Distinct CDH3 mutations cause ectodermal dysplasia, ectrodactyly, macular dystrophy (EEM syndrome).

BACKGROUND: EEM syndrome is the rare association of ectodermal dysplasia, ectrodactyly, and macular dystrophy. METHODS: We here demonstrate through molecular analysis that EEM is caused by distinct homozygous CDH3 mutations in two previously published families. RESULTS: In family 1, a missense mutation (c.965A-->T) causes a change of amino acid 322 from asparagine to isoleucine; this amino acid is located in a highly conserved motif likely to affect Ca2+ binding affecting specificity of the cell-cell binding function. In family 2, a homozygous frameshift deletion (c.829delG) introduces a truncated fusion protein with a premature stop codon at amino acid residue 295, expected to cause a non-functional protein lacking both its intracellular and membrane spanning domains and its extracellular cadherin repeats 3-5. Our mouse in situ expression data demonstrate that Cdh3 is expressed in the apical ectodermal ridge from E10.5 to E12.5, and later in the interdigital mesenchyme, a pattern compatible with the EEM phenotype. Furthermore, we discuss possible explanations for the phenotypic differences between EEM and congenital hypotrichosis with juvenile macular dystrophy (HJMD), which is also caused by CDH3 mutations. CONCLUSIONS: In summary, we have ascertained a third gene associated with ectrodactyly and have demonstrated a hitherto unrecognised role of CDH3 in shaping the human hand.

A homozygous BMPR1B mutation causes a new subtype of acromesomelic chondrodysplasia with genital anomalies.

We present a patient with acromesomelic chondrodysplasia and genital anomalies caused by a novel homozygous mutation in BMPR1B, the gene coding for bone morphogenetic protein receptor 1B. The 16 year old girl, the offspring of a multiconsanguinous family, showed a severe form of limb malformation consisting of aplasia of the fibula, severe brachydactyly, ulnar deviation of the hands, and fusion of carpal/tarsal bones. In addition, she presented with hypoplasia of the uterus and ovarian dysfunction resulting in hypergonadotrophic hypogonadism. Mutation analysis of BMPR1B revealed a homozygous 8 bp deletion (del359-366). This mutation is expected to result in a loss of function and is thus different from the heterozygous missense mutations in BMPR1B recently shown to cause brachydactyly type A2 through a dominant negative effect. The patient's skeletal phenotype shows an overlap with the clinical spectrum of the acromesomelic chondrodysplasias of the Grebe, Hunter-Thompson, and DuPan types caused by homozygous mutations in the gene coding for growth differentiation factor 5 (GDF5) which is a high-affinity ligand to BMPR1B. However, the phenotype described here differs from GDF5 associated chondrodysplasias because of the additional presence of genital anomalies and the distinct limb phenotype.

Genetics of congenital hand anomalies.

Congenital limb malformations exhibit a wide spectrum of phenotypic manifestations and may occur as an isolated malformation and as part of a syndrome. They are individually rare, but due to their overall frequency and severity they are of clinical relevance. In recent years, increasing knowledge of the molecular basis of embryonic development has significantly enhanced our understanding of congenital limb malformations. In addition, genetic studies have revealed the molecular basis of an increasing number of conditions with primary or secondary limb involvement. The molecular findings have led to a regrouping of malformations in genetic terms. However, the establishment of precise genotype-phenotype correlations for limb malformations is difficult due to the high degree of phenotypic variability. We present an overview of congenital limb malformations based on an anatomic and genetic concept reflecting recent molecular and developmental insights.

Distinct mutations in the receptor tyrosine kinase gene ROR2 cause brachydactyly type B.

Brachydactyly type B (BDB) is an autosomal dominant skeletal disorder characterized by hypoplasia/aplasia of distal phalanges and nails. Recently, heterozygous mutations of the orphan receptor tyrosine kinase (TK) ROR2, located within a distinct segment directly after the TK domain, have been shown to be responsible for BDB. We report four novel mutations in ROR2 (two frameshifts, one splice mutation, and one nonsense mutation) in five families with BDB. The mutations predict truncation of the protein within two distinct regions immediately before and after the TK domain, resulting in a complete or partial loss of the intracellular portion of the protein. Patients affected with the distal mutations have a more severe phenotype than do those with the proximal mutation. Our analysis includes the first description of homozygous BDB in an individual with a 5-bp deletion proximal to the TK domain. His phenotype resembles an extreme form of brachydactyly, with extensive hypoplasia of the phalanges and metacarpals/metatarsals and absence of nails. In addition, he has vertebral anomalies, brachymelia of the arms, and a ventricular septal defect-features that are reminiscent of Robinow syndrome, which has also been shown to be caused by mutations in ROR2. The BDB phenotype, as well as the location and the nature of the BDB mutations, suggests a specific mutational effect that cannot be explained by simple haploinsufficiency and that is distinct from that in Robinow syndrome.

Mapping of the breakpoints on the short arm of chromosome 17 in neoplasms with an i(17q).

Isochromosomes are monocentric or dicentric chromosomes with homologous arms that are attached in a reverse configuration as mirror images. With an incidence of 3-4%, the i(17q) represents the most frequent isochromosome in human cancer. It is found in a variety of tumors, particularly in blast crisis of chronic myeloid leukemia (CML-BC), acute myeloid leukemia (AML), non-Hodgkin's lymphoma (NHL), and medulloblastoma (MB), and indicates a poor prognosis. To determine the breakpoints on the molecular genetic level, we analyzed 18 neoplasms (six CML, four AML, one NHL, and seven MB) with an i(17q) and two MB with a pure del(17p) applying fluorescence in situ hybridization (FISH) with yeast artificial chromosome (YAC) clones, P1-artificial chromosome (PAC) clones, and cosmids from a well-characterized contig covering more than 6 Mb of genomic DNA. We identified four different breakpoint cluster regions. One is located close to or within the centromere of chromosome 17 and a second in the Charcot-Marie-Tooth (CMT1A) region at 17(p11.2). A third breakpoint was found telomeric to the CMT1A region. The fourth, most common breakpoint was detected in MB, AML, and in CML-BC specimens and was bordered by two adjacent cosmid clones (clones D14149 and M0140) within the Smith-Magenis syndrome (SMS) region. These results indicate that the low copy number repeat gene clusters which are present in the CMT and SMS regions may be one of the factors for the increased instability that may trigger the formation of an i(17q).

Molecular analysis of childhood primitive neuroectodermal tumors defines markers associated with poor outcome.

PURPOSE: The diagnostic and prognostic significance of well-defined molecular markers was investigated in childhood primitive neuroectodermal tumors (PNET). MATERIALS AND METHODS: Using microsatellite analysis, Southern blot analysis, and fluorescence in situ hybridization (FISH), 30 primary tumors and six CSF metastasis specimens were analyzed for loss of heterozygosity (LOH) of chromosomes 1q31, 6q, 9q22, 10q, 11, 16q22, and 17p13.1 and/or high-level amplification of the c-myc gene. Experimental data were compared with clinical stage and outcome. RESULTS: LOH of chromosome 17p13.1 was found most frequently (14 of 30 tumors, six of six CSF metastasis specimens); LOH of chromosomes 10q, 16q22, 11, 6, 9q22, and 1q31 was observed in 20.6%, 20%, 14.3%, 12%, 10%, and 0%, respectively. Eight of 32 tumors and CSF specimens showed amplification of c-myc. All tumors with amplification of c-myc were resistant to therapy and had a fatal outcome (mean survival time, 9.3 months). Tumors that displayed LOH of chromosome 17p were associated with metastatic disease. The prognosis of these tumors was worse only when associated with amplification of c-myc. Three of three patients with LOH of 9q22 relapsed. CONCLUSION: In our study, amplification of c-myc was a poor-prognosis marker in PNET. LOH of chromosome 17p was associated with metastatic disease. Molecular analysis of primary tumors using these markers may be useful for stratification of children with PNET in future prospective studies. The other aberrations investigated were not of significant prognostic value, but may provide an entry point for future large-scale molecular studies.