The flamingo-related mouse Celsr family (Celsr1-3) genes exhibit distinct patterns of expression during embryonic development.

We have isolated cDNAs for three members of a family of seven-pass transmembrane cadherins in mouse (Celsr1, 2 and 3). These three genes represent vertebrate homologues of flamingo/starry night, recently identified as an essential component of the Drosophila planar cell polarity pathway and for the correct formation of dendritic fields within the Drosophila peripheral nervous system. In this study, we show that each member of the mouse Celsr family exhibit distinct patterns of expression within a range of different tissues within the developing embryo. Celsr1 and Celsr2 expression is observed during gastrulation and within the developing nervous system. Celsr3 transcripts, however, are found only at sites of active neurogenesis.

mCelsr1 is an evolutionarily conserved seven-pass transmembrane receptor and is expressed during mouse embryonic development.

Mcelsr1 encodes a protein of 3034 amino acids predicted to contain seven membrane spanning domains having homology to a group of peptide hormone binding G-protein coupled receptors. Its extracellular domain comprises epidermal growth factor-like repeats, laminin A G-domains and cadherin repeats. Homologous genes have been identified in C. elegans and D. melanogaster suggesting that the Celsr gene family is ancient. mCelsr1 mRNA expression precedes gastrulation, is subsequently restricted primarily to ectodermal derivatives and is tightly regulated in the developing central nervous system (CNS). We observe segmentally-restricted gene expression in the developing hindbrain and in the spinal cord dynamic dorso-ventrally restricted 'stripes' of expression.

Aberrant RNA splicing of the protein C and protein S genes in healthy individuals.

RNA-based studies are an important tool for the identification and functional characterization of mutations underlying inherited disease. These studies could in principle be compromised by 'aberrant splicing' (the generation of alternatively spliced transcripts lacking any obvious function) during normal expression of the genes under investigation. Using a highly sensitive RT-PCR assay, we show here that aberrant splicing is a frequent occurrence during expression of the protein C (PROC) and protein S (PROS) genes. Aberrantly spliced transcripts were present in different cell types including liver, the main expressing tissue for both protein C and protein S. In an attempt to compare individual mRNA splicing patterns, PROC and PROS RNA from easily accessible cells of different healthy control individuals was studied. However, variation between different RT-PCR assays from the same individual precluded both the relative quantitation of the aberrant transcripts and the analysis of interindividual differences. Our findings are consistent with the notion that a low level of aberrantly spliced transcripts are routinely generated during PROC and PROS gene expression. The possibility that these transcripts may complicate the RT-PCR analysis of pathological transcripts must be taken into account when RNA-based strategies of disease analysis are considered.

Severe perinatal thrombosis in double and triple heterozygous offspring of a family segregating two independent protein S mutations and a protein C mutation.

Molecular genetic and phenotypic analyses were performed in a highly unusual case of combined protein S and protein C deficiency manifesting in a family in which a child had died perinatally from renal vein thrombosis. Antenatal diagnosis in a second pregnancy was initially performed by indirect restriction fragment length polymorphism (RFLP) tracking using a neutral dimorphism within the PROS gene and served to exclude severe protein S deficiency. Am umbilical vein blood sample at 22 weeks gestation showed isolated protein C deficiency. This pregnancy proceeded to a full-term delivery without thrombotic complications. Molecular genetic analysis of the PROC and PROS gene segregating in the family then yielded one PROC gene lesion in the father and two PROS gene lesions, one in each parent. These lesions were shown to segregate with the respective deficiency states through the family pedigree. Analysis of DNA from paraffin-embedded liver tissue taken from the deceased child showed the presence of both PROS mutations, as well as the PROC mutation. Genotypic analysis of the second child showed a PROC mutation, but neither PROS mutation consistent with its possession of normal protein S levels and a low/borderline protein C level. Antenatal diagnosis was then performed in a third pregnancy by direct mutation detection. However, although the fetus carried only the paternal PROS and PROC gene lesions, the child developed renal thrombosis in utero. It may be that a further genetic lesion at a third locus still remains to be defined. Alternatively, the intrauterine development of thrombosis in this infant could have been caused, at least in part by a transplacental thrombotic stimulus arising in the protein S-deficient maternal circulation. This analysis may, therefore, serve as a warning against extrapolating too readily from genotype to phenotype in families with a complex thrombotic disorder.

Detection and characterization of seven novel protein S (PROS) gene lesions: evaluation of reverse transcript-polymerase chain reaction as a mutation screening strategy.

The molecular genetic analysis of protein S deficiency has been hampered by the complexity of the protein S (PROS) gene and by the existence of a homologous pseudogene. In an attempt to overcome these problems, a reverse transcript-polymerase chain reaction (RT-PCR) mutation screening procedure was developed. However, the application of this mRNA-based strategy to the detection of gene lesions causing heterozygous type I protein S deficiency appears limited owing to the high proportion of patients exhibiting absence of mRNA derived from the mutation-bearing allele ("allelic exclusion"). Nevertheless, this strategy remains extremely effective for rapid mutation detection in type II/III protein S deficiency. Using the RT-PCR technique, a G-to-A transition was detected at position +1 of the exon IV donor splice site, which was associated with type I deficiency and resulted in both exon skipping and cryptic splice site utilization. No abnormal protein S was detected in plasma from this patient. A missense mutation (Asn 217 to Ser), which may interfere with calcium binding, was also detected in exon VIII in a patient with type III protein S deficiency. A further three PROS gene lesions were detected in three patients with type I deficiency by direct sequencing of exon-containing genomic PCR fragments: a single base-pair (bp) deletion in exon XIV, a 2-bp deletion in exon VIII, and a G0to-A transition at position -1 of the exon X donor splice site all resulted in the absence of mRNA expressed from the disease allele. Thus, the RT-PCR methodology proved effective for further analysis of the resulting protein S-deficient phenotypes. A missense mutation (Met570 to Thr) in exon XIV of a further type III-deficient proband was subsequently detected in this patient's cDNA. No PROS gene abnormalities were found in the remaining four subjects, three of whom exhibited allelic exclusion. However, the father of one such patient exhibiting allelic exclusion was subsequently shown to carry a nonsense mutation (Gly448 to Term) within exon XII.

The order and orientation of a cluster of metalloproteinase genes, stromelysin 2, collagenase, and stromelysin, together with D11S385, on chromosome 11q22-q23.

A cluster of metalloproteinase genes, stromelysin, fibroblast collagenase, and stromelysin 2 together with the anonymous DNA marker D11S385, was mapped using pulsed-field gel electrophoresis to a 135-kb region of chromosome 11q22-q23. The physical proximity of these markers was subsequently confirmed using two YAC clones, and their relative order was established as stromelysin 2-collagenase-stromelysin-D11S385. The pattern of marker representation in a panel of radiation-reduced chromosome 11 hybrids suggests that the metalloproteinase gene/D11S385 cluster is orientated with STMY2 closest to the centromere.

Development of T-cell leukaemia in an ataxia telangiectasia patient following clonal selection in t(X;14)-containing lymphocytes.

Ataxia telangiectasia is a rare inherited and progressive neurological disorder in which patients show an unusual predisposition to T-cell leukaemia. We report here observations on a patient with a large cytogenetically abnormal clone showing a single t(X;14)(q28;q11) translocation which conferred a proliferative advantage on the cells. The further evolution of this clone to cytogenetically more complex clones of lymphocytes was seen in the patient. She subsequently developed a rapidly progressing T-cell leukaemia, with a CD4+CD8+ T-cell phenotype, about five years after the first appearance of additional chromosome translocations in the clone cells.

Fine mapping of the chromosome 11q22-23 region using PFGE, linkage and haplotype analysis; localization of the gene for ataxia telangiectasia to a 5cM region flanked by NCAM/DRD2 and STMY/CJ52.75, phi 2.22.

Using pulsed-field gel electrophoresis, and a range of different enzyme digests, we have established that both markers of each of the pairs CJ52.208/YNB3.12, NCAM/DRD2, and STMY/CJ52.75, on chromosome 11q22-23, show physical linkage on a single DNA fragment. We have also shown, using genetic linkage and haplotype analyses, that these markers lie within a region of approximately 18cM, which, it has been shown previously, is likely to contain the A-T gene. The relative positions of these marker loci, and the distance between them was determined in order to construct a detailed map which has allowed a more precise localization of the A-T gene. We have shown that in pairwise linkage analysis the strongest support for linkage to the A-T gene was with the STMY/CJ52.75 locus (Z = 5.59, theta = 0.0). A three-point analysis using the results from STMY/CJ52.75 and the closely linked marker phi 2.22 gave Z = 5.55, theta = 0.03. Despite persisting evidence of some linkage to Thy-1 our results are consistent with the existence of a single A-T locus on chromosome 11q22-23 and our best estimate of the position of this locus places it between NCAM/DRD2 and (STMY/CJ52.75, F2.22) (Z = 6.74), a region of approximately 5cM in males.