Non–cell autonomous effect of glia on motor neurons in an embryonic stem cell–based ALS model

FP Di Giorgio, MA Carrasco, MC Siao, T Maniatis… - Nature …, 2007 - nature.com
FP Di Giorgio, MA Carrasco, MC Siao, T Maniatis, K Eggan
Nature neuroscience, 2007nature.com
Here we report an in vitro model system for studying the molecular and cellular mechanisms
that underlie the neurodegenerative disease amyotrophic lateral sclerosis (ALS). Embryonic
stem cells (ESCs) derived from mice carrying normal or mutant transgenic alleles of the
human SOD1 gene were used to generate motor neurons by in vitro differentiation. These
motor neurons could be maintained in long-term coculture either with additional cells that
arose during differentiation or with primary glial cells. Motor neurons carrying either the …
Abstract
Here we report an in vitro model system for studying the molecular and cellular mechanisms that underlie the neurodegenerative disease amyotrophic lateral sclerosis (ALS). Embryonic stem cells (ESCs) derived from mice carrying normal or mutant transgenic alleles of the human SOD1 gene were used to generate motor neurons by in vitro differentiation. These motor neurons could be maintained in long-term coculture either with additional cells that arose during differentiation or with primary glial cells. Motor neurons carrying either the nonpathological human SOD1 transgene or the mutant SOD1G93A allele showed neurodegenerative properties when cocultured with SOD1G93A glial cells. Thus, our studies demonstrate that glial cells carrying a human SOD1G93A mutation have a direct, non–cell autonomous effect on motor neuron survival. More generally, our results show that ESC-based models of disease provide a powerful tool for studying the mechanisms of neural degeneration. These phenotypes displayed in culture could provide cell-based assays for the identification of new ALS drugs.
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