Abstract
The deubiquitylating enzyme Usp9x is highly expressed in the developing mouse brain, and increased Usp9x expression enhances the self-renewal of neural progenitors in vitro. USP9X is a candidate gene for human neurodevelopmental disorders, including lissencephaly, epilepsy and X-linked intellectual disability. To determine if Usp9x is critical to mammalian brain development we conditionally deleted the gene from neural progenitors, and their subsequent progeny. Mating Usp9xloxP/loxP mice with mice expressing Cre recombinase from the Nestin promoter deleted Usp9x throughout the entire brain, and resulted in early postnatal lethality. Although the overall brain architecture was intact, loss of Usp9x disrupted the cellular organization of the ventricular and sub-ventricular zones, and cortical plate. Usp9x absence also led to dramatic reductions in axonal length, in vivo and in vitro, which could in part be explained by a failure in Tgf-β signaling. Deletion of Usp9x from the dorsal telencephalon only, by mating with Emx1-cre mice, was compatible with survival to adulthood but resulted in reduction or loss of the corpus callosum, a dramatic decrease in hippocampal size, and disorganization of the hippocampal CA3 region. This latter phenotypic aspect resembled that observed in Doublecortin knock-out mice, which is an Usp9x interacting protein. This study establishes that Usp9x is critical for several aspects of CNS development, and suggests that its regulation of Tgf-β signaling extends to neurons.
Highlights
During embryonic development of the brain, neural cells need to respond rapidly to changing environmental cues
As Usp9x is required for pre-implantation mouse embryo development [41], in order to study Usp9x’s role in brain development we generated Usp9xloxP/loxP females and bred them with heterozygous males expressing Cre recombinase from the Nestin promoter-enhancer, which is active in all CNS neural progenitors from E10.5 [52]
To investigate whether Usp9x is required for neural development and maintenance we deleted Usp9x in neural progenitors of the developing brain using both a Nestin-Cre and Emx1-Cre deletion strategy
Summary
During embryonic development of the brain, neural cells need to respond rapidly to changing environmental cues. The ubiquitin system regulates protein stability, localisation and function in a rapid and quantitative manner and has been shown to regulate multiple aspects of neural development [1] [2] [3] [4]. DUBs function downstream in the ubiquitin pathway, having the potential to act as final arbiters of protein substrate fate and function [10] [11] [12]. Several studies have shown that DUBs play important roles in the growth, function and maintenance of neurons and synapses [13] [14,15]
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