Koenraad Devriendt

Mutations in the TGFβ Binding-Protein-Like Domain 5 of FBN1 Are Responsible for Acromicric and Geleophysic Dysplasias

Geleophysic (GD) and acromicric dysplasia (AD) belong to the acromelic dysplasia group and are both characterized by severe short stature, short extremities, and stiff joints. Although AD has an unknown molecular basis, we have previously identified ADAMTSL2 mutations in a subset of GD patients. After exome sequencing in GD and AD cases, we selected fibrillin 1 (FBN1) as a candidate gene, even though mutations in this gene have been described in Marfan syndrome, which is characterized by tall stature and arachnodactyly. We identified 16 heterozygous FBN1 mutations that are all located in exons 41 and 42 and encode TGFβ-binding protein-like domain 5 (TB5) of FBN1 in 29 GD and AD cases. Microfibrillar network disorganization and enhanced TGFβ signaling were consistent features in GD and AD fibroblasts. Importantly, a direct interaction between ADAMTSL2 and FBN1 was demonstrated, suggesting a disruption of this interaction as the underlying mechanism of GD and AD phenotypes. Although enhanced TGFβ signaling caused by FBN1 mutations can trigger either Marfan syndrome or GD and AD, our findings support the fact that TB5 mutations in FBN1 are responsible for short stature phenotypes.

Disclosing incidental findings in genetics contexts: A review of the empirical ethical research

The disclosure of incidental findings, also called unsolicited findings, unexpected results, and secondary variants, is increasingly recognised as an issue in clinical and research genetics contexts. The rise of next generation sequencing methods has only intensified the issue, increasing the likelihood of incidental findings appearing. This review focuses on empirical research on the ethical issues involved. Electronic databases were searched for articles covering quantitative and qualitative research on the ethical issues involved in the disclosure of incidental findings in clinical and research genetics contexts. 16 articles were ultimately accepted for review. Data was extracted and synthesised on the factors that should be taken into account during the decision-making process surrounding the disclosure of an incidental finding in a genetics context. These factors include the possibility of disclosure, various practical and technical factors, and various ethical factors. We suggest the development of a decision-making tree, involving an exploration of the practical and ethical concerns raised by the studies. This is in our view the best way of handling the wide variety of both possible incidental findings and parties interested in the disclosure of incidental findings.

The diagnostic value of next generation sequencing in familial nonsyndromic congenital heart defects

To determine the diagnostic value of massive parallel sequencing of a panel of known cardiac genes in familial nonsyndromic congenital heart defects (CHD), targeted sequencing of the coding regions of 57 genes previously implicated in CHD was performed in 36 patients from 13 nonsyndromic CHD families with probable autosomal dominant inheritance. Following variant analysis and Sanger validation, we identified six potential disease causing variants in three genes (MYH6, NOTCH1, and TBX5), which may explain the defects in six families. Several problematic situations were encountered when performing genotype‐phenotype correlations in the families to confirm the causality of these variants.

Distal limb deficiencies, micrognathia syndrome, and syndromic forms of split hand foot malformation (SHFM) are caused by chromosome 10q genomic rearrangements

Background The 10q24 chromosomal region has previously been implicated in split hand foot malformation (SHFM). SHFM3 was mapped to a large interval on chromosome 10q. The corresponding dactylaplasia mouse model was linked to the syntenic locus on chromosome 19. It was shown that the two existing Dac alleles result from MusD-insertions upstream of or within Dactylin (Fbxw4). However, all efforts to find the underlying cause for the human SHFM3 have failed on the analysis of all the genes within the linkage region. Intriguingly a submicroscopic duplication within the critical locus on chromosome 10q24 was associated with the phenotype. Methods and results As a part of screening for genomic rearrangements in cases with unexplained syndromic limb defects, a cohort of patients was analysed by array comparative genomic hybridisation (CGH). A 10q24 microduplication was detected in two individuals with distal limb deficiencies associated with micrognathia, hearing problems and renal hypoplasia. In addition, in a family with two affected siblings, a somatic/gonadal mosaicism for the microduplication was detected in the apparently healthy mother. Using a high resolution oligoarray further delineation of the duplication size was performed. Conclusions The detected 10q24 genomic imbalance in our syndromic patients has a similar size to the duplication in the previously reported individuals with an isolated form of SHFM, thus extending the clinical spectrum of SHFM3. These findings clearly demonstrate the importance of array CGH in the detection of the aetiology of complex, clinically heterogeneous entities.

Refinement of the critical 2p25.3 deletion region: the role of MYT1L in intellectual disability and obesity

Purpose:Submicroscopic deletions of chromosome band 2p25.3 are associated with intellectual disability and/or central obesity. Although MYT1L is believed to be a critical gene responsible for intellectual disability, so far no unequivocal data have confirmed this hypothesis.Methods:In this study we evaluated a cohort of 22 patients (15 sporadic patients and two families) with a 2p25.3 aberration to further refine the clinical phenotype and to delineate the role of MYT1L in intellectual disability and obesity. In addition, myt1l spatiotemporal expression in zebrafish embryos was analyzed by quantitative polymerase chain reaction and whole-mount in situ hybridization.Results:Complete MYT1L deletion, intragenic deletion, or duplication was observed in all sporadic patients, in addition to two patients with a de novo point mutation in MYT1L. The familial cases comprise a 6-Mb deletion in a father and his three children and a 5′ MYT1L overlapping duplication in a father and his two children. Expression analysis in zebrafish embryos shows specific myt1l expression in the developing brain.Conclusion:Our data strongly strengthen the hypothesis that MYT1L is the causal gene for the observed syndromal intellectual disability. Moreover, because 17 patients present with obesity/overweight, haploinsufficiency of MYT1L might predispose to weight problems with childhood onset.Genet Med 17 6, 460–466.

Why genomics shouldn't get too personal: in favor of filters: Re: invited comment by Holly K. Tabor et al. in American Journal of Medical Genetics Part A Volume 155.

We read with great interest the recent Invited Comment by Tabor et al. on the new ethical challenges raised by exome sequencing and whole genome sequencing (ES/WGS) [Tabor et al., 2011]. We are in general agreement with their position that ES/WGS fundamentally challenge assumptions valid for other genetic sequencing techniques in the areas of informed consent, data sharing, and unanticipated findings. What we would like to add is the query whether it is in fact desirable to generate so many unanticipated findings. While Tabor et al. acknowledge that ES/WGS results with potential clinical utility may not have actual utility, and that the return of ES/WGS results will be a strain on resources—financial, time, and expertise—their starting premise appears to be that these are obstacles to be overcome. We wish to suggest an alternative starting premise: thenumber of ES/WGS results of potential clinical utility should be limited as far as possible; concerns about actual utility and the strain to resources then become secondary. We base this premise on several arguments:

A complex submicroscopic chromosomal imbalance in 19p13.11 with one microduplication and two microtriplications

Complex chromosomal rearrangements [CCRs] are considered very rare, but are being detected with an increasing frequency because of the enhanced resolution of novel molecular karyotyping techniques like array-CGH. This report describes a patient carrying a unique CCR involving one duplication and two triplications in a 3.2 Mb region on 19p13.11. The patient presented with microcephaly, velopharyngeal insufficiency, dysmorphism, mental retardation and a muscular ventricular septal defect. We show that CCRs are likely to be more frequent than hitherto appreciated. This has important consequences for genotype-phenotype correlations and warrants caution before labelling imbalances as simple.

Novel FRMD7 Mutations and Genomic Rearrangement Expand the Molecular Pathogenesis of X-Linked Idiopathic Infantile Nystagmus.

PURPOSEnIdiopathic infantile nystagmus (IIN; OMIM 31700) with X-linked inheritance is one of the most common forms of infantile nystagmus. Up to date, three X-linked loci have been identified, Xp11.4-p11.3 (calcium/calmodulin-dependent serine protein kinase [CASK]), Xp22 (GPR143), and Xq26-q27 (FRMD7), respectively. Here, we investigated the role of mutations and copy number variations (CNV) of FRMD7 and GPR143 in the molecular pathogenesis of IIN in 49 unrelated Belgian probands.nnnMETHODSnWe set up a comprehensive molecular genetic workflow based on Sanger sequencing, targeted next generation sequencing (NGS) and CNV analysis using multiplex ligation-dependent probe amplification (MLPA) for FRMD7 (NM_194277.2) and GPR143 (NM_000273.2).nnnRESULTSnIn 11/49 probands, nine unique FRMD7 changes were found, five of which are novel: frameshift mutation c.2036del, missense mutations c.801C>A and c.875T>C, splice-site mutation c.497+5G>A, and one genomic rearrangement (1.29 Mb deletion) in a syndromic case. Additionally, four known mutations were found: c.70G>A, c.886G>C, c.910C>T, and c.660del. The latter was found in three independent families. In silico predictions and segregation testing of the novel mutations support their pathogenic effect. No GPR143 mutations or CNVs were found in the remainder of the probands (38/49).nnnCONCLUSIONSnOverall, genetic defects of FRMD7 were found in 11/49 (22.4%) probands, including the first reported genomic rearrangement of FRMD7 in IIN, expanding its mutational spectrum. Finally, we generate a discovery cohort of IIN patients potentially harboring either hidden a variation of FRMD7 or mutations in genes at known or novel loci sustaining the genetic heterogeneity of IIN.

Neuroimaging findings in Mowat-Wilson syndrome: a study of 54 patients

Purpose:Mowat–Wilson syndrome (MWS) is a genetic disease characterized by distinctive facial features, moderate to severe intellectual disability, and congenital malformations, including Hirschsprung disease, genital and eye anomalies, and congenital heart defects, caused by haploinsufficiency of the ZEB2 gene. To date, no characteristic pattern of brain dysmorphology in MWS has been defined.Methods:Through brain magnetic resonance imaging (MRI) analysis, we delineated a neuroimaging phenotype in 54 MWS patients with a proven ZEB2 defect, compared it with the features identified in a thorough review of published cases, and evaluated genotype–phenotype correlations.Results:Ninety-six percent of patients had abnormal MRI results. The most common features were anomalies of corpus callosum (79.6% of cases), hippocampal abnormalities (77.8%), enlargement of cerebral ventricles (68.5%), and white matter abnormalities (reduction of thickness 40.7%, localized signal alterations 22.2%). Other consistent findings were large basal ganglia, cortical, and cerebellar malformations. Most features were underrepresented in the literature. We also found ZEB2 variations leading to synthesis of a defective protein to be favorable for psychomotor development and some epilepsy features but also associated with corpus callosum agenesis.Conclusion:This study delineated the spectrum of brain anomalies in MWS and provided new insights into the role of ZEB2 in neurodevelopment.Genet Med advance online publication 10 November 2016

ACTB Loss-of-Function Mutations Result in a Pleiotropic Developmental Disorder

ACTB encodes β-actin, an abundant cytoskeletal housekeeping protein. In humans, postulated gain-of-function missense mutations cause Baraitser-Winter syndrome (BRWS), characterized by intellectual disability, cortical malformations, coloboma, sensorineural deafness, and typical facial features. To date, the consequences of loss-of-function ACTB mutations have not been proven conclusively. We describe heterozygous ACTB deletions and nonsense and frameshift mutations in 33 individuals with developmental delay, apparent intellectual disability, increased frequency of internal organ malformations (including those of the heart and the renal tract), growth retardation, and a recognizable facial gestalt (interrupted wavy eyebrows, dense eyelashes, wide nose, wide mouth, and a prominent chin) that is distinct from characteristics of individuals with BRWS. Strikingly, this spectrum overlaps with that of several chromatin-remodeling developmental disorders. In wild-type mouse embryos, β-actin expression was prominent in the kidney, heart, and brain. ACTB mRNA expression levels in lymphoblastic lines and fibroblasts derived from affected individuals were decreased in comparison to those in control cells. Fibroblasts derived from an affected individual and ACTB siRNA knockdown in wild-type fibroblasts showed altered cell shape and migration, consistent with known roles of cytoplasmic β-actin. We also demonstrate that ACTB haploinsufficiency leads to reduced cell proliferation, altered expression of cell-cycle genes, and decreased amounts of nuclear, but not cytoplasmic, β-actin. In conclusion, we show that heterozygous loss-of-function ACTB mutations cause a distinct pleiotropic malformation syndrome with intellectual disability. Our biological studies suggest that a critically reduced amount of this protein alters cell shape, migration, proliferation, and gene expression to the detriment of brain, heart, and kidney development.