Loss of function of the retinoid-related nuclear receptor (RORB) gene and epilepsy

Rudolf, Gabrielle; Lesca, Gaëtan; Mehrjouy, Mana M.; Labalme, Audrey; Salmi, Manal; Bache, Iben; Bruneau, Nadine; Pendziwiat, Manuela; Fluss, Joël Victor; Bellescize, Julitta de; Scholly, Julia; Møller, Rikke S.; Craiu, Dana; Tommerup, Niels; Valenti-Hirsch, Maria Paola; Schluth-Bolard, Caroline; Sloan‐Béna, Frédérique; Helbig, Katherine L.; Weckhuysen, Sarah; Edery, Patrick; Coulbaut, Safia; Abbas, Mohamed; Scheffer, Ingrid E.; Tang, Sha; Myers, Candace T.; Stamberger, Hannah; Carvill, Gemma L.; Shinde, Deepali N.; Mefford, Heather C; Neagu, Elena; Huether, Robert; Lu, Hsiao-Mei; Dica, Alice; Cohen, Julie S.; Iliescu, Catrinel; Pomeran, C; Rubenstein, James L.; Helbig, Ingo; Sanlaville, Damien; Hirsch, Édouard; Szepetowski, Pierre

doi:10.1038/ejhg.2016.80

Cited by 36 publications

(27 citation statements)

References 30 publications

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“…The previous study of a family and four sporadic individuals with RORB epilepsies reported a broad phenotypic spectrum encompassing GGE, predominantly eyelid myoclonia with absence epilepsy, and DEE. Individuals in the study had a cognitive profile ranging from learning disabilities to severe ID . The phenotypes in these previously reported families are similar to what we have identified; however, they did not report any occipital epilepsies.…”

Section: Discussionsupporting

confidence: 78%

“…One example in the epilepsies is the identification of RORB , encoding the retinoid‐related orphan receptor β, which lies within the 9q21.13 microdeletion . There is only a single study reporting patients with pathogenic variants in RORB . The epilepsy phenotypes in this study varied from developmental and epileptic encephalopathies (DEEs) to photosensitive genetic generalized epilepsies, predominantly eyelid myoclonia with absence epilepsy associated with mild intellectual disability (ID) …”

Section: Introductionmentioning

confidence: 99%

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Inherited RORB pathogenic variants: Overlap of photosensitive genetic generalized and occipital lobe epilepsy

et al. 2020

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Variants in RORB have been reported in eight individuals with epilepsy, with phenotypes ranging from eyelid myoclonia with absence epilepsy to developmental and epileptic encephalopathies. We identified novel RORB variants in 11 affected individuals from four families. One was from whole genome sequencing and three were from RORB screening of three epilepsy cohorts: developmental and epileptic encephalopathies (n = 1021), overlap of generalized and occipital epilepsy (n = 84), and photosensitivity (n = 123). Following interviews and review of medical records, individuals' seizure and epilepsy syndromes were classified. Three novel missense variants and one exon 3 deletion were predicted to be pathogenic by in silico tools, not found in population databases, and located in key evolutionary conserved domains. Median age at seizure onset was 3.5 years (0.5-10 years). Generalized, predominantly absence and myoclonic, and occipital seizures were seen in all families, often within the same individual (6/11). All individuals with epilepsy were photosensitive, and seven of 11 had cognitive abnormalities. Electroencephalograms showed generalized spike and wave and/or polyspike and wave. Here we show a striking RORB phenotype of overlap of photosensitive generalized and occipital epilepsy in both individuals and families. This is the first report of a gene associated with this overlap of epilepsy syndromes. e24 |

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Section: Discussionsupporting

confidence: 78%

Section: Introductionmentioning

confidence: 99%

Inherited RORB pathogenic variants: Overlap of photosensitive genetic generalized and occipital lobe epilepsy

et al. 2020

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“…We also found several CNVs that included the genes HNRNPU (1q44) and RORB (9p21.13), both recently associated with epilepsy . Microdeletions of the 1q43q44 critical region have been associated with ID, dysmorphism, abnormalities of the corpus callosum, and seizures .…”

Section: Discussionmentioning

confidence: 75%

“…We also found several CNVs that included the genes HNRNPU (1q44) and RORB (9p21.13), both recently associated with epilepsy. 28,[30][31][32] Microdeletions of the 1q43q44 critical region have been associated with ID, dysmorphism, The reported phenotype associated with each known epilepsy gene refers to the phenotype reported in the OMIM or, if not available, the citation indicated in the supplementary material (Table S2) (Table S6a). In our cohort, five patients carried CNVs mapping to the 1q43q44 critical region, and in addition to the HNRNPU gene, in two duplications and one deletion, the chromosomal rearrangement included also the AKT3 gene, which might contribute to brain abnormalities observed in these patients.…”

Section: Discussionmentioning

confidence: 99%

Diagnostic implications of genetic copy number variation in epilepsy plus

et al. 2019

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Summary Objective Copy number variations ( CNV s) represent a significant genetic risk for several neurodevelopmental disorders including epilepsy. As knowledge increases, reanalysis of existing data is essential. Reliable estimates of the contribution of CNV s to epilepsies from sizeable populations are not available. Methods We assembled a cohort of 1255 patients with preexisting array comparative genomic hybridization or single nucleotide polymorphism array based CNV data. All patients had “epilepsy plus,” defined as epilepsy with comorbid features, including intellectual disability, psychiatric symptoms, and other neurological and nonneurological features. CNV classification was conducted using a systematic filtering workflow adapted to epilepsy. Results Of 1097 patients remaining after genetic data quality control, 120 individuals (10.9%) carried at least one autosomal CNV classified as pathogenic; 19 individuals (1.7%) carried at least one autosomal CNV classified as possibly pathogenic. Eleven patients (1%) carried more than one (possibly) pathogenic CNV . We identified CNV s covering recently reported ( HNRNPU ) or emerging ( RORB ) epilepsy genes, and further delineated the phenotype associated with mutations of these genes. Additional novel epilepsy candidate genes emerge from our study. Comparing phenotypic features of pathogenic CNV carriers to those of noncarriers of pathogenic CNV s, we show that patients with nonneurological comorbidities, especially dysmorphism, were more likely to carry pathogenic CNV s (odds ratio = 4.09, confidence interval = 2.51‐6.68; P = 2.34 × 10 −9 ). Meta‐analysis including data from published control groups showed that the presence or absence of epilepsy did not affect the detected frequency of CNV s. Significance The use of a specifically adapted workflow enabled identification of pathogenic autosomal CNV s in 10.9% of patients with epilepsy plus, which rose to 12.7% when we also considered possibly pathogenic CNV s. Our data indicate that epilepsy with comorbid features should be considered an indication for patients to be selected for a diagnostic algorithm including CNV detection. Collaborative large‐scale CNV reanalysis leads to novel declaration of pathogenicity in unexplained cases and can promote discovery of promising candidate epilepsy genes.

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“…Lhx2 has been shown to contribute to the differentiation of tanycytes and the maintenance of the mature state of Müller glia, two astrocyte-like cell types found in the hypothalamus and the retina, respectively (de Melo et al, 2012;Salvatierra et al, 2014), but Rorb, Dbx2 and Fezf2 have not been previously implicated in the development of glial cells. Interestingly, pathogenic mutations in RORB have been identified in genetic forms of epilepsy (Rudolf et al, 2016). Since astrocyte dysfunction is considered a key pathological mechanism in epilepsy (Patel et al, 2019), these RORB mutations may act by blocking the induction of mature astrocyte genes protecting from epileptogenesis (Patel et al, 2019), such as the Rorb target Glul, whose deletion in astrocytes in the mouse causes seizures and neurodegeneration (Zhou et al, 2019), or the glutamate transporter Slc1a2, which has been shown to be mutated in epileptic encephalopathies (Epi, 2016).…”

Section: Discussionmentioning

confidence: 99%

Extensive transcriptional and chromatin changes underlie astrocyte maturationin vivoand in culture

Lattke

Goldstone

Guillemot

2020

Preprint

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Astrocytes have diverse functions in brain homeostasis. Many of these functions are acquired during late stages of differentiation when astrocytes become fully mature. The mechanisms underlying astrocyte maturation are not well understood. Here we identified extensive transcriptional changes that occur during astrocyte maturation and are accompanied by chromatin remodelling at enhancer elements. Investigating astrocyte maturation in a cell culture model revealed that in vitro-differentiated astrocytes lacked expression of many mature astrocyte-specific genes, including genes for the transcription factors Rorb, Dbx2, Lhx2 and Fezf2. Forced expression of these factors in vitro induced distinct sets of mature astrocytesspecific transcripts. Culturing astrocytes with FGF2 in a three-dimensional gel induced expression of Rorb, Dbx2 and Lhx2 and improved their maturity based on transcriptional and chromatin profiles. Therefore extrinsic signals orchestrate the expression of multiple intrinsic regulators, which in turn induce in a modular manner the transcriptional and chromatin changes underlying astrocyte maturation.

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Loss of function of the retinoid-related nuclear receptor (RORB) gene and epilepsy

Cited by 36 publications

References 30 publications

Inherited RORB pathogenic variants: Overlap of photosensitive genetic generalized and occipital lobe epilepsy

Inherited RORB pathogenic variants: Overlap of photosensitive genetic generalized and occipital lobe epilepsy

Diagnostic implications of genetic copy number variation in epilepsy plus

Extensive transcriptional and chromatin changes underlie astrocyte maturationin vivoand in culture

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