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A pore-localizing CACNA1C-E1115K missense mutation, identified in a patient with idiopathic QT prolongation, bradycardia, and autism spectrum disorder, converts the L-type calcium channel into a hybrid nonselective monovalent cation channel.
Ye, D, Tester, DJ, Zhou, W, Papagiannis, J, Ackerman, MJ
Heart rhythm. 2019;(2):270-278
Abstract
BACKGROUND Gain-of-function variants in the CACNA1C-encoded L-type calcium channel (LTCC, Cav1.2) cause type 8 long QT syndrome (LQT8). The pore region contains highly conserved glutamic acid (E) residues that collectively form the LTCC's selectivity filter. Here, we identified and characterized a pore-localizing missense variant, E1115K, that yielded a novel perturbation in the LTCC. OBJECTIVE The purpose of this study was to determine whether CACNA1C-E1115K alters the LTCC's selectivity and is the substrate for the patient's LQTS. METHODS The proband was a 14-year-old male with idiopathic QT prolongation and bradycardia. Genetic testing revealed a missense variant, CACNA1C-E1115K. The whole-cell patch clamp technique was used to measure CACNA1C-WT and -E1115K currents when heterologously expressed in TSA201 cells. RESULTS The CACNA1C-E1115K channel exhibited no inward calcium current. Instead, robust cardiac transient outward potassium current (Ito)-like outward currents that were blocked significantly by nifedipine were measured when 2 mM/0.1 mM extracellular/intracellular CaCl2 or 4 mM/141 mM extracellular/intracellular KCl was applied. Furthermore, when 140 mM extracellular NaCl was applied, the CACNA1C-E1115K channel revealed both robust inward persistent Na+ currents with slower inactivation and outward currents, which were also nifedipine sensitive. In contrast, CACNA1C-WT revealed only a small inward persistent Na+ current without a robust outward current. CONCLUSION This CACNA1C-E1115K variant destroyed the LTCC's calcium selectivity and instead converted the mutant channel into a channel with a marked increase in sodium-mediated inward currents and potassium-mediated outward currents. Despite the anticipated 50% reduction in LTCC, the creation of a new population of channels with accentuated inward and outward currents represents the likely pathogenic substrates for the patient's LQTS and arrhythmia phenotype.
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Heterozygous familial hypercholesterolaemia in a pair of identical twins: a case report and updated review.
Mohd Nor, NS, Al-Khateeb, AM, Chua, YA, Mohd Kasim, NA, Mohd Nawawi, H
BMC pediatrics. 2019;(1):106
Abstract
BACKGROUND Familial hypercholesterolaemia (FH) is the most common inherited metabolic disease with an autosomal dominant mode of inheritance. It is characterised by raised serum levels of total cholesterol (TC) and low-density lipoprotein cholesterol (LDL-c), leading to premature coronary artery disease. Children with FH are subjected to early and enhanced atherosclerosis, leading to greater risk of coronary events, including premature coronary artery disease. To the best of our knowledge, this is the first report of a pair of monochorionic diamniotic identical twins with a diagnosis of heterozygous FH, resulting from mutations in both LDLR and ABCG8 genes. CASE PRESENTATION This is a rare case of a pair of 8-year-old monochorionic diamniotic identical twin, who on family cascade screening were diagnosed as definite FH, according to the Dutch Lipid Clinic Criteria (DLCC) with a score of 10. There were no lipid stigmata noted. Baseline lipid profiles revealed severe hypercholesterolaemia, (TC = 10.5 mmol/L, 10.6 mmol/L; LDL-c = 8.8 mmol/L, 8.6 mmol/L respectively). Their father is the index case who initially presented with premature CAD, and subsequently diagnosed as FH. Family cascade screening identified clinical FH in other family members including their paternal grandfather who also had premature CAD, and another elder brother, aged 10 years. Genetic analysis by targeted next-generation sequencing using MiSeq platform (Illumina) was performed to detect mutations in LDLR, APOB100, PCSK9, ABCG5, ABCG8, APOE and LDLRAP1 genes. Results revealed that the twin, their elder brother, father and grandfather are heterozygous for a missense mutation (c.530C > T) in LDLR that was previously reported as a pathogenic mutation. In addition, the twin has heterozygous ABCG8 gene mutation (c.55G > C). Their eldest brother aged 12 years and their mother both had normal lipid profiles with absence of LDLR gene mutation. CONCLUSION A rare case of Asian monochorionic diamniotic identical twin, with clinically diagnosed and molecularly confirmed heterozygous FH, due to LDLR and ABCG8 gene mutations have been reported. Childhood FH may not present with the classical physical manifestations including the pathognomonic lipid stigmata as in adults. Therefore, childhood FH can be diagnosed early using a combination of clinical criteria and molecular analyses.
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Familial Disease Is Not Always Genetic: A Family With Atrioventricular Block and Mitral Regurgitation.
Vermeer, AM, Lodder, EM, Christiaans, I, van Langen, IM, Wilde, AA, Bezzina, CR, Tadros, R
The Canadian journal of cardiology. 2017;(4):554.e9-554.e11
Abstract
We present a family from a founder population referred for cardiogenetic evaluation for atrioventricular block in 3 siblings. Genetic testing, including whole-exome sequencing, did not identify a disease-causing mutation. After reconsidering the differential diagnosis, a nongenetic cause was identified. This case highlights the importance of a thorough clinical evaluation even when a genetic cause is seemingly obvious.
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The biophysical characterization of the first SCN5A mutation R1512W identified in Chinese sudden unexplained nocturnal death syndrome.
Zheng, J, Zhou, F, Su, T, Huang, L, Wu, Y, Yin, K, Wu, Q, Tang, S, Makielski, JC, Cheng, J
Medicine. 2016;(23):e3836
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Abstract
Increasing evidence observed in clinical phenotypes show that abrupt breathing disorders during sleep may play an important role in the pathogenesis of sudden unexplained nocturnal death syndrome (SUNDS). The reported Brugada syndrome causing mutation R1512W in cardiac sodium channel α subunit encoded gene SCN5A, without obvious loss of function of cardiac sodium channel in previous in vitro study, was identified as the first genetic cause of Chinese SUNDS by us. The R1512W carrier was a 38-year-old male SUNDS victim who died suddenly after tachypnea in nocturnal sleep without any structural heart disease. To test our hypothesis that slight acidosis conditions may contribute to the significant loss of function of mutant cardiac sodium channels underlying SUNDS, the biophysical characterization of SCN5A mutation R1512W was performed under both extracellular and intracellular slight acidosis at pH 7.0. The cDNA of R1512W was created using site-directed mutagenesis methods in the pcDNA3 plasmid vector. The wild type (WT) or mutant cardiac sodium channel R1512W was transiently transfected into HEK293 cells. Macroscopic voltage-gated sodium current (INa) was measured 24 hours after transfection with the whole-cell patch clamp method at room temperature in the HEK293 cells. Under the baseline conditions at pH 7.4, R1512W (-175 ± 15 pA/pF) showed about 30% of reduction in peak INa compared to WT (-254 ± 23 pA/pF, P < 0.05). Under the acidosis condition at pH 7.0, R1512W (-130 ± 17 pA/pF) significantly decreased the peak INa by nearly 50% compared to WT (-243 ± 23 pA/pF, P < 0.005). Compared to baseline condition at pH 7.4, the acidosis at pH 7.0 did not affect the peak INa in WT (P > 0.05) but decreased peak INa in R1512W (P < 0.05). This initial functional study for SCN5A mutation in the Chinese SUNDS victim revealed that the acidosis aggravated the loss of function of mutant channel R1512W and suggested that nocturnal sleep disorders-associated slight acidosis may trigger the lethal arrhythmia underlying the sudden death of SUNDS cases in the setting of genetic defect.
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Whole Exome Sequencing, Familial Genomic Triangulation, and Systems Biology Converge to Identify a Novel Nonsense Mutation in TAB2-encoded TGF-beta Activated Kinase 1 in a Child with Polyvalvular Syndrome.
Ackerman, JP, Smestad, JA, Tester, DJ, Qureshi, MY, Crabb, BA, Mendelsohn, NJ, Ackerman, MJ
Congenital heart disease. 2016;(5):452-461
Abstract
OBJECTIVE To use whole exome sequencing (WES) of a family trio to identify a genetic cause for polyvalvular syndrome. METHODS AND RESULTS A male child was born with mild pulmonary valve stenosis and mild aortic root dilatation, and an atrial septal defect, ventricular septal defect, and patent ductus arteriosus that were closed surgically. Subsequently, the phenotype of polyvalvular syndrome with involvement of both semilunar and both atrioventricular valves emerged. His family history was negative for congenital heart disease. Because of hypotonia, myopia, soft pale skin, joint hypermobility, and mild facial dysmorphism, either Noonan syndrome- or William syndrome-spectrum disorders were suspected clinically. However, chromosomal analysis was normal and commercially available Noonan syndrome and William syndrome genetic tests were negative. Whole exome sequencing of the patient and both parents was performed. Variants were analyzed by sporadic and autosomal recessive inheritance models. A sporadic mutation, annotated as c.1491 T > A, in TAB2, resulting in a nonsense mutation, p.Y497X, in the TAB2-encoded TGF-beta activated kinase 1 (TAK1) was identified as the most likely disease-susceptibility gene. This mutation results in elimination of the terminal 197 amino acids, including the C-terminal binding motif critical for interactions with TRAF6 and TAK1. CONCLUSIONS The combination of WES, genomic triangulation, and systems biology has uncovered perturbations in TGF-beta activated kinase 1 signaling as a novel pathogenic substrate for polyvalvular syndrome.
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Tricho-hepato-enteric syndrome (THE-S): two cases and review of the literature.
Chong, JH, Jamuar, SS, Ong, C, Thoon, KC, Tan, ES, Lai, A, Aan, MK, Tan, WL, Foo, R, Tan, EC, et al
European journal of pediatrics. 2015;(10):1405-11
Abstract
UNLABELLED Tricho-hepato-enteric syndrome (THE-S) is characterized by severe infantile diarrhea, failure to thrive, dysmorphism, woolly hair, and immune or hepatic dysfunction. We report two cases of East Asian descent with THE-S who had remained undiagnosed despite extensive investigations but were diagnosed on whole exome sequencing (WES). Both cases presented with chronic diarrhea, failure to thrive, and recurrent infections. Case 1 had posteriorly rotated low set ears, mild retrognathia, and fine curly hypopigmented hair. She was managed with prolonged total parenteral nutrition and intravenous immunoglobulin infusions. Case 2 had sparse coarse brown hair as well as multiple lentigines and café-au-lait macules. She was managed with amino acid-based formula. For both cases, routine investigations were inconclusive. WES in both cases showed biallelic truncating mutations in TTC37 (c.3507T>G;p.Y1169X and c.3601C>T;p.R1201X in case 1 and c.3507T>G;p.Y1169X and c.154G>T;p.E52X in case 2), suggesting a diagnosis of THE-S. CONCLUSION We present novel mutations in the TTC37 gene in two individuals of East Asian descent with the rare THE-S, detected by WES. Future identification of patients with THE-S and establishing genotype-phenotype correlations will aid in counseling the patients and their families. WHAT IS KNOWN • Tricho-Hepato-Enteric syndrome (THE-S) is characterized by severe infantile diarrhea, failure to thrive, dysmorphism, woolly hair, and immune or hepatic dysfunction. • Complex patients with diagnostic dilemmas undergo extensive investigations. What is New: • This is a report of novel mutations in TTC37 in individuals of East Asian descent. • Whole exome sequencing (WES) can be useful in certain complex cases with diagnostic dilemmas.
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Short-coupled polymorphic ventricular tachycardia at rest linked to a novel ryanodine receptor (RyR2) mutation: leaky RyR2 channels under non-stress conditions.
Cheung, JW, Meli, AC, Xie, W, Mittal, S, Reiken, S, Wronska, A, Xu, L, Steinberg, JS, Markowitz, SM, Iwai, S, et al
International journal of cardiology. 2015;:228-36
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Abstract
BACKGROUND Ryanodine receptor (RyR2) mutations have largely been associated with catecholaminergic polymorphic ventricular tachycardia (PMVT). The role of RyR2 mutations in the pathogenesis of arrhythmias and syncope at rest is unknown. We sought to characterize the clinical and functional characteristics associated with a novel RyR2 mutation found in a mother and daughter with PMVT at rest. METHODS AND RESULTS A 31-year-old female with syncope at rest and recurrent short-coupled premature ventricular contractions (PVCs) initiating PMVT was found to be heterozygous for a novel RyR2-H29D mutation. Her mother, who also had syncope at rest and short-coupled PMVT, was found to harbor the same mutation. Human RyR2-H29D mutant channels were generated using site-directed mutagenesis and heterologously expressed in HEK293 cells together with the stabilizing protein calstabin2 (FKPB12.6). Single channel measurements of RyR2-H29D mutant channels and wild type (WT) RyR2 channels were compared at varying concentrations of cytosolic Ca(2+). Binding affinities of the RyR2-H29D channels and RyR2-WT channels to calstabin2 were compared. Functional characterization of the RyR2-H29D mutant channel revealed significantly higher open probability and opening frequency at diastolic levels of cytosolic Ca(2+) under non-stress conditions without protein kinase A treatment. This was associated with a modest depletion of calstabin2 binding under resting conditions. CONCLUSIONS The RyR2-H29D mutation is associated with a clinical phenotype of short-coupled PMVT at rest. In contrast to catecholaminergic PMVT-associated RyR2 mutations, RyR2-H29D causes a leaky channel at diastolic levels of Ca(2+) under non-stress conditions. Leaky RyR2 may be an under-recognized mechanism for idiopathic PMVT at rest.
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CALM3 mutation associated with long QT syndrome.
Reed, GJ, Boczek, NJ, Etheridge, SP, Ackerman, MJ
Heart rhythm. 2015;(2):419-22
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Next-generation sequencing: Application of a novel platform to analyze atypical iron disorders.
McDonald, CJ, Ostini, L, Wallace, DF, Lyons, A, Crawford, DH, Subramaniam, VN
Journal of hepatology. 2015;(5):1288-93
Abstract
The development of targeted next-generation sequencing (NGS) applications now promises to be a clinically viable option for the diagnosis of rare disorders. This approach is proving to have significant utility where standardized testing has failed to identify the underlying molecular basis of disease. We have developed a unique targeted NGS panel for the systematic sequence-based analysis of atypical iron disorders. We report the analysis of 39 genes associated with iron regulation in eight cases of atypical iron dysregulation, in which five cases we identified the definitive causative mutation, and a possible causative mutation in a sixth. We further provide a molecular and cellular characterization study of one of these mutations (TFR2, p.I529N) in a familial case as proof of principle. Cellular analysis of the mutant protein indicates that this amino acid substitution affects the localization of the protein, which results in its retention in the endoplasmic reticulum and thus failure to function at the cell surface. Our unique NGS panel presents a rapid and cost-efficient approach to identify the underlying genetic cause in cases of atypical iron homeostasis disorders.
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Neonatal multiple sulfatase deficiency with a novel mutation and review of the literature.
Nur, BG, Mıhçı, E, Pepe, S, Biberoğlu, G, Ezgü, FS, Ballabio, A, Öztekin, O, Dursun, O
The Turkish journal of pediatrics. 2014;(4):418-22
Abstract
Multiple sulfatase deficiency is a rare autosomal recessive disorder in which affected individuals present a complex phenotype due to the impaired activity of all sulfatases. There are different types of multiple sulfatase deficiency; among them, the neonatal form is the most severe, with a broad range of mucopolysaccharidosis-like symptoms and death within the first year of life. The disorder is caused by homozygous or compound heterozygous mutations in the sulfatase-modifying factor-1 (SUMF1) gene. In this article, we describe a non-ichthyotic neonatal multiple sulfatase deficiency patient with a novel mutation in the SUMF1 gene. The missense mutation c.777C>G, for which the patient was homozygous, had been caused by a p.N259K amino acid substitution. We evaluated the patient using clinical findings, neuroimaging studies and molecular analysis via the literature; we also wanted to note the difficulties in the diagnosis of this rare disease.