Abstract
Mutations in SCO2 are among the most common causes of COX deficiency, resulting in reduced mitochondrial oxidative ATP production capacity, often leading to hypertrophic cardiomyopathy (HCM). To date, none of the recent pertaining reports provide deep understanding of the SCO2 disease pathophysiology. To investigate the cardiac pathology of the disease, we were the first to generate induced pluripotent stem cell (iPSC)‐derived cardiomyocytes (iPSC‐CMs) from SCO2‐mutated patients. For iPSC generation, we reprogrammed skin fibroblasts from two SCO2 patients and healthy controls. The first patient was a compound heterozygote to the common E140K mutation, and the second was homozygote for the less common G193S mutation. iPSC were differentiated into cardiomyocytes through embryoid body (EB) formation. To test the hypothesis that the SCO2 mutation is associated with mitochondrial abnormalities, and intracellular Ca2+‐overload resulting in functional derangements and arrhythmias, we investigated in SCO2‐mutated iPSC‐CMs (compared to control cardiomyocytes): (i) the ultrastructural changes; (ii) the inotropic responsiveness to β‐adrenergic stimulation, increased [Ca2+]o and angiotensin‐II (AT‐II); and (iii) the Beat Rate Variability (BRV) characteristics. In support of the hypothesis, we found in the mutated iPSC‐CMs major ultrastructural abnormalities and markedly attenuated response to the inotropic interventions and caffeine, as well as delayed afterdepolarizations (DADs) and increased BRV, suggesting impaired SR Ca2+ handling due to attenuated SERCA activity caused by ATP shortage. Our novel results show that iPSC‐CMs are useful for investigating the pathophysiological mechanisms underlying the SCO2 mutation syndrome.
Highlights
Derangements in the mitochondrial respiratory chain and in cytochrome c oxidase (COX) are associated with deleterious effects in organs with high energy demands, such as the heart
Based on the COX deficiency caused by SCO2 mutations, we hypothesized that the SCO2 mutation is associated with mitochondrial abnormalities, and intracellular Ca2+-overload resulting in functional derangements and arrhythmias
We investigated in SCO2-mutated induced pluripotent stem cell (iPSC)-CMs generated from two babies carrying different SCO2 mutations: (i) the ultrastructural changes; (ii) the inotropic responsiveness to b-adrenergic stimulation, increased [Ca2+]o and AT-II; and (iii) the Beat Rate Variability (BRV) characteristics
Summary
Derangements in the mitochondrial respiratory chain and in cytochrome c oxidase (COX) are associated with deleterious effects in organs with high energy demands, such as the heart. The human SCO2 gene encodes a 266-amino-acid metallochaperone that participates in copper delivery to COX [2], and mutations in SCO2 are among the most common causes of COX deficiency [3] These disorders are characterized by encephalopathy and HCM, collectively leading to death in infancy or early childhood [4]. Based on the COX deficiency caused by SCO2 mutations (resulting in ATP shortage), we hypothesized that the SCO2 mutation is associated with mitochondrial abnormalities, and intracellular Ca2+-overload resulting in functional derangements and arrhythmias. To test this hypothesis, we investigated in SCO2-mutated iPSC-CMs generated from two babies (who died at 3–4 months) carrying different SCO2 mutations: (i) the ultrastructural changes; (ii) the inotropic responsiveness to b-adrenergic stimulation, increased [Ca2+]o and AT-II; and (iii) the Beat Rate Variability (BRV) characteristics. In support of our hypothesis, the diseased cardiomyocytes demonstrated abnormal mitochondrial ultrastructure, functional derangements including arrhythmias, suggesting disturbed intracellular Ca2+ homoeostasis, likely due to ATP deficiency
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