The mutation m.13513G>A impairs cardiac function, favoring a neuroectoderm commitment, in a mutant-load dependent way.
Teresa Galera-MongeFrancisco Zurita-DíazRafael GaresseMaría Esther GallardoPublished in: Journal of cellular physiology (2019)
Mitochondrial disorders (MDs) arise as a result of a respiratory chain dysfunction. While some MDs can affect a single organ, many involve several organs, the brain being the most affected, followed by heart and/or muscle. Many of these diseases are associated with heteroplasmic mutations in the mitochondrial DNA (mtDNA). The proportion of mutated mtDNA must exceed a critical threshold to produce disease. Therefore, understanding how embryonic development determines the heteroplasmy level in each tissue could explain the organ susceptibility and the clinical heterogeneity observed in these patients. In this report, the dynamics of heteroplasmy and the influence in cardiac commitment of the mutational load of the m.13513G>A mutation has been analyzed. This mutation has been reported as a frequent cause of Leigh syndrome (LS) and is commonly associated with cardiac problems. In this report, induced pluripotent stem cell (iPSc) technology has been used to delve into the molecular mechanisms underlying cardiac disease in LS. When mutation m.13513G>A is above a threshold, iPSc-derived cardiomyocytes (iPSc-CMs) could not be obtained due to an inefficient epithelial-mesenchymal transition. Surprisingly, these cells are redirected toward neuroectodermal lineages that would give rise to the brain. However, when mutation is below that threshold, dysfunctional CM are generated in a mutant-load dependent way. We suggest that distribution of the m.13513G>A mutation during cardiac differentiation is not at random. We propose a possible explanation of why neuropathology is a frequent feature of MD, but cardiac involvement is not always present.
Keyphrases
- mitochondrial dna
- copy number
- left ventricular
- stem cells
- epithelial mesenchymal transition
- end stage renal disease
- heart failure
- chronic kidney disease
- ejection fraction
- mental health
- induced apoptosis
- signaling pathway
- prognostic factors
- skeletal muscle
- white matter
- newly diagnosed
- peritoneal dialysis
- wild type
- transforming growth factor
- gene expression
- functional connectivity
- blood brain barrier
- case report
- mesenchymal stem cells
- induced pluripotent stem cells