Integrating Genetic, Clinical, and Histopathological Data for Definitive Diagnosis of PRKAG2-Related Disease

A previously healthy 32-year-old female undergoes evaluation after a syncopal episode. Physical examination reveals a systolic ejection murmur. Echocardiography demonstrates a vigorous LV with marked asymmetric septal hypertrophy, systolic anterior motion of the mitral valve, and a 50–mm Hg outflow tract gradient. Family history is notable for unexpected death in 4 paternal family members. She has 2 children (Figure 1A). Figure 1. A, HCM is a genetic cardiovascular disease. This family shows autosomal dominant inheritance with &50% of the family affected and equal numbers of affected male (▪) and female (•) family members. The case patient is indicated by an arrow. Deceased individuals are indicated by a diagonal slash (all died suddenly). B, DNA sequence analysis can identify sarcomere mutations that cause HCM. Top, The normal sequence of a portion of the cardiac troponin T gene is displayed with a triplet codon, TCC, encoding serine present. Bottom, DNA sequence obtained from a patient with HCM. The normal sequence is present on the allele inherited from the unaffected parent; the other allele shows a single base-pair substitution of a thymidine residue for the normal cytosine residue. This triplet codon, TTC, encodes phenylalanine and results in the substitution of a phenylalanine residue for the normal serine residue at amino acid position 179. The prevalence of unexplained left ventricular hypertrophy (LVH) in the general population is estimated to be 1 in 500.1,2 Hypertrophic cardiomyopathy (HCM) caused by sarcomere mutations may account for up to 60% of unexplained LVH, making HCM the most common genetic cardiovascular disorder.3–5 Accurate diagnosis of HCM is important for appropriate management of major HCM comorbidities, including atrial fibrillation, stroke, heart failure, and sudden cardiac death (SCD).6,7 HCM typically is diagnosed by unexplained LVH on echocardiography. Age of onset of LVH ranges from early childhood to …

PRKAG2 cardiomyopathy is a rare genetic disorder that manifests early in life with an autosomal dominant inheritance pattern. It harbors left ventricular hypertrophy (LVH), ventricular pre-excitation and progressively worsening conduction system defects. Its estimated prevalence among patients with LVH ranges from 0.23 to about 1%, but it is likely an underdiagnosed condition. We report the association of the PRKAG2 missense variant c.1006G>A p. (Val336Ile) with LVH, conduction abnormalities (short PR interval and incomplete right bundle branch bock) and early-onset arterial hypertension (AH) in a 44-year-old Caucasian patient. While cardiac magnetic resonance (CMR) showed a mild hypertrophic phenotype with maximal wall thickness of 17 mm in absence of tissue alterations, the electric phenotype was relevant including brady-tachy syndrome and recurrent syncope. The same variant has been detected in the patient's sister and daughter, with LVH + early-onset AH and electrocardiographic (ECG) alterations + lipothymic episodes, respectively. Paying close attention to the coexistence of LVH and ECG alterations in the proband has been helpful in directing genetic tests to exclude primary cardiomyopathy. Hence, identifying the genetic basis in the patient allowed for familial screening as well as a proper follow-up and therapeutic management of the affected members. A review of the PRKAG2 cardiomyopathy literature is provided alongside the case report.

A Pacemaker Red Herring and a Hypertrophic Cardiomyopathy Copycat.

Hypertrophic cardiomyopathy (HCM) is a common monogenetic cardiac disease with a prevalence of 0.2%1 that usually is inherited as an autosomal dominant trait with variable penetrance and expression. Clinically, HCM is defined by the presence of left ventricular (LV) hypertrophy (LVH) unexplained by abnormal loading conditions.1 The natural history varies from an asymptomatic course to drug-refractory angina/dyspnea, sudden cardiac death (SCD), and end-stage heart failure. The incidence of HCM-related SCD is approximately 1% to 2% in children and adolescents and 0.5% to 1% in adults.2,3 In this review, we examine the impact of advanced diagnostic imaging technologies on HCM, with particular emphasis on the detection of particular genetic subtypes. In ≈60% of cases, HCM is inherited as an autosomal dominant trait caused by mutations in genes coding for cardiac sarcomere proteins (Figure 1).4–7 Mutations in genes encoding Z-disc proteins and proteins involved in calcium regulation account for <5% of cases. The absence of sarcomeric gene mutations can be explained by limitations of current mutation detection techniques or mutations in as yet unidentified genes, but in some cases, hypertrophy is caused by other diseases that mimic the phenotype of sarcomeric protein disease. Table 1 lists genetic disorders associated with HCM. Figure 1. A schematic illustration of a cardiac sarcomere. View this table: Table 1. Currently Known Genes Implicated in HCM More than 600 different sarcomeric gene mutations are reported in patients with HCM.8–16 The majority are missense mutations, but nonsense, frameshift, and in-frame insertion/deletion mutations also occur. Most mutations are characterized by incomplete penetrance and variable clinical expression likely due to locus heterogeneity and the effect of mutations at different locations within the same gene. Most mutations probably have a dominant negative effect on sarcomere function, but in some cases, haploinsufficiency (ie, only a single functional …

Background: Transthyretin (TTR) amyloid cardiomyopathy (ATTR-CM) is increasingly being recognized as a cause of left ventricular (LV) hypertrophy (LVH) and progressive heart failure in elderly patients. However, little is known about the cardiac morphology of ATTR-CM and the association between the degree of TTR amyloid deposition and cardiac dysfunction in these patients. Methods: We studied 28 consecutive patients with ATTR-CM and analyzed the relationship between echocardiographic parameters and pathological features using endomyocardial biopsy samples. Results: The cardiac geometries of patients with ATTR-CM were mainly classified as concentric LVH (96.4%). The relative wall thickness, a marker of LVH, tended to be positively correlated with the degree of non-cardiomyocyte area. The extent of TTR deposition was positively correlated with enlargement of the non-cardiomyocyte area, and these were positively correlated with LV diastolic dysfunction. Additionally, the extent of the area containing TTR was positively correlated with the percentage of cardiomyocyte nuclei stained for 8-hydroxy-2′deoxyguanosine, a marker of reactive oxygen species (ROS). ROS accumulation in cardiomyocytes was positively correlated with LV systolic dysfunction. Conclusion: Patients with ATTR-CM mainly displayed concentric LVH geometry. TTR amyloid deposition was associated with cardiac dysfunction via increased non-cardiomyocyte area and ROS accumulation in cardiomyocytes.

BackgroundPRKAG2 cardiac syndrome is a rare autosomal dominant genetic disorder caused by a PRKAG2 gene variant. There are several major adverse cardiac presentations, including hypertrophic cardiomyopathy (HCM) and life‐threatening arrhythmia. Two cases with pathogenic variants in the PRKAG2 gene are reported here who presents different cardiac phenotypes.MethodsExome sequencing and variant analysis of PRKAG2 were performed to obtain genetic data, and clinical characteristics were determined.ResultsThe first proband was a 9‐month‐old female infant (Case 1), and was identified with severe DCM and resistant heart failure. The second proband was a 10‐year‐old female infant (Case 2), and presented with HCM and ventricular preexcitation. Exome sequencing identified a de novo c.425C > T (p.T142I) heterozygous variant in the PRKAG2 gene for Case 1, and a c.869A > T (p.K290I) for Case 2. The mutated sites in the protein were labeled and identified as p.K290 in the CBS domain and p.T142 in the non‐CBS domain. Differences in the molecular functions of CBS and non‐CBS domains have not been resolved, and variants might lead to the different cardiomyopathy phenotypes. Single‐cell RNA analysis demonstrated similar expression levels of PRKAG2 in cardiomyocytes and conductive tissues. These results suggest that the arrhythmia induced by the PRKAG2 variant was the primary change, and not secondary to cardiomyopathy.ConclusionIn summary, this is the first case report to describe a DCM phenotype with early onset in patients possessing a PRKAG2 c.425C > T (p.T142I) pathogenic variant. Our results aid in understanding the molecular function of non‐CBS variants in terms of the disordered sequence of transcripts. Moreover, we used scRNA‐seq to show that electrically conductive cells express a higher level of PRKAG2 than do cardiomyocytes. Therefore, variants in PRKAG2 are expected to also alter the biological function of the conduction system.

case presentation: A 48-year-old woman presents with exertional dyspnea and recurrent syncope. One year earlier, a permanent pacemaker was placed after she complained of fatigue and was found to have high-grade atrioventricular block. Now, she has echocardiographic evidence of moderate to severe left ventricular (LV) systolic dysfunction with regional wall-motion abnormalities. Nuclear imaging is notable for heterogeneous myocardial uptake of technetium Tc99m sestamibi, and coronary angiography reveals widely patent epicardial vessels. Multiple episodes of nonsustained ventricular tachycardia (VT) are documented on continuous ECG monitoring. What are the diagnostic considerations for this patient, and what further evaluations are indicated? This patient presents with dilated cardiomyopathy (DCM) with electric instability (DCM+E), which we define as conduction disease and arrhythmia out of proportion to the severity of LV systolic dysfunction. Diverse causes can result in DCM+E and fall into general categories of inflammatory, infectious, hereditary, and infiltrative processes. Cardiac presentation associated with these conditions is distinct from more common causes of DCM such as ischemic heart disease, viral myocarditis, valvular dysfunction, pregnancy, or substance abuse. Clinical features that are suggestive of DCM+E include supraventricular arrhythmias or conduction disease that precedes cardiomyopathy, multiple VT morphologies, and features suggestive of ischemic heart disease (Q waves, regional wall-motion abnormalities, perfusion defects, ventricular aneurysm) in the absence of epicardial stenoses. In this Clinician Update, we focus on the diagnostic approach to patients with DCM+E. Emphasis is placed on diagnoses that are relatively common or for which the clinical management would be impacted significantly by recognition of the underlying cause. Ischemic heart disease may present with conduction disease and a high burden of arrhythmia, especially in the setting of acute myocardial ischemia/infarction. The exclusion of obstructive coronary artery disease is strongly recommended in patients with DCM+E because atherosclerosis is so prevalent, evidence-based treatment is readily available, and the …

Mechanical dyssynchrony: another mechanism of left ventricular dysfunction in hypertension?

BackgroundIn young patients presenting with Wolff-Parkinson-White syndrome and left ventricular hypertrophy (LVH), a genetic aetiology should be considered, particularly when cardiovascular risk factors such as hypertension or valvular heart disease are not present, or when there is a suggestive family history of cardiomyopathy. PRKAG2 syndrome is a rare genetic disorder characterized by cardiac glycogen storage, ventricular pre-excitation, and hypertrophy, often mimicking hypertrophic cardiomyopathy (HCM).Case SummaryA 22-year-old male with a history of WPW syndrome presented with recurrent palpitations and wide QRS tachycardia. Post-cardioversion electrocardiography (ECG) revealed persistent pre-excitation, and transthoracic echocardiography confirmed LVH with preserved systolic function. Cardiac magnetic resonance imaging demonstrated normal myocardial mass without late gadolinium enhancement. Genetic testing, prompted by a family history of sudden cardiac death (SCD), using a targeted panel sequencing including sarcomere protein gene mutations and other cardiomyopathy-related genes, identified a heterozygous PRKAG2 mutation. Given the high-risk of SCD, implantable cardioverter-defibrillator placement was recommended but declined. The patient subsequently experienced a fatal cardiac arrest 8 days after the last clinic visit.DiscussionThis case highlights the importance of genetic evaluation in young patients with unexplained arrhythmias and hypertrophy. PRKAG2 mutations, often overlooked in standard HCM panels, can lead to misdiagnosis and inadequate risk stratification. Clinicians should maintain a high index of suspicion for PRKAG2 syndrome, particularly in patients with conduction abnormalities, ventricular arrhythmias, and LVH. Early identification using genetic tests, risk assessment, and family screening are crucial to preventing adverse outcomes, including SCD.

Anderson-Fabry disease.

Clinical characteristics and natural history of PRKAG2 syndrome

In the coming years, remarkable advances in understanding the genetic underpinnings of rare and common disorders will transform the clinical care of patients with inherited cardiovascular conditions. Discoveries from genome-wide association studies, next-generation sequencing studies, and novel bioinformatics approaches have already revolutionized our diagnostic capabilities for monogenic and polygenic disorders. Translating and implementing this information into daily clinical practice lags considerably. We are confronting a significant genetics/genomics literacy gap in the clinical workforce that threatens to widen without dedicated efforts to address it. Here, we present a case that highlights the importance of a soliciting a minimum 3-generation family history in all cases of cardiomyopathy and the pitfalls of ordering genetic testing without a sufficient infrastructure for interpretation and return of results. A 58-year-old woman was referred to our institution for management of recurrent atrial and ventricular arrhythmias. She first experienced palpitations at age 14 years, which were initially attributed to atrial arrhythmias and were well controlled on medical therapy. In her early 40s, they became refractory to antiarrhythmic medications. She underwent multiple electrical cardioversions and catheter ablations for atrial flutter, atrial fibrillation, and atrial tachycardia with a decrease in atrial arrhythmia burden but incomplete control. At age of 50 years, a dual chamber pacemaker was implanted for sinus node dysfunction. On routine device interrogation 19 months later, she was noted to have recurrent nonsustained ventricular tachycardia (VT) and was referred for cardiac magnetic resonance imaging (MRI) to evaluate for left ventricular (LV) and right ventricular fibrosis. Cardiac MRI demonstrated extensive multifocal patchy midmyocardial delayed gadolinium enhancement thought to be consistent with myocarditis versus cardiac sarcoidosis. Her moderately decreased LV ejection fraction of 43% was attributed to poor ventricular rate control with recurrent atrial arrhythmias. Subsequent evaluation with F-18 fluorodeoxyglucose (18F-FDG) cardiac positron emission tomography/computed tomography (PET/CT) showed no …

Idiopathic left ventricular hypertrophy (LVH) is defined as LVH in the absence of myocyte disarray or secondary causes. It is unclear whether idiopathic LVH represents the phenotypic spectrum of hypertrophic cardiomyopathy (HCM) or whether it is a unique disease entity. We aimed to ascertain the prevalence of HCM in first-degree relatives of decedents from sudden death with idiopathic LVH at autopsy. Decedents also underwent molecular autopsy to identify the presence of pathogenic variants in genes implicated in HCM. Families of 46 decedents with idiopathic LVH (125 first-degree relatives) were investigated with electrocardiogram, echocardiogram exercise tolerance test, cardiovascular magnetic resonance imaging, 24-h Holter, and ajmaline provocation test. Next-generation sequencing molecular autopsy was performed in 14 (30%) cases. Decedents with idiopathic LVH were aged 33 ± 14 years and 40 (87%) were male. Fourteen families (30%) comprising 16 individuals were diagnosed with cardiac disease, including Brugada syndrome (n = 8), long QT syndrome (n = 3), cardiomyopathy (n = 2), and Wolff-Parkinson-White syndrome (n = 1). None of the family members were diagnosed with HCM. Molecular autopsy did not identify any pathogenic or likely pathogenic variants in genes encoding sarcomeric proteins. Two decedents had pathogenic variants associated with long QT syndrome, which were confirmed in relatives with the clinical phenotype. One decedent had a pathogenic variant associated with Danon disease in the absence of any histopathological findings of the condition or clinical phenotype in the family. Idiopathic LVH appears to be a distinct disease entity from HCM and is associated with fatal arrhythmias in individuals with primary arrhythmia syndromes. Family screening in relatives of decedents with idiopathic LVH should be comprehensive and encompass the broader spectrum of inherited cardiac conditions, including channelopathies.

Reduced Diagnostic Accuracy of Apical-Sparing Strain Abnormality for Cardiac Amyloidosis in Patients with Chronic Kidney Disease

DEVELOPMENT OF AN IN VITRO STUDY MODEL OF PRKAG2 CARDIOMYOPATHY USING HUMAN INDUCED PLURIPOTENT STEM CELLS