Autosomal recessive cystinuria caused by genome-wide paternal uniparental isodisomy in a patient with Beckwith-Wiedemann syndrome.

Approximately 20% of Beckwith-Wiedemann syndrome (BWS) cases are caused by mosaic paternal uniparental disomy of chromosome 11 (pUPD11). Although pUPD11 is usually limited to the short arm of chromosome 11, a small minority of BWS cases show genome-wide mosaic pUPD (GWpUPD). These patients show variable clinical features depending on mosaic ratio, imprinting status of other chromosomes, and paternally inherited recessive mutations. To date, there have been no reports of a mosaic GWpUPD patient with an autosomal recessive disease caused by a paternally inherited recessive mutation. Here, we describe a patient concurrently showing the clinical features of BWS and autosomal recessive cystinuria. Genetic analyses revealed that the patient has mosaic GWpUPD and an inherited paternal homozygous mutation in SLC7A9. This is the first report indicating that a paternally inherited recessive mutation can cause an autosomal recessive disease in cases of GWpUPD mosaicism. Investigation into recessive mutations and the dysregulation of imprinting domains is critical in understanding precise clinical conditions of patients with mosaic GWpUPD.

Maternal uniparental isodisomy and heterodisomy on chromosome 6 encompassing a CUL7 gene mutation causing 3M syndrome.

We report a case of segmental uniparental maternal hetero- and isodisomy involving the whole of chromosome 6 (mat-hUPD6 and mat-iUPD6) and a cullin 7 (CUL7) gene mutation in a Japanese patient with 3M syndrome. 3M syndrome is a rare autosomal recessive disorder characterized by severe pre- and postnatal growth retardation that was recently reported to involve mutations in the CUL7 or obscurin-like 1 (OBSL1) genes. We encountered a patient with severe growth retardation, an inverted triangular gloomy face, an inverted triangle-shaped head, slender long bones, inguinal hernia, hydrocele testis, mild ventricular enlargement, and mild mental retardation. Sequence analysis of the CUL7 gene of the patient revealed a homozygous missense mutation, c.2975G>C. Genotype analysis using a single nucleotide polymorphism array revealed two mat-hUPD and two mat-iUPD regions involving the whole of chromosome 6 and encompassing CUL7. 3M syndrome caused by complete paternal iUPD of chromosome 6 involving a CUL7 mutation has been reported, but there have been no reports describing 3M syndrome with maternal UPD of chromosome 6. Our results represent a combination of iUPDs and hUPDs from maternal chromosome 6 involving a CUL7 mutation causing 3M syndrome.

Patched homologue 1 mutations in four Japanese families with basal cell nevus syndrome.

AIM: To search for patched homologue 1 (PTCH1) mutations in four families with basal cell nevus syndrome (BCNS). METHODS: Mutation analysis of PTCH1 in unrelated Japanese families affected with BCNS was carried out by direct sequencing. RESULTS: Six novel PTCH1 mutations, 833G-->A in exon 6, 1415C-->A and 1451G-->T in exon 10, 2798delC in exon 17, 2918-2925dupAGTTCCCT in exon 18 and 3956C-->A in exon 23, were identified. CONCLUSIONS: Among the six PTCH1 mutations, two frameshift mutations (2798delC and 2918-2925dupAGTTCCCT) and one nonsense mutation (833G-->A) are predicted to lead to premature termination of PTCH1 protein translation. Three simultaneous mutations, 1415C-->A (A472D) and 1451G-->T (G484V) in exon 10, and 3956G-->A (R1319H) in exon 23, were found on one allele in only affected members in one family and none of them were found among 90 unrelated healthy Japanese. The three mutations on one chromosome may have resulted from errors in the recombinational repair process and this is the first report on the PTCH1 mutations due to such a mechanism.

Confirmation of genetic homogeneity of syndactyly type 1 in an Iranian family.

Syndactyly type 1 (SD1) is the most common type of syndactyly, inherited in an autosomal dominant fashion and characterized by complete or partial webbings between the third and fourth fingers and/or between the second and third toes. We recently encountered an Iranian family in which 33 members in six generations were affected with SD1. As a locus of SD1 in a German family has recently been assigned to chromosome 2q34-q36, we performed a linkage analysis of the Iranian SD1 in order to know whether the disorder is genetically homogeneous. With the analysis on 15 affected and 16 unaffected persons in the Iranian family, using dinucleotide repeat polymorphisms as markers, we mapped the SD1 locus to 2q34-q36 with a maximum LOD score of 6.92 at a recombination fraction straight theta = 0.00 (penetrance = 1.00) for the D2S2179 locus. The result not only confirmed the gene assignment, but also suggests genetic homogeneity of the disease.

Transforming growth factor-alpha (TGFA): genomic structure, boundary sequences, and mutation analysis in nonsyndromic cleft lip/palate and cleft palate only.

Transforming growth factor-alpha (TGFA) has been proposed as a candidate gene in the etiology of nonsyndromic cleft lip with or without cleft palate (NS-CL/P) and of nonsyndromic cleft palate only (NS-CPO). Biologic support for a role of TGFA arises from its presence at high levels in the epithelial tissue of the medial edge of the palatal shelves at the time of shelf fusion in mice. Genetic support for the role of TGFA in clefting comes from the reported association of TGFA alleles with human NS-CPO and NS-CL/P. In this study we report the sequence and structure of human genomic TGFA and the search for causal TGFA mutations in 250 individuals with NS-CL/P or NS-CPO by conformational analysis of the coding sequence, splice junctions, and a portion of the 3' untranslated region strongly homologous between human and mouse. We confirm that human TGFA is composed of six exons and here report several new sequence substitutions and their frequencies. Five variants in conserved segments may represent rare causes for clefting in humans and provide support for the role of TGFA in facial morphogenesis.

Sequence and chromosomal assignment of human BAPX1, a bagpipe-related gene, to 4p16.1: a candidate gene for skeletal dysplasia.

Homeobox-containing genes play an important role in both body axis determination and specific organ development. They have increasingly been found to be mutated in human birth defect disorders. Sequences of two bagpipe-related genes in the mouse, Nkx-3.1 and Nkx-3.2, have already been reported. Nkx-3.1 was isolated from the prostate, and its human homolog NKX-3.1 has also been described. Mouse Nkx-3.2, or bapx1, has also been isolated, and its expression in the visceral mesoderm and embryonic skeleton in the mouse has been described. We report here the human BAPX1 sequence and its localization to chromosome region 4p16.1 and suggest BAPX1 as a candidate for disorders of skeletal development that might map to 4p16.1.

A comparison of GC content and the proportion of Alu/KpnI-repetitive sequences in a single dark- and light-band region from a human chromosome.

To obtain direct evidence for a molecular basis of differentiation between regular Giemsa dark (G)- and light (R)-band regions of human chromosomes, two regions of chromosome 11, q14-q22 (G-band) and q23-q25 (R-band), were microdissected. The DNA fragments were amplified by the linker-primer polymerase chain reaction and cloned into pUC19. Microclones from each library were then compared by colony hybridization with repetitive DNA sequences, by Southern blot hybridization of each microclone to total human genomic DNA and mouse-human hybrid cell DNA containing only human chromosome 11, and by sequencing of unique and Alu-repetitive clones. Among the G-band-derived microclones analyzed, 43.0% were single-copy (unique) sequences and 23.2% contained highly repetitive sequence elements; in the R-band-derived library, 54.2% were unique clones and 20.3% had highly repetitive elements. The G-band library was significantly richer in clones positive for KpnI sequences (4.1% in the G-band library vs 2.8% in the R-band library). No significant difference was found in the proportion of Alu repetitive clones present in the two libraries, but Class IV Alu sequence derivatives were more frequently observed in the R-library than in the G-library. Sequence analysis revealed no significant difference in GC content or in the ratio of CpG sequence to GpC dinucleotide between 30 microclones derived from G-bands and 29 microclones derived from R-bands.(ABSTRACT TRUNCATED AT 250 WORDS)