Mónica Roselló

Detection of known and novel genomic rearrangements by array based comparative genomic hybridisation: deletion of ZNF533 and duplication of CHARGE syndrome genes

Background: Mental retardation can be caused by copy number variations (deletions, insertions, duplications), ranging in size from 1 kb to several megabases. Array based comparative genomic hybridisation (array-CGH) allows detection of an increasing number of genomic alterations. Methods: A series of 46 patients with mental retardation and congenital abnormalities (previously screened for subtelomeric rearrangements) were evaluated for cryptic chromosomal imbalances by array-CGH. This array contains 6465 large-insert BAC/PAC clones, representing sequences uniformly distributed throughout the human genome. The results were confirmed by alternative techniques. Results: Four pathogenic rearrangements were detected: two of them were novel, a deletion at 2q31.2 and a duplication at 8q12 band; the other two have been previously reported—a duplication of the Williams–Beuren region and a deletion of 3q29. By adding the subtelomeric alterations previously identified, a total rate of 18% of pathogenic rearrangements was found in the series. Conclusion: Based on our results, ZNF533 is the only gene contained in the overlapping region with other deletions at 2q31.2, and it is most probably the fourth zinc-finger gene implied in mental retardation. On the other hand, we propose that the CHD7 gene, associated with CHARGE syndrome by haploinsufficiency, causes a different phenotype by gain-of-dosage.

TAF1 Variants Are Associated with Dysmorphic Features, Intellectual Disability, and Neurological Manifestations.

We describe an X-linked genetic syndrome associated with mutations in TAF1 and manifesting with global developmental delay, intellectual disability (ID), characteristic facial dysmorphology, generalized hypotonia, and variable neurologic features, all in male individuals. Simultaneous studies using diverse strategies led to the identification of nine families with overlapping clinical presentations and affected by de novo or maternally inherited single-nucleotide changes. Two additional families harboring large duplications involving TAF1 were also found to share phenotypic overlap with the probands harboring single-nucleotide changes, but they also demonstrated a severe neurodegeneration phenotype. Functional analysis with RNA-seq for one of the families suggested that the phenotype is associated with downregulation of a set of genes notably enriched with genes regulated by E-box proteins. In addition, knockdown and mutant studies of this gene in zebrafish have shown a quantifiable, albeit small, effect on a neuronal phenotype. Our results suggest that mutations in TAF1 play a critical role in the development of this X-linked ID syndrome.

Corpus Callosum Abnormalities and the Controversy about the Candidate Genes Located in 1q44

Submicroscopic deletions of 1q44–qter cause severe mental retardation, profound growth retardation, microcephaly and corpus callosum hypo/agenesis in most patients. At least 3 intervals in 1q44 have been described as critical regions containing genes leading to corpus callosum abnormalities. In this report we describe a patient with a de novo small interstitial 1q44 deletion of 1,152 kb detected with 44K oligonucleotide array-CGH (44K Agilent Technologies) and a mild phenotype lacking corpus callosum abnormalities. The first deleted oligonucleotide was located at 242.638 Mb (within the ADSS gene), and the last deleted oligonucleotide at 243.791 Mb (within the KIF26B gene). The clinical and molecular findings of the patient here reported remain consistent with a role for the AKT3 or ZNF238 genes in corpus callosum development.

High diagnostic yield of syndromic intellectual disability by targeted next-generation sequencing

Background Intellectual disability is a very complex condition where more than 600 genes have been reported. Due to this extraordinary heterogeneity, a large proportion of patients remain without a specific diagnosis and genetic counselling. The need for new methodological strategies in order to detect a greater number of mutations in multiple genes is therefore crucial. Methods In this work, we screened a large panel of 1256 genes (646 pathogenic, 610 candidate) by next-generation sequencing to determine the molecular aetiology of syndromic intellectual disability. A total of 92 patients, negative for previous genetic analyses, were studied together with their parents. Clinically relevant variants were validated by conventional sequencing. Results A definitive diagnosis was achieved in 29 families by testing the 646 known pathogenic genes. Mutations were found in 25 different genes, where only the genes KMT2D, KMT2A and MED13L were found mutated in more than one patient. A preponderance of de novo mutations was noted even among the X linked conditions. Additionally, seven de novo probably pathogenic mutations were found in the candidate genes AGO1, JARID2, SIN3B, FBXO11, MAP3K7, HDAC2 and SMARCC2. Altogether, this means a diagnostic yield of 39% of the cases (95% CI 30% to 49%). Conclusions The developed panel proved to be efficient and suitable for the genetic diagnosis of syndromic intellectual disability in a clinical setting. Next-generation sequencing has the potential for high-throughput identification of genetic variations, although the challenges of an adequate clinical interpretation of these variants and the knowledge on further unknown genes causing intellectual disability remain to be solved.

Reciprocal deletion and duplication at 2q23.1 indicates a role for MBD5 in autism spectrum disorder

Copy number variations associated with abnormal gene dosage have an important role in the genetic etiology of many neurodevelopmental disorders, including intellectual disability (ID) and autism. We hypothesize that the chromosome 2q23.1 region encompassing MBD5 is a dosage-dependent region, wherein deletion or duplication results in altered gene dosage. We previously established the 2q23.1 microdeletion syndrome and report herein 23 individuals with 2q23.1 duplications, thus establishing a complementary duplication syndrome. The observed phenotype includes ID, language impairments, infantile hypotonia and gross motor delay, behavioral problems, autistic features, dysmorphic facial features (pinnae anomalies, arched eyebrows, prominent nose, small chin, thin upper lip), and minor digital anomalies (fifth finger clinodactyly and large broad first toe). The microduplication size varies among all cases and ranges from 68 kb to 53.7 Mb, encompassing a region that includes MBD5, an important factor in methylation patterning and epigenetic regulation. We previously reported that haploinsufficiency of MBD5 is the primary causal factor in 2q23.1 microdeletion syndrome and that mutations in MBD5 are associated with autism. In this study, we demonstrate that MBD5 is the only gene in common among all duplication cases and that overexpression of MBD5 is likely responsible for the core clinical features present in 2q23.1 microduplication syndrome. Phenotypic analyses suggest that 2q23.1 duplication results in a slightly less severe phenotype than the reciprocal deletion. The features associated with a deletion, mutation or duplication of MBD5 and the gene expression changes observed support MBD5 as a dosage-sensitive gene critical for normal development.

Identification of Intellectual Disability Genes in Female Patients with a Skewed X-Inactivation Pattern.

Intellectual disability (ID) is a heterogeneous disorder with an unknown molecular etiology in many cases. Previously, X‐linked ID (XLID) studies focused on males because of the hemizygous state of their X chromosome. Carrier females are generally unaffected because of the presence of a second normal allele, or inactivation of the mutant X chromosome in most of their cells (skewing). However, in female ID patients, we hypothesized that the presence of skewing of X‐inactivation would be an indicator for an X chromosomal ID cause. We analyzed the X‐inactivation patterns of 288 females with ID, and found that 22 (7.6%) had extreme skewing (>90%), which is significantly higher than observed in the general population (3.6%; P = 0.029). Whole‐exome sequencing of 19 females with extreme skewing revealed causal variants in six females in the XLID genes DDX3X, NHS, WDR45, MECP2, and SMC1A. Interestingly, variants in genes escaping X‐inactivation presumably cause both XLID and skewing of X‐inactivation in three of these patients. Moreover, variants likely accounting for skewing only were detected in MED12, HDAC8, and TAF9B. All tested candidate causative variants were de novo events. Hence, extreme skewing is a good indicator for the presence of X‐linked variants in female patients.

De novo Interstitial Triplication of MECP2 in a Girl with Neurodevelopmental Disorder and Random X Chromosome Inactivation

Loss-of-function mutations of the MECP2 gene are the cause of most cases of Rett syndrome in females, a progressive neurodevelopmental disorder characterized by severe mental retardation, global regression, hand stereotypies, and microcephaly. On the other hand, gain of dosage of this gene causes the MECP2 duplication syndrome in males characterized by severe mental retardation, absence of speech development, infantile hypotonia, progressive spasticity, recurrent infections, and facial dysmorphism. Female carriers of a heterozygous duplication show a skewed X-inactivation pattern which is the most probable cause of the lack of clinical symptoms. In this paper, we describe a girl with a complex de novo copy number gain at Xq28 and non-skewed X-inactivation pattern that causes mental retardation and motor and language delay. This rearrangement implies triplication of the MECP2 and IRAK1 genes, but it does not span other proximal genes located in the common minimal region of patients affected by the MECP2 duplication syndrome. We conclude that the triplication leads to a severe phenotype due to random X-inactivation, while the preferential X chromosome inactivation in healthy carriers may be caused by a negative selection effect of the duplication on some proximal genes like ARD1A or HCFC1.

Duplication of 14q11.2 associates with short stature and mild mental retardation: A putative relation with quantitative trait loci†

Submicroscopic chromosomal rearrangements are a frequent cause of mental retardation in patients with additional phenotypic features. The clinical consequences of these genomic copy-number abnormalities are determined by the kind of alteration (deletion or duplication) and by the number and function of those genes affected by the dosage alteration [Biesecker, 2002; de Vries et al., 2005]. However, the identification of the specific genes directly implied in the phenotypic consequences is a question far from being resolved. Here we report our findings on a patient with short stature and mild mental retardation with a de novo duplication of 14q11.2, a region where significant linkage of quantitative trait loci (QTL) for stature or for a component of the intelligencehavebeen reported [Beck et al., 2003; Buyske et al., 2006]. The patient is a 14-year-old male referred for short stature (<3rd centile), hypogenitalism and mild mental retardation. He is the second child of healthy non-consanguineous parents. After pre-term delivery (38 weeks), the following signs or conditions were recorded: birth weight 2,350 g (<3rd centile), length 45 cm (<3rd centile), occipitofrontal circumference33 cm(3rd–10th centile), iris colobomaat the left eye and retrognathia. Psychomotor development was subsequently delayed: he started to walk at 16 months of age, and he spoke his first words at 2 years old. After 11 years pubertal development stopped and growth development declined dramatically. Upon clinical examination at 13 years, he showed short stature (144 cm; <3rd centile), mild hypogenitalism, and dysmorphic features including micrognathia, a bulbous nose, short philtrum, thin lips, clinodactyly and bilateral partial syndactyly between toes 2–3 (see Fig. 1). Hormone determinations, including FSH, LH, testosterone and GH, were reported at normal levels. No relevant family history was reported, except for short stature of the paternal grandmother and one half-sibling of the father. Blood samples of the patient, and the parents were obtained after informed consent. Routine chromosome analysis was normal. However, one 14q11 copy-number gain was detected by quantitative analysis of the subtelomeric regionswith the use of MLPA (SALSA P036B and P019 from MRCHolland,Amsterdam, TheNetherlands), as described elsewhere [Monfort et al., 2006], where this case was referred as case 90. The duplication was validated by microsatellite segregation analysis with markers D14S72, D14S1023, and D14S990. In addition, MLPA testing on the parental samples allowed to establish a de novo condition in the patient. On the other hand, FISH studies with BAC DNA clone RP11-52401 ruled out the possibility of a cryptic chromosomal translocation with another acrocentric chromosome. In order to determine the size of the duplication, the patient’s DNA sample was tested against a pool of normal DNA samples by array-based comparative genomic hybridization (human genome CGH microarray G4410B from Agilent Technologies, Palo Alto,

Enrichment of ultraconserved elements among genomic imbalances causing mental delay and congenital anomalies

BackgroundThe ultraconserved elements (UCEs) are defined as stretches of at least 200 base pairs of human DNA that match identically with corresponding regions in the mouse and rat genomes, albeit their real significance remains an intriguing issue. These elements are most often located either overlapping exons in genes involved in RNA processing or in introns or nearby genes involved in the regulation of transcription and development. Interestingly, human UCEs have been reported to be strongly depleted among segmental duplications and benign copy number variants (CNVs). However no comprehensive survey of a putative enrichment of these elements among pathogenic dose variants has yet been reported.ResultsA survey for UCEs was performed among the 26 cryptic genomic rearrangements detected in our series of 200 patients with idiopathic neurodevelopmental disorders associated to congenital anomalies. A total of 29 elements, out of the 481 described UCEs, were contained in 13 of the 26 pathogenic gains or losses detected in our series, what represents a highly significant enrichment of ultraconserved elements. In addition, here we show that these elements are preferentially found in pathogenic deletions (enrichment ratio 3.6 vs. 0.5 in duplications), and that this association is not related with a higher content of genes. In contrast, pathogenic CNVs lacking UCEs showed almost a threefold higher content in genes.ConclusionsWe propose that these elements may be interpreted as hallmarks for dose-sensitive genes, particularly for those genes whose gain or loss may be directly implied in neurodevelopmental disorders. Therefore, their presence in genomic imbalances of unknown effect might be suggestive of a clinically relevant condition.

Novel UBE3A mutations causing Angelman syndrome: Different parental origin for single nucleotide changes and multiple nucleotide deletions or insertions†

Angelman syndrome (AS) is a genetic disorder caused by a deficiency of UBE3A imprinted gene expression from the maternal chromosome 15. In 10% of AS cases the genetic cause is a mutation affecting the maternal copy of the UBE3A gene. In two large Spanish series of clinically stringently selected and nonstringently selected patients, we have identified 11 pathological mutations—eight of them novel mutations—and 14 sequence changes considered polymorphic variants. Remarkably, single nucleotide substitutions are more likely to be inherited, while multiple nucleotide deletions or insertions are less frequently inherited, thus indicating that single nucleotide substitutions are more likely to originate from the paternal germline. Additionally, there seems to be a different distribution of nucleotide changes and multiple nucleotide deletions or insertions along the UBE3A gene sequence.