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Mutations in the WWOX gene cause a broad range of ultra-rare neurodevelopmental and brain degenerative disorders, associated with a high likelihood of premature death in animal models as well as in humans. The encoded Wwox protein is a WW domain-containing oxidoreductase that participates in crucial biological processes including tumour suppression, cell growth/differentiation and regulation of steroid metabolism, while its role in neural development is less understood. We analyzed the exomes of a family affected with multiple pre- and postnatal anomalies, including cerebellar vermis hypoplasia, severe neurodevelopmental impairment and refractory epilepsy, and identified a segregating homozygous WWOX mutation leading to a premature stop codon. Abnormal cerebral cortex development due to a defective architecture of granular and molecular cell layers was found in the developing brain of a WWOX-deficient human foetus from this family. A similar disorganization of cortical layers was identified in lde/lde rats (carrying a homozygous truncating mutation which disrupts the active C-terminal domain) investigated at perinatal stages. Transcriptomic analyses of Wwox-depleted human neural progenitor cells showed an impaired expression of a number of neuronal migration-related genes encoding for tubulins, kinesins and associated proteins. These findings indicate that loss of Wwox may affect different cytoskeleton components and alter prenatal cortical development, highlighting a regulatory role of the WWOX gene in neural progenitor cells and migrating neurons across different species.

Developmental and epileptic encephalopathies (DEE) are a group of disorders associated with intractable seizures, brain development, and functional abnormalities, and in some cases, premature death. Pathogenic human germline biallelic mutations in tumor suppressor WW domain‐containing oxidoreductase ( WWOX ) are associated with a relatively mild autosomal recessive spinocerebellar ataxia‐12 (SCAR12) and a more severe early infantile WWOX ‐related epileptic encephalopathy (WOREE). In this study, we generated an in vitro model for DEEs, using the devastating WOREE syndrome as a prototype, by establishing brain organoids from CRISPR‐engineered human ES cells and from patient‐derived iPSCs. Using these models, we discovered dramatic cellular and molecular CNS abnormalities, including neural population changes, cortical differentiation malfunctions, and Wnt pathway and DNA damage response impairment. Furthermore, we provide a proof of concept that ectopic WWOX expression could potentially rescue these phenotypes. Our findings underscore the utility of modeling childhood epileptic encephalopathies using brain organoids and their use as a unique platform to test possible therapeutic intervention strategies. SYNOPSIS Mutations in the human WWOX gene cause devastating developmental and neurological diseases in young children called WOREE syndrome and SCAR12 syndrome. Using both gene editing and reprogramming technologies these maladies can now be modeled in human brain organoids, allowing for molecular and electrophysiological study of the pathology, together with testing possible therapeutic interventions. At early stages of development WWOX is highly expressed in neural stem cells called ventricular radial glia (vRGs). WWOX ‐mutated brain organoids have imbalanced levels of excitatory and inhibitory neurons and are hyperexcitable, demonstrating epileptiform activity upon electrophysiological recordings. WWOX mutations cause increased astrogenesis and cortical dysplasia. WOREE‐modeled organoids have impaired DNA damage response and chronic activation of the Wnt‐signaling pathway. WWOX gene reintroduction could benefit patients suffering from WWOX mutations. Graphical Abstract Mutations in the human WWOX gene cause devastating developmental and neurological diseases in young children called WOREE syndrome and SCAR12 syndrome. Using both gene editing and reprogramming technologies these maladies can now be modeled in human brain organoids, allowing for molecular and electrophysiological study of the pathology, together with testing possible therapeutic interventions.

WW domain‐containing oxidoreductase ( WWOX ) is an emerging neural gene‐regulating homeostasis of the central nervous system. Germline biallelic mutations in WWOX cause WWOX‐related epileptic encephalopathy (WOREE) syndrome and spinocerebellar ataxia and autosomal recessive 12 (SCAR12), two devastating neurodevelopmental disorders with highly heterogenous clinical outcomes, the most common being severe epileptic encephalopathy and profound global developmental delay. We recently demonstrated that neuronal ablation of murine Wwox recapitulates phenotypes of Wwox ‐null mice leading to intractable epilepsy, hypomyelination, and postnatal lethality. Here, we designed and produced an adeno‐associated viral vector (AAV9) harboring murine Wwox or human WWOX cDNA and driven by the human neuronal Synapsin I promoter ( AAV‐SynI‐WWOX ). Testing the efficacy of AAV‐SynI‐WWOX delivery in Wwox ‐null mice demonstrated that specific neuronal restoration of WWOX expression rescued brain hyperexcitability and seizures, hypoglycemia, myelination deficits, and the premature lethality and behavioral deficits of Wwox ‐null mice. These findings provide a proof‐of‐concept for WWOX gene therapy as a promising approach to curing children with WOREE and SCAR12. SYNOPSIS AAV‐mediated neuronal WWOX restoration reverses abnormal defects of Wwox null mice, providing a proof‐of‐concept for WWOX gene therapy as a promising approach for treating children with WOREE syndrome. Neuronal WWOX restoration improves the overall growth of Wwox null mice. WWOX restoration reduces neuronal hyperexcitability and neuroinflammation. Neuronal WWOX delivery increases myelination, likely by promoting differentiation of OPCs to mature oligodendrocytes. Neuronal restoration of WWOX is associated with normal behavioral and motor functions of the rescued Wwox null mice. Graphical Abstract AAV‐mediated neuronal WWOX restoration reverses abnormal defects of Wwox null mice, providing a proof‐of‐concept for WWOX gene therapy as a promising approach for treating children with WOREE syndrome.

Background Biallelic loss-of-function variants in WWOX cause WWOX-related epileptic encephalopathy (WOREE syndrome), which has been reported in 60 affected individuals to date. In this study, we report on an affected individual with WOREE syndrome who presented with early-onset refractory seizures and global neurodevelopmental delay and died at the age of two and a half years. Methods We present clinical and molecular findings in the affected individual, including biallelic pathogenic variants in the WWOX gene. We employed different molecular approaches, such as whole exome sequencing, quantitative real-time polymerase chain reaction (qPCR), and whole-genome sequencing, to identify the genetic variants. The breakpoints were determined through gap PCR and Sanger sequencing. Result Whole exome sequencing revealed homozygous exon 6 deletion in the WWOX gene in the proband. Quantitative real-time PCR confirmed that the parents were heterozygous carriers of exon 6 deletion. However, using whole-genome sequencing, we identified three larger deletions (maternal allele with exon 6–8 deletion and paternal allele with two deletions in proximity one in intron 5 and the other in exon 6) involving the WWOX gene in the proband, with deletion sizes of 13,261 bp, 53,904 bp, and 177,200 bp. The exact breakpoints were confirmed through gap PCR and Sanger sequencing. We found that the proband inherited the discontinuous deletion of intron 5 and exon 6 from the father, and the exons 6–8 deletion from the mother using gap PCR. Conclusion Our findings extend the variant spectrum of WOREE syndrome and support the critical role of the WWOX gene in neural development.

The WW domain-containing oxidoreductase (WWOX) gene was originally discovered as a putative tumor suppressor spanning the common fragile site FRA16D, but as time has progressed the extent of its pleiotropic function has become apparent. At present, WWOX is a major source of interest in the context of neurological disorders, and more specifically developmental and epileptic encephalopathies (DEEs). This review article aims to introduce the many model systems used through the years to study its function and roles in neuropathies. Similarities and fundamental differences between rodent and human models are discussed. Finally, future perspectives and promising research avenues are suggested.