Molecular Mechanisms Generating and Stabilizing Terminal 22q13 Deletions in 44 Subjects with Phelan/McDermid Syndrome

Bonaglia, María Clara; Giorda, Roberto; Beri, Silvana; Agostini, Cristina De; Novara, Francesca; Fichera, Marco; Grillo, Lucia; Galesi, Ornella; Vetro, Annalisa; Ciccone, Roberto; Bonati, Maria Teresa; Giglio, Sabrina; Guerrini, Renzo; Osimani, Sara; Marelli, Susan; Zucca, Claudio; Grasso, Rita; Borgatti, Renato; Mani, Elisa; Motta, C M S; Molteni, Massimo; Romano, Corrado; Greco, Donatella; Reitano, S; Baroncini, Anna; Lapi, Elisabetta; Cecconi, Antonella; Arrigo, Giulia; Patricelli, Maria Grazia; Pantaleoni, Chiara; D’Arrigo, Stefano; Riva, Daria; Sciacca, Francesca L.; Bernardina, Bernardo Dalla; Zoccante, Leonardo; Darra, Francesca; Termine, Cristiano; Maserati, Emanuela; Bigoni, Stefania; Priolo, Emanuela; Bottani, Armand; Gimelli, Stefania; Béna, Frédérique; Brusco, Alfredo; Gregorio, Eleonora Di; Bagnasco, Irene; Giussani, Ursula; Nitsch, Lucio; Politi, Pierluigi; Martı́nez-Frı́as, María Luisa; Martínez‐Fernández, M.L.; Guardia, N. Martínez; Bremer, Anna; Anderlid, Britt‐Marie; Zuffardi, Orsetta

doi:10.1371/journal.pgen.1002173

Cited by 168 publications

(191 citation statements)

References 43 publications

(67 reference statements)

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“…14 The mutation of SHANK3 was inherited from her normal father. SHANK3 alterations are causative of PhelanMcDermid syndrome 18 and are characterized by complete penetrance. Thus, we assumed that this missense mutation was likely benign.…”

Section: Discussionmentioning

confidence: 99%

Improving molecular diagnosis in epilepsy by a dedicated high-throughput sequencing platform

et al. 2014

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We analyzed by next-generation sequencing (NGS) 67 epilepsy genes in 19 patients with different types of either isolated or syndromic epileptic disorders and in 15 controls to investigate whether a quick and cheap molecular diagnosis could be provided. The average number of nonsynonymous and splice site mutations per subject was similar in the two cohorts indicating that, even with relatively small targeted platforms, finding the disease gene is not an univocal process. Our diagnostic yield was 47% with nine cases in which we identified a very likely causative mutation. In most of them no interpretation would have been possible in absence of detailed phenotype and familial information. Seven out of 19 patients had a phenotype suggesting the involvement of a specific gene. Disease-causing mutations were found in six of these cases. Among the remaining patients, we could find a probably causative mutation only in three. None of the genes affected in the latter cases had been suspected a priori. Our protocol requires 8-10 weeks including the investigation of the parents with a cost per patient comparable to sequencing of 1-2 medium-to-large-sized genes by conventional techniques. The platform we used, although providing much less information than whole-exome or whole-genome sequencing, has the advantage that can also be run on 'benchtop' sequencers combining rapid turnaround times with higher manageability.

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Section: Discussionmentioning

confidence: 99%

Improving molecular diagnosis in epilepsy by a dedicated high-throughput sequencing platform

et al. 2014

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“…The SHANK/Shank proteins also interact with signaling molecules and enzymes to regulate receptor endocytosis, facilitate crosstalk between signaling pathways, and promote synaptic plasticity, a process critical for learning and memory [20,21]. The loss of SHANK3 can be caused by any number of errors in genetic coding, including deletions [14,[25][26][27], and splice site [28], missense [12,13] or frameshift [11] mutations, resulting in deleterious effects on neuronal physiology and synaptic functioning. Deletions result from simple 22q13 terminal deletions, ring chromosome 22, and unbalanced translocations.…”

Section: Etiologymentioning

confidence: 99%

Phelan–McDermid Syndrome and SHANK3: Implications for Treatment

Costales

Kolevzon

2015

Neurotherapeutics

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“…For details, see Supplementary Material. FISH experiments were performed on case 3, as reported, 19 by using the following probes: RP11-238F2, RP11-589A10, CTD-2652P12, RP11-879D6, RP11-474K15, RP11-676K3, RP11-13H17, RP11-661B15, RP11-103P20, RP11-36H11. SRY analysis was done as reported in Supplementary Material.…”

Section: Conventional and Molecular Cytogeneticsmentioning

confidence: 99%

Testis development in the absence of SRY: chromosomal rearrangements at SOX9 and SOX3

et al. 2014

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Duplications in the~2 Mb desert region upstream of SOX9 at 17q24.3 may result in familial 46,XX disorders of sex development (DSD) without any effects on the XY background. A balanced translocation with its breakpoint falling within the same region has also been described in one XX DSD subject. We analyzed, by conventional and molecular cytogenetics, 19 novel SRY-negative unrelated 46,XX subjects both familial and sporadic, with isolated DSD. One of them had a de novo reciprocal t(11;17) translocation. Two cases carried partially overlapping 17q24.3 duplications~500 kb upstream of SOX9, both inherited from their normal fathers. Breakpoints cloning showed that both duplications were in tandem, whereas the 17q in the reciprocal translocation was broken at~800 kb upstream of SOX9, which is not only close to a previously described 46,XX DSD translocation, but also to translocations without any effects on the gonadal development. A further XX male, ascertained because of intellectual disability, carried a de novo cryptic duplication at Xq27.1, involving SOX3. CNVs involving SOX3 or its flanking regions have been reported in four XX DSD subjects. Collectively in our cohort of 19 novel cases of SRY-negative 46,XX DSD, the duplications upstream of SOX9 account for~10.5% of the cases, and are responsible for the disease phenotype, even when inherited from a normal father. Translocations interrupting this region may also affect the gonadal development, possibly depending on the chromatin context of the recipient chromosome. SOX3 duplications may substitute SRY in some XX subjects. European Journal of Human Genetics (2015) 23, 1025-1032; doi:10.1038/ejhg.2014.237; published online 5 November 2014 INTRODUCTION 46,XX disorders of sex development (DSDs) are congenital conditions in which, in the presence of a female karyotype, the development of gonadal and anatomical sex is atypical, ranging from various degrees of ambiguous genitalia to phenotypic males with azoospermia. These conditions are poorly characterized, at least in subjects whose DNA does not contain SRY, the gene triggering testis differentiation in mammals. 1 In fact, in most XX males, SRY is transposed to the tip of Xp as a consequence of a recurrent Xp;Yp translocation, arising predominantly by nonallelic homologous recombination between PRKX and PRKY on a particular Y haplotypic background. 2,3 These males, usually with small testes, are essentially picked up among men with nonobstructive azoospermia.A much less well-understood category is that of the 46,XX DSDs negative for SRY. Recently, six of these cases have been reported

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Molecular Mechanisms Generating and Stabilizing Terminal 22q13 Deletions in 44 Subjects with Phelan/McDermid Syndrome

Cited by 168 publications

References 43 publications

Improving molecular diagnosis in epilepsy by a dedicated high-throughput sequencing platform

Improving molecular diagnosis in epilepsy by a dedicated high-throughput sequencing platform

Phelan–McDermid Syndrome and SHANK3: Implications for Treatment

Testis development in the absence of SRY: chromosomal rearrangements at SOX9 and SOX3

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