7.1%) and three of 390 (0.7%) relatives with and without echocardiographic abnormalities respectively, and 16 controls (0.8%). Twenty-two of 26 subjects were AEA-positive, and 25 HLA-positive. Of the five patients with cardiomyopathy and biopsy-proven CD, four suffered iron-deficiency anaemia. Two CD-positive DCM patients and two tTG-positive relatives were from families with inherited disease in which CD did not co-segregate with DCM.
Conclusions The higher prevalence of CD in patients with sporadic or inherited DCM, and of tTG-positive serology in relatives with echocardiographic abnormalities, suggests that immune-mediated mechanisms are active in subsets of patients/families. However, gluten intolerance cannot be considered causative since CD seems to be associated but not co-segregated with DCM in familial cases.
Key Words: Celiac disease Dilated cardiomyopathy Tissue-transglutaminase
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1. Introduction |
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Bearing in mind the above data, Curione et al.10, found an increased prevalence of CD among patients with idiopathic dilated cardiomyopathy (DCM) (3/52 patients, 5.7% vs 0.4% in the general population), a severe chronic disease in which autoimmune mechanisms may play a part.11The association between CD and cardiomyopathy was further confirmed in the Danish National Registry of patients.12More recently, a smaller percentage of patients entering the waiting list for heart transplantation for end-stage cardiomyopathy (12/642, 1.9%) were found to be endomysial antibody positive as against 0.35% of healthy controls (34/9729).13Although to different extents both of these series confirm that CD is more prevalent in DCM patients than the control population.
The aetiological setting of cardiomyopathies is extremely complex and heterogeneous: hypertrophic cardiomyopathies (HCM) are monogenic disorders mainly inherited as autosomal dominant traits,14whereas only 25% of idiopathic DCM cases are inherited.15The full phenotypical expression of the disease can be preceded by echo- or electro-cardiographic changes such as left ventricular dilatation, decreased fractional shortening, left bundle branch block or atrio-ventricular block.16,17
In this study, we screened for CD a consecutive series of index patients with DCM as well as their relatives with or without instrumental signs indicating myocardial alterations. We also evaluated how other autoimmune disorders in the study population are related to silent, unrecognized CD.
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2. Methods |
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The diagnosis of DCM was based on WHO criteria.18All of the patients with DCM underwent endomyocardial biopsy. All of the male patients underwent dystrophin gene analysis,19and all of the patients with familial disease underwent screening for known disease-causing genes.20The informed and consenting relatives who accepted the screening underwent a clinical examination, 12-lead electrocardiography, echocardiography and serum creatine-phosphokinase determinations.15Clinical and pathological records were obtained for deceased affected relatives.
The healthy control group consisted of 2000 informed and consent potential blood donors at their first test (1390 male, median age 35 years, range 1860).
2.2. Study design
Serum samples positive for IgA-IgG anti-h-tTG were analysed for IgA anti-endomysial antibodies (AEA) and the related CD class II HLA molecules: the DQ2 heterodimer encoded by the DQ1*0501/DQß1*02 combination, or the HLA DQ8 heterodimer encoded by the DQ
1*0301/DQß1*0302 alleles. All of the subjects who were positive for both CD-related auto-antibodies and HLA DQ2-8 were recommended to undergo small intestine biopsies, which were classified according to a modified version of Marsh's classification.21The subjects with normal IgA and IgG anti-tTG antibody values were categorized as not having CD.
2.3. ELISA for anti-h-tTG
Serum IgA and IgG anti-h-tTG antibodies were determined as previously reported.22Microtitre plates (EIA/RIA 2580, Costar) were coated by incubating 1µg of h-tTG in 100l of phosphate buffered saline (PBS) in each well overnight at 4°C. The plates were washed three times with PBS, 0.05% Tween 20, and the wells were blocked by means of incubation with 100µl of PBS, 0.1% Tween 20, for 20min at room temperature (RT). Serum samples diluted 1:100 in PBS, 0.1% Tween 20, were incubated for 1h at RT. The plates were washed and incubated for 1h at RT with either 1:4000 phosphatase-conjugated anti-human IgA (Sigma A-3062) or 1:2000 anti-human IgG (Sigma A-8542) diluted in PBS, bovine serum albumin 1%. The immune reaction was developed by adding a substrate solution and the absorbance was read in a microplate reader at 405nm until the positive control serum reached an optical density value of 2 for IgA or 1.5 for IgG. The results were expressed as percentages of the positive control serum. Normal values were taken as <16% for IgA and <42% for IgG, which represented a value >2SD above the mean of 400 healthy subjects (210 female, 190 male, median age 17 years, range 224).
2.4. Anti-endomysial antibody assay
Serum IgA anti-endomysial antibody (AEA) levels were measured by means of an indirect immunofluorescence assay using cryostat sections of human umbilical cord tissue, as previously described.23Briefly, the sections were incubated for 30min with the subject's serum diluted 1:5. After washing, the sections were incubated with fluorescein-labelled goat anti-human IgA antibodies for 30min. The slides were washed and examined by means of fluorescent microscopy. The immunological tests were performed by four operators (T.A., F.E., N.T., B.V.) unaware of the clinical and laboratory findings.
2.5. HLA-DQ typing
The known susceptibility alleles for CD were determined by means of polymerase chain reaction with allele-specific primers identifying DQ2 and DQ8, carried out using a Dynal Classic SSP DQ kit (Dynal A.S.). The genetic tests were performed by three operators (S.A., S.D., M.R.) unaware of the clinical and immunological findings.
2.6. Statistical analysis
The categorical variables were expressed as percentages and compared using the chi-square test. The continuous variables were expressed as mean values.
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3. Results |
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The comorbidities in the five celiac patients discovered during the present screening included iron-deficiency anaemia in four cases, as well as a series of other conditions potentially associated with CD (Table 1). Of the five CD-positive relatives, one had iron-deficiency anaemia and a 17-year-old healthy boy has a recent history of two bone fractures.
3.4. Clinical and genetic basis of the cardiomyopathies and co-morbidities(Fig. 2)
Ofthe five CD-positive DCM patients, one had familial autosomal dominant disease and one X-linked recessive dystrophin defect-related disease (in-frame deletion of exon 48). A third patient (24 years old) had a history of acute myeloid leukaemia treated with anthracyclines at the age of 6 years. The two remaining DCM patients had sporadic disease.
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4. Discussion |
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Our data emphasise the diagnostic value of anti-h-tTG antibodies, which were able to identify one biopsy proven celiac subject missed by AEA assay (patient no. A4). The present finding confirms previous studies and our own experience in which human recombinant tTG based ELISA has higher sensitivity (98% vs 90%) and specificity (99% vs 100%) and positive predictive value (97% vs 100%) of the standard AEA test.24
The non-causative role of CD in the cardiomyopathy is proved by the inheritance of DCM in 2/5 cases: one had X-linked DCM caused by the in-frame deletion of exons 48 of the dystrophin gene, and the other autosomal dominant DCM (more than one living member of the family is proven to be affected) without any within-family co-segregation of CD with the cardiac phenotype. Furthermore, one of the three sporadic DCM cases has a history of acute myeloid leukaemia treated with anthracyclines at the age of 6 years. Myocardial toxicity by anthracyclines is a proven cause of DCM.25Unrecognized CD may have a facilitated DCM, when a genetic- or drug-related cofactor is present. Further support for the non-causative role of CD emerges from the non-segregation of the cardiac phenotype with CD in the families with inherited DCM both autosomal dominant and with four affected siblings, in which the tTG-positive members had echocardiographic abnormalities but did not meet the full diagnostic criteria for DCM and the corresponding probands are tTG-negative (cases no. 7, no. 8; Table 1).
As a number of studies bear witness to the higher prevalence of CD among patients with DCM than in normal controls,10,13the major clinical problem seems to be identifying this sub-population. If CD is found in both sporadic and inherited DCM, and the combination of the two conditions is not casual, specific clinical markers of the CD should be identified. The recent study by Frustaci et al.26showing a higher prevalence of CD among patients with idiopathic congestive heart failure and a biopsy-proven diagnosis of myocarditis suggests a potential link between inflammatory myocardial disease and autoimmunity. Thirteen of the 187 patients with biopsy- proven myocarditis had CD-related autoantibodies, nine of whom also had AEAs (4.4%). In terms of myocarditis, our DCM series differs from that reported by Frustaci et al.26in so far as all of them underwent endomyocardial biopsy but none of the CD-positive patients had myocarditis and none of those with biopsy-proven myocarditis had CD. The rationale for linking the two apparently unrelated disorders of CD and myocarditis is strong, especially in the case of sporadic forms of idiopathic heart failure. If confirmed in other series, myocardial inflammation may be a useful marker for CD screening in patients with idiopathic congestive heart failure.
The extra-intestinal manifestations of CD could also be helpful. All of the nine patients described by Frustaci et al.26, and four of our five DCM patients (as well as one of the relatives with echocardiographic abnormalities) had iron-deficiency anaemia. Iron-deficiency anaemia is the most common clinical presentation of CD in adults,27,28and its presence may have a negative impact on the clinical outcome of DCM patients. It has recently been shown that anaemia is associated with worse symptoms, greater functional impairment, and a significant increase in mortality in patients with congestive heart failure.29Other extra-intestinal manifestations that may be useful in CD screening include thyroiditis, type-1 diabetes mellitus, dermatitis herpetiformis, bone fractures, psychiatric and neurological syndromes, infertility and abortions. For example, one of our two female CD-positive DCM patients had experienced two spontaneous abortions. Furthermore, the 17-year-old CD-positive family member of our series had experienced two bone fractures that are known to recur more frequently in CD patients than in normal controls.30In the practical clinical setting, patients with DCM and iron-refractory anaemia, or poli-abortivity, infertility, or evidence of bone fragility etc. could be elective candidates to CD screening. Alternatively, all DCM patients should undergo screening: the low costs of the tTG test would not be a major limit.
A potentially significant association between CD and DCM is highly suggestive, especially in the case of sporadic diseases. Mechanisms shared by CD and DCM could involve ubiquitary activation of metalloproteases,31extramolecular epitope spreading,32and non tTG-related autoimmunity.33Anti-tTG antibodies may have a shared affinity to antigen epitopes of different cells/tissues, or different antigens could mimic tTG epitopes. Cardiomyopathies may enter the list of atypical presentations of CD, but this hypothesis requires confirmation.
In conclusion, our study indicates a non-causal link between CD and DCM. This association seems to be unrelated to the aetiology: CD was diagnosed in autosomal dominant, X-linked, drug-toxicity and sporadic DCM. However, the higher prevalence of CD in DCM patients (confirming previous reports) and their relatives than in controls, and the extra-intestinal co-morbidity data, suggest that CD may contribute to the cardiac phenotype either as a direct effect of the autoantibodies or by means of associated conditions that may worsen the DCM outcome. Furthermore, comorbidities such as iron-deficiency anaemia, could be useful markers for arousing the clinical suspicion of CD in patients with cardiomyopathy. Therefore, CD should be specifically looked for in patients diagnosed with DCM at least when co-morbidity signs potentially related to CD are present.
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Appendix A |
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The authors thank the informed and consenting patients and relatives who agreed to participate in the clinical programme of family screening, as well as all volunteers who accepted to enter the screening of the normal population.
Role of funding source
The study was entirely supported by public funding from the Ministry of Health, granted to E.A., L.T., A.G., and A.V.
Patient consent
The patients and relatives gave their informed consent; in addition to informative interviews that the clinicians had with the patients first, and then with their relatives, a booklet entitled Informative path for patients diagnosed as having cardiomyopathies and their families was given to each family. The screening program on healthy subjects was approved by Ethical Committee of I.R.C.C.S. Burlo Garofolo, Trieste (Research Programs from 1997 up to #30/2000, updated 17/05/2000 and 21/12/2000). The Research Projects on Familial Cardiomyopathies: non invasive screening of relatives and Celiac Disease and Dilated Cardiomyopathy were approved by the Ethical Committee of the I.R.C.C.S. Policlinico San Matteo, Pavia (RC/1998 and RC/2000, confirmed 2002).
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References |
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