Fraser syndrome and mouse blebbed phenotype caused by mutations in FRAS1/Fras1 encoding a putative extracellular matrix protein.

Fraser syndrome (OMIM 219000) is a multisystem malformation usually comprising cryptophthalmos, syndactyly and renal defects. Here we report autozygosity mapping and show that the locus FS1 at chromosome 4q21 is associated with Fraser syndrome, although the condition is genetically heterogeneous. Mutation analysis identified five frameshift mutations in FRAS1, which encodes one member of a family of novel proteins related to an extracellular matrix (ECM) blastocoelar protein found in sea urchin. The FRAS1 protein contains a series of N-terminal cysteine-rich repeat motifs previously implicated in BMP metabolism, suggesting that it has a role in both structure and signal propagation in the ECM. It has been speculated that Fraser syndrome is a human equivalent of the blebbed phenotype in the mouse, which has been associated with mutations in at least five loci including bl. As mapping data were consistent with homology of FRAS1 and bl, we screened DNA from bl/bl mice and identified a premature termination of mouse Fras1. Thus, the bl mouse is a model for Fraser syndrome in humans, a disorder caused by disrupted epithelial integrity in utero.

No evidence for submicroscopic 22qter deletions in patients with features suggestive for Angelman syndrome.

Patients with monosomy 22q13.3 --> qter have, in addition to (usually severe) developmental delay, hypotonia, severe expressive language delay leading to absence of speech, pervasive developmental abnormalities, and subtle facial anomalies. Thus far, it has been one of the more common submicroscopic telomere deletions seen in patients with mental retardation. Due to the phenotypic overlap between monosomy 22q13.3 and Angelman syndrome (AS), 44 patients with AS features but without one of the characteristic molecular 15q abnormalities were tested for 22qter deletions. In the study group, 31/44 (70%) were heterozygous for locus D22S163 with probe cMS607 (distance 0.125 Mb from telomere). The remaining 13/44 (30%) patients were heterozygous for one or more of four microsatellite markers centromeric from D22S163 in the 22qter region (distances 1.5-4.3 Mb from telomere). Based on the present study, there is no evidence that patients with an "Angelman-like" phenotype are more likely to have a 22qter deletion than other individuals with mental retardation.

Pseudodominant inheritance of Langer mesomelic dysplasia caused by a SHOX homeobox missense mutation.

We report the clinical and molecular analysis in a consanguineous family in which the skeletal dysplasias Léri-Weill dyschondrosteosis (LWD) and Langer mesomelic dysplasia (LMD) both segregate. A newborn male and his mother, both with Langer mesomelic dysplasia, are described. A homozygous SHOX homeobox point mutation, C517T, was identified by direct sequencing in the proband and his mother. The same mutation was present in the heterozygous state in the proband's father and in the maternal grandmother, both of whom had features of LWD. This C to T transition is predicted to cause an arginine to cysteine amino acid change in a highly conserved region of the recognition helix of the homeodomain, which may reduce the stability of the interaction between the SHOX protein and its target DNA. In addition, the mutation may disrupt a nuclear localization signal in SHOX. This is the first SHOX point mutation identified in a case of LMD, and the first case in which parent to child transmission of LMD has been described.

Type 1 Arnold-Chiari malformation and Noonan syndrome. A new diagnostic feature?

Noonan syndrome is a clinically and genetically heterogeneous genetic condition. Arnold-Chiari malformation has been previously reported in three cases of Noonan syndrome. We describe a fourth case with this association. We suggest that brain and cervical spine MRI should be performed if neurological symptoms are present.

Three craniosynostotic patients with tracheal sleeve.

The gene was analysed in three craniosynostotic patients with a tracheal sleeve and other abnormalities. Although the majority of mutations are found in either exons IIIa or IIIc, this was not found in this study. It may be that patients with a tracheal sleeve are genetically heterogeneous.

The appearance of the feet in Pfeiffer syndrome caused by FGFR1 P252R mutation.

Patients affected by Pfeiffer syndrome generally present with syndromic craniosynostosis and typical limb defects including broad thumbs, wide halluces with varus deformity, toe syndactyly and sometimes elbow ankylosis. This autosomal dominant condition can be caused by mutations in either fibroblast growth factor receptor gene type 1 or 2 (FGFR1 or FGFR2). We report four new affected families showing an FGFR1 P252R mutation and emphasize the characteristic malformations of the feet in this form of Pfeiffer syndrome. In one family this was the only abnormality.

Septo-optic dysplasia, subglottic stenosis and skeletal abnormalities: a case report.

We report a girl with septo-optic dysplasia in association with subglottic stenosis, sagittal craniosynostosis, osteoporosis and dental anomalies. It is uncommon for patients with septo-optic dysplasia to have multiple, extra-cranial malformations. A number of differential diagnoses were considered in this case, including Cole-Carpenter syndrome, Pfeiffer syndrome and osteoglophonic dwarfism. However, none can account for all the abnormalities seen. We therefore believe that this is a previously unreported, but highly distinctive, phenotype.

Complex chromosomal rearrangement and associated counseling issues in a family with Pelizaeus-Merzbacher disease.

We report cytogenetic and molecular findings in a family in which Pelizaeus-Merzbacher disease has arisen by a sub-microscopic duplication of the proteolipid protein (PLP1) gene involving the insertion of approximately 600 kb from Xq22 into Xq26.3. The duplication arose in an asymptomatic mother on a paternally derived X chromosome and was inherited by her son, the proband, who is affected with Pelizaeus-Merzbacher disease. The mother also carries a large interstitial deletion of approximately 70 Mb extending from Xq21.1 to Xq27.3, which is present in a mosaic form. In lymphocytes, the mother has no normal cells, having one population with three copies of the PLP1gene (one normal X and one duplication X chromosome) and the other population having only one copy of the PLP1 gene (one normal X and one deleted X chromosome). Her karyotype is 46,XX.ish dup (X) (Xpter --> Xq26.3::Xq22 --> Xq22::Xq26.3 --> Xqter)(PLP++)/46,X,del(X)(q21.1q27.3).ish del(X)(q21.1q27.3)(PLP-). Both ends of the deletion have been mapped by fluorescence in situ hybridization using selected DNA clones and neither involves the PLP1 gene or are in the vicinity of the duplication breakpoints. Prenatal diagnosis was carried out in a recent pregnancy and the complex counseling issues associated with these chromosomal rearrangements are discussed.

Different mutations in the NF1 gene are associated with Neurofibromatosis-Noonan syndrome (NFNS).

The association of the Noonan phenotype with neurofibromatosis type 1 (NF1) was first noted by Allanson et al. [Am J Med Genet 1985;21:457-462.] and 30 further cases have subsequently been reported. It has been suggested that this phenotype is more common than previously appreciated, as Colley et al. [Clin Genet 1996;49:59-64.] examined 94 sequentially identified patients with NF1 from their genetic register and found Noonan features in 12. A 3-bp deletion of exon 17 of the NF1 neurofibromin gene was described in one family by Carey et al. [Proc Greenwood Genet Center 1997;17:52-53]. However, it remains unclear whether Neurofibromatosis-Noonan syndrome (NFNS) represents a form of NF1 (with mutations in the NF1 neurofibromin gene) or a separate syndrome. We have used a new, rapid sequence analysis technique-comparative sequence analysis (CSA)-to examine the NF1 gene in six patients with NFNS. None of the six patients had the previously identified mutation, nor did we observe other mutations within this exon. However, two other mutations were found: in exon 25, a 3-bp deletion 4312 del GAA, and in exon 23-2, a 2-bp insertion 4095 ins TG. The PTPN11 gene, now known to cause over 50% of Noonan syndrome was also examined in four cases of NFNS, and no mutations were found. These results show that NFNS can in some cases result from different mutations in the NF1 gene and therefore represents a variant form of NF1.

Okihiro syndrome is caused by SALL4 mutations.

Okihiro syndrome refers to the association of forearm malformations with Duane syndrome of eye retraction. Based on the reported literature experience, clinical diagnosis of the syndrome can be elusive, owing to the variable presentation in families reported. Specifically, there is overlap of clinical features with other conditions, most notably Holt-Oram syndrome, a condition resulting from mutation of the TBX5 locus and Townes-Brocks syndrome, known to be caused by mutations in the SALL1 gene. Arising from our observation of several malformations in Okihiro syndrome patients which are also described in Townes-Brocks syndrome, we postulated that Okihiro syndrome might result from mutation of another member of the human SALL gene family. We have characterized the human SALL4 gene on chromosome 20q13.13-q13.2. Moreover, we have identified literature reports of forelimb malformations in patients with cytogenetically identifiable abnormalities of this region. We here present evidence in 5 of 8 affected families that mutation at this locus results in the Okihiro syndrome phenotype.

Molecular defect of RAPADILINO syndrome expands the phenotype spectrum of RECQL diseases.

The RECQL4 helicase gene is a member of the RECQL gene family, mutated in some Rothmund-Thomson syndrome (RTS) patients. Other members of this gene family are BLM mutated in Bloom syndrome, WRN mutated in Werner syndrome and RECQL and RECQL5. All polypeptides encoded by RECQL genes share a central region of seven helicase domains. The function of RECQL4 remains unknown, but based on the domain homology it possesses ATP-dependent DNA helicase activity such as BLM and WRN. Rothmund-Thomson, Bloom and Werner syndromes have overlapping clinical features, of which high predisposition to malignancies is the most remarkable feature. Here we report a fourth syndrome resulting in mutations in the RECQL genes. RAPADILINO syndrome is an autosomal recessive disorder characterized by short stature, radial ray defects and other malformations, as well as infantile diarrhoea, but not by a significant cancer risk. Four mutations in the RECQL4 gene were found in the Finnish patients, the most common mutation representing exon 7 in-frame deletion saving the helicase domain and showing dominant effect over other three nonsense mutations. The tissue expression of Recql4 in mouse well agrees with the tissue symptoms of RAPADILINO. The skeletal malformations in RAPADILINO and RTS patients as well as the high osteosarcoma risk in RTS propose a special role for RECQL4 in bone development.

3D analysis of facial morphology.

Dense surface models can be used to analyze 3D facial morphology by establishing a correspondence of thousands of points across each 3D face image. The models provide dramatic visualizations of 3D face-shape variation with potential for training physicians to recognize the key components of particular syndromes. We demonstrate their use to visualize and recognize shape differences in a collection of 3D face images that includes 280 controls (2 weeks to 56 years of age), 90 individuals with Noonan syndrome (NS) (7 months to 56 years), and 60 individuals with velo-cardio-facial syndrome (VCFS; 3 to 17 years of age). Ten-fold cross-validation testing of discrimination between the three groups was carried out on unseen test examples using five pattern recognition algorithms (nearest mean, C5.0 decision trees, neural networks, logistic regression, and support vector machines). For discriminating between individuals with NS and controls, the best average sensitivity and specificity levels were 92 and 93% for children, 83 and 94% for adults, and 88 and 94% for the children and adults combined. For individuals with VCFS and controls, the best results were 83 and 92%. In a comparison of individuals with NS and individuals with VCFS, a correct identification rate of 95% was achieved for both syndromes. This article contains supplementary material, which may be viewed at the American Journal of Medical Genetics website at http://www.interscience.wiley.com/jpages/0148-7299/suppmat/index.html.

Bilateral frontoparietal polymicrogyria: clinical and radiological features in 10 families with linkage to chromosome 16.

Polymicrogyria is a common malformation of cortical development characterized by an excessive number of small gyri and abnormal cortical lamination. Multiple syndromes of region-specific bilateral symmetric polymicrogyria have been reported. We previously have described two families with bilateral frontoparietal polymicrogyria (BFPP), an autosomal recessive syndrome that we mapped to a locus on chromosome 16q12-21. Here, we extend our observations to include 19 patients from 10 kindreds, all linked to the chromosome 16q locus, allowing us to define the clinical and radiological features of BFPP in detail. The syndrome is characterized by global developmental delay of at least moderate severity, seizures, dysconjugate gaze, and bilateral pyramidal and cerebellar signs. Magnetic resonance imaging demonstrated symmetric polymicrogyria affecting the frontoparietal regions most severely, as well as ventriculomegaly, bilateral white matter signal changes, and small brainstem and cerebellar structures. We have refined our genetic mapping and describe two apparent founder haplotypes, one of which is present in two families with BFPP and associated microcephaly. Because 11 of our patients initially were classified as having other malformations, the syndrome of BFPP appears to be more common than previously recognized and may be frequently misdiagnosed.

A locus for bilateral perisylvian polymicrogyria maps to Xq28.

Polymicrogyria (PMG) is one of a large group of human cortical malformations that collectively account for a significant percentage of patients with epilepsy, congenital neurological deficits, and intellectual disability. PMG is characterized by an excess of small gyri and abnormal cortical lamination. The most common distribution is bilateral, symmetrical, and maximal, in the region surrounding the sylvian fissures, and is known as "bilateral perisylvian polymicrogyria" (BPP). Most cases are sporadic, although several families have been observed with multiple affected members, usually following an X-linked inheritance pattern. Here we report the first genetic locus for BPP mapped by linkage analysis in five families. Linkage places the critical region for BPP at Xq28 (LOD score 3.08 in Xq28, distal to DXS8103 by multipoint analysis). We suggest that this region contains a gene that is necessary for correct neuronal organization and that the identification of this gene will both enhance our understanding of normal cortical development and accelerate the identification of other genes responsible for PMG.

G protein-coupled receptor-dependent development of human frontal cortex.

The mammalian cerebral cortex is characterized by complex patterns of anatomical and functional areas that differ markedly between species, but the molecular basis for this functional subdivision is largely unknown. Here, we show that mutations in GPR56, which encodes an orphan G protein-coupled receptor (GPCR) with a large extracellular domain, cause a human brain cortical malformation called bilateral frontoparietal polymicrogyria (BFPP). BFPP is characterized by disorganized cortical lamination that is most severe in frontal cortex. Our data suggest that GPCR signaling plays an essential role in regional development of human cerebral cortex.