Medicine (Austin & Northern Health) - Research Publications

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Author: Berkovic, Samuel × Author: Hildebrand, Michael × Start date: 2013 ×

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    Brain mosaicism of hedgehog signalling and other cilia genes in hypothalamic hamartoma
    Green, TE ; Fujita, A ; Ghaderi, N ; Heinzen, EL ; Matsumoto, N ; Klein, KM ; Berkovic, SF ; Hildebrand, MS (ACADEMIC PRESS INC ELSEVIER SCIENCE, 2023-09)
    Hypothalamic hamartoma (HH) is a rare benign developmental brain lesion commonly associated with a well characterized epilepsy phenotype. Most individuals with HH are non-syndromic without additional developmental anomalies nor a family history of disease. Nonetheless, HH is a feature of Pallister-Hall (PHS) and Oro-Facial-Digital Type VI (OFD VI) syndromes, both characterized by additional developmental anomalies. Initial genetic of analysis HH began with syndromic HH, where germline inherited or de novo variants in GLI3, encoding a central transcription factor in the sonic hedgehog (Shh) signalling pathway, were identified in most individuals with PHS. Following these discoveries in syndromic HH, the hypothesis that post-zygotic mosaicism in related genes may underly non-syndromic HH was tested. We discuss the identified mosaic variants within individuals with non-syndromic HH, review the analytical methodologies and diagnostic yields, and explore understanding of the functional role of the implicated genes with respect to Shh signalling, and cilia development and function. We also outline future challenges in studying non-syndromic HH and suggest potential novel strategies to interrogate brain mosaicism in HH.
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    Recognition and epileptology of protracted CLN3 disease
    Cameron, JM ; Damiano, JA ; Grinton, B ; Carney, PW ; McKelvie, P ; Silbert, P ; Lawn, N ; Scheffer, IE ; Oliver, KL ; Hildebrand, MS ; Berkovic, SF (WILEY, 2023-07)
    OBJECTIVE: This study was undertaken to analyze phenotypic features of a cohort of patients with protracted CLN3 disease to improve recognition of the disorder. METHODS: We analyzed phenotypic data of 10 patients from six families with protracted CLN3 disease. Haplotype analysis was performed in three reportedly unrelated families. RESULTS: Visual impairment was the initial symptom, with onset at 5-9 years, similar to classic CLN3 disease. Mean time from onset of visual impairment to seizures was 12 years (range = 6-41 years). Various seizure types were reported, most commonly generalized tonic-clonic seizures; focal seizures were present in four patients. Progressive myoclonus epilepsy was not seen. Interictal electroencephalogram revealed mild background slowing and 2.5-3.5-Hz spontaneous generalized spike-wave discharges. Additional interictal focal epileptiform discharges were noted in some patients. Age at death for the three deceased patients was 31, 31, and 52 years. Molecular testing revealed five individuals were homozygous for c.461-280_677 + 382del966, the "common 1-kb" CLN3 deletion. The remaining individuals were compound heterozygous for various combinations of recurrent pathogenic CLN3 variants. Haplotype analysis demonstrated evidence of a common founder for the common 1-kb deletion. Dating analysis suggested the deletion arose approximately 1500 years ago and thus did not represent cryptic familial relationship in this Australian cohort. SIGNIFICANCE: We highlight the protracted phenotype of a disease generally associated with death in adolescence, which is a combined focal and generalized epilepsy syndrome with progressive neurological deterioration. The disorder should be suspected in an adolescent or adult patient presenting with generalized or focal seizures preceded by progressive visual loss. The common 1-kb deletion has been typically associated with classic CLN3 disease, and the protracted phenotype has not previously been reported with this genotype. This suggests that modifying genetic factors may be important in determining this somewhat milder phenotype and identification of these factors should be the subject of future research.
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    Contribution of Somatic Ras/Raf/Mitogen-Activated Protein Kinase Variants in the Hippocampus in Drug-Resistant Mesial Temporal Lobe Epilepsy
    Khoshkhoo, S ; Wang, Y ; Chahine, Y ; Erson-Omay, EZ ; Robert, SM ; Kiziltug, E ; Damisah, EC ; Nelson-Williams, C ; Zhu, G ; Kong, W ; Huang, AY ; Stronge, E ; Phillips, HW ; Chhouk, BH ; Bizzotto, S ; Chen, MH ; Adikari, TN ; Ye, Z ; Witkowski, T ; Lai, D ; Lee, N ; Lokan, J ; Scheffer, IE ; Berkovic, SF ; Haider, S ; Hildebrand, MS ; Yang, E ; Gunel, M ; Lifton, RP ; Richardson, RM ; Bluemcke, I ; Alexandrescu, S ; Huttner, A ; Heinzen, EL ; Zhu, J ; Poduri, A ; DeLanerolle, N ; Spencer, DD ; Lee, EA ; Walsh, CA ; Kahle, KT (AMER MEDICAL ASSOC, 2023-06)
    IMPORTANCE: Mesial temporal lobe epilepsy (MTLE) is the most common focal epilepsy subtype and is often refractory to antiseizure medications. While most patients with MTLE do not have pathogenic germline genetic variants, the contribution of postzygotic (ie, somatic) variants in the brain is unknown. OBJECTIVE: To test the association between pathogenic somatic variants in the hippocampus and MTLE. DESIGN, SETTING, AND PARTICIPANTS: This case-control genetic association study analyzed the DNA derived from hippocampal tissue of neurosurgically treated patients with MTLE and age-matched and sex-matched neurotypical controls. Participants treated at level 4 epilepsy centers were enrolled from 1988 through 2019, and clinical data were collected retrospectively. Whole-exome and gene-panel sequencing (each genomic region sequenced more than 500 times on average) were used to identify candidate pathogenic somatic variants. A subset of novel variants was functionally evaluated using cellular and molecular assays. Patients with nonlesional and lesional (mesial temporal sclerosis, focal cortical dysplasia, and low-grade epilepsy-associated tumors) drug-resistant MTLE who underwent anterior medial temporal lobectomy were eligible. All patients with available frozen tissue and appropriate consents were included. Control brain tissue was obtained from neurotypical donors at brain banks. Data were analyzed from June 2020 to August 2022. EXPOSURES: Drug-resistant MTLE. MAIN OUTCOMES AND MEASURES: Presence and abundance of pathogenic somatic variants in the hippocampus vs the unaffected temporal neocortex. RESULTS: Of 105 included patients with MTLE, 53 (50.5%) were female, and the median (IQR) age was 32 (26-44) years; of 30 neurotypical controls, 11 (36.7%) were female, and the median (IQR) age was 37 (18-53) years. Eleven pathogenic somatic variants enriched in the hippocampus relative to the unaffected temporal neocortex (median [IQR] variant allele frequency, 1.92 [1.5-2.7] vs 0.3 [0-0.9]; P = .01) were detected in patients with MTLE but not in controls. Ten of these variants were in PTPN11, SOS1, KRAS, BRAF, and NF1, all predicted to constitutively activate Ras/Raf/mitogen-activated protein kinase (MAPK) signaling. Immunohistochemical studies of variant-positive hippocampal tissue demonstrated increased Erk1/2 phosphorylation, indicative of Ras/Raf/MAPK activation, predominantly in glial cells. Molecular assays showed abnormal liquid-liquid phase separation for the PTPN11 variants as a possible dominant gain-of-function mechanism. CONCLUSIONS AND RELEVANCE: Hippocampal somatic variants, particularly those activating Ras/Raf/MAPK signaling, may contribute to the pathogenesis of sporadic, drug-resistant MTLE. These findings may provide a novel genetic mechanism and highlight new therapeutic targets for this common indication for epilepsy surgery.
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    Loss-of-function variants in the KCNQ5 gene are implicated in genetic generalized epilepsies
    Krueger, J ; Schubert, J ; Kegele, J ; Labalme, A ; Mao, M ; Heighway, J ; Seebohm, G ; Yan, P ; Koko, M ; Aslan-Kara, K ; Caglayan, H ; Steinhoff, BJ ; Weber, YG ; Keo-Kosal, P ; Berkovic, SF ; Hildebrand, MS ; Petrou, S ; Krause, R ; May, P ; Lesca, G ; Maljevic, S ; Lerche, H (ELSEVIER, 2022-10)
    BACKGROUND: De novo missense variants in KCNQ5, encoding the voltage-gated K+ channel KV7.5, have been described to cause developmental and epileptic encephalopathy (DEE) or intellectual disability (ID). We set out to identify disease-related KCNQ5 variants in genetic generalized epilepsy (GGE) and their underlying mechanisms. METHODS: 1292 families with GGE were studied by next-generation sequencing. Whole-cell patch-clamp recordings, biotinylation and phospholipid overlay assays were performed in mammalian cells combined with homology modelling. FINDINGS: We identified three deleterious heterozygous missense variants, one truncation and one splice site alteration in five independent families with GGE with predominant absence seizures; two variants were also associated with mild to moderate ID. All missense variants displayed a strongly decreased current density indicating a loss-of-function (LOF). When mutant channels were co-expressed with wild-type (WT) KV7.5 or KV7.5 and KV7.3 channels, three variants also revealed a significant dominant-negative effect on WT channels. Other gating parameters were unchanged. Biotinylation assays indicated a normal surface expression of the variants. The R359C variant altered PI(4,5)P2-interaction. INTERPRETATION: Our study identified deleterious KCNQ5 variants in GGE, partially combined with mild to moderate ID. The disease mechanism is a LOF partially with dominant-negative effects through functional deficits. LOF of KV7.5 channels will reduce the M-current, likely resulting in increased excitability of KV7.5-expressing neurons. Further studies on network level are necessary to understand which circuits are affected and how this induces generalized seizures. FUNDING: DFG/FNR Research Unit FOR-2715 (Germany/Luxemburg), BMBF rare disease network Treat-ION (Germany), foundation 'no epilep' (Germany).
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    Cutting edge approaches to detecting brain mosaicism associated with common focal epilepsies: implications for diagnosis and potential therapies
    Ye, Z ; Bennett, MF ; Bahlo, M ; Scheffer, IE ; Berkovic, SF ; Perucca, P ; Hildebrand, MS (TAYLOR & FRANCIS LTD, 2021-11-02)
    INTRODUCTION: Mosaic variants arising in brain tissue are increasingly being recognized as a hidden cause of focal epilepsy. This knowledge gain has been driven by new, highly sensitive genetic technologies and genome-wide analysis of brain tissue from surgical resection or autopsy in a small proportion of patients with focal epilepsy. Recently reported novel strategies to detect mosaic variants limited to brain have exploited trace brain DNA obtained from cerebrospinal fluid liquid biopsies or stereo-electroencephalography electrodes. AREAS COVERED: The authors review the data on these innovative approaches published in PubMed before 12 June 2021, discuss the challenges associated with their application, and describe how they are likely to improve detection of mosaic variants to provide new molecular diagnoses and therapeutic targets for focal epilepsy, with potential utility in other nonmalignant neurological disorders. EXPERT OPINION: These cutting-edge approaches may reveal the hidden genetic etiology of focal epilepsies and provide guidance for precision medicine.
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    Sporadic hypothalamic hamartoma is a ciliopathy with somatic and bi-allelic contributions
    Green, TE ; Motelow, JE ; Bennett, MF ; Ye, Z ; Bennett, CA ; Griffin, NG ; Damiano, JA ; Leventer, RJ ; Freeman, JL ; Harvey, AS ; Lockhart, PJ ; Sadleir, LG ; Boys, A ; Scheffer, IE ; Major, H ; Darbro, BW ; Bahlo, M ; Goldstein, DB ; Kerrigan, JF ; Heinzen, EL ; Berkovic, SF ; Hildebrand, MS (OXFORD UNIV PRESS, 2022-07-21)
    Hypothalamic hamartoma with gelastic seizures is a well-established cause of drug-resistant epilepsy in early life. The development of novel surgical techniques has permitted the genomic interrogation of hypothalamic hamartoma tissue. This has revealed causative mosaic variants within GLI3, OFD1 and other key regulators of the sonic-hedgehog pathway in a minority of cases. Sonic-hedgehog signalling proteins localize to the cellular organelle primary cilia. We therefore explored the hypothesis that cilia gene variants may underlie hitherto unsolved cases of sporadic hypothalamic hamartoma. We performed high-depth exome sequencing and chromosomal microarray on surgically resected hypothalamic hamartoma tissue and paired leukocyte-derived DNA from 27 patients. We searched for both germline and somatic variants under both dominant and bi-allelic genetic models. In hamartoma-derived DNA of seven patients we identified bi-allelic (one germline, one somatic) variants within one of four cilia genes-DYNC2I1, DYNC2H1, IFT140 or SMO. In eight patients, we identified single somatic variants in the previously established hypothalamic hamartoma disease genes GLI3 or OFD1. Overall, we established a plausible molecular cause for 15/27 (56%) patients. Here, we expand the genetic architecture beyond single variants within dominant disease genes that cause sporadic hypothalamic hamartoma to bi-allelic (one germline/one somatic) variants, implicate three novel cilia genes and reconceptualize the disorder as a ciliopathy.
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    UNC13B and focal epilepsy
    Green, TE ; Scheffer, IE ; Berkovic, SF ; Hildebrand, MS (OXFORD UNIV PRESS, 2022-04-29)
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    Defective lipid signalling caused by mutations in PIK3C2B underlies focal epilepsy
    Gozzelino, L ; Kochlamazashvili, G ; Baldassari, S ; Mackintosh, AI ; Licchetta, L ; Iovino, E ; Liu, YC ; Bennett, CA ; Bennett, MF ; Damiano, JA ; Zsurka, G ; Marconi, C ; Giangregorio, T ; Magini, P ; Kuijpers, M ; Maritzen, T ; Norata, GD ; Baulac, S ; Canafoglia, L ; Seri, M ; Tinuper, P ; Scheffer, IE ; Bahlo, M ; Berkovic, SF ; Hildebrand, MS ; Kunz, WS ; Giordano, L ; Bisulli, F ; Martini, M ; Haucke, V ; Hirsch, E ; Pippucci, T (OXFORD UNIV PRESS, 2022-07-29)
    Epilepsy is one of the most frequent neurological diseases, with focal epilepsy accounting for the largest number of cases. The genetic alterations involved in focal epilepsy are far from being fully elucidated. Here, we show that defective lipid signalling caused by heterozygous ultra-rare variants in PIK3C2B, encoding for the class II phosphatidylinositol 3-kinase PI3K-C2β, underlie focal epilepsy in humans. We demonstrate that patients' variants act as loss-of-function alleles, leading to impaired synthesis of the rare signalling lipid phosphatidylinositol 3,4-bisphosphate, resulting in mTORC1 hyperactivation. In vivo, mutant Pik3c2b alleles caused dose-dependent neuronal hyperexcitability and increased seizure susceptibility, indicating haploinsufficiency as a key driver of disease. Moreover, acute mTORC1 inhibition in mutant mice prevented experimentally induced seizures, providing a potential therapeutic option for a selective group of patients with focal epilepsy. Our findings reveal an unexpected role for class II PI3K-mediated lipid signalling in regulating mTORC1-dependent neuronal excitability in mice and humans.
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    Mosaicism in tuberous sclerosis complex: Lowering the threshold for clinical reporting
    Ye, Z ; Lin, S ; Zhao, X ; Bennett, MF ; Brown, NJ ; Wallis, M ; Gao, X ; Sun, L ; Wu, J ; Vedururu, R ; Witkowski, T ; Gardiner, F ; Stutterd, C ; Duan, J ; Mullen, SA ; McGillivray, G ; Bodek, S ; Valente, G ; Reagan, M ; Yao, Y ; Li, L ; Chen, L ; Boys, A ; Adikari, TN ; Cao, D ; Hu, Z ; Beshay, V ; Zhang, VW ; Berkovic, SF ; Scheffer, IE ; Liao, J ; Hildebrand, MS (WILEY-HINDAWI, 2022-12)
    Tuberous sclerosis complex (TSC) is a multi-system genetic disorder. Most patients have germline mutations in TSC1 or TSC2 but, 10%-15% patients do not have TSC1/TSC2 mutations detected on routine clinical genetic testing. We investigated the contribution of low-level mosaic TSC1/TSC2 mutations in unsolved sporadic patients and families with TSC. Thirty-one sporadic TSC patients negative on routine testing and eight families with suspected parental mosaicism were sequenced using deep panel sequencing followed by droplet digital polymerase chain reaction. Pathogenic variants were found in 22/31 (71%) unsolved sporadic patients, 16 were mosaic (median variant allele fraction [VAF] 6.8% in blood) and 6 had missed germline mutations. Parental mosaicism was detected in 5/8 families (median VAF 1% in blood). Clinical testing laboratories typically only report pathogenic variants with allele fractions above 10%. Our findings highlight the critical need to change laboratory practice by implementing higher sensitivity assays to improve diagnostic yield, inform patient management and guide reproductive counseling.
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    Climate change and epilepsy: Insights from clinical and basic science studies
    Gulcebi, M ; Bartolini, E ; Lee, O ; Lisgaras, CP ; Onat, F ; Mifsud, J ; Striano, P ; Vezzani, A ; Hildebrand, MS ; Jimenez-Jimenez, D ; Junck, L ; Lewis-Smith, D ; Scheffer, IE ; Thijs, RD ; Zuberi, SM ; Blenkinsop, S ; Fowler, HJ ; Foley, A ; Sisodiya, SM ; Balestrini, S ; Berkovic, S ; Cavalleri, G ; Correa, DJ ; Custodio, HM ; Galovic, M ; Guerrini, R ; Henshall, D ; Howard, O ; Hughes, K ; Katsarou, A ; Koeleman, BPC ; Krause, R ; Lowenstein, D ; Mandelenaki, D ; Marini, C ; O'Brien, TJ ; Pace, A ; De Palma, L ; Perucca, P ; Pitkanen, A ; Quinn, F ; Selmer, KK ; Steward, CA ; Swanborough, N ; Thijs, R ; Tittensor, P ; Trivisano, M ; Weckhuysen, S ; Zara, F (ACADEMIC PRESS INC ELSEVIER SCIENCE, 2021-03)
    Climate change is with us. As professionals who place value on evidence-based practice, climate change is something we cannot ignore. The current pandemic of the novel coronavirus, SARS-CoV-2, has demonstrated how global crises can arise suddenly and have a significant impact on public health. Global warming, a chronic process punctuated by acute episodes of extreme weather events, is an insidious global health crisis needing at least as much attention. Many neurological diseases are complex chronic conditions influenced at many levels by changes in the environment. This review aimed to collate and evaluate reports from clinical and basic science about the relationship between climate change and epilepsy. The keywords climate change, seasonal variation, temperature, humidity, thermoregulation, biorhythm, gene, circadian rhythm, heat, and weather were used to search the published evidence. A number of climatic variables are associated with increased seizure frequency in people with epilepsy. Climate change-induced increase in seizure precipitants such as fevers, stress, and sleep deprivation (e.g. as a result of more frequent extreme weather events) or vector-borne infections may trigger or exacerbate seizures, lead to deterioration of seizure control, and affect neurological, cerebrovascular, or cardiovascular comorbidities and risk of sudden unexpected death in epilepsy. Risks are likely to be modified by many factors, ranging from individual genetic variation and temperature-dependent channel function, to housing quality and global supply chains. According to the results of the limited number of experimental studies with animal models of seizures or epilepsy, different seizure types appear to have distinct susceptibility to seasonal influences. Increased body temperature, whether in the context of fever or not, has a critical role in seizure threshold and seizure-related brain damage. Links between climate change and epilepsy are likely to be multifactorial, complex, and often indirect, which makes predictions difficult. We need more data on possible climate-driven altered risks for seizures, epilepsy, and epileptogenesis, to identify underlying mechanisms at systems, cellular, and molecular levels for better understanding of the impact of climate change on epilepsy. Further focussed data would help us to develop evidence for mitigation methods to do more to protect people with epilepsy from the effects of climate change.