MID1 mutations in patients with X-linked Opitz G/BBB syndrome

Mutations in the MID1 gene are responsible for the X-linked form of Opitz G/BBB syndrome (OS), a disorder that affects the development of midline structures. OS is characterized by hypertelorism, hypospadias, laryngo-tracheo-esophageal (LTE) abnormalities, and additional midline defects. Cardiac, anal, and neurological defects are also present. The expressivity of OS is highly variable, even within the same family. We reviewed all the MID1 mutations reported so far, in both familial and sporadic cases. The mutations are scattered along the entire length of the gene and consist of missense and nonsense mutations, insertions and deletions, either in-frame or causing frameshifts, and deletions of either single exons or the entire MID1 coding region. The variety of described mutations and the lack of a strict genotype-phenotype correlation confirm the previous suggestion of the OS phenotype being caused by a loss-of-function mechanism. However, although a specific mutation cannot entirely account for the observed phenotype, we observed preferential association between some types of mutation and specific clinical manifestations, e.g., brain anatomical defects and truncating mutations. This may suggest that the pathogenetic mechanism underlying the OS phenotype is more complex and may vary among the affected organs.     

New mutations in MID1 provide support for loss of function as the cause of X-linked Opitz syndrome

Opitz syndrome (OS) is a genetically heterogeneous malformation disorder. Patients with OS may present with a variable array of malformations that are indicative of a disturbance of the primary midline developmental field. Mutations in the C-terminal half of MID1, an RBCC (RING, B-box and coiled-coil) protein, have recently been shown to underlie the X-linked form of OS. Here we show that the MID1 gene spans at least 400 kb, almost twice the distance originally reported and has a minimum of six mRNA isoforms as a result of the alternative use of 5' untranslated exons. In addition, our detailed mutational analysis of MID1 in a cohort of 15 patients with OS has resulted in the identification of seven novel mutations, two of which disrupt the N-terminus of the protein. The most severe of these (E115X) is predicted to truncate the protein before the B-box motifs. In a separate patient, a missense change (L626P) was found that also represents the most C-terminal alteration reported to date. As noted with other C-terminal mutations, GFP fusion constructs demonstrated that the L626P mutant formed cytoplasmic clumps in contrast to the microtubular distribution seen with the wild-type sequence. Notably, however, both N-terminal mutants showed no evidence of cytoplasmic aggregation, inferring that this feature is not pathognomonic for X-linked OS. These new data and the finding of linkage to MID1 in the absence of a demonstrable open reading frame mutation in a further family support the conclusion that X-linked OS results from loss of function of MID1.     

MID1 mutation screening in a large cohort of Opitz G/BBB syndrome patients: twenty-nine novel mutations identified

Opitz G/BBB Syndrome (OS) is a multiple congenital anomaly disorder characterized by defects along the body midline. The disease is characterized by variable expressivity of signs that include hypertelorism, cleft lip and/or palate, laryngo-tracheo-esophageal abnormalities, cardiac defects, and hypospadias. OS patients also present with mental retardation and brain anatomical abnormalities. An autosomal dominant form mapping to chromosome 22 and an X-linked form of OS are known. The gene responsible for the X-linked form of OS, MID1, codes for a member of the Tripartite Motif family of E3 ubiquitin ligases. Here we report 29 novel mutations in 29 unrelated patients of a cohort of 140 male OS cases. These mutations are found in both familial and sporadic cases. They are scattered along the entire length of the gene and are represented by missense and nonsense mutations, insertions and deletions causing frame shift mutations, and deletion of either single exons or the entire gene. The variety of the mutations found confirms that loss-of-function is the mechanism underlying the OS phenotype. Moreover, the low percentage of MID1-mutated OS patients, 47% of the familial and 13% of the sporadic cases, suggests a wider genetic heterogeneity underlying the OS phenotype.     

Mild phenotypes in a series of patients with Opitz GBBB syndrome with MID1 mutations

Opitz syndrome (OS; MIM 145410 and MIM 300000) is a congenital midline malformation syndrome characterized by hypertelorism, hypospadias, cleft lip/palate, laryngotracheoesophageal (LTE) abnormalities, imperforate anus, developmental delay, and cardiac defects. The X-linked form (XLOS) is caused by mutations in the MID1 gene, which encodes a microtubule-associated RBCC protein. In this study, phenotypic manifestations of patients with and without MID1 mutations were compared to determine genotype-phenotype correlations. We detected 10 novel mutations, 5 in familial cases, 2 in sporadic cases, and 3 in families for whom it was not clear if they were familial or sporadic. The genotype and phenotype was compared for these 10 families, clinically diagnosed OS patients found not to have MID1 mutations, and 4 families in whom we have previously reported MID1 mutations. This combined data set includes clinical and mutation data on 70 patients. The XLOS patients with MID1 mutations were less severely affected than patients with MID1 mutations reported in previous studies, particularly in functionally significant neurologic, LTE, anal, and cardiac abnormalities. Minor anomalies were more prevalent in patients with MID1 mutations compared to those without mutations in this study. Female MID1 mutation carriers had milder phenotypes compared to male MID1 mutation carriers, with the most common manifestation being hypertelorism in both sexes. Most of the anomalies found in the patients of the present study do not correlate with the MID1 mutation type, with the possible exception of LTE malformations. This study demonstrates the wide spectrum of severity and manifestations of OS. It also shows that XLOS patients with MID1 mutations may be less severely affected than indicated in prior reports.     

A structure-function study of MID1 mutations associated with a mild Opitz phenotype

The X-linked form of Opitz syndrome (OS) affects midline structures and produces a characteristic, but heterogeneous, phenotype that may include severe mental retardation, hypertelorism, broad nasal bridge, widow's peak, cleft lip/cleft palate, congenital heart disease, laryngotracheal defects, and hypospadias. The MID1 gene was implicated in OS by linkage to Xp22. It encodes a 667 amino acid protein that contains a RING finger motif, two B-box zinc fingers, a coiled-coil, a fibronectin type III (FNIII) domain, and a B30.2 domain. Several mutations in MID1 are associated with severe OS. Here, we describe an intelligent male with a milder phenotype characterized by hypertelorism, broad nasal bridge, widow's peak, mild hypospadias, pectus excavatum, and a surgically corrected tracheo-esophageal fistula. He has an above average intelligence and no cleft lip/palate or heart disease. We identified a novel mutation in MID1 (P441L) which is in exon 8 and functionally associated with the FNIII domain. While OS phenotypes have been attributed to mutations in the C-terminal part of MID1, little is currently known about the structure-function relationships of MID1 mutations, and how they affect phenotype. We find from a literature review that missense mutations within the FNIII domain of MID1 are associated with a milder presentation of OS than missense mutations elsewhere in MID1. All truncating mutations (frameshift, insertions/deletions) lead to severe OS. We used homology analysis of the MID1 FNIII domain to investigate structure-function changes caused by our missense mutation. This and other missense mutations probably cause disruption of protein-protein interactions, either within MID1 or between MID1 and other proteins. We correlate these protein structure-function findings to the absence of CNS or palatal changes and conclude that the FNIII domain of the MID1 protein may be involved in midline differentiation after neural tube and palatal structures are completed.     

X-linked recessive chondrodysplasia punctata: spectrum of arylsulfatase E gene mutations and expanded clinical variability

Partial trisomy of the long arm of chromosome 10 is a well-defined but rare syndrome. Clinical features of this chromosomopathy are a distinctive dysmorphic appearance, developmental delay, growth retardation, and in some cases, abnormalities of the extremities and renal, cardiac and ocular anomalies. This report describes a neonate with symmetric growth retardation and multiple dysmorphic features, in whom chromosomal analysis revealed a partial trisomy of chromosome 10q with a monosomy of the 13q34 region. The phenotype shares many common features with previously published cases. In addition to the typical features, our case also shows renal hypoplasia with early renal insufficiency and some genital anomalies.     

Clinical and molecular studies of patients with characteristics of Opitz G/BBB syndrome shows a novel MID1 mutation

Opitz G/BBB syndrome is characterized by midline abnormalities such as hypertelorism, cleft palate, and hypospadias. This syndrome is heterogeneous with an X-linked recessive form caused by mutations in the MID1 gene at band Xp22.3. However, mutations in MID1 have only been identified in 47% of familial cases of X-linked Opitz G/BBB syndrome, and 13% of sporadic cases. We performed a phenotype-genotype analysis of a group of nine new patients with clinical characteristics commonly seen in Opitz G/BBB syndrome, and of previously reported patients. We identified a novel mutation in exon 9 of the MID1 gene, c.1941insTGAGTCATCATCC, leading to a premature termination codon at amino acid 514 in a patient with hypertelorism, apparently low-set ears, a short philtrum, bilateral cleft of lip and palate and hypospadias. This mutation affects the PRY domain of the C-terminus of the MID1 protein.     

WASP gene mutations in Wiskott-Aldrich syndrome and X-linked thrombocytopenia

The WASP gene has been recently cloned from Xp11.23 and shownto be mutated in three patients with the Wiskott-Aldrich syndrome(WAS). We have developed a screening protocol for identifyingWASP gene alterations in genomic DNA and have identified a spectrumof novel mutations In 12 additional unrelated families. Thesemissense, nonsense and frameshift mutations involve eight ofthe 12 exons of the gene. Two mutations creating premature terminationcodons were associated with lack of detectable mRNA on Northernblots. Four amino acid substitutions, Leu27Phe, Thr48lle, Val75Metand Arg477Lys, were found In patients with congenital thrombocytopeniaand no clinically evident immune defect indicating that theWASP gene is the site for mutations in X-linked thrombocytopeniaas well as in WAS. A T-cell line from a WAS patient containedtwo independent DNA alterations, a constitutional frameshiftmutation, also present in peripheral blood leukocytes from thepatient, and a compensatory splice site mutation unique to thecell line. The distribution of eight missense mutations providesvaluable information on amino acids which are essential fornormal protein function, and suggests that sites in the firsttwo exons are hot-spots for mutation.     

Expanding the molecular basis and phenotypic spectrum of X-linked Joubert syndrome associated with OFD1 mutations

Using a combination of linkage mapping and massively parallel sequencing of the X-chromosome exome, we identified an 18-bp deletion in exon 8 of the oral-facial-digital syndrome type 1 (OFD1) gene in a family with X-linked Joubert syndrome (JBTS10). The deletion results in an in-frame deletion of six amino acids. New features not noted in the two previously reported cases of X-linked Joubert syndrome include the presence of polycystic kidney disease, polymicrogyria and hydrocephalus. Our study further underlines the power of genetic mapping combined with massively parallel sequencing as a powerful tool for novel disease gene and mutation discovery.     

X-linked Opitz G/BBB syndrome: identification of a novel mutation and prenatal diagnosis in a Korean family

X-linked Opitz G/BBB syndrome (XLOS; MIM 300000) is a rare multiple congenital anomaly disorder that is characterized by facial anomalies, laryngeal/tracheal/esophageal defects and genitourinary abnormalities. XLOS is caused by mutations in the MID1 gene which encodes a microtubule-associated RING-Bbox-Coiled-coil (RBCC) protein. We recently found a four-year Korean male patient who was suspected of having XLOS. Mutation analysis of the MID1 gene in the patient and his mother demonstrated that the patient had a novel insertion mutation (c.1798_1799-insC), and his mother was a heterozygous carrier of the mutation. After identification of the causative mutation in this family, prenatal diagnosis of two consecutive fetuses were successfully undertaken. This is the first report on a genetically confirmed case of XLOS in Korea.     

马凡综合征两种新的原纤维蛋白-1基因突变

目的对9例马凡综合征(Marfansyndrome,MFS)患者的原纤维蛋白-1(fibrillin-1,FBN1)基因进行突变筛查,以发现新的FBN1基因突变。方法应用变性高效液相色谱法对MFS患者FBN1基因65个外显子中的35个进行突变筛查,对变性高效液相色谱图形异常的PCR扩增片段用DNA测序鉴定突变位置及性质,并用等位基因特异性PCR以及限制性片段长度多态性分析等方法进一步证实突变。结果在两例MFS患者中发现两种新的FBN1基因突变。其中一种为第34外显子4307～4308位4个碱基TCGT的插入突变(4307insTCGT),另一种为第43外显子5309位的点突变5309G>A。结论FBN1基因移码突变(4307insTCGT)与点突变(5309G>A)分别是这两例MFS患者的发病原因。     

A MID1 gene mutation in a patient with Opitz G/BBB syndrome that altered the 3D structure of SPRY domain

Mutations in the MID1 gene result in X-linked Opitz G/BBB syndrome (OS), a disorder that affects development of midline structures and comprises hypertelorism, cleft lip/palate, hypospadias, and laryngo-tracheo-esophageal abnormalities, and, at times, neurological, anal, and cardiac defects. MID1 gene abnormalities include missense, nonsense, and splicing mutations, small insertions, small deletions, and complex rearrangements. Here, we present a patient with Opitz G/BBB syndrome and a unique MID1 gene point mutation c.1703T相似文献   

Six novel mutations in the emerin gene causing X-linked Emery-Dreifuss muscular dystrophy

Mutations in the emerin gene, also referred to as the STA- or EMD-gene, have been found to be the cause of X-linked Emery-Dreifuss muscular dystrophy (EMD). For the present study an optimized set of primers was designed to amplify and sequence each of the six emerin gene exons, including the intron/exon boundaries. All emerin gene exons of 30 unrelated EMD patients have been screened by heteroduplex analysis. Aberrant patterns of single exons were found in seven patients. Direct sequencing of the respective exons revealed six novel mutations distributed in the promotor region and exons 3–6 (Δ nt - 19 to -40; Δ AG nt 620–621; ins A nt 895; Δ AT nt 908–909; C→A nt 1420; ins TA nt 1570). By this study, the first mutations in the promotor region and in exon 5 have been identified. Each of the 25 mutations that have been described so far, including those from the present study, abolishes the synthesis of functional emerin. The mutations were submitted to the EMD Mutation database ( http://www.path.cam.ac.uk/emd ). Hum Mutat 9:526–530, 1997. © 1997 Wiley-Liss, Inc.     

X-连锁的肾上腺脑白质营养不良患者ABCD1基因突变分析

目的　分析我国 X-连锁的肾上腺脑白质营养不良 (X- linked adrenoleukodystrophy,X- AL D)患者 ABCD1基因突变。方法　提取 2 5例 AL D患者外周血基因组 DNA,用 PCR扩增和 DNA直接测序的方法 ,分析 AL D患者 ABCD1基因突变。结果　 2 5例患者中发现 18例有 17种不同的 ABCD1基因突变 ,突变存在于除 4、9和 10以外的每一个外显子 ,错义突变为最常见的类型。10例患者有 10种不同的错义突变 ,其中4种错义突变是国际首次报道 ;3例患者有 3种不同的无义突变 ;1例患者有碱基缺失导致移码突变 ;1例患者有剪切部位的碱基缺失 ;2例患者同时具有两个相同的同义突变。结论　我国 AL D患者大部分存在ABCD1基因突变 ,无突变热点。不同个体常有不同的突变点 ,检测到的突变率约为 70 %。突变类型和表型之间无特殊的相关关系。     

CHARGE syndrome: the phenotypic spectrum of mutations in the CHD7 gene

Background

CHARGE syndrome is a non‐random clustering of congenital anomalies including coloboma, heart defects, choanal atresia, retarded growth and development, genital hypoplasia, ear anomalies, and deafness. A consistent feature in CHARGE syndrome is semicircular canal hypoplasia resulting in vestibular areflexia. Other commonly associated congenital anomalies are facial nerve palsy, cleft lip/palate, and tracheo‐oesophageal fistula. Specific behavioural problems, including autistic‐like behaviour, have been described. The CHD7 gene on chromosome 8q12.1 was recently discovered as a major gene involved in the aetiology of this syndrome.

Methods

The coding regions of CHD7 were screened for mutations in 107 index patients with clinical features suggestive of CHARGE syndrome. Clinical data of the mutation positive patients were sampled to study the phenotypic spectrum of mutations in the CHD7 gene.

Results

Mutations were identified in 69 patients. Here we describe the clinical features of 47 of these patients, including two sib pairs. Most mutations were unique and were scattered throughout the gene. All patients but one fulfilled the current diagnostic criteria for CHARGE syndrome. No genotype‐phenotype correlations were apparent in this cohort, which is best demonstrated by the differences in clinical presentation in sib pairs with identical mutations. Somatic mosaicism was detected in the unaffected mother of a sib pair, supporting the existence of germline mosaicism.

Conclusions

CHD7 mutations account for the majority of the cases with CHARGE syndrome, with a broad clinical variability and without an obvious genotype‐phenotype correlation. In one case evidence for germline mosaicism was provided.     

Incidence and clinical features of X-linked Cornelia de Lange syndrome due to SMC1L1 mutations

Cornelia de Lange syndrome (CdLS) is a multisystem developmental disorder characterized by facial dysmorphism, growth and mental retardation, microcephaly, and various malformations. Heterozygous mutations in the NIPBL gene have been detected in approximately 45% of affected individuals. Recently, a second CdLS gene, mapping to the X chromosome, has been identified: SMC1L1 (structural maintenance of chromosomes 1-like 1; or SMC1A). In order to estimate the incidence and refine the clinical presentation of X-linked CdLS, we have screened a series of 11 CdLS boys carrying no NIPBL anomaly. We have identified two novel de novo SMC1L1 missense mutations (c.587G>A [p.Arg196His] and c.3254A>G [p.Tyr1085Cys]). Our results confirm that SMC1L1 mutations cause CdLS and support the view that SMC1L1 accounts for a significant fraction of boys with unexplained CdLS. Furthermore, we suggest that SMC1L1 mutations have milder effects than NIPBL mutations with respect to pre- and postnatal growth retardation and associated malformations. If confirmed, these data may have important implications for directing mutation screening in CdLS.