Waardenburg syndrome type II in a Chinese pedigree caused by frameshift mutation in the SOX10 gene

Waardenburg syndrome (WS) is a congenital hereditary disease, attributed to the most common symptoms of sensorineural deafness and iris hypopigmentation. It is also known as the hearing-pigmentation deficient syndrome. Mutations on SOXl0 gene often lead to congenital deafness and has been shown to play an important role in the pathogenesis of WS. We investigated one family of five members, with four patients exhibiting the classic form of WS2, whose DNA samples were analyzed by the technique of Whole-exome sequencing (WES). From analysis of WES data, we found that both the mother and all three children in the family have a heterozygous mutation on the Sex Determining Region Y - Box 10 (SOX10) gene. The mutation was c.298_300delinsGG in exon 2 of SOX10 ({"type":"entrez-nucleotide","attrs":{"text":"NM_006941","term_id":"1732746331"}}NM_006941), which leads to a frameshift of nine nucleotides, hence the amino acids (p. S100Rfs*9) are altered and the protein translation may be terminated prematurely. Further flow cytometry confirmed significant down-regulation of SOX10 protein, which indicated the SOX10 gene mutation was responsible for the pathogenesis of WS2 patients. In addition, we speculated that some other mutated genes might be related to disease phenotype in this family, which might also participate in promoting the progression of WS2.     

Novel mutations in the SOX10 gene in the first two Chinese cases of type IV Waardenburg syndrome

Objective: We analyzed the clinical features and family-related gene mutations for the first two Chinese cases of type IV Waardenburg syndrome (WS4). Methods: Two families were analyzed in this study. The analysis included a medical history, clinical analysis, a hearing test and a physical examination. In addition, the EDNRB, EDN3 and SOX10 genes were sequenced in order to identify the pathogenic mutation responsible for the WS4 observed in these patients. Results: The two WS4 cases presented with high phenotypic variability. Two novel heterozygous mutations (c.254G>A and c.698-2A>T) in the SOX10 gene were detected. The mutations identified in the patients were not found in unaffected family members or in 200 unrelated control subjects. Conclusions: This is the first report of WS4 in Chinese patients. In addition, two novel mutations in SOX10 gene have been identified.     

Neurological phenotype in Waardenburg syndrome type 4 correlates with novel SOX10 truncating mutations and expression in developing brain

Waardenburg syndrome type 4 (WS4), also called Shah-Waardenburg syndrome, is a rare neurocristopathy that results from the absence of melanocytes and intrinsic ganglion cells of the terminal hindgut. WS4 is inherited as an autosomal recessive trait attributable to EDN3 or EDNRB mutations. It is inherited as an autosomal dominant condition when SOX10 mutations are involved. We report on three unrelated WS4 patients with growth retardation and an as-yet-unreported neurological phenotype with impairment of both the central and autonomous nervous systems and occasionally neonatal hypotonia and arthrogryposis. Each of the three patients was heterozygous for a SOX10 truncating mutation (Y313X in two patients and S251X [corrected] in one patient). The extended spectrum of the WS4 phenotype is relevant to the brain expression of SOX10 during human embryonic and fetal development. Indeed, the expression of SOX10 in human embryo was not restricted to neural-crest-derived cells but also involved fetal brain cells, most likely of glial origin. These data emphasize the important role of SOX10 in early development of both neural-crest-derived tissues, namely melanocytes, autonomic and enteric nervous systems, and glial cells of the central nervous system.     

Screening of MITF and SOX10 Regulatory Regions in Waardenburg Syndrome Type 2

Waardenburg syndrome (WS) is a rare auditory-pigmentary disorder that exhibits varying combinations of sensorineural hearing loss and pigmentation defects. Four subtypes are clinically defined based on the presence or absence of additional symptoms. WS type 2 (WS2) can result from mutations within the MITF or SOX10 genes; however, 70% of WS2 cases remain unexplained at the molecular level, suggesting that other genes might be involved and/or that mutations within the known genes escaped previous screenings. The recent identification of a deletion encompassing three of the SOX10 regulatory elements in a patient presenting with another WS subtype, WS4, defined by its association with Hirschsprung disease, led us to search for deletions and point mutations within the MITF and SOX10 regulatory elements in 28 yet unexplained WS2 cases. Two nucleotide variations were identified: one in close proximity to the MITF distal enhancer (MDE) and one within the U1 SOX10 enhancer. Functional analyses argued against a pathogenic effect of these variations, suggesting that mutations within regulatory elements of WS genes are not a major cause of this neurocristopathy.     

Phenotypic similarities in pigs with SOX10c.321dupC and SOX10c.325A>T mutations implied the correlation of SOX10 haploinsufficiency with Waardenburg syndrome

SOX10 is a causative gene of Waardenburg syndrome (WS) that is a rare genetic disorder characterized by hearing loss and pigment disturbance. More than 100 mutations of SOX10 have been found in patients with Type 2 WS (WS2), Type 4 WS (WS4), and more complex syndromes. However, no mutation hotspot has been detected in SOX10, and most cases are sporadic, making it difficult to establish a correlation between the high phenotypic and genetic variability. In this study, a duplication of the 321th cytosine (c.321dupC) was introduced into SOX10 in pigs, which induced premature termination of the translation of SOX10 (p.K108QfsX45). The premature stop codon in Exon 3 triggered the degradation of mutant mRNA through nonsense-mediated mRNA decay. However, SOX10^c.321dupC induced a highly similar phenotype of WS2 with heterogeneous inner ear malformation compared with its adjacent missense mutation SOX10^c.325A>T. In addition, a site-saturation mutation analysis of the SOX10 N-terminal nuclear localization signal (n-NLS), where these two mutations located, revealed the correlation between SOX10 haploinsufficiency and WS by an in vitro reporter assay. The analysis combining the in vitro assay with clinical cases may provide a clue to clinical diagnoses.     

Deletions and a translocation interrupt a cloned gene at the neurofibromatosis type 1 locus.

Three new neurofibromatosis type 1 (NF1) mutations have been detected and characterized. Pulsed-field gel and Southern blot analyses reveal the mutations to be deletions of 190, 40, and 11 kb of DNA. The 11 kb deletion does not contain any of the previously characterized genes that lie between two NF1 translocation breakpoints, but it does include a portion of a rodent/human conserved DNA sequence previously shown to span one of the translocation breakpoints. By screening cDNA libraries with the conserved sequence, we identified a number of cDNA clones from the translocation breakpoint region (TBR), one of which hybridizes to an approximately 11 kb mRNA. The TBR gene crosses at least one of the chromosome 17 translocation breakpoints found in NF1 patients. Furthermore, the newly characterized NF1 deletions remove internal exons of the TBR gene. Although these mutations might act by compromising regulatory elements affecting some other gene, these findings strongly suggest that the TBR gene is the NF1 gene.     

Probable loose linkage between the ABO locus and Waardenburg syndrome type I.

The possibility of linkage was tested in 3 large kindreds with Waardenburg syndrome type I against the ABO locus. Loose linkage is probably present; the recombination fraction in males, females, and both sexes combined seems to be approximately theta' equals 0.175, theta equals 0.255, and theta', theta equals 0.20, respectively. There are still more informative matings to be studied in those pedigrees, as well as the inminent possibility of determining the phase status in several of them, for the ABO locus and a few other loci.     

Waardenburg综合征Ⅱ型患者MITF基因突变分析

Waardenburg综合征(WS)是临床上常见的常染色体显性遗传性耳聋综合征, MITF基因突变与部分Waardenburg 综合征Ⅱ型(WS2)病例的发病有关。MITF属于碱性螺旋-环-螺旋亮氨酸拉链转录因子家族, 能调节酪氨酸酶基因, 参与黑色素细胞的分化。文章报道了1个携带MITF基因点突变的3代Waardenburg综合征Ⅱ型中国家系。先证者表现为先天性重度感音神经性聋、虹膜异色、面部雀斑; 其他家系成员除一名仅表现为先天性耳聋外, 均表现为颜面、上肢雀斑和/或早白发。患者可检测到c.639delA杂合突变, 该突变在MITF基因第7外显子上产生了终止密码子(p.I220X), 突变产生的截短的MITF蛋白没有DNA结合活性。该突变是WS2病例中第3个位于MITF第7外显子的突变, 尚未见报道。该突变与已报道的位于第7外显子其他两个突变仅相差1个碱基, 氨基酸改变十分相似, 但在表型上有显著差别, 提示遗传背景对WS临床表型有重要影响。     

Novel mutations of PAX3, MITF, and SOX10 genes in Chinese patients with type I or type II Waardenburg syndrome

Waardenburg syndrome (WS) is a rare disorder characterized by distinctive facial features, pigment disturbances, and sensorineural deafness. There are four WS subtypes. WS1 is mostly caused by PAX3 mutations, while MITF, SNAI2, and SOX10 mutations are associated with WS2. More than 100 different disease-causing mutations have been reported in many ethnic groups, but the data from Chinese patients with WS remains poor. Herein we report 18 patients from 15 Chinese WS families, in which five cases were diagnosed as WS1 and the remaining as WS2. Clinical evaluation revealed intense phenotypic variability in Chinese WS patients. Heterochromia iridis and sensorineural hearing loss were the most frequent features (100% and 88.9%, respectively) of the two subtypes. Many brown freckles on normal skin could be a special subtype of cutaneous pigment disturbances in Chinese WS patients. PAX3, MITF, SNAI2, and SOX10 genes mutations were screened for in all the patients. A total of nine mutations in 11 families were identified and seven of them were novel. The SOX10 mutations in WS2 were first discovered in the Chinese population, with an estimated frequency similar to that of MITF mutations, implying SOX10 is an important pathogenic gene in Chinese WS2 cases and should be considered for first-step analysis in WS2, as well as MITF.     

Characterization and mapping of the human SOX4 gene

The SOX genes comprise a large family related by homology to the HMG-box region of the testis-determining gene SRY. We have cloned and sequenced the human SOX4 gene. The open reading frame encodes a 474 amino acid protein, which includes an HMG-box. The non-box sequence is particularly rich in serine residues and has several polyglycine and polyalanine stretches. With somatic cell hybrids, human SOX4 has been mapped to Chromosome (Chr) 6p distal to the MHC region. There is no evidence for clustering of other members of the SOX1,-2, and-3 or SOX4 gene families around the SOX4 locus.     

Mutations in the KIAA0196 gene at the SPG8 locus cause hereditary spastic paraplegia

Hereditary spastic paraplegia (HSP) is a progressive upper-motor neurodegenerative disease. The eighth HSP locus, SPG8, is on chromosome 8p24.13. The three families previously linked to the SPG8 locus present with relatively severe, pure spastic paraplegia. We have identified three mutations in the KIAA0196 gene in six families that map to the SPG8 locus. One mutation, V626F, segregated in three large North American families with European ancestry and in one British family. An L619F mutation was found in a Brazilian family. The third mutation, N471D, was identified in a smaller family of European origin and lies in a spectrin domain. None of these mutations were identified in 500 control individuals. Both the L619 and V626 residues are strictly conserved across species and likely have a notable effect on the structure of the protein product strumpellin. Rescue studies with human mRNA injected in zebrafish treated with morpholino oligonucleotides to knock down the endogenous protein showed that mutations at these two residues impaired the normal function of the KIAA0196 gene. However, the function of the 1,159-aa strumpellin protein is relatively unknown. The identification and characterization of the KIAA0196 gene will enable further insight into the pathogenesis of HSP.     

Assignment of the locus for Waardenburg syndrome type I to human chromosome 2q37 and possible homology to the Splotch mouse.

We have demonstrated close linkage between the locus for the autosomal dominant Waardenburg syndrome type I and the placental alkaline phosphatase locus on chromosome 2q37. In five families the peak lod score was 4.76 at a recombination fraction of .023. In the mouse the Splotch locus maps to near the homologous position. Splotch mice have white spotting and hearing defects, suggesting that Splotch may be the murine homologue of Waardenburg syndrome type I.     

Identification and functional analysis of a novel mutation in the SOX10 gene associated with Waardenburg syndrome type IV

Waardenburg syndrome type IV (WS4) is a rare genetic disorder, characterized by auditory–pigmentary abnormalities and Hirschsprung disease. Mutations of the EDNRB gene, EDN3 gene, or SOX10 gene are responsible for WS4. In the present study, we reported a case of a Chinese patient with clinical features of WS4. In addition, the three genes mentioned above were sequenced in order to identify whether mutations are responsible for the case. We revealed a novel nonsense mutation, c.1063C>T (p.Q355*), in the last coding exon of SOX10. The same mutation was not found in three unaffected family members or 100 unrelated controls. Then, the function and mechanism of the mutation were investigated in vitro. We found both wild-type (WT) and mutant SOX10 p.Q355* were detected at the expected size and their expression levels are equivalent. The mutant protein also localized in the nucleus and retained the DNA-binding activity as WT counterpart; however, it lost its transactivation capability on the MITF promoter and acted as a dominant-negative repressor impairing function of the WT SOX10.     

Mutations in the paired domain of the human PAX3 gene cause Klein-Waardenburg syndrome (WS-III) as well as Waardenburg syndrome type I (WS-I).

Waardenburg syndrome type I (WS-I) is an autosomal dominant disorder characterized by sensorineural hearing loss, dystopia canthorum, pigmentary disturbances, and other developmental defects. Klein-Waardenburg syndrome (WS-III) is a disorder with many of the same characteristics as WS-I and includes musculoskeletal abnormalities. We have recently reported the identification and characterization of one of the first gene defects, in the human PAX3 gene, which causes WS-I. PAX3 is a DNA-binding protein that contains a structural motif known as the paired domain and is believed to regulate the expression of other genes. In this report we describe two new mutations, in the human PAX3 gene, that are associated with WS. One mutation was found in a family with WS-I, while the other mutation was found in a family with WS-III. Both mutations were in the highly conserved paired domain of the human PAX3 gene and are similar to other mutations that cause WS. The results indicate that mutations in the PAX3 gene can cause both WS-I and WS-III.