Eve Õiglane-Shlik

Three patients with 9p deletions including DMRT1 and DMRT2: A girl with XY complement, bilateral ovotestes, and extreme growth retardation, and two XX females with normal pubertal development

It is well documented that distal 9p monosomy can be associated with XY sex reversal. Recently, the possibility of DMRT1 and/or DMRT2 (the genes for doublesex and mab‐3 related transcription factor 1 and 2) being the sex determining genes(s) at 9p has been raised. DMRT1 and DMRT2 map near the 9p telomere, distal of marker D9S1779. We describe here three unrelated females with distal 9p monosomy, one with XY complement and two with XX complements. In each individual, fluorescent in situ hybridization predicted the loss of the DMRT genes. Patient 1, an XY individual with monosomy 9pter → p24.1 ∼ 24.2 and trisomy 7q32 → qter had normal female external genitalia, a blind ending vagina, no uterus, a Fallopian tube on the right, and bilateral ovotestes with primitive ovarian tissue. She also had extreme growth retardation. Around 80 cases of distal 9p monosomy have been reported previously, but there has been no report of ovotestes or gonads comprising ovarian tissue in a XY patient with 9p deletion. Findings in Patient 1 suggest that the phenotypic spectrum of the heterozygous DMRT deletion may include true hermaphroditism. Patients 2 and 3 were 12‐ and 14‐year‐old females with XX complements, normal external genitalia, and normal pubertal development. Patient 2 had pure monosomy 9pter → p23 and Patient 3 had monosomy 9pter → p22.3 ∼ 23 combined with trisomy 3pter → p23 ∼ 24. To date, detailed reports on the gonadal status of XX 9p‐females have been limited to prepubertal girls. Patients 2 and 3 are the first females reported to have distal 9p monosomy and a normal puberty.

Genetic and phenotypic heterogeneity suggest therapeutic implications in SCN2A-related disorders

Mutations in SCN2A, a gene encoding the voltage-gated sodium channel Nav1.2, have been associated with a spectrum of epilepsies and neurodevelopmental disorders. Here, we report the phenotypes of 71 patients and review 130 previously reported patients. We found that (i) encephalopathies with infantile/childhood onset epilepsies (≥3 months of age) occur almost as often as those with an early infantile onset (<3 months), and are thus more frequent than previously reported; (ii) distinct phenotypes can be seen within the late onset group, including myoclonic-atonic epilepsy (two patients), Lennox-Gastaut not emerging from West syndrome (two patients), and focal epilepsies with an electrical status epilepticus during slow sleep-like EEG pattern (six patients); and (iii) West syndrome constitutes a common phenotype with a major recurring mutation (p.Arg853Gln: two new and four previously reported children). Other known phenotypes include Ohtahara syndrome, epilepsy of infancy with migrating focal seizures, and intellectual disability or autism without epilepsy. To assess the response to antiepileptic therapy, we retrospectively reviewed the treatment regimen and the course of the epilepsy in 66 patients for which well-documented medical information was available. We find that the use of sodium channel blockers was often associated with clinically relevant seizure reduction or seizure freedom in children with early infantile epilepsies (<3 months), whereas other antiepileptic drugs were less effective. In contrast, sodium channel blockers were rarely effective in epilepsies with later onset (≥3 months) and sometimes induced seizure worsening. Regarding the genetic findings, truncating mutations were exclusively seen in patients with late onset epilepsies and lack of response to sodium channel blockers. Functional characterization of four selected missense mutations using whole cell patch-clamping in tsA201 cells-together with data from the literature-suggest that mutations associated with early infantile epilepsy result in increased sodium channel activity with gain-of-function, characterized by slowing of fast inactivation, acceleration of its recovery or increased persistent sodium current. Further, a good response to sodium channel blockers clinically was found to be associated with a relatively small gain-of-function. In contrast, mutations in patients with late-onset forms and an insufficient response to sodium channel blockers were associated with loss-of-function effects, including a depolarizing shift of voltage-dependent activation or a hyperpolarizing shift of channel availability (steady-state inactivation). Our clinical and experimental data suggest a correlation between age at disease onset, response to sodium channel blockers and the functional properties of mutations in children with SCN2A-related epilepsy.

The neonatal phenotype of Prader-Willi syndrome.

Eve Õiglane-Shlik, Riina Žordania, Heili Varendi, Anne Antson, Marja-Liis Mägi, Gunnar Tasa, Oliver Bartsch, Tiina Talvik, and Katrin Õunap* Department of Pediatrics, University of Tartu, Tartu, Estonia Tallinn Children’s Hospital, Tallinn, Estonia Children’s Hospital, Tartu University Clinics, Tartu, Estonia Institute of General and Molecular Pathology, University of Tartu, Tartu, Estonia Institute for Human Genetics, Mainz University School of Medicine, Mainz, Germany Medical Genetics Center, United Laboratories, Tartu University Clinics, Tartu, Estonia

Prevalence of Angelman syndrome and Prader–Willi syndrome in Estonian children: Sister syndromes not equally represented†

In 2000–2004, we performed a focused search for individuals with Angelman syndrome (AS) and Prader–Willi syndrome (PWS) aiming to establish the prevalence data for the individuals born between 1984 and 2004 in Estonia. All persons with probable AS or PWS (n = 184) were studied using the DNA methylation test. Individuals with abnormal methylation were all further tested by chromosomal and FISH analysis, and if necessary for uniparental disomy and UBE3A gene mutation. Nineteen cases with abnormal methylation test result were identified. Seven of them had AS, including six (85.7%) due to 15q11‐13 deletion and one paternal UPD15. Twelve subjects had PWS: 4 (33%) 15q11‐13 deletions, 6 (50%) maternal UPD15, 1 unbalanced chromosome 14;15 translocation resulting in a chromosome 15pter‐q13 deletion, and 1 Robertsonian 15q;15q translocation. The minimum livebirth prevalence in 1984–2004 for AS was 1:52,181 (95% CI 1:25,326–1:1,29,785) and for PWS 1:30,439 (95% CI 1:17,425–1:58,908). The livebirth prevalence of AS and PWS increased within this period, but the change was statistically significant only for PWS (P = 0.032), from expected 1:88,495 (95% CI 1:24,390–1:3,22,580) to expected 1:12,547 (95% CI 1:540–1:29,154). Six individuals with AS and 11 with PWS were alive on the prevalence day (January 1, 2005), indicating the point prevalence proportion of 1:56,112 (95% CI 1:25,780–1:1,52,899) and 1:30,606 (95% CI 1:17,105–1:61,311), respectively. Our results showing the birth prevalence of AS 1.7 times less than PWS challenge the opinion that both syndromes are equally represented, and are in line with the view that mutations in sperm and oocytes occur at different frequencies.

Biallelic CACNA1A mutations cause early onset epileptic encephalopathy with progressive cerebral, cerebellar, and optic nerve atrophy.

The CACNA1A gene encodes the transmembrane pore‐forming alpha‐1A subunit of the Cav2.1 P/Q‐type voltage‐gated calcium channel. Several heterozygous mutations within this gene, including nonsense mutations, missense mutations, and expansion of cytosine‐adenine‐guanine repeats, are known to cause three allelic autosomal dominant conditions—episodic ataxia type 2, familial hemiplegic migraine type 1, and spinocerebellar ataxia type 6. An association with epilepsy and CACNA1A mutations has also been described. However, the link with epileptic encephalopathies has emerged only recently. Here we describe two patients, sister and brother, with compound heterozygous mutations in CACNA1A. Exome sequencing detected biallelic mutations in CACNA1A: A missense mutation c.4315T>A (p.Trp1439Arg) in exon 27, and a seven base pair deletion c.472_478delGCCTTCC (p.Ala158Thrfs*6) in exon 3. Both patients were normal at birth, but developed daily recurrent seizures in early infancy with concomitant extreme muscular hypotonia, hypokinesia, and global developmental delay. The brain MRI images showed progressive cerebral, cerebellar, and optic nerve atrophy. At the age of 5, both patients were blind and bedridden with a profound developmental delay. The elder sister died at that age. Their parents and two siblings were heterozygotes for one of those pathogenic mutations and expressed a milder phenotype. Both of them have intellectual disability and in addition the mother has adult onset cerebellar ataxia with a slowly progressive cerebellar atrophy. Compound heterozygous mutations in the CACNA1A gene presumably cause early onset epileptic encephalopathy, and progressive cerebral, cerebellar and optic nerve atrophy with reduced lifespan.

A patient with the classic features of Phelan‐McDermid syndrome and a high immunoglobulin E level caused by a cryptic interstitial 0.72‐Mb deletion in the 22q13.2 region

Phelan‐McDermid syndrome, also known as the 22q13 deletion syndrome, is a chromosomal microdeletion syndrome characterized by neonatal hypotonia, normal growth, profound developmental delay, absent or delayed speech, and minor dysmorphic features. Almost all of the 22q13 deletions published so far have been described as terminal. It is believed that the SHANK3 gene is the major candidate gene for the neurologic features of the syndrome. Here we describe a patient with a 0.72‐Mb interstitial 22q13.2 deletion, intellectual disability, autistic behavior, epilepsy, mild dysmorphic features, and no deletion in the SHANK3 gene. The patient also has urticarial rash and an elevated level of immunoglobulin E, the latter has previously been described only once in a patient with monosomy 22q13.2‐qter and SHANK3 gene deletion. To our knowledge, this is one of the smallest interstitial deletion in this region which has been published up to now. Although the patient has the classic phenotype of the 22q13 terminal deletion syndrome, the etiology for the neurologic and immunological features must be due to genes located more proximal to SHANK3 and this is also supported by other previously published cases of interstitial 22q13.2 deletions. The deleted area in our patient is gene‐rich (26 genes), containing several known genes with different functions. Two of them—NFAM1 and TNFRSF13C are involved in immune system functioning. We suggest the haploinsufficiency of these genes might be related to hyper IgE syndrome in our patient.

Coffin–Siris Syndrome with obesity, macrocephaly, hepatomegaly and hyperinsulinism caused by a mutation in the ARID1B gene

Coffin–Siris Syndrome (CSS, MIM 135900) is a rare genetic disorder, and mutations in ARID1B were recently shown to cause CSS. In this study, we report a novel ARID1B mutation identified by whole-exome sequencing in a patient with clinical features of CSS. We identified a novel heterozygous frameshift mutation c.1584delG in exon 2 of ARID1B (NM_020732.3) predicting a premature stop codon p.(Leu528Phefs*65). Sanger sequencing confirmed the c.1584delG mutation as a de novo in the proband and that it was not present either in her parents, half-sister or half-brother. Clinically, the patient presented with extreme obesity, macrocephaly, hepatomegaly, hyperinsulinism and polycystic ovarian syndrome (PCOS), which have previously not been described in CSS patients. We suggest that obesity, macrocephaly, hepatomegaly and/or PCOS may be added to the list of clinical features of ARID1B mutations, but further clinical reports are required to make a definite conclusion.

Mosaicism for maternal uniparental disomy 15 in a boy with some clinical features of Prader–Willi syndrome

Prader-Willi syndrome (PWS) is caused by the lack of paternal expression of imprinted genes in the human chromosomal region 15q11.2-q13.2, which can be due to an interstitial deletion at 15q11.2-q13 of paternal origin (65-75%), maternal uniparental disomy (matUPD) of chromosome 15 (20-30%), or an imprinting defect (1-3%). The majority of PWS-associated matUPD15 cases represent a complete heterodisomy of chromosome 15 or a mixture of hetero- and isodisomic regions across the chromosome 15. Pure maternal isodisomy is observed in only a few matUPD15 patients. Here we report a case of an 18-year-old boy with some clinical features of Prader-Willi syndrome, such as overweight, muscular hypotonia, facial dysmorphism and psychiatric problems, but there was no reason to suspect PWS in the patient based solely on the phenotype estimation. However, chromosomal microarray analysis (CMA) revealed mosaic loss of heterozygosity of the entire chromosome 15. Methylation-specific multiplex ligation-dependant probe amplification (MS-MLPA) analysis showed hypermethylation of the SNRPN and NDN genes in the PWS/AS critical region of chromosome 15 in this patient. Taking into consideration the MS-MLPA results and the presence of PWS features in the patient, we concluded that it was matUPD15, although the patients parents were not enrolled in the study. According to CMA and karyotyping, no trisomic or monosomic cells were present. To the best of our knowledge, only two PWS cases with mosaic maternal isodisomy 15 and without trisomic/monosomic cell lines have been reported so far.

Monosomy 1p36 - a multifaceted and still enigmatic syndrome: four clinically diverse cases with shared white matter abnormalities.

Monosomy 1p36 is the most common subtelomeric deletion syndrome seen in humans. Uniform features of the syndrome include early developmental delay and consequent intellectual disability, muscular hypotonia, and characteristic dysmorphic facial features. The gene-rich nature of the chromosomal band, inconsistent deletion sizes and overlapping clinical features have complicated relevant genotype-phenotype correlations. We describe four patients with isolated chromosome 1p36 deletions. All patients shared white matter abnormalities, allowing us to narrow the critical region for white matter involvement to the deletion size of up to 2.5 Mb from the telomere. We hypothesise that there might be a gene(s) responsible for myelin development in the 1p36 subtelomeric region. Other significant clinical findings were progressive spastic paraparesis, epileptic encephalopathy, various skeletal anomalies, Prader-Willi-like phenotype, neoplastic changes - a haemangioma and a benign skin tumour, and in one case, sleep myoclonus, a clinical entity not previously described in association with 1p36 monosomy. Combined with prior studies, our results suggest that the clinical features seen in monosomy 1p36 have more complex causes than a classical contiguous gene deletion syndrome.

Effectiveness of whole exome sequencing in unsolved patients with a clinical suspicion of a mitochondrial disorder in Estonia

Objective Reaching a genetic diagnosis of mitochondrial disorders (MDs) is challenging due to their broad phenotypic and genotypic heterogeneity. However, there is growing evidence that the use of whole exome sequencing (WES) for diagnosing patients with a clinical suspicion of an MD is effective (39–60%). We aimed to study the effectiveness of WES in clinical practice in Estonia, in patients with an unsolved, but suspected MD. We also show our first results of mtDNA analysis obtained from standard WES reads. Methods Retrospective cases were selected from a database of 181 patients whose fibroblast cell cultures had been stored from 2003 to 2013. Prospective cases were selected during the period of 2014–2016 from patients referred to a clinical geneticist in whom an MD was suspected. We scored each patient according to the mitochondrial disease criteria (MDC) (Morava et al., 2006) after re-evaluation of their clinical data, and then performed WES analysis. Results A total of 28 patients were selected to the study group. A disease-causing variant was found in 16 patients (57%) using WES. An MD was diagnosed in four patients (14%), with variants in the SLC25A4, POLG, SPATA5, and NDUFB11 genes. Other variants found were associated with a neuromuscular disease (SMN1, MYH2, and LMNA genes), neurodegenerative disorder (TSPOAP1, CACNA1A, ALS2, and SCN2A genes), multisystemic disease (EPG5, NKX1–2, ATRX, and ABCC6 genes), and one in an isolated cardiomyopathy causing gene (MYBPC3). The mtDNA point mutation was found in the MT-ATP6 gene of one patient upon mtDNA analysis. Conclusions The diagnostic yield of WES in our cohort was 57%, proving to be a very good effectiveness. However, MDs were found in only 14% of the patients. We suggest WES analysis as a first-tier method in clinical genetic practice for children with any multisystem, neurological, and/or neuromuscular problem, as nuclear DNA variants are more common in children with MDs; a large number of patients harbor disease-causing variants in genes other than the mitochondria-related ones, and the clinical presentation might not always point towards an MD. We have also successfully conducted analysis of mtDNA from standard WES reads, providing further evidence that this method could be routinely used in the future.