Seizures are regulated by ubiquitin-specific peptidase 9 X-linked (USP9X), a de-ubiquitinase.

Lily Paemka,Salleh N Ehaideb,Vinit B Mahajan,Polly J Ferguson,J Robert Manak,Amy Schneider,Jessica M Skeie,Levi P Sowers,Gemma L Carvill,Ingrid E Scheffer,Shu Wu,Alexander G Bassuk,Stephen A Wood,Men Chee Tan,Allison Cox ,Heather C Mefford ,Jozef Gécz ,Benjamin W Darbro ,Hatem El‐Shanti ,Lachlan A Jolly

doi:10.1371/journal.pgen.1005022

Abstract

Epilepsy is a common disabling disease with complex, multifactorial genetic and environmental etiology. The small fraction of epilepsies subject to Mendelian inheritance offers key insight into epilepsy disease mechanisms; and pathologies brought on by mutations in a single gene can point the way to generalizable therapeutic strategies. Mutations in the PRICKLE genes can cause seizures in humans, zebrafish, mice, and flies, suggesting the seizure-suppression pathway is evolutionarily conserved. This pathway has never been targeted for novel anti-seizure treatments. Here, the mammalian PRICKLE-interactome was defined, identifying prickle-interacting proteins that localize to synapses and a novel interacting partner, USP9X, a substrate-specific de-ubiquitinase. PRICKLE and USP9X interact through their carboxy-termini; and USP9X de-ubiquitinates PRICKLE, protecting it from proteasomal degradation. In forebrain neurons of mice, USP9X deficiency reduced levels of Prickle2 protein. Genetic analysis suggests the same pathway regulates Prickle-mediated seizures. The seizure phenotype was suppressed in prickle mutant flies by the small-molecule USP9X inhibitor, Degrasyn/WP1130, or by reducing the dose of fat facets a USP9X orthologue. USP9X mutations were identified by resequencing a cohort of patients with epileptic encephalopathy, one patient harbored a de novo missense mutation and another a novel coding mutation. Both USP9X variants were outside the PRICKLE-interacting domain. These findings demonstrate that USP9X inhibition can suppress prickle-mediated seizure activity, and that USP9X variants may predispose to seizures. These studies point to a new target for anti-seizure therapy and illustrate the translational power of studying diseases in species across the evolutionary spectrum.

Highlights

Mutations in the PRICKLE genes can cause seizures in humans, zebrafish, mice, and flies, suggesting the seizure-suppression pathway is evolutionarily conserved.[1,2,3,4,5]
We have previously shown that disruption of Prickle genes in multiple species including humans, results in a predisposition to seizures
We identified the deubiquitinase Usp9x as a new Prickle binding partner which stabilized Prickle by preventing its degradation

Summary

Introduction

Mutations in the PRICKLE genes can cause seizures in humans, zebrafish, mice, and flies, suggesting the seizure-suppression pathway is evolutionarily conserved.[1,2,3,4,5]. Prickle binding partners have been studied extensively only in either non-neuronal vertebrate cell lines or nonneuronal tissues in the fly. (In both cases Prickles were shown to bind other WNT/PCP proteins.[6, 7]) Such targeted approaches showed Prickles interact with REST, some kinases (including BCR), and post-synaptic density proteins, including TANC1 and TANC2.[4, 6] To identify neuronal proteins that bind Prickles, recent work by our group and others showed PRICKLE1 binds to Smurf (a ubiquitin ligase),[8] and Synapsin, (a gene implicated in both epilepsy and autism)[1]; and PRICKLE2 binds PSD-95 and p150Glued.[9] To identify other PRICKLE binding partners in neuronal-like cells, we used mass spectroscopy: a more global, unbiased approach

Methods

Results

Discussion

Conclusion