Multiple fetal anomalies associated with subtle subtelomeric chromosomal rearrangements.

We report two cases of multiple fetal anomalies detected by prenatal ultrasound and associated with subtle subtelomeric chromosomal rearrangements. The first case presented at 25 weeks of gestation with an enlarged cisterna magna and ventriculomegaly. Karyotyping of amniocytes showed a subtle terminal abnormality of chromosome 6q. Thereafter, screening of all unique chromosomal subtelomeric regions using a panel of telomere-specific, fluorescence in situ hybridization (FISH) probes revealed an unbalanced reciprocal translocation between 6q and 17p [46,XX.ish der(6)t(6;17)(q25.3;p13)(TelVysion6q-;TelVysion17p+)]. The second case presented at 25 weeks of gestation with tetralogy of Fallot and at 34 weeks of gestation had additional ultrasound findings of an arachnoid cyst and intrauterine growth restriction. Postnatal karyotyping of peripheral blood was performed and appeared normal. However, a cryptic deletion of the subtelomeric region of the long arm of chromosome 14 was identified when the infant's blood sample was used as a control for an oncology FISH probe. Thereafter, screening of all unique chromosomal subtelomeric regions using a panel of telomere-specific FISH probes revealed an unbalanced reciprocal translocation of chromosomes 14q and 20p [46,XY.ish der(14)t(14;20)(q32.3;p13)(IGH-, D14S308-,TelVysion20p+)mat]. These two cases add to a growing number of reports of cryptic subtelomeric chromosomal rearrangements associated with congenital anomalies. This is the first report of multiple, simultaneous FISH screening of the subtelomeric regions in amniotic fluid and has demonstrated the technical feasibility of this technique in the prenatal period.

Partial COL1A2 gene duplication produces features of osteogenesis imperfecta and Ehlers-Danlos syndrome type VII.

Type I collagen is the most abundant structural protein in the mammalian body. It exists as a heterotrimer of two subunits in the form [alpha1(I)]2alpha2(I). Pathogenic mutations in COL1A1 and COL1A2, the genes that encode the two subunits, cause a range of phenotypes including mild to lethal forms of osteogenesis imperfecta and a restricted set of Ehlers-Danlos syndrome phenotypes. Lethal mutations usually result from missense mutations that disrupt the normal triple helical structure of the molecule. Multi-exon duplication or deletion in type I collagen genes has rarely been observed and has generally resulted in a lethal or severe phenotype. We report a partial duplication in the COLIA2 gene that causes a relatively mild phenotype, despite the addition of 477 amino acids to the triple helical domain of the proalpha2(I) chain. The abnormal molecule is synthesized and secreted by cultured dermal fibroblasts in a normal fashion. Electron microscopy of dermal tissue reveals small but otherwise near normal collagen fibrils. The gene duplication occurred by mitotic sister chromatid exchange in the mother who is mosaic for the duplication allele. Examination of the abnormal sequence suggests a means by which the duplicated molecule could be processed and properly incorporated into mature collagen fibrils.

Brachydactyly type A1 with abnormal menisci and scoliosis in three generations.

We report a three-generation family in which four members had brachydactyly type A1, degenerative arthritis of the knee as a complication of abnormal menisci, and variable scoliosis. Nine of the 15 individuals in the two generations preceding the proband had brachydactyly. Three of these nine had degenerative arthritis of the knee including the proband's father who had meniscal degeneration with tears. One other had radiologically confirmed discoid menisci. Of those with brachydactyly, five also had scoliosis. Although autosomal dominant inheritance of brachydactyly A1 and discoid menisci have been reported separately, cosegregation of these features in one family has not previously been described and seems to comprise a unique autosomal dominant condition. The combination of brachydactyly, meniscal abnormalities including discoid meniscus, and scoliosis suggests that this disorder represents a new osteochondrodysplasia syndrome.

Joint hypermobility syndromes.

Inherited connective tissue disorders, among them Ehlers-Danlos syndrome, osteogenesis imperfecta, Marfan syndrome, and Larsen syndrome, are characterized by generalized joint hypermobility. Others, such as Morquio syndrome or achondroplasia, have hypermobility in a more limited distribution. Recent clinical and molecular genetic studies have defined the range of clinical variation and the underlying molecular defects in several disorders. These studies provide hope that more common varieties of joint hypermobility can be understood and that effective therapies are within reach.

Genetic characterization of a MUT locus mutation discriminating heterogeneity in mut0 and mut- methylmalonic aciduria by interallelic complementation.

Genetic complementation of fibroblasts from patients with methylmalonic aciduria (MMA) defines a unique class of allelic mutations arising from mutations at the locus encoding the methylmalonyl coenzyme A (CoA) mutase apoenzyme. Various phenotypes of MMA have been delineated including complete absence of enzyme activity (mut0) and abnormal enzyme activity with an elevated Km for adenosylcobalamin (mut-). We describe genetic studies on a cell line (WG1130) from a patient with mut0 MMA which exhibited an unusual complementation phenotype, complementing with three of nine mut0 cell lines and four of five mut- cell lines. This suggests that interallelic complementation occurs between mutant alleles in WG1130 and subsets of alleles associated with both mut0 and mut- phenotypes. The methylmalonyl CoA mutase cDNA was cloned from WG1130 and found to contain a G354----A (Arg93----His) mutation. Gene transfer of this mutant clone into primary fibroblasts from patients with MMA confirms that this mutation expresses a mut0 phenotype when transferred into a mut0 cell line with low levels of mRNA but can contribute to apoenzyme function when transferred into mut cell lines which show correction with WG1130 by somatic cell complementation. These results point to further heterogeneity within both mut0 and mut- and may enable identification of mutations affecting discrete components of apoenzyme function.