<i>TBC1D24</i>
            genotype–phenotype correlation

Balestrini, Simona; Milh, Mathieu; Castiglioni, Claudia; Lüthy, Kevin; Finelli, Mattéa J.; Verstreken, Patrik; Cardon, Aaron L.; Stražišar, Barbara Gnidovec; Holder, J. Lloyd; Lesca, Gaëtan; Mancardi, Maria Margherita; Poulat, Anne-Lise; Repetto, Gabriela M.; Banka, Siddharth; Bilo, Leonilda; Birkeland, Laura E.; Bosch, Friedrich; Brockmann, Knut; Cross, J. Helen; Doummar, Diane; Félix, Têmis Maria; Giuliano, Fabienne; Hori, Mutsuki; Hüning, Irina; Kayserili, Hulia; Kini, Usha; Lees, Melissa; Girish, Meenakshi; Mewasingh, Leena; Pagnamenta, Alistair T.; Peluso, Silvio; Mey, Antje; Rice, Gregory M.; Rosenfeld, Jill A.; Taylor, Jenny C.; Troester, Matthew M.; Stanley, Christine M.; Ville, Dorothée; Walkiewicz, Magdalena; Falace, Antonio; Fassio, Anna; Lemke, Johannes R.; Biskup, Saskia; Tardif, Jessica; Ajeawung, Norbert F.; Tolun, Aslıhan; Corbett, Mark; Gécz, Jozef; Afawi, Zaid; Howell, Katherine; Oliver, Karen; Berkovic, Samuel F.; Scheffer, Ingrid E.; Falco, Fabrizio Antonio de; Oliver, Peter L.; Striano, Pasquale; Zara, Federico; Campeau, Philippe M.; Sisodiya, Sanjay M.

doi:10.1212/wnl.0000000000002807

Cited by 99 publications

(91 citation statements)

References 35 publications

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“…Overall, among disorders associated with TBC1D24 mutations, recurring phenotypes include seizures, myoclonus, neurodevelopmental impairment, sensorineural hearing impairment, visual impairment, and cerebral and/or cerebellar atrophy on brain imaging. Movement disorders including dystonia, choreoathetosis, and dyskinesia have also been reported 12,13. Our sibship shares a number of clinical features with previously reported TBC1D24 cases.…”

Section: Discussionsupporting

confidence: 79%

“…Ictal EEG not availableFocal migrating EEG discharges during seizuresInterictal EEG: disorganizedSlow background in EEGMultifocal or bilateral generalized multiple spikes and spike waves in EEG associated with myoclonias.Generalized spike-wave discharges with frontocentral predominance during seizuresNo clear EEG correlate for myoclonic jerksImaging findingsNormal 1 individual with nodular periventricular heterotopia 1 individual had MRI abnormalities in lentiform nuclei, ventricular dilatation and white matter changes post-cardiac arrest. An earlier MRI was normalSelective atrophy and signal abnormality in cerebellumCerebral cortical thickening most marked in cingulate regions and occipital polesGlobal cerebral atrophy sparing the posterior fossaThin corpus callosumDelayed myelinationDiffuse cerebral atrophy (asymmetrical for one patient)Cerebellar atrophyProminent frontotemporal atrophyClinical PhenotypeSpectrum of Epilepsy Phenotypes Including DOORS SyndromeDOORS Syndrome (OMIM 220500)Non-syndromic Deafness (DFNB86) (OMIM 614617)Non-syndromic Hearing Loss (DFNA65) (OMIM 616044)Migrating Paroxysmal Myoclonus and Cerebellar SignsReferencesBalastrini et al13Campeau et al18Rehman et al14, Bakhchane et al15Azaiez et al16, Zhang et al17Doummar et al22Reported mutations/genotypec.32A>G (p.Asp11Gly)c.58C>T (p.Gln20*)c.115G>C (p.Ala39Pro)c.118C>T (p.Arg40Cys)c.119G>T (p.Arg40Leu)c.277C>T (p.Pro93Ser)c.313T>C (p.Cys105Arg)c.328G>A (p.Gly110Ser)c.439G>C (p.Asp147His)c.457G>A (p.Glu153Lys)c.468C>A (p.Cys156*)c.533C>G (p.Ser178Trp)c.619C>T (p.Gln207*)c.679C>T (p.Arg227Trp)c.680G>A (p.Arg227Gln)c.686T>C (p.Phe229Ser)c.724C>T (p.Arg242Cys)c.731C>T (p.Ala244Val)c.751T>C (p.Phe251Leu)c.809G>A (p.Arg270His)c.845C>G (p.Pro282Arg)c.919A>G (p.Asn307Asp)c.957G>C (p.Lys319Asn)c.969_970delGT(p.Ser324Thrfs*3)c.999G>T (p.Leu333Phe)c.1008delT (p.His336Glnfs*12)c.1126G>C (p.Gly376Arg)c.1384del (p.Glu462Serfs*61)c.1460dup (p.His487Glnfs*71)c.1079G>T (p.Arg360Leu)c.1499C>T (p.Ala500Val)c.1544C>T (p.Ala515Val)c.1661_1667del (p.Gln554Leufs*12)c.724C>T (p.Arg24...…”

Section: Discussionmentioning

confidence: 99%

“…Using these criteria, two heterozygous variants confirmed by Sanger sequencing were identified in TBC1D24 (Supplementary Figure 1): 1) a previously reported missense change c.457G>A (p.Glu153Lys; rs376712059)6,13,15 and 2) a previously unreported frameshift mutation, c.545del (p.Thr182Serfs*6) predicted to cause nonsense-mediated RNA decay or result in a truncated protein. Both mutations showed appropriate familial segregation.…”

Section: Case Reportmentioning

confidence: 99%

See 2 more Smart Citations

TBC1D24 Mutations in a Sibship with Multifocal Polymyoclonus

Ngoh

Brás²,

Guerreiro³

et al. 2017

Tremor and Other Hyperkinetic Movements

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Section: Discussionsupporting

confidence: 79%

Section: Discussionmentioning

confidence: 99%

Section: Case Reportmentioning

confidence: 99%

See 1 more Smart Citation

TBC1D24 Mutations in a Sibship with Multifocal Polymyoclonus

Ngoh

Brás²,

Guerreiro³

et al. 2017

Tremor and Other Hyperkinetic Movements

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“…These roles are essential for long-term neuronal health, as evidenced by the identification of human patients with neurologic and neurodegenerative conditions who have mutations in these genes. [17][18][19][20][21][22][23] In this review, we will discuss how the antagonistic and synergistic functions of molecules within the Rab35 signaling network are necessary for regulating SV protein trafficking, degradation, and neurotransmitter release, and conclude with a discussion of how dysfunction of this signaling network may induce neurologic and neurodegenerative diseases.…”

Section: Introductionmentioning

confidence: 99%

Coordination of synaptic vesicle trafficking and turnover by the Rab35 signaling network

Sheehan

Waites

2017

Small GTPases

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Rab35 and the Rab35 network of GAPs, GEFs, and effectors are important regulators of membrane trafficking for a variety of cellular processes, from cytokinesis and phagocytosis to neurite outgrowth. In the past five years, components of this signaling network have also been implicated as critical mediators of synaptic vesicle (SV) recycling and protein homeostasis. Recent studies by several groups, including our own, have demonstrated that Rab35-mediated endosomal sorting is required for the degradation of SV proteins via the ESCRT pathway, thereby eliminating old or damaged proteins from the SV pool. This sorting process is regulated by Rab35 activation in response to neuronal activity, and potentially by an antagonistic signaling relationship between Rab35 and the small GTPase Arf6 that directs SVs into distinct recycling pathways depending on neuronal activity levels. Furthermore, mutations in genes encoding Rab35 regulatory proteins are emerging as causative factors in human neurologic and neurodegenerative diseases, consistent with their important roles in synaptic and neuronal health. Here, we review these recent findings and offer our perspective on how the Rab35 signaling network functions to maintain neurotransmission and synaptic fitness.

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“…Mutations in the TBC1D24 gene are the cause of multiple rare disorders whose phenotype consists of varying degrees of intellectual disability, deafness, cortical malformations, and/or epilepsy 1 . To date, the disorders caused by TBC1D24 dysfunction make up a continuum of six distinct phenotypes that include DOORS syndrome (Deafness, Onochydystrophy, Osteodystrophy, mental Retardation and Seizures; autosomal recessive; AR), familial infantile myoclonic epilepsy (FIME; AR), progressive myoclonus epilepsy (PME; AR), early-infantile epileptic encephalopathy (EIEE16; AR), autosomal recessive non-syndromic hearing loss (DFNB86; AR), and autosomal dominant non-syndromic hearing loss (DFNA65; AD).…”

Section: Introductionmentioning

confidence: 99%

Case Report: Novel mutations in TBC1D24 are associated with autosomal dominant tonic-clonic and myoclonic epilepsy and recessive Parkinsonism, psychosis, and intellectual disability

et al. 2017

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Mutations disrupting presynaptic protein TBC1D24 are associated with a variable neurological phenotype, including DOORS syndrome, myoclonic epilepsy, early-infantile epileptic encephalopathy, and non-syndromic hearing loss. In this report, we describe a family segregating autosomal dominant epilepsy, and a 37-year-old Caucasian female with a severe neurological phenotype including epilepsy, Parkinsonism, psychosis, visual and auditory hallucinations, gait ataxia and intellectual disability. Whole exome sequencing revealed two missense mutations in the TBC1D24 gene segregating within this family (c.1078C>T; p.Arg360Cys and c.404C>T; p.Pro135Leu). The female proband who presents with a severe neurological phenotype carries both of these mutations in a compound heterozygous state. The p.Pro135Leu variant, however, is present in the proband’s mother and sibling as well, and is consistent with an autosomal dominant pattern linked to tonic-clonic and myoclonic epilepsy. In conclusion, we describe a single family in which TBC1D24 mutations cause expanded dominant and recessive phenotypes. In addition, we discuss and highlight that some variants in TBC1D24 might cause a dominant susceptibility to epilepsy

show abstract

TBC1D24 genotype–phenotype correlation

Cited by 99 publications

References 35 publications

TBC1D24 Mutations in a Sibship with Multifocal Polymyoclonus

TBC1D24 Mutations in a Sibship with Multifocal Polymyoclonus

Coordination of synaptic vesicle trafficking and turnover by the Rab35 signaling network

Case Report: Novel mutations in TBC1D24 are associated with autosomal dominant tonic-clonic and myoclonic epilepsy and recessive Parkinsonism, psychosis, and intellectual disability

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