Novel domain-specific POU3F4 mutations are associated with X-linked deafness: examples from different populations.

BACKGROUND: Mutations in the POU3F4 gene cause X-linked deafness type 3 (DFN3), which is characterized by inner ear anomalies. METHODS: Three Turkish, one Ecuadorian, and one Nigerian families were included based on either inner ear anomalies detected in probands or X-linked family histories. Exome sequencing and/or Sanger sequencing were performed in order to identify the causative DNA variants in these families. RESULTS: Four novel, c.707A>C (p.(Glu236Ala)), c.772delG (p.(Glu258ArgfsX30)), c.902C>T (p.(Pro301Leu)), c.987T>C (p.(Ile308Thr)), and one previously reported mutation c.346delG (p.(Ala116ProfsX26)) in POU3F4, were identified. All mutations identified are predicted to affect the POU-specific or POU homeo domains of the protein and co-segregated with deafness in all families. CONCLUSIONS: Expanding the spectrum of POU3F4 mutations in different populations along with their associated phenotypes provides better understanding of their clinical importance and will be helpful in clinical evaluation and counseling of the affected individuals.

An amino acid deletion inSZT2 in a family with non-syndromic intellectual disability.

Autosomal recessive intellectual disability (ID) is characterized by extensive genetic heterogeneity. Recently, three mutations in SZT2 were reported in two unrelated children with unexplained infantile epileptic encephalopathy with severe ID. Here we report a European American family with three children having non-syndromic mild or moderate ID without seizures. Whole-exome sequencing of three affected siblings revealed a three base pair deletion (c.4202_4204delTTC) located in a 19 mb autozygous region on chromosome 1, leading to an amino acid deletion (p.Phe1401del) in SZT2. All three children were homozygous for the deletion and their parents were heterozygous as expected in autosomal recessive inheritance. SZT2 is highly expressed in neuronal tissues and regulates seizure threshold and neuronal excitation in mice. We conclude that the disruption of SZT2 with some residual function might lead to mild or moderate ID without seizures.

Mutations in OTOGL, encoding the inner ear protein otogelin-like, cause moderate sensorineural hearing loss.

Hereditary hearing loss is characterized by a high degree of genetic heterogeneity. Here we present OTOGL mutations, a homozygous one base pair deletion (c.1430 delT) causing a frameshift (p.Val477Glufs(∗)25) in a large consanguineous family and two compound heterozygous mutations, c.547C>T (p.Arg183(∗)) and c.5238+5G>A, in a nonconsanguineous family with moderate nonsyndromic sensorineural hearing loss. OTOGL maps to the DFNB84 locus at 12q21.31 and encodes otogelin-like, which has structural similarities to the epithelial-secreted mucin protein family. We demonstrate that Otogl is expressed in the inner ear of vertebrates with a transcription level that is high in embryonic, lower in neonatal, and much lower in adult stages. Otogelin-like is localized to the acellular membranes of the cochlea and the vestibular system and to a variety of inner ear cells located underneath these membranes. Knocking down of otogl with morpholinos in zebrafish leads to sensorineural hearing loss and anatomical changes in the inner ear, supporting that otogelin-like is essential for normal inner ear function. We propose that OTOGL mutations affect the production and/or function of acellular structures of the inner ear, which ultimately leads to sensorineural hearing loss.

Randomized phase II trial of letrozole plus anti-MUC1 antibody AS1402 in hormone receptor-positive locally advanced or metastatic breast cancer.

PURPOSE: AS1402 is a humanized immunoglobulin G1 antibody that targets the aberrantly glycosylated antigen MUC1, which is overexpressed in 90% of breast tumors and contributes to estrogen-mediated growth and survival of breast cancer cells in vitro by modulating estrogen receptor (ER) activity. Aromatase inhibitors have been reported to enhance antibody-dependent cell-mediated cytotoxicity elicited by antibodies in vitro. We compared the outcomes of patients with breast cancer treated with letrozole with or without AS1402. EXPERIMENTAL DESIGN: The study population included 110 patients with locally advanced or metastatic hormone receptor-positive breast cancer randomized to receive 2.5 mg letrozole only once daily or with a weekly 9 mg/kg AS1402 infusion. The primary endpoint was overall response rate. Secondary endpoints included progression-free survival, time to progression, and safety. AS1402 exposure and influence of allotypes of FcγRIIIa, FcγRIIa, and MUC1 were evaluated. RESULTS: The study was stopped early because of a trend toward worse response rates and a higher rate of early disease progression in the AS1402 + letrozole arm. Final analysis revealed no significant difference in efficacy between the study arms. Evaluated gene polymorphisms did not define patient subgroups with improved outcomes. Addition of AS1402 to letrozole was associated with manageable toxicity. CONCLUSIONS: Because adding AS1402 to letrozole did not improve outcomes compared with letrozole only, blocking ER may be a better strategy for harnessing MUC1 modulation of the ER to a clinical advantage. FcγRIIIa, FcγRIIa, and MUC1 allotype did not predict outcome for patients treated with letrozole with or without AS1402.

Inherited mutation of the luteinizing hormone/choriogonadotropin receptor (LHCGR) in empty follicle syndrome.

OBJECTIVE: To test by genomic analysis whether empty follicle syndrome (EFS) in a family with two affected sisters has a genetic basis. DESIGN: Whole-exome sequencing in the context of clinical genetics. SETTING: University hospital. PATIENT(S): Two women (36 and 32 years old at the time of the study) with EFS. INTERVENTION(S): Genetic counseling based on autosomal recessive inheritance. MAIN OUTCOME MEASURE(S): Discovery of a mutation in the LH/choriogonadotropin receptor (LHCGR) as the cause of EFS. RESULT(S): A novel missense mutation in LHCGR, p.N400S, was homozygous in sisters with EFS and/or infertility, but not in their unaffected siblings or parents. The mutation was not present in 500 ancestry-matched control subjects. Asparagine at residue 400 is highly conserved and its substitution by serine predicted to alter critical interactions that stabilize LHCGR. CONCLUSION(S): We describe a genetic basis for EFS and provide strong evidence for the existence of genuine EFS in some patients. A mutation impairing the function of LHCGR explains the lack of response of these patients to repeated administration of ß-hCG.

Rare missense and synonymous variants in UBE1 are associated with X-linked infantile spinal muscular atrophy.

X-linked infantile spinal muscular atrophy (XL-SMA) is an X-linked disorder presenting with the clinical features hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and infantile death. To identify the XL-SMA disease gene, we performed large-scale mutation analysis in genes located between markers DXS8080 and DXS7132 (Xp11.3-Xq11.1). This resulted in detection of three rare novel variants in exon 15 of UBE1 that segregate with disease: two missense mutations (c.1617 G-->T, p.Met539Ile; c.1639 A-->G, p.Ser547Gly) present each in one XL-SMA family, and one synonymous C-->T substitution (c.1731 C-->T, p.Asn577Asn) identified in another three unrelated families. Absence of the missense mutations was demonstrated for 3550 and absence of the synonymous mutation was shown in 7914 control X chromosomes; therefore, these results yielded statistical significant evidence for the association of the synonymous substitution and the two missense mutations with XL-SMA (p = 2.416 x 10(-10), p = 0.001815). We also demonstrated that the synonymous C-->T substitution leads to significant reduction of UBE1 expression and alters the methylation pattern of exon 15, implying a plausible role of this DNA element in developmental UBE1 expression in humans. Our observations indicate first that XL-SMA is part of a growing list of neurodegenerative disorders associated with defects in the ubiquitin-proteasome pathway and second that synonymous C-->T transitions might have the potential to affect gene expression.

X-linked infantile spinal muscular atrophy: clinical definition and molecular mapping.

PURPOSE: X-linked infantile spinal-muscular atrophy (XL-SMA) is a rare disorder, which presents with the clinical characteristics of hypotonia, areflexia, and multiple congenital contractures (arthrogryposis) associated with loss of anterior horn cells and death in infancy. We have previously reported a single family with XL-SMA that mapped to Xp11.3-q11.2. Here we report further clinical description of XL-SMA plus an additional seven unrelated (XL-SMA) families from North America and Europe that show linkage data consistent with the same region. METHODS: We first investigated linkage to the candidate disease gene region using microsatellite repeat markers. We further saturated the candidate disease gene region using polymorphic microsatellite repeat markers and single nucleotide polymorphisms in an effort to narrow the critical region. Two-point and multipoint linkage analysis was performed using the Allegro software package. RESULTS: Linkage analysis of all XL-SMA families displayed linkage consistent with the original XL-SMA region. CONCLUSION: The addition of new families and new markers has narrowed the disease gene interval for a XL-SMA locus between SNP FLJ22843 near marker DXS 8080 and SNP ARHGEF9 which is near DXS7132 (Xp11.3-Xq11.1).