FDX2 and ISCU Gene Variations Lead to Rhabdomyolysis With Distinct Severity and Iron Regulation
Sebastian Montealegre, Elise Lebigot, Hugo Debruge, Norma Romero, Bénédicte Héron, Pauline Gaignard, Antoine Legendre, Apolline Imbard, Stéphanie Gobin, Emmanuelle Lacène, Patrick Nusbaum, Arnaud Hubas, Isabelle Desguerre, Aude Servais, Pascal Laforêt, Peter van Endert, François Jérome Authier, Cyril Gitiaux, Pascale de Lonlay
Abstract
<h3>Background and Objectives</h3> To determine common clinical and biological traits in 2 individuals with variants in <i>ISCU</i> and <i>FDX2</i>, displaying severe and recurrent rhabdomyolyses and lactic acidosis. <h3>Methods</h3> We performed a clinical characterization of 2 distinct individuals with biallelic <i>ISCU</i> or <i>FDX2</i> variants from 2 separate families and a biological characterization with muscle and cells from those patients. <h3>Results</h3> The individual with <i>FDX2</i> variants was clinically more affected than the individual with <i>ISCU</i> variants. Affected FDX2 individual fibroblasts and myoblasts showed reduced oxygen consumption rates and mitochondrial complex I and PDHc activities, associated with high levels of blood FGF21. ISCU individual fibroblasts showed no oxidative phosphorylation deficiency and moderate increase of blood FGF21 levels relative to controls. The severity of the FDX2 individual was not due to dysfunctional autophagy. Iron was excessively accumulated in ISCU-deficient skeletal muscle, which was accompanied by a downregulation of <i>IRP1</i> and <i>mitoferrin2</i> genes and an upregulation of frataxin (<i>FXN</i>) gene expression. This excessive iron accumulation was absent from FDX2 affected muscle and could not be correlated with variable gene expression in muscle cells. <h3>Discussion</h3> We conclude that <i>FDX2</i> and <i>ISCU</i> variants result in a similar muscle phenotype, that differ in severity and skeletal muscle iron accumulation. ISCU and FDX2 are not involved in mitochondrial iron influx contrary to frataxin.