Human USP18 deficiency underlies type 1 interferonopathy leading to severe pseudo-TORCH syndrome.

Pseudo-TORCH syndrome (PTS) is characterized by microcephaly, enlarged ventricles, cerebral calcification, and, occasionally, by systemic features at birth resembling the sequelae of congenital infection but in the absence of an infectious agent. Genetic defects resulting in activation of type 1 interferon (IFN) responses have been documented to cause Aicardi-Goutières syndrome, which is a cause of PTS. Ubiquitin-specific peptidase 18 (USP18) is a key negative regulator of type I IFN signaling. In this study, we identified loss-of-function recessive mutations of USP18 in five PTS patients from two unrelated families. Ex vivo brain autopsy material demonstrated innate immune inflammation with calcification and polymicrogyria. In vitro, patient fibroblasts displayed severely enhanced IFN-induced inflammation, which was completely rescued by lentiviral transduction of USP18. These findings add USP18 deficiency to the list of genetic disorders collectively termed type I interferonopathies. Moreover, USP18 deficiency represents the first genetic disorder of PTS caused by dysregulation of the response to type I IFNs. Therapeutically, this places USP18 as a promising target not only for genetic but also acquired IFN-mediated CNS disorders.

Prenatal diagnostic testing of the Noonan syndrome genes in fetuses with abnormal ultrasound findings.

In recent studies on prenatal testing for Noonan syndrome (NS) in fetuses with an increased nuchal translucency (NT) and a normal karyotype, mutations have been reported in 9-16% of cases. In this study, DNA of 75 fetuses with a normal karyotype and abnormal ultrasound findings was tested in a diagnostic setting for mutations in (a subset of) the four most commonly mutated NS genes. A de novo mutation in either PTPN11, KRAS or RAF1 was detected in 13 fetuses (17.3%). Ultrasound findings were increased NT, distended jugular lymphatic sacs (JLS), hydrothorax, renal anomalies, polyhydramnios, cystic hygroma, cardiac anomalies, hydrops fetalis and ascites. A second group, consisting of anonymized DNA of 60 other fetuses with sonographic abnormalities, was tested for mutations in 10 NS genes. In this group, five possible pathogenic mutations have been identified (in PTPN11 (n=2), RAF1, BRAF and MAP2K1 (each n=1)). We recommend prenatal testing of PTPN11, KRAS and RAF1 in pregnancies with an increased NT and at least one of the following additional features: polyhydramnios, hydrops fetalis, renal anomalies, distended JLS, hydrothorax, cardiac anomalies, cystic hygroma and ascites. If possible, mutation analysis of BRAF and MAP2K1 should be considered.

Phenotypic variability of atypical 22q11.2 deletions not including TBX1.

Interstitial deletions of the chromosome 22q11.2 region are the most common microdeletions in humans. The TBX1 gene is considered to be the major candidate gene for the main features in 22q11.2 deletion syndrome, including congenital heart malformations, (para)thyroid hypoplasia, and craniofacial abnormalities. We report on eight patients with atypical deletions of chromosome 22q11.2. These deletions comprise the distal part of the common 22q11.2 deleted region but do not encompass the TBX1 gene. Ten similar patients with overlapping distal 22q11.2 deletions have been reported previously. The clinical features of these patients are described and compared to those found in the classic 22q11.2 deletion syndrome. We discuss the possible roles of a position effect or haploinsufficiency of distally located genes (e.g., CRKL) in the molecular pathogenesis of the 22q11.2 deletion syndrome.

Genomic SNP array as a gold standard for prenatal diagnosis of foetal ultrasound abnormalities.

BACKGROUND: We have investigated whether replacing conventional karyotyping by SNP array analysis in cases of foetal ultrasound abnormalities would increase the diagnostic yield and speed of prenatal diagnosis in clinical practice. FINDINGS/RESULTS: From May 2009 till June 2011 we performed HumanCytoSNP-12 array (HCS) (http://www.Illumina.com) analysis in 207 cases of foetal structural abnormalities. HCS allows detecting unbalanced genomic abnormalities with a resolution of about 150/200 kb. All cases were selected by a clinical geneticist after excluding the most common aneuploidies by RAD (rapid aneuploidy detection). Pre-test genetic counselling was offered in all cases.In 24/207 (11,6%) foetuses a clinically relevant genetic abnormality was detected. Only 8/24 abnormalities would have been detected if only routine karyotyping was performed. Submicroscopic abnormalities were found in 16/207 (7,7%) cases. The array results were achieved within 1-2 weeks after amniocentesis. CONCLUSIONS: Prenatal SNP array testing is faster than karyotyping and allows detecting much smaller aberrations (~0.15 Mb) in addition to the microscopic unbalanced chromosome abnormalities detectable with karyotyping (~ > 5 Mb). Since karyotyping would have missed 66% (16/24) of genomic abnormalities in our cohort, we propose to perform genomic high resolution array testing assisted by pre-test counselling as a primary prenatal diagnostic test in cases of foetal ultrasound abnormalities.

Abnormal facial appearance, body asymmetry, limb deformities, and internal malformations.

We describe a newborn girl with multiple congenital anomalies and abnormal phenotype comprising underdeveloped corpus callosum with ventriculomegaly, chorioretinal atrophy, pulmonary arterial hypertension, annular pancreas, horseshoe kidney, asymmetric limb and chest anomalies, spinal segmentation defects, hypertrichosis, and unusual face with large anterior fontanel, high anterior hairline, broad forehead, mildly underdeveloped midface, hypertelorism, depressed nasal bridge, short and upturned nose, large mouth, retrognathia, and large and malformed ears. Work-up included cytogenetic studies of lymphocytes and skin fibroblasts, subtelomere Multiplex Ligation-dependent Probe Amplification (MLPA), whole-genome oligo-array, and molecular analysis of SETBP1 and NSDHL: no abnormalities were found. Mucopolysaccharide urinary excretion was elevated. Results of metabolic studies for sterol and peroxisomal abnormalities in fibroblasts were normal. Additional electronic microscopy studies in skin fibroblasts did not show evidence for storage in fibroblasts or lysosomal changes. Nosologic considerations allowed exclusion of Schinzel-Giedion and Urioste syndrome. This condition seems not to have been described before; a segregating Mendelian mutation is assumed.

Prenatally diagnosed submicroscopic familial aberrations at 18p11.32 without phenotypic effect.

BACKGROUND: Recent development of MLPA (Multiplex-Ligation-dependent Probe Amplification, MRC-Holland) and microarray technology allows detection of a wide range of new submicroscopic abnormalities. Publishing new cases and case reviews associated with both clinical abnormalities and a normal phenotype is of great value. FINDINGS/RESULTS: We report on two phenotypically normal foetuses carrying a maternally-inherited interstitial submicroscopic abnormality of chromosome 18p11.32. Both abnormalities were found with the aneuploidy MLPA kit P095 during rapid aneuploidy detection, which was offered along with conventional karyotyping. Foetus 1 and its mother have a 1,7 Mb deletion and foetus 2 and its mother have a 1,9 Mb duplication. In both cases normal babies were born. We used the HumanCytoSNP-12 array of Illumina to visualize the CNVs and map the breakpoints. CONCLUSIONS: We suggest that a CNV at 18p11.32 (528,050-2,337,486) may represent a new benign euchromatic variant.

Application of SNP array for rapid prenatal diagnosis: implementation, genetic counselling and diagnostic flow.

We report on the validation and implementation of the HumanCytoSNP-12 array (Illumina) (HCS) in prenatal diagnosis. In total, 64 samples were used to validate the Illumina platform (20 with a known (sub) microscopic chromosome abnormality, 5 with known maternal cell contamination (MCC) and 39 normal control samples). There were no false-positive or false-negative results. In addition to the diagnostic possibilities of arrayCGH, the HCS allows detection of regions of homozygosity (ROH), triploidy and helps recognising MCC. Moreover, in two cases of MCC, a deletion was correctly detected. Furthermore we found out that only about 50 ng of DNA is required, which allows a reporting time of only 3 days. We also present a prospective pilot study of 61 fetuses with ultrasound abnormalities and a normal karyotype tested with HCS. In 4 out of 61 (6.5%) fetuses, a clinically relevant abnormality was detected. We designed and present pre-test genetic counselling information on categories of possible test outcomes. On the basis of this information, about 90% of the parents chose to be informed about adverse health outcomes of their future child at infancy and childhood, and 55% also about outcomes at an adult stage. The latter issue regarding the right of the future child itself to decide whether or not to know this information needs to be addressed.

[Prenatally detected orofacial cleft]. / Prenataal vastgestelde orofaciale schisis.

An increasing number of pregnancies are presumed being terminated following prenatal detection of orofacial cleft during structural ultrasound.After examining the data and literature on this topic it is concluded that the reported cases are merely incidents. For the interpretation of prenatal detection rates a distinction should be made between isolated orofacial cleft and the frequently occurring associated form of orofacial cleft which is usually characterized by other, often major structural or chromosome anomalies. The ultrasound detection rate of the isolated form is low and varies in the literature between 18 and 56%. Together with all Dutch centres of prenatal medicine a care plan was adopted for the management of prenatally detected orofacial cleft including diagnosis (detailed ultrasound examination and karyotyping), medical support (genetic consultations, plastic surgery and psychosocial counselling) and treatment (obstetric and neonatal management). In the presence of associated major congenital anomalies termination of pregnancy may be considered before the 24th week of pregnancy.

Mutation screening of the Ectodysplasin-A receptor gene EDAR in hypohidrotic ectodermal dysplasia.

Hypohidrotic ectodermal dysplasia (HED) can be caused by mutations in the X-linked ectodysplasin A (ED1) gene or the autosomal ectodysplasin A-receptor (EDAR) and EDAR-associated death domain (EDARADD) genes. X-linked and autosomal forms are sometimes clinically indistinguishable. For genetic counseling in families, it is therefore important to know the gene involved. In 24 of 42 unrelated patients with features of HED, we found a mutation in ED1. ED1-negative patients were screened for mutations in EDAR and EDARADD. We found mutations in EDAR in 5 of these 18 patients. One mutation, p.Glu354X, is novel. In EDARADD, a novel variant p.Ser93Phe, probably a neutral polymorphism, was also found. Clinically, there was a difference between autosomal dominant and autosomal recessive HED patients. The phenotype in patients with mutations in both EDAR alleles was comparable to males with X-linked HED. Patients with autosomal dominant HED had features comparable to those of female carriers of X-linked HED. The teeth of these patients were quite severely affected. Hypohidrosis and sparse hair were also evident, but less severe. This study confirms Chassaing et al's earlier finding that mutations in EDAR account for approximately 25% of non-ED1-related HED. Mutations leading to a premature stop codon have a recessive effect except when the stop codon is in the last exon. Heterozygous missense mutations in the functional domains of the gene may have a dominant-negative effect with much variation in expression. Patients with homozygous or compound heterozygous mutations in the EDAR gene have a more severe phenotype than those with a heterozygous missense, nonsense or frame-shift mutation.

New cases of Bohring-Opitz syndrome, update, and critical review of the literature.

We report on four additional unrelated cases of Bohring-Opitz syndrome with the highly characteristic phenotype of facial anomalies including bulging forehead over the metopic suture, frontal nevus flammeus, exophthalmos, hypertelorism, upslanting palpebral fissures, and cleft lip and/or palate, as well as flexion deformities of the upper limbs, multiple other anomalies, and severe failure to thrive. We also update the clinical outcome of the patients reported in the original article by Bohring et al. [Am J Med Genet 85:438-446] and critically review the subsequently published cases considered to have Bohring-Opitz syndrome.

Plantar lipomatosis, unusual facies, and developmental delay: confirmation of Pierpont syndrome.

In 1998, Pierpont et al. reported on two unrelated boys with plantar lipomatosis, unusual facial phenotype, and developmental delay as a possible new MR/MCA syndrome. Here we report on a 2-year-old boy with similar manifestations: axial hypotonia in the first few months, prolonged feeding problems, moderate developmental delay, no speech development, deep palmar and plantar grooves, fat pads at the anteromedial aspect of the heels, and a distinct facial phenotype (high forehead, high anterior hairline, mild midfacial hypoplasia, remarkably narrow and upward slanted palpebral fissures, broad nasal ridge and tip, broad philtrum, bowed upper lip, "pouting" lower lip, full cheeks, and flat occiput). Brain MRI and MR spectroscopy studies showed relatively small frontal lobes, some widening of the lateral and third ventricles, and increased choline levels in the frontal white matter. Cytogenetic studies in lymphocytes and skin fibroblasts and whole genome micro-array CGH failed to show abnormalities. The present patient has a phenotype almost identical to that of the earlier reported children (Pierpont et al. [1998]: Am J Med Genet 75:18-21), which thereby validates this as a separate MR/MCA syndrome, appropriately designated Pierpont syndrome. The cause of the entity remains uncertain, the most likely etiologies being X-linked recessive or autosomal dominant genes.

A novel mutation identified in the DFNA5 gene in a Dutch family: a clinical and genetic evaluation.

A novel DFNA5 mutation was found in a Dutch family, of which 37 members were examined. A nucleotide substitution was identified in the splice acceptor site of intron 7, leading to skipping of exon 8 in part of the transcripts. The mutation was found in 18 individuals. Sensorineural hearing impairment was non-syndromic and symmetric. In early life, presumably congenitally, hearing impairment amounted to 30 dB in the high frequencies. Progression was most pronounced at 1 kHz (1.8 dB/year). Speech recognition was relatively good with a phoneme score of about 50% at the age of 70. Onset age was 37 years, and recognition deteriorated by 1.3% per year. The recognition score deteriorated by 1.0% per decibel threshold increase from a mean pure-tone average (PTA at 1, 2 and 4 kHz) of 63 dB onwards. Vestibular function was generally normal. The second mutation identified in the DFNA5 gene results in hearing impairment, similar to that in the original DFNA5 family in terms of pure-tone thresholds, but with more favourable speech recognition.

Congenital conductive hearing loss in dyschondrosteosis.

Conductive hearing loss was detected in a boy with a previous diagnosis of dyschondrosteosis. Dyschondrosteosis is a rare inherited condition characterized by mesomelic dwarfism and Madelung's deformity. The syndrome can be caused by mutations in the SHOX gene, and in that case, the pattern of inheritance is pseudoautosomal dominant. Indeed, SHOX mutation analysis in our patient revealed a deletion. The combination of dyschondrosteosis and conductive hearing loss has been reported in 2 previous cases. In our patient, exploratory tympanotomy revealed ankylosis of the stapes and a malformed incus. A substantial gain in hearing threshold was obtained by a stapedectomy in combination with a malleovestibulopexy.