Diagnosis and Management of Beckwith-Wiedemann Syndrome

Wang, Kathleen H.; Kupa, Jonida; Duffy, Kelly A.; Kalish, Jennifer M.

doi:10.3389/fped.2019.00562

Cited by 86 publications

(102 citation statements)

References 108 publications

(204 reference statements)

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“…A recent international consensus document has recognized the existence of a Beckwith-Wiedemann spectrum (BWSp) covering classical BWS without a molecular diagnosis and BWS-related phenotypes with an 11p15.5 molecular anomaly [64]. The typical BWS molecular abnormalities affect one or both of two functional domains of the imprinted gene cluster located at chromosome 11p15.5-11p15.4 [65]. The telomeric domain harbors the insulin-like growth factor 2 (IGF2) gene that is expressed from the paternal allele and encodes a protein promoting fetal growth, and H19, which is expressed from the maternal allele and encodes a non-translated long non-coding RNA with growth inhibitory properties.…”

Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

“…A molecular defect affecting imprinted genes in the chromosome region 11p15 can be detected iñ 85% of patients [64,65]. DNA methylation changes are the most frequent abnormalities.…”

Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

“…Molecular diagnosis of BWS is obtained by detection of abnormal methylation of IC1, IC2 or both, and is most commonly reached by using MS-MLPA, which also recognizes CNVs [64,65]. A further microsatellite analysis is needed to confirm upd(11)pat, and Sanger sequencing is needed to detect possible clinical variants in IC1 and CDKN1C.…”

Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

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DNA Methylation in the Diagnosis of Monogenic Diseases

Cerrato

Sparago

Ariani

et al. 2020

Genes

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DNA methylation in the human genome is largely programmed and shaped by transcription factor binding and interaction between DNA methyltransferases and histone marks during gamete and embryo development. Normal methylation profiles can be modified at single or multiple loci, more frequently as consequences of genetic variants acting in cis or in trans, or in some cases stochastically or through interaction with environmental factors. For many developmental disorders, specific methylation patterns or signatures can be detected in blood DNA. The recent use of high-throughput assays investigating the whole genome has largely increased the number of diseases for which DNA methylation analysis provides information for their diagnosis. Here, we review the methylation abnormalities that have been associated with mono/oligogenic diseases, their relationship with genotype and phenotype and relevance for diagnosis, as well as the limitations in their use and interpretation of results.

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Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

“…A molecular defect affecting imprinted genes in the chromosome region 11p15 can be detected iñ 85% of patients [64,65]. DNA methylation changes are the most frequent abnormalities.…”

Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

Section: Beckwith-wiedemann Syndrome and Silver-russell Syndromementioning

confidence: 99%

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DNA Methylation in the Diagnosis of Monogenic Diseases

Cerrato

Sparago

Ariani

et al. 2020

Genes

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“…The Beckwith-Wiedemann syndrome (BWS) is a genetic overgrowth and tumor predisposition syndrome caused by genetic or epigenetic changes on chromosome 11p15, involving the IGF2 gene [17]. BWS is characterized by hemihypertrophy, macroglossia, macrosomia, organomegaly, hyperinsulinism, omphalocele/umbilical hernia as well as by the risk of developing embryonal tumors [18]. In particular, the overall risk of intra-abdominal tumor development is between 5 and 10% [19] and the most associated tumors in BWS are the Wilms tumor, hepatoblastoma, neuroblastoma and ACC [20].…”

Section: Molecular Basis Of Adrenocortical Carcinoma: a Lesson From Fmentioning

confidence: 99%

Medical Approaches in Adrenocortical Carcinoma

et al. 2020

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Adrenocortical carcinoma (ACC) represents one of the most aggressive endocrine tumors. In spite of a correct therapeutic strategy based on a multidisciplinary approach between endocrinologist, surgeon and oncologist, the prognosis is often poor. Surgery is the mainstay treatment in ACC. Mitotane, a dichloro-diphenyl-trichloro-ethane derivate, represents the main medical treatment of ACC in consideration of its adrenocytolitic activity and it is mainly employed as adjuvant treatment after complete surgical resection and for the treatment of advanced ACC. However, the use of mitotane as adjuvant therapy is still controversial, also in consideration of the retrospective nature of several studies. The recurrence of disease is frequent, especially in advanced disease at the diagnosis. Therefore, in these contexts, conventional chemotherapy must be considered in association with mitotane, being the combination etoposide, doxorubicin and cisplatin (EDP) the standard of care in this setting. A more modern therapeutic approach, based on the need of a salvage therapy for advanced ACC that progresses through first-line EDP, is focused on molecular-targeted therapies. However, robust clinical trials are necessary to assess the real efficacy of these treatments.

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“…These genes are important regulators in prenatal growth and development, as well as, in postnatal brain functions and metabolic pathways [reviewed in (Tucci et al, 2019)]. The dysregulation of imprinted genes has been associated with several developmental and behavioural disorders, such as Beckwith-Weidemann, Angelman and Prader-Willi syndromes (Cassidy et al, 2012; Maranga et al, 2020; Wang et al, 2019). Most imprinted genes are located in close proximity in defined genomic loci, called imprinted clusters.…”

Section: Introductionmentioning

confidence: 99%

Sex of donor cell and reprogramming conditions predict the extent and nature of imprinting defects in mouse iPSCs

Arez

Eckersley-Maslin

Klobučar

et al. 2020

Preprint

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Reprogramming of somatic cells into induced Pluripotent Stem Cells (iPSCs) is a major leap towards personalized approaches to disease modelling and cell-replacement therapies. However, we still lack the ability to fully control the epigenetic status of iPSCs, which is a major hurdle for their downstream applications. A sensible indicator for epigenetic fidelity is genomic imprinting, a phenomenon dependent on DNA methylation, which is frequently perturbed in iPSCs by yet unidentified reasons. By using a secondary reprogramming system with murine hybrid donor cells, we conducted a thorough imprinting analysis using IMPLICON in multiple female and male iPSCs generated under different culture conditions. Our results show that imprinting defects are remarkably common in mouse iPSCs causing dysregulation of the typical monoallelic expression of imprinted genes. Interestingly, the nature of imprinting defects depends on the sex of the donor cell and their respective response to culture conditions. Under serum-free conditions, male iPSCs show global hypomethylation at imprinted regions, whereas in serum conditions show focal hypermethylation at specific loci. In contrast, female iPSCs always exhibit hypomethylation defects regardless of culture conditions. These imprinting defects are more severe than the global changes in DNA methylation, highlighting the sensitivity of imprinting loci to current iPSC generation protocols. Our results reveal clear predictors underlying different types of imprinting defects in mouse iPSCs. This knowledge is essential to devise novel reprogramming strategies aiming at generating epigenetically faithful iPSCs.

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Diagnosis and Management of Beckwith-Wiedemann Syndrome

Cited by 86 publications

References 108 publications

DNA Methylation in the Diagnosis of Monogenic Diseases

DNA Methylation in the Diagnosis of Monogenic Diseases

Medical Approaches in Adrenocortical Carcinoma

Sex of donor cell and reprogramming conditions predict the extent and nature of imprinting defects in mouse iPSCs

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