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Organoid cultures of MELAS neural cells reveal hyperactive Notch signaling that impacts neurodevelopment

Winanto Winanto, Zi Jian Khong, Boon-Seng Soh, Yong Fan, Shi‐Yan Ng

2020Cell Death and Disease43 citationsDOIOpen Access PDF

Abstract

Mutations in mitochondrial DNA (mtDNA), typically maternally inherited, can result in severe neurological conditions. There is currently no cure for mitochondrial DNA diseases and treatments focus on management of the symptoms rather than correcting the defects downstream of the mtDNA mutation. Mitochondrial encephalomyopathy, lactic acidosis and stroke-like episodes (MELAS) is one such mitochondrial disease that affects many bodily systems, particularly the central nervous system and skeletal muscles. Given the motor deficits seen in MELAS patients, we investigate the contribution of motor neuron pathology to MELAS. Using a spinal cord organoid system derived from induced pluripotent stem cells of a MELAS patient, as well as its isogenically corrected control, we found that high levels of Notch signaling underlie neurogenesis delays and neurite outgrowth defects that are associated with MELAS neural cultures. Furthermore, we demonstrate that the gamma-secretase inhibitor DAPT can reverse these neurodevelopmental defects.

Topics & Concepts

Mitochondrial encephalomyopathyMitochondrial DNALactic acidosisMELAS syndromeNeurogenesisInduced pluripotent stem cellOrganoidBiologyNotch signaling pathwayMitochondrial diseaseMitochondrionMitochondrial myopathyNeuroscienceMutationPathologyMedicineCell biologyGeneticsEndocrinologyEmbryonic stem cellSignal transductionGeneMitochondrial Function and PathologyMetabolism and Genetic DisordersRNA Research and Splicing
Organoid cultures of MELAS neural cells reveal hyperactive Notch signaling that impacts neurodevelopment | Litcius