Abstract

Modeling the Peripheral Nervous System Disorder Familial Dysautonomia Using Human Pluripotent Stem Cells

Functional and molecular aspects of human genetic disease can be recapitulated in vitro using patient-specific pluripotent stem cells (PSCs). Familial Dysautonomia (FD) is a debilitating developmental and degenerative disorder that primarily affects derivatives of the neural crest (NC), such as the peripheral nervous system (PNS). For unknown reasons, FD patients present with mild or severe disease despite carrying the identical, homozygous point mutation in ELP1. We present in vitro phenotypes at various stages of development that capture severe and mild FD in human PSC-derived cellular lineages. Patient-specific cells only from severe but not mild FD display an impaired capacity of developing into NC derivatives, such as autonomic and sensory neurons, thus they have neurodevelopmental defects. Interestingly however, both severe and mild FD cells show defects in peripheral neuron survival, indicating neurodegeneration as the primary culprit in mild FD. Genetic rescue of the FD mutation in severe FD iPSCs reversed NC, but not sensory neuron lineage phenotypes, implicating that the known FD mutation does not account for all symptoms. Employing whole-exome sequencing (WES), we identified candidate mutations that were only found in severe but not mild FD patients and show that these modifier mutations converge onto defects withing the extracellular matrix. We further found that the sympathetic lineage in severe FD patients is hyperactive, a previously shown culprit of degeneration. Our study demonstrates that human PSC-based disease modeling is highly sensitive in recapitulating disease severity and paves the road for applications in personalized medicine.


Author(s): Nadja Zeltner

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