Oya Uyguner

Mutations in different components of FGF signaling in LADD syndrome.

Lacrimo-auriculo-dento-digital (LADD) syndrome is characterized by lacrimal duct aplasia, malformed ears and deafness, small teeth and digital anomalies. We identified heterozygous mutations in the tyrosine kinase domains of the genes encoding fibroblast growth factor receptors 2 and 3 (FGFR2, FGFR3) in LADD families, and in one further LADD family, we detected a mutation in the gene encoding fibroblast growth factor 10 (FGF10), a known FGFR ligand. These findings increase the spectrum of anomalies associated with abnormal FGF signaling.

Loss of desmoplakin isoform I causes early onset cardiomyopathy and heart failure in a Naxos-like syndrome

Background: Desmosomes are cellular junctions important for intercellular adhesion and anchoring the intermediate filament (IF) cytoskeleton to the cell membrane. Desmoplakin (DSP) is the most abundant desmosomal protein with 2 isoforms produced by alternative splicing. Methods: We describe a patient with a recessively inherited arrhythmogenic dilated cardiomyopathy with left and right ventricular involvement, epidermolytic palmoplantar keratoderma, and woolly hair. The patient showed a severe heart phenotype with an early onset and rapid progression to heart failure at 4 years of age. Results: A homozygous nonsense mutation, R1267X, was found in exon 23 of the desmoplakin gene, which results in an isoform specific truncation of the larger DSPI isoform. The loss of most of the DSPI specific rod domain and C-terminal area was confirmed by Western blotting and immunofluorescence. We further showed that the truncated DSPI transcript is unstable, leading to a loss of DSPI. DSPI is reported to be an obligate constituent of desmosomes and the only isoform present in cardiac tissue. To address this, we reviewed the expression of DSP isoforms in the heart. Our data suggest that DSPI is the major cardiac isoform but we also show that specific compartments of the heart have detectable DSPII expression. Conclusions: This is the first description of a phenotype caused by a mutation affecting only one DSP isoform. Our findings emphasise the importance of desmoplakin and desmosomes in epidermal and cardiac function and additionally highlight the possibility that the different isoforms of desmoplakin may have distinct functional properties within the desmosome.

hKChIP2 is a functional modifier of hKv4.3 potassium channels: cloning and expression of a short hKChIP2 splice variant.

OBJECTIVE The Ca(2+) independent transient outward K(+) current (I(to1)) in the heart is responsible for the initial phase of repolarization. The hKv4.3 K(+) channel alpha-subunit contributes to the I(to1) current in many regions of the human heart. Consistently, downregulation of hKv4.3 transcripts in heart failure and atrial fibrillation is linked to reduction in I(to1) conductance. The recently cloned KChIP family of calcium sensors has been shown to modulate A-type potassium channels of the Kv4 K(+) channel subfamily. METHODS AND RESULTS We describe the cloning and tissue distribution of hKChIP2, as well as its functional interaction with hKv4.3 after expression in Xenopus oocytes. Furthermore, we isolated a short splice variant of the hKChIP2 gene (hKCNIP2), which represents the major hKChIP2 transcript. Northern blot analyses revealed that hKChIP2 is expressed in the human heart and occurs in the adult atria and ventricles but not in the fetal heart. Upon coexpression with hKv4.3 both hKChIP2 isoforms increased the current amplitude, slowed the inactivation and increased the recovery from inactivation of hKv4.3 currents. For the first time we analyzed the influence of a KChIP protein on the voltage of half-maximal inactivation of Kv4 channels. We demonstrate that the hKChIP2 isoforms shifted the half-maximal inactivation to more positive potentials, but to a different extent. By elucidating the genomic structure, we provide important information for future analysis of the hKCNIP2 gene in candidate disorders. In the course of this work we mapped the hKCNIP2 gene to chromosome 10q24. CONCLUSIONS Heteromeric hKv4.3/hKChIP2 currents more closely resemble native epicardial I(to1), suggesting that hKChIP2 is a true beta-subunit of human cardiac I(to1). As a result hKChIP2 might play a role in cardiac diseases, where a contribution of I(to1) has been shown.

Frequencies of gap- and tight-junction mutations in Turkish families with autosomal-recessive non-syndromic hearing loss

Mutations in genes encoding gap‐ and tight‐junction proteins have been shown to cause distinct forms of hearing loss. We have now determined the GJB2[connexin 26 (Cx26)] mutation spectrum in 60 index patients from mostly large Turkish families with autosomal‐recessive inherited non‐syndromic sensorineural hearing loss (NSSHL). GJB2 mutations were found in 31.7% of the families, and the GJB2–35delG mutation accounted for 73.6% of all GJB2 mutations. The carrier frequency of GJB2–35delG in the normal Turkish population was found to be 1.17% (five in 429). In addition to the described W24X, 233delC, 120delE and R127H mutations, we also identified a novel mutation, Q80R, in the GJB2 gene. Interestingly, the Q80R allele was inherited on the same haplotype as V27I and E114G polymorphisms. As little is known about the mutation frequencies of most other recently identified gap‐ and tight‐junction genes as a cause for hearing loss, we further screened our patients for mutations in GJB3 (Cx31), GJA1 (Cx43), ΔGJB6–D13S1830 (Cx30) and the gene encoding the tight‐junction protein, claudin 14 (CLDN14). Several novel polymorphisms, but no disease‐associated mutations, were identified in the CLND14 and GJA1 genes, and we were unable to detect the ΔGJB6–D13S1830 deletion. A novel putative mutation, P223T, was found in the GJB3 gene in heterozygous form in a family with two affected children. Our data shows that the frequency of GJB2 mutations in Turkish patients with autosomal‐recessive NSSHL and the carrier rate of the GJB2–35delG mutation in the Turkish population, is much lower than described for other Mediterranean countries. Furthermore, mutations in other gap‐ and tight‐junction proteins are not a frequent cause of hearing loss in Turkey.

ALX4 dysfunction disrupts craniofacial and epidermal development

Genetic control of craniofacial morphogenesis requires a complex interaction of numerous genes encoding factors essential for patterning and differentiation. We present two Turkish families with a new autosomal recessive frontofacial dysostosis syndrome characterized by total alopecia, a large skull defect, coronal craniosynostosis, hypertelorism, severely depressed nasal bridge and ridge, bifid nasal tip, hypogonadism, callosal body agenesis and mental retardation. Using homozygosity mapping, we mapped the entity to chromosome 11p11.2-q12.3 and subsequently identified a homozygous c.793C-->T nonsense mutation in the human ortholog of the mouse aristaless-like homeobox 4 (ALX4) gene. This mutation is predicted to result in a premature stop codon (p.R265X) of ALX4 truncating 146 amino acids of the protein including a part of the highly conserved homeodomain and the C-terminal paired tail domain. Although the RNA is stable and not degraded by nonsense-mediated RNA decay, the mutant protein is likely to be non-functional. In a skin biopsy of an affected individual, we observed a hypomorphic interfollicular epidermis with reduced suprabasal layers associated with impaired interfollicular epidermal differentiation. Hair follicle-like structures were present but showed altered differentiation. Our data indicate that ALX4 plays a critical role both in craniofacial development as in skin and hair follicle development in human.

The novel R75Q mutation in the GJB2 gene causes autosomal dominant hearing loss and palmoplantar keratoderma in a Turkish family.

Dominant mutations in the GJB2 gene encoding connexin 26 (Cx26) can cause non‐syndromic hearing impairment alone or in association with palmoplantar keratoderma (PPK). We have identified the novel G224A (R75Q) mutation in the GJB2 gene in a four‐generation family from Turkey with autosomal dominant inherited hearing impairment and PPK. The age of onset and progression of hearing loss were found to be variable among affected family members, but all of them had more severe impairment at higher hearing frequencies. Interestingly, the novel R75Q mutation affects the same amino acid residue as described recently in a small family (R75W) with profound prelingual hearing loss and PPK. However, the R75W mutation was also observed in a control individual without PPK and unknown hearing status. Therefore, the nature of the R75W mutation remains ambiguous. Our molecular findings provide further evidence for the importance of the conserved R75 in Cx26 for the physiological function of the inner ear and the epidermal cells of the skin.

Homozygous and heterozygous inheritance of PAX3 mutations causes different types of Waardenburg syndrome.

Type I Waardenburg syndrome (WS‐I) is an auditory‐pigmentary syndrome caused by heterozygous loss of function mutations in the PAX3 gene. Klein–Waardenburg syndrome (WS‐III) is a very rare condition and represents an extreme presentation of WS‐I, additionally associated with musculoskeletal abnormalities. We present an 18‐months old Turkish child with typical Klein–Waardenburg syndrome (WS) including dystopia canthorum, partial albinism, and upper‐limb defects. The child was born to a consanguineous couple and both parents had WS‐I. We screened the entire coding region of the PAX3 gene for mutations and identified a novel missense mutation, Y90H, within the paired box domain of PAX3. Both parents were heterozygous for the mutation and the proposita was homozygous. This is the third report of a homozygous PAX3 mutation causing the WS‐III phenotype. Molecular analysis of four additional Turkish families with variable clinical expression of WS‐I identified two missense mutations, one splice‐site mutation, and one small insertion in the PAX3 gene.

Mutation analysis of TMC1 identifies four new mutations and suggests an additional deafness gene at loci DFNA36 and DFNB7/11

Hearing loss is the most frequent sensorineural disorder affecting 1 in 1000 newborns. In more than half of these babies, the hearing loss is inherited. Hereditary hearing loss is a very heterogeneous trait with about 100 gene localizations and 44 gene identifications for non‐syndromic hearing loss. Transmembrane channel‐like gene 1 (TMC1) has been identified as the disease‐causing gene for autosomal dominant and autosomal recessive non‐syndromic hearing loss at the DFNA36 and DFNB7/11 loci, respectively. To date, 2 dominant and 18 recessive TMC1 mutations have been reported as the cause of hearing loss in 34 families. In this report, we describe linkage to DFNA36 and DFNB7/11 in 1 family with dominant and 10 families with recessive non‐syndromic sensorineural hearing loss. In addition, mutation analysis of TMC1 was performed in 51 familial Turkish patients with autosomal recessive hearing loss. TMC1 mutations were identified in seven of the families segregating recessive hearing loss. The pathogenic variants we found included two known mutations, c.100C>T and c.1165C>T, and four new mutations, c.2350C>T, c.776+1G>A, c.767delT and c.1166G>A. The absence of TMC1 mutations in the remaining six linked families implies the presence of mutations outside the coding region of this gene or alternatively at least one additional deafness‐causing gene in this region. The analysis of copy number variations in TMC1 as well as DNA sequencing of 15 additional candidate genes did not reveal any proven pathogenic changes, leaving both hypotheses open.

CADASIL syndrome in a large Turkish kindred caused by the R90C mutation in the Notch3 receptor

Mutations in the Notch3 gene are the cause of the autosomal dominant disorder CADASIL (cerebral autosomal dominant arteriopathy with subcortical infarcts and leukoencephalopathy). The CADASIL is an adult‐onset neurologic disorder (average age of onset is 45 years) characterized by recurrent strokes and dementia. Clinical features combined with cerebral magnetic resonance imaging (MRI), showing a diffuse leukoencephalopathy with subcortical infarcts in the basal ganglia and white matter, are highly contributive to the diagnosis. We present a Turkish family with CADASIL, in which 12 individuals in four generations were affected showing the typical clinical features of recurrent strokes. Mutation analysis of the Notch3 receptor gene identified the recently described R90C mutation in the N‐terminal part of the gene in affected individuals. Interestingly, migraine without aura was found as an initial symptom of the disease in two young mutation carriers (22 and 25 years, respectively), who did not show any additional clinical features or any MRI abnormalities. This indicates that migraine without aura in the absence of MRI abnormalities may represent an early initial symptom of CADASIL, which is difficult to diagnose in the absence of molecular diagnosis. Therefore, the used molecular screening method for Notch3 mutations provides a rapid and accurate diagnostic tool in addition to the standard diagnostic procedures.

MYO15A (DFNB3) mutations in Turkish hearing loss families and functional modeling of a novel motor domain mutation.

Myosin XVA is an unconventional myosin which has been implicated in autosomal recessive nonsyndromic hearing impairment (ARNSHI) in humans. In Myo15A mouse models, vestibular dysfunction accompanies the autosomal recessive hearing loss. Genomewide homozygosity mapping and subsequent fine mapping in two Turkish families with ARNSHI revealed significant linkage to a critical interval harboring a known deafness gene MYO15A on chromosome 17p13.1‐17q11.2. Subsequent sequencing of the MYO15A gene led to the identification of a novel missense mutation, c.5492G → T (p.Gly1831Val) and a novel splice site mutation, c.8968 − 1G → C. These mutations were not detected in additional 64 unrelated ARNSHI index patients and in 230 Turkish control chromosomes. Gly1831 is a conserved residue located in the motor domains of the different classes of myosins of different species. Molecular modeling of the motor head domain of the human myosin XVa protein suggests that the Gly1831Val mutation inhibits the powerstroke by reducing backbone flexibility and weakening the hydrophobic interactions necessary for signal transmission to the converter domain.