Clinical outcome and phenotypic expression in LAMP2 cardiomyopathy.

CONTEXT: Mutations in X-linked lysosome-associated membrane protein gene (LAMP2; Danon disease) produce a cardiomyopathy in young patients that clinically mimics severe hypertrophic cardiomyopathy (HCM) due to sarcomere protein mutations. However, the natural history and phenotypic expression of this newly recognized disease is incompletely resolved and its identification may have important clinical implications. OBJECTIVES: To determine the clinical consequences, outcome, and phenotypic expression of LAMP2 cardiomyopathy associated with diagnostic and management strategies. DESIGN, SETTING, AND PATIENTS: Clinical course and outcome were assessed prospectively in 7 young patients (6 boys) with defined LAMP2 mutations from the time of diagnosis (age 7-17 years; median, 14 years) to October 2008. Phenotypic expression of this disease was assessed both clinically and at autopsy. MAIN OUTCOME MEASURES: Progressive heart failure, cardiac death, and transplant. RESULTS: Over a mean (SD) follow-up of 8.6 (2.6) years, and by age 14 to 24 years, the study patients developed left ventricular systolic dysfunction (mean [SD] ejection fraction, 25% [7%]) and cavity enlargement, as well as particularly adverse clinical consequences, including progressive refractory heart failure and death (n = 4), sudden death (n = 1), aborted cardiac arrest (n = 1), or heart transplantation (n = 1). Left ventricular hypertrophy was particularly marked (maximum thickness, 29-65 mm; mean [SD], 44 [15] mm), including 2 patients with massive ventricular septal thickness of 60 mm and 65 mm at ages 23 and 14 years, respectively. In 6 patients, a ventricular pre-excitation pattern at study entry was associated with markedly increased voltages of R-wave or S-wave (15-145 mm; mean [SD], 69 [39] mm), and deeply inverted T-waves. Autopsy findings included a combination of histopathologic features that were consistent with a lysosomal storage disease (ie, clusters of vacuolated myocytes) but also typical of HCM due to sarcomere protein mutations (ie, myocyte disarray, small vessel disease, myocardial scarring). CONCLUSIONS: LAMP2 cardiomyopathy is a profound disease process characterized by progressive clinical deterioration leading rapidly to cardiac death in young patients (<25 years). These observations underscore the importance of timely molecular diagnosis for predicting prognosis and early consideration of heart transplantation.

Glycogen storage diseases presenting as hypertrophic cardiomyopathy.

BACKGROUND: Unexplained left ventricular hypertrophy often prompts the diagnosis of hypertrophic cardiomyopathy, a sarcomere-protein gene disorder. Because mutations in the gene for AMP-activated protein kinase gamma2 (PRKAG2) cause an accumulation of cardiac glycogen and left ventricular hypertrophy that mimics hypertrophic cardiomyopathy, we hypothesized that hypertrophic cardiomyopathy might also be clinically misdiagnosed in patients with other mutations in genes regulating glycogen metabolism. METHODS: Genetic analyses performed in 75 consecutive unrelated patients with hypertrophic cardiomyopathy detected 40 sarcomere-protein mutations. In the remaining 35 patients, PRKAG2, lysosome-associated membrane protein 2 (LAMP2), alpha-galactosidase (GLA), and acid alpha-1,4-glucosidase (GAA) genes were studied. RESULTS: Gene defects causing Fabry's disease (GLA) and Pompe's disease (GAA) were not found, but two LAMP2 and one PRKAG2 mutations were identified in probands with prominent hypertrophy and electrophysiological abnormalities. These results prompted the study of two additional, independent series of patients. Genetic analyses of 20 subjects with massive hypertrophy (left ventricular wall thickness, > or =30 mm) but without electrophysiological abnormalities revealed mutations in neither LAMP2 nor PRKAG2. Genetic analyses of 24 subjects with increased left ventricular wall thickness and electrocardiograms suggesting ventricular preexcitation revealed four LAMP2 and seven PRKAG2 mutations. Clinical features associated with defects in LAMP2 included male sex, severe hypertrophy, early onset (at 8 to 17 years of age), ventricular preexcitation, and asymptomatic elevations of two serum proteins. CONCLUSIONS: LAMP2 mutations typically cause multisystem glycogen-storage disease (Danon's disease) but can also present as a primary cardiomyopathy. The glycogen-storage cardiomyopathy produced by LAMP2 or PRKAG2 mutations resembles hypertrophic cardiomyopathy but is distinguished by electrophysiological abnormalities, particularly ventricular preexcitation.

Profound left ventricular remodeling associated with LAMP2 cardiomyopathy.

Lysosome-associated membrane protein (LAMP2) cardiomyopathy is an X-linked and highly progressive myocardial storage disorder associated with diminished survival, which clinically resembles sarcomeric hypertrophic cardiomyopathy. As shown here in a young woman, the natural history of LAMP2 may demonstrate an extreme profile of left ventricular remodeling with regression of hypertrophy (i.e. marked wall thinning), chamber dilatation, and severe systolic dysfunction, all of which are associated with widespread transmural scarring.

Fetal and neonatal presentation of noncompacted ventricular myocardium: expanding the clinical spectrum.

BACKGROUND: Noncompaction of the ventricular myocardium (NCVM) is a rare cardiomyopathy characterized by varying degrees of ventricular dysfunction and numerous, prominent trabeculations with deep intertrabecular recesses caused by arrest in myocardial embryogenesis. NCVM is rarely described in fetal and neonatal patients, and only isolated reports exist to date. METHODS: We conducted a review of clinical and echocardiographic data from 6 neonates found to have NCVM to elucidate aspects of prenatal manifestations, initial presentations, and clinical course/outcome. RESULTS: Six neonates met criteria for diagnosis of NCVM. Five were initially evaluated during fetal life, whereas one patient presented for initial cardiology examination as a neonate. Three of the 5 fetuses had NCVM recognized at the initial examination. Both unrecognized fetuses also had severe prenatal left ventricular dilation and dysfunction. Left ventricular enlargement or increased wall thickness with decreased ejection fraction was evident in all patients at presentation. Mean ejection fraction at presentation was 36% and improved to 57% during an average follow-up of 2 years. Associated congenital cardiac anomalies were noted in 3 patients. After initial improvement, two patients had transient, late decreases in ejection fraction, which improved with medication adjustment. There have been no deaths. CONCLUSION: Fetuses with enlarged and poorly functioning left ventricles should be evaluated for NCVM, which may not be easily recognized on initial fetal studies. Unlike previous reports of neonatal NCVM, all 6 neonates, including the 3 requiring inotropic support, showed significant early recovery of cardiac function with aggressive therapy.