Development and implementation of a new rapid aneuploidy diagnostic service within the UK National Health Service and implications for the future of prenatal diagnosis.

BACKGROUND: Prenatal diagnosis for chromosome abnormality is routinely undertaken by full karyotype analysis of chromosomes from cultured cells; pregnant women must wait on average 13-14 days for their results. Autosomal trisomies, which account for around 80% of significant abnormalities, can be detected by quantitative fluorescence (QF) PCR. We report on the development and implementation of this technique as the first such routine service within a diagnostic department of the UK National Health Service (NHS). METHODS: We designed a "one-tube test" comprising four primer pairs for polymorphic tetranucleotide repeat sequences on chromosome 21, four primer pairs for sequences on chromosome 18, three primer pairs for sequences on chromosome 13, and one primer pair to identify the sex chromosomes. All prenatal samples received by our NHS diagnostic department between April, 2000, and April, 2001, were tested. After DNA extraction, PCR amplification was done and the products separated on a capillary-based genetic analyser; the results were interpreted with dedicated software. Follow-up karyotype analysis was done on all samples. FINDINGS: 1148 amniotic fluid samples, 188 chorionic villus samples, and 37 fetal tissue samples were tested; the amplification failure rate was zero with our current protocol. QF-PCR results were obtained and reported on 1314 (98%) of the prenatal samples; the remaining 22 (2%) were uninformative because of maternal-cell contamination. One case of mosaicism in a chorionic villus sample, and two cases indicating somatic expansion of a tetranucleotide repeat were found. No false positive or false negative results were obtained. The mean reporting time for the last 4 months of data collection was 1.25 working days. INTERPRETATION: QF-PCR aneuploidy testing is an efficient and accurate technique for the detection of autosomal trisomies in prenatal samples. Implementation of this service has led to the rapid diagnosis of abnormalities and early reassurance for women with normal results.

Comparative mutation detection screening of the type VII collagen gene (COL7A1) using the protein truncation test, fluorescent chemical cleavage of mismatch, and conformation sensitive gel electrophoresis.

Mutations in the type VII collagen gene, COL7A1, give rise to the blistering skin disease, dystrophic epidermolysis bullosa. We have developed two new mutation detection strategies for the screening of COL7A1 mutations in patients with dystrophic epidermolysis bullosa and compared them with an established protocol using conformational sensitive gel electrophoresis. The first strategy consisted of an RNA based protein truncation test that amplified the entire coding region in only four overlapping nested reverse transcriptase-polymerase chain reaction assays. These fragments were transcribed and translated in vitro and analyzed using sodium dodecyl sulfate-polyacrylamide gel electrophoresis. We have used the protein truncation test procedure to characterize 15 truncating mutations in 13 patients with severe recessive dystrophic epidermolysis bullosa yielding a detection sensitivity of 58%. The second strategy was a DNA-based fluorescent chemical cleavage of mismatch (fl-CCM) procedure that amplified the COL7A1 gene in 21 polymerase chain reaction assays. Mismatches, formed between patient and control DNA, were identified using chemical modification and cleavage of the DNA. We have compared fl-CCM with conformational sensitive gel electrophoresis by screening a total of 50 dominant and recessive dystrophic epidermolysis bullosa patients. The detection sensitivity for fl-CCM was 81% compared with 75% for conformational sensitive gel electrophoresis (p = 0.37 chi2-test). Using a combination of the three techniques we have screened 93 dystrophic epidermolysis bullosa patients yielding an overall sensitivity of 87%, detecting 79 different mutations, 57 of which have not been reported previously. Comparing all three approaches, we believe that no single method is consistently better than the others, but that the fl-CCM procedure is a sensitive, semiautomated, high throughput system that can be recommended for COL7A1 mutation detection.

Identification and quantification of somatic mosaicism for a point mutation in a Duchenne muscular dystrophy family.

Relatively few point mutations have been found in the dystrophin gene and of these only two have been associated with mosaicism. A single base insertion has been identified and quantified in a mother of two sons affected with Duchenne muscular dystrophy. It has been determined that she is a somatic mosaic with the mutation present in 25% of lymphocyte DNA. Further tissue lineages have been tested and the time at which the mutation arose was determined to be before the cellular differentiation into the bilaminar disc at approximately eight days after fertilisation. We suggest that the incidence of mosaicism for dystrophin point mutations may be higher than current data suggest.

Correlation of SMNt and SMNc gene copy number with age of onset and survival in spinal muscular atrophy.

Childhood-onset autosomal recessive spinal muscular atrophy (SMA) is associated with absence of the telomeric survival motor neuron gene (SMNt) in most patients, and deletion of the neuronal apoptosis inhibitory protein (NAIP) gene in the majority of severely affected patients. Analysis of SMNt has been complicated by the existence of a centromeric copy, SMNc, which is almost identical to SMNt but which can be distinguished from it by restriction enzyme analysis. In this study 143 SMA patients have been genotyped for the presence or absence of the SMNt, SMNc and NAIP genes, and the data correlated with quantifiable clinical variables. Although a significant correlation was observed between the presence or absence of the NAIP gene and the severity of the clinical phenotype in SMA patients generally, there was no difference in age of onset or survival in type I patients with the NAIP+ or NAIP- genotype. Fluorimetric PCR analysis of SMNc gene dosage in 57 patients homozygous for the absence of the SMNt gene but in whom the NAIP gene was present showed a highly significant correlation between SMNc copy number and SMA subtype, and between SMNc copy number and both age of onset and length of survival. The data provide strong statistical support for the emerging consensus that the clinical phenotype in SMA is directed primarily by the level of functional SMN protein. The lower SMNc copy number in type I patients in whom the NAIP gene is present suggests that the SMNt gene is removed by deletion in the majority of such patients, rather than by gene conversion as is the case in SMA types II and III.

Dystrophin point mutation screening using a multiplexed protein truncation test.

We report here the first use of a multiplexed protein truncation test for the high throughput screening of dystrophin point mutations. We have developed a substantially more robust and efficient procedure incorporating large savings in cost which uses muscle biopsy or lymphocyte total RNA as the template. The entire dystrophin open reading frame is screened in only five overlapping fragments using a long RT-PCR strategy to amplify dystrophin cDNA in excess of 3.7 kb. These five fragments are uniquely transcribed and translated in vitro in a single multiplexed reaction containing magnesium ions to reduce nonspecific internal initiation of translation. We have used this system to analyze mutations in 11 Duchenne muscular dystrophy patients (10 unrelated) with previously uncharacterized mutations. A single truncating mutation was identified in all patients, which was confirmed at the genomic level. Multiplex PTT provides the most efficient method for point mutation screening in this large gene and has potential applications to several disease genes with a significant proportion of truncating mutations.

Accurate diagnosis of carriers of deletions and duplications in Duchenne/Becker muscular dystrophy by fluorescent dosage analysis.

We have developed a semiautomated approach to amplify 25 exons of the dystrophin gene using two fluorescent multiplex PCR assays which detect over 98% of reported deletions and 90% of duplications causing Duchenne/Becker muscular dystrophy. The 5' multiplex detects 11 exons from the proximal deletion hotspot of the gene while the 3' multiplex detects 14 exons from the central deletion hotspot. The PCR products are accurately sized and quantified by a fluorescent DNA sequencer after only 18 cycles of amplification. The amount of product amplified from each exon in a multiplex is divided by that from each of the other exons, and this ratio is compared with those from control samples to obtain a series of dosage quotients (DQ), from which the copy number of each exon is determined. No overlap was observed between the DQ values obtained from single and double copy loci. The assays can be used to screen both affected males and at risk female relatives for a mutation. The method has been evaluated as a female carrier test by conducting a blind trial on 150 coded samples. Sixty-three deletion carriers, two duplication carriers, and 84 normal female controls were all correctly identified, showing that carrier diagnosis is possible even in families where the nature of the mutation is unknown. Additionally the analysis showed a non-pathogenic duplication involving the muscle specific promoter and exon 1. Together these two multiplex assays detect over 70% of all mutations in the dystrophin gene, greatly simplifying and partly automating molecular diagnosis in Duchenne and Becker muscular dystrophy.

Linkage of Emery-Dreifuss muscular dystrophy to the red/green cone pigment (RGCP) genes, proximal to factor VIII.

Further DNA linkage studies on two previously described X-linked recessive Emery-Dreifuss muscular dystrophy (EMD) families are reported, which refine the localization of the gene responsible for EMD. Two recombination events indicate that the most likely localization for the EMD gene lies in the interval between DXS15/DXS52 and F8C. A maximum LOD score of 3.44 at theta = 0 is obtained for EMD vs the red and green cone pigment genes (RCP and GCP). Our data provide additional support for one of the two proposed orientations of genes and markers distal to DXS15/DXS52, with respect to the telomere. Given this favoured orientation, our data best fit a localization of EMD to within a 2 megabase (Mb) interval between DXS15/DXS52 and F8C.