Research Article

Originally Published 16 August 2004

Prevalence of Fabry Disease in Female Patients With Late-Onset Hypertrophic Cardiomyopathy

Cristina Chimenti, MD PhD, Maurizio Pieroni, MD, Emanuela Morgante, MD, Daniela Antuzzi, PhD, Andrea Russo, MD, Matteo Antonio Russo, MD, Attilio Maseri, MD, and Andrea Frustaci, MDAuthor Info & Affiliations

Circulation

Volume 110, Number 9

https://doi.org/10.1161/01.CIR.0000139847.74101.03

PDF/EPUB

Abstract

Background— Fabry disease (FD) has been recognized as the cause of left ventricular hypertrophy in 6% of men with late-onset hypertrophic cardiomyopathy (HCM). Although FD is considered a recessive X-linked disorder, affected women are increasingly reported. The aim of our study was to determine the prevalence of FD in female patients with HCM.

Methods and Results— Thirty-four consecutive women (mean age, 50±13.6 years) who received an ECG and echocardiographic diagnosis of HCM were submitted to an invasive cardiac study that included a biventricular endomyocardial biopsy. Tissue samples were analyzed for histology and electron microscopy. Peripheral blood activity of α-galactosidase (α-Gal) A was assessed in all patients. None of them had a family history of FD. Histology and electron microscopy showed in 4 patients (12%; mean age, 51.5±3.9 years) the presence of cell vacuoles characterized by the accumulation of glycolipid material organized in concentric lamellar structures, diagnostic for FD. In the remaining patients, histology was consistent with HCM. In all the female carriers, the heart was the only organ clinically involved in the disease, showing concentric hypertrophy in 2 patients, asymmetric hypertrophy in 1, and apical hypertrophy in 1. The α-Gal A enzymatic activity was 44±14% of control values. Genetic analysis showed the presence of α-Gal A gene mutation in all 4 cases.

Conclusions— FD may account for up to 12% of females with late-onset HCM. Those heterozygous for FD with left ventricular hypertrophy are potential candidates for enzyme enhancement/replacement therapy.

Fabry disease (FD) is an inborn lysosomal storage disorder characterized by a pathological intracellular glycosphingolipids deposition. The disease is caused by a deficit in the lysosomal enzyme α-galactosidase A (α-Gal A), the gene for which is located in the X chromosomal region Xq22.¹ Cardiac involvement, consisting of progressive left ventricular hypertrophy (LVH), is very common and is the most frequent cause of death.¹ The heart can be the only organ involved in the so called “cardiac variant,” an entity that has been recognized in 3% of male patients with LVH and in up to 6% of men with late-onset hypertrophic cardiomyopathy (HCM).^2,3

Although FD has been considered an X-linked recessive disorder,¹ affected women are increasingly recognized, suggesting that the disease follows an X-linked–dominant rather than –recessive transmission.⁴ Clinical manifestations in female carriers range from severe symptoms manifesting in childhood and adolescence, as in affected males, to a relative asymptomatic condition. In late adulthood, some carriers develop LVH and, more rarely, renal manifestations. In a recent study, cardiac involvement was detected in 56% of heterozygous female patients <38 years of age, in 86% of female patients >38 years of age, and in all patients >45 years of age.⁴

The prevalence of FD in female patients with HCM is still unknown. The differential diagnosis between the 2 entities is very important because effective enzyme enhancement/replacement therapy for FD has recently been made available.^5,6

The aim of the present study was to investigate the prevalence of FD in a population of female patients with a clinical and instrumental diagnosis of HCM.

Methods

Study Population

From October 1996 to June 2003 in our institution, 475 consecutive unrelated female patients (age, 68±12 years) showed ECG and echocardiograph evidence of LVH (ventricular septum and/or posterior wall thickness ≥13 mm).² Of these 475, 272 (57%) had systemic hypertension, 143 (30%) had aortic valvular stenosis, 26 (5%) were affected by severe aortic valve regurgitation, and 34 (7%; mean age, 50±14 years) received a diagnosis of HCM on the basis of otherwise unexplained left ventricular (LV) wall thickening.⁷ Our institution is a tertiary referral center dedicated to the study of different types of cardiac muscle diseases, including HCM, in adults. The patients referred came mainly from the center and south of Italy, and ≈30% of them were intrainstitutional referrals.

Beginning in October 1996, all patients with a noninvasive diagnosis of HCM underwent systematically invasive studies, including endomyocardial biopsy, and the assessment of α-Gal A activity. The female patients studied before this period were not considered in the present study, although all women evaluated from that date until June 2003 were included, without any other selection criteria. In the same time period, 62 male patients were diagnosed as being affected by HCM, resulting in a total of 96 patients. The screening for α-Gal A activity allowed us to recognize 2 of the 62 men (3.3%) as being affected by the cardiac variant of FD, and that diagnosis was confirmed by histological and ultrastructural studies of the endomyocardial tissue and by gene mutation analysis.

Among the 34 female patients with HCM, 28 were diagnosed at ≥40 years of age (mean, 55±9 years; range, 40 to 67 years) and 6 at ≤40 years of age (mean, 27±6 years; range, 20 to 36 years). Five patients had a family history of HCM, whereas none had a family history of FD.

Clinical Studies

Clinical examination, resting ECG, Holter monitoring, 2D echocardiography with Doppler analysis, and cardiac MRI were performed in all 34 patients. Echocardiographic study was performed as previously described.⁸ Tissue Doppler analysis was also performed in the pulsed Doppler mode to record mitral annulus velocities at septal and lateral corners. Fifteen age-matched women with no evidence of LVH or cardiac or systemic disease were used as control subjects. The pattern of hypertrophy was defined as asymmetric septal (septal-to-posterior free-wall-thickness ratio of ≥1.3), concentric (septal-to-posterior free-wall-thickness ratio <1.3),⁹ or apical in the presence of a prevalent involvement of the LV apex.

All patients were submitted to invasive cardiac studies, including cardiac catheterization, coronary and biventricular angiography, and biventricular endomyocardial biopsy. The invasive cardiac exams were performed after informed consent was obtained and were approved by the ethics committee of our institution.

Endomyocardial biopsies (3 to 4 per ventricular chamber) were performed with a Bipal (Cordis) bioptome, approached by a 7F (501–613 and 501–613A) long sheet in the septal-apical region of both ventricles. Myocardial samples were processed for routine histological and histochemical analyses, including periodic acid-Schiff and Sudan black staining on frozen tissue, and for transmission electron microscopy as previously described.⁶

Biochemical Studies

Α-Gal A activity was assessed in the white blood cells in all patients.⁶ Normal values were considered between 1012 to 2824 nmol/h per 1 mg protein. The α-Gal A enzymatic activity was also expressed as a percentage of the control mean value in each assay.

Genetic Analysis

Genomic DNA was isolated from peripheral blood (Puregene DNA Isolation Kit, Gentra System), and all α-Gal A coding regions and adjacent intronic regions were sequenced.⁶

Statistical Analysis

All values were expressed as mean±SD. Significance between 2 groups was determined by unpaired Student’s t test for continuous variables and by Fisher’s exact test for discrete variables. Tissue Doppler imaging variables were compared among the 3 groups by ANOVA with Bonferroni’s t test for pairwise comparisons. Values of P<0.05 were considered significant.

Results

In 4 of 34 patients (12%), histological examination of biventricular endomyocardial tissue showed the presence of regularly arranged and severely hypertrophied myocardial fibers with large perinuclear vacuoles containing material that, on frozen sections, stained positively with periodic acid-Schiff and Sudan black, suggesting the accumulation of glycolipids. At electron microscopy, the vacuoles appeared to be represented by concentric, lamellar figures in single membrane-bound vesicles (Figure 1B), consistent with the diagnosis of FD. Figure 2 shows a FD mimicking an apical HCM.

**Figure 1.** Patient 2. A, 2D echocardiographic apical 4-chamber view during diastole showing marked concentric LVH. B, Transmission electron microscopy of endomyocardial biopsy showing at low magnification (right; ×3600; bar=10 μm) 3 myocardiocytes containing large inclusions consisting at higher magnification (left; ×11 000; bar=1 μm) of single membrane-bound vesicles containing concentric, lamellar, electron-dense figures typical of glycolipid storage.

**Figure 2.** Patient 3. A, 12-lead ECG showing signs of LVH and ST-segment depression with giant negative T waves in precordial leads, suggesting apical HCM. B, End-diastolic (left) and end-systolic (right) echocardiographic apical 4-chamber view showing severe wall hypertrophy and cavity obliteration of ventricular apex. C, LV angiography in right anterior oblique (30°) view showing massive apical hypertrophy of LV. D, LV endomyocardial biopsy showing normal cells (arrows) intermingled with cells containing glycolipid inclusion vacuoles (arrowheads) (hematoxylin and eosin; ×200).

The histological findings of the 4 female patients were compared with endomyocardial biopsy samples from 5 hemizygous male patients affected by FD. In female carriers, 2 populations of cells, 1 without glycolipid accumulation and 1 with severe lipid deposits, were observed in all cases; the affected cells represented 65% to 90% of myocardiocytes (Figure 3A). No right ventricular or LV specimen showed the absence of affected cells. The amount and localization of affected cells were evaluated in serial histological sections of each endomyocardial sample, thus excluding the plane of sectioning as the cause of the different appearance of myocytes. Conversely, in male patients, a homogeneous population of cells with lipid storage was always detected, even in the presence of the same α-Gal gene mutation as in the female patients (Figure 3B).

**Figure 3.** LV endomyocardial biopsy of patient 4 (A) and her 58-year-old cousin (B) showing focal and diffuse myocyte engulfment, respectively, by glycolipid material (hematoxylin and eosin; ×250).

In the other 30 patients, the histology was suggestive of HCM, showing severely hypertrophied myocytes, often in disarray, and short runs of myocardial fibers interrupted by connective tissue. These findings were observed in each patient in at least 1 LV endomyocardial sample and, because of the absence of histological markers of other specific diseases, were considered consistent with HCM.

At electron microscopy, the hypertrophied myocytes showed a disorganization of myofibrils and myofilaments, and no intracellular lamellar inclusions were seen.

Mean age at diagnosis and clinical manifestations did not differ between the FD and HCM patients (Table 1). The ECGs met the criteria for LVH (Sokolow-Lyon index) with repolarization changes in all 34 patients. At echocardiography, there was no difference between FD and HCM in terms of severity of LVH and LV dimensions and contractility (Table 1). Tissue Doppler imaging showed a reduction in Sa, Ea, and Aa velocities in all patients at both corners of the mitral annulus compared with normal control subjects, indicating an alteration in contraction and relaxation properties of cardiac muscle, but these parameters did not differentiate FD from HCM (Table 2). Moreover, the acoustic qualities of the LV myocardium did not differ between patients with HCM and FD. LV angiography showed an increase in wall thickness and ventricular contractility and no abnormalities in the segmental wall motion. Coronary angiography was normal in all 34 patients. LV end-diastolic pressure was increased in all patients. Cardiac MRI confirmed the presence of LVH in all patients without specific intramyocardial signal alterations.

TABLE 1. Clinical and Echocardiographic Data of HCM and FD Patients

	HCM Patients (n=30)	FD Patients (n=4)	P
LVESD indicates LV end-systolic diameter; LVEDD, LV end-diastolic diameter, IVS, interventricular septum; LVPW, LV posterior wall; LVEF, LF ejection fraction; and SAM, systolic anterior motion of the mitral valve. Values are mean±SD when appropriate. P<0.05 was considered significant.
Age, y	50±14.4	51.0±4.6	0.88
NYHA class, n (%)
I	8 (31)	1 (25)	1
II	13 (50)	2 (50)	1
III	4 (15)	1 (25)	0.48
Ventricular arrhythmias, n (%)	12 (40)	1 (25)	1
Chest pain, n (%)	10 (33)	1 (25)	1
LVESD, mm	29.2±2.5	28±4.9	0.42
LVEDD, mm	44.2±5.8	44.7±4.1	0.86
IVS, mm	18.0±3.5	18.5±4.0	0.88
LVPW, mm	14.4±2.3	14.5±2.6	0.93
LVEF, %	65.6±5.1	66.2±8.5	0.83
SAM, n (%)	5 (16)	0	1
Outflow gradient ≥30 mm Hg, n (%)	5 (16)	0	1
Left atrium, mm	46±5	47±3.6	0.84
Pattern of LVH, n (%)
Asymmetric	18 (60)	1 (25)	0.29
Concentric	10 (33)	2 (50)	0.60
Apical	4 (14)	1 (25)	0.48

TABLE 2. Tissue Doppler Velocities in HCM Patients, FD Patients, and Normal Control Subjects

	HCM Patients (n=30), cm/s	FD Patients (n=4), cm/s	Control Subjects (n=15), cm/s
*P<0.001 vs control subjects.
†P= NS vs HCM patients.
Lateral Sa	6.2±0.4^*	6.1±0.5^*^†	14.6±1.9
Lateral Ea	5.9±0.4^*	5.8±0.2^*^†	15.3±1.5
Lateral Aa	6.7±0.6^*	6.6±0.2^*^†	9.5±0.7
Septal Sa	6.0±0.6^*	5.9±0.7^*^†	14.5±1.9
Septal Ea	5.4±0.9^*	5.3±0.8^*^†	15.1±1.2
Septal Aa	6.2±0.6^*	6.1±0.6^*^†	9.7±1.0

Characteristics of FD patients, including the pattern of LVH, are shown in Table 3. No significant valvular abnormalities, particularly mitral valve insufficiency, were detected.

TABLE 3. Characteristics of FD Patients

	Patient 1	Patient 2	Patient 3	Patient 4
Abbreviations as in Table 1, plus VA indicates ventricular arrhythmias.
Age, y	45	53	50	56
Cardiac manifestations	Dyspnea	Dyspnea, VA	Dyspnea, VA, chest pain	Dyspnea, chest pain
Enzymatic activity
nmol/h per 1 mg protein	1067.50±56.47	1445.25±268.36	923.15±73	378.43±160.83
Percentage of normal mean values, %	60	41	48	25
LVESD, mm	32	30	26	29
LVEDD, mm	51	49	44	45
IVS, mm	17	20	13	20
LVPW, mm	15	18	12	13
LVEF, %	55	70	75	65
Pattern of LVH	Concentric	Concentric	Apical	Asymmetric
Mutation in α-Gal A gene
Exon/intron location	Exon 7	Exon 7	Exon 5	Exon 5
Nucleotide change	Del CT	c1133G→A	c680A→T	c215A→G
Effect on coding sequence	Frameshift/stop codon	Amino acid change	Amino acid change	Amino acid change
Genotype	L344-X₂₈-stop	C378Y	R227Q	N215S

All FD patients were >40 years of age at diagnosis. None of them was aware of being a carrier of FD or had other clinical manifestations of the disease. Routine laboratory investigations showed in patient 4 the presence of mild proteinuria (0.85 g/L) with normal creatinine clearance. A renal biopsy performed in this patient revealed the presence of patchy intracellular glycolipid accumulation, consistent with the early renal changes observed in FD.¹⁰ The same patient had also cornea verticillata that did not affect the vision, typical of FD.

No abnormalities in the laboratory tests or extracardiac signs of FD were detected in the other 3 cases.

Biochemical Studies

The α-Gal A enzymatic activity showed normal values in 2 patients, nearly normal values in 1 patient, and low values in the remaining patient (patient 4) (Table 3). In particular, the percentage of mean control value was 44±14%, showing a high residual enzymatic activity. The α-Gal A enzymatic activity was normal in all HCM patients (2326±453 nmol/h per 1 mg protein).

Genetic Analysis and Family Survey

The causal mutation was identified in all 4 patients affected by FD (Table 3). Although none of them were aware of being a carrier or had family members with a diagnosis of this disorder, their identification allowed the detection of FD in relatives.

Indeed, after the diagnosis of FD was made in the patients, the assessment of α-Gal A activity was extended to all available family members. In addition, a careful evaluation of the extracardiac clinical signs of FD, particularly in male subjects, and a gene mutation analysis were performed.

Affected members were detected in 3 patients’ families. Patient 1 did not have any family member affected by the disease, suggesting a de novo mutation. However, the mother, who died at 71 years of age of idiopathic heart failure, might have been affected by FD.

Mutation analysis of the mother of patient 2 revealed that she was the carrier of the disease in the family, despite normal enzymatic activity and only mild LVH misdiagnosed as caused by hypertension. The abnormal X chromosome was inherited by the patient’s sister, who was asymptomatic, and the patient’s brother, who suffered of several episodes of hypoacusia and died at 42 years of age of a cerebrovascular accident. One of the patient’s 2 sons, 24 years of age, showed at clinical evaluation the presence of angiokeratomas in the umbilical area; the other son, 21 years of age, suffered episodes of acroparesthesias. Both sons suffered from hypohydrosis and, at ophthalmologic examination, had whorled corneal opacity. The 17-year-old daughter of the patient’s brother was significantly clinically affected by the disease, showing acroparesthesias, hypohydrosis, exercise intolerance, hypoacusia, and cornea verticillata at the initial stage, with low levels of enzymatic activity comparable to that of the affected male patients.

Clinical evaluation of the 2 sons (29 and 27 years old) of patient 3 revealed the presence of angiokeratomas and corneal opacity in both. The 29-year-old son referred also to suffering from exercise intolerance and episodic pain in the extremities. The patient’s brother died at 53 years of age of renal failure without being diagnosed as suffering from FD. His 25-year-old daughter was a carrier of the disease with no clinical signs and normal enzymatic activity. In this family, the carrier of the disease was presumably the patient’s grandmother, who was deceased at the time of the diagnosis of FD.

The pedigree and the clinical, biochemical, and molecular study of the family of patient 4 are shown in Figure 4.

**Figure 4.** Family pedigree of patient 4 (A) and clinical manifestation of affected family members (B). Enzymatic activity is expressed as nmol/h per 1 mg protein. NE indicates not evaluated.

Discussion

Although several reports exist in the literature on cardiac involvement in female carriers of FD, in terms of either systemic disease similar to hemizygous males or as the predominantly affected organ,^4,11 no systematic study on the prevalence of FD in women with HCM is available.

Isolated cardiac manifestations in women without a family history of FD have included cardiomegaly with complete AV block,¹² short PR interval, and cardiac sudden death.¹³

Our study documented, for the first time in a large cohort of female patients with a clinical and instrumental diagnosis of HCM, that up to 12% of these patients were affected by FD. This high prevalence, however, derived from a study population of ≈50 years of age and should be expected in women with late-onset (≥ 40 years) HCM. In a larger HCM group including a higher number of young patients, such a percentage would decrease because it is related to the typical late-age presentation of Fabry cardiomyopathy.

FD was indistinguishable from HCM in all noninvasive and invasive cardiac exams except endomyocardial biopsy. In fact, clinical features of Fabry patients were those of concentric HCM in 2 patients, asymmetric HCM in 1 patient, and apical HCM in 1 patient.

Unpredictably, histology showed in these 4 patients no cell disarray but regularly arranged myocardiocytes containing large perinuclear and cytoplasmic vacuoles that at electron microscopy consisted of concentric lamellar bodies. Histological lesions had a patchy distribution affecting 65% to 90% of myocardiocytes. This finding was absent in endomyocardial biopsies of male hemizygous patients even in the presence of the same mutation of the α-Gal A gene. Indeed, the presence of 2 different populations, one with normal and one with reduced α-Gal A activity, has been demonstrated in cultured skin fibroblasts from a patient heterozygous for FD.¹⁴

The higher percentage of myocardial cells involved in the disease suggested a nonrandom or skewed inactivation of the wild-type X chromosome. Skewed X inactivation, a phenomenon by which the same X chromosome is silenced in most of or all the cells of a tissue, has been shown to be common in normal female subjects, and the X-inactivation pattern can vary widely between different tissues.^15–17 This variability makes inaccurate the extrapolation of the X-inactivation status from one tissue to another and explains the nearly normal values of blood α-Gal A activity in most (75%) of our female patients despite severe cardiac disease and the higher prevalence of isolated cardiac involvement compared with hemizygous males. The poor diagnostic role of blood α-Gal A activity (indicative of FD in only 25% of our cases) and the nonspecific contributions of noninvasive tools such as 2D echocardiography and cardiac MRI raise questions as to how Fabry cardiomyopathy can be detected in women with idiopathic LVH. In our series, male family members of 3 of 4 women with Fabry cardiomyopathy showed, at retrospective clinical analysis, systemic evidence of FD as angiokeratoma, cornea verticillata, or acroparesthesia associated with low levels of α-Gal A activity. Therefore, a careful family survey can in many instances provide useful indications for a correct diagnosis, which can be confirmed by appropriate genetic study. Questions remain about women with Fabry cardiomyopathy in the absence of affected male family members and with normal α-Gal A enzymatic levels, like patient 1 of our series, in whom a de novo mutation might be present. In this context, genetic screening of the α-Gal A gene, eventually implemented by an endomyocardial biopsy, particularly before the institution of a lifelong enzyme replacement treatment, should be considered. In particular, analysis of the α-Gal A gene is a reliable noninvasive approach for diagnosing FD because both we and Sachdev et al³ identified mutations in all patients with HCM affected by FD. The differential diagnosis of the 2 pathological conditions has important clinical implications because β-blockers, Ca²⁺ antagonists, and disopyramide, commonly adopted in HCM, may be contraindicated in Fabry cardiomyopathy patients in whom a latent contractile dysfunction is common. In addition, for FD, both enzyme enhancement therapy with galactose infusion⁶ and enzyme replacement therapy⁵ have been effective in clearing glycolipid accumulation in myocytes, with a reduction in LV hypertrophy and mass and an improvement in cardiac function, even in female patients.¹⁸

On the other hand, cardiovascular complications in the form of thromboembolic events, cardiac arrhythmias, and sudden death can occur at any time in the clinical course of the disease. Now we have a chance to be prevent these complications by enzyme enhancement/replacement therapy

Acknowledgments

The financial support of Telethon-Italy (grant GGP030344) is gratefully acknowledged.

References

Desnick RJ, Ioannou YA, Eng CM. α-Galactosidase A deficiency: Fabry disease. In: Scriver CR, Beaudet AL, Sly WS, et al, eds. The Metabolic and Molecular Bases of Inherited Disease. New York, NY: McGraw-Hill; 2001: 3733–3774.

Abstract

Methods

Study Population

Clinical Studies

Biochemical Studies

Genetic Analysis

Statistical Analysis

Results

Biochemical Studies

Genetic Analysis and Family Survey

Discussion

Acknowledgments

References

eLetters(0)

Information

Published In

Copyright

Versions

History

Permissions

Keywords

Subjects

Notes

Authors

Affiliations

Notes

Metrics

Citations

View options

PDF and All Supplements

PDF/EPUB

Login options

Purchase Options

Restore your content access

Share

Share article link

Share