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Dichloroacetate improves mitochondrial function, physiology, and morphology in FBXL4 disease models
来源: | 作者:Manuela Lavorato 1, Eiko Nakamaru-Ogiso 1, Neal D Mathew 1, Elizabeth Herman 1, Nina K Shah 1, Suraiya Haroon 1, Rui Xiao 2, Christoph Seiler 3, Marni J Falk 1 | 发布时间: 2022-08-08 | 315 次浏览 | 分享到:

Pathogenic variants in the human F Box and Leucine Rich Repeat Protein 4 (FBXL4) gene result in an autosomal recessive, multi-systemic, mitochondrial disorder involving variable mitochondrial depletion and respiratory chain (RC) complex deficiencies with lactic acidemia. As no FDA-approved effective therapies exist, we sought to characterize translational C. elegans and zebrafish animal models, as well as human fibroblasts, to study FBXL4-/- disease mechanisms and identify preclinical therapeutic leads. Developmental delay, impaired fecundity and neurologic and/or muscular activity, mitochondrial dysfunction, and altered lactate metabolism were identified in fbxl-1(ok3741) C. elegans. Detailed studies of a pyruvate dehydrogenase complex activator, dichloroacetate (DCA) in fbxl-1(ok3741) C. elegans demonstrated its beneficial effects on fecundity, neuromotor activity, and mitochondrial function. Validation studies were performed in fbxl4sa12470 zebrafish larvae and in FBXL4-/- human fibroblasts, which showed DCA efficacy in preventing brain damage, impairment of neurologic and/or muscular function, mitochondrial biochemical dysfunction, and stress-induced morphologic and ultrastructural mitochondrial defects. These data demonstrate that fbxl-1 (ok3741) C. elegans and fbxl4sa12470 zebrafish provide robust translational models to study mechanisms and identify preclinical therapeutic candidates for FBXL4-/- disease. Further, DCA is a lead therapeutic candidate with therapeutic benefit on diverse aspects of survival, neurologic and/or muscular function, and mitochondrial physiology that warrants rigorous clinical trial study in human subjects with FBXL4-/- disease.

Keywords: Drug therapy; Genetic diseases; Genetics; Metabolism; Mitochondria.

原文地址:http://www.ncbi.nlm.nih.gov/pubmed/35881484