We present the cytogenetic, molecular cytogenetic, and molecular genetic results on 20 unrelated patients with an interstitial duplication of the proximal long arm of chromosome 15. Multiple probes showed that the Prader-Willi/Angelman critical region (PWACR) was included in the duplication in 4/20 patients, each ascertained with developmental delay. The duplication was also found in two affected but not in three unaffected sibs of one of these patients. All four probands had inherited their duplication from their mothers, three of whom were also affected. Two of the affected mothers also carried a maternally inherited duplication, whereas the duplication in the unaffected mother and in an unaffected grandmother was paternal in origin, raising the possibility of a parental-origin effect. The PWACR was not duplicated in the remaining 16 patients, of whom 4 were referred with developmental delay. In the 14 families for which parental samples were available, the duplication was inherited with equal frequency from a phenotypically normal parent, mother or father. Comparative genomic hybridization undertaken on two patients suggested that proximal 15q outside the PWACR was the origin of the duplicated material. The use of PWACR probes discriminates between a large group of duplications of no apparent clinical significance and a smaller group, in which a maternally derived PWACR duplication is consistently associated with developmental delay and speech difficulties but not with overt features of either Prader-Willi syndrome or Angelman syndrome.
In Williams syndrome (WS), a deletion of approximately 1.5 Mb on one copy of chromosome 7 causes specific physical, cognitive, and behavioral abnormalities. Molecular dissection of the phenotype may be a route to identification of genes important in human cognition and behavior. Among the genes known to be deleted in WS are ELN (which encodes elastin), LIMK1 (which encodes a protein tyrosine kinase expressed in the developing brain), STX1A (which encodes a component of the synaptic apparatus), and FZD3. Study of patients with deletions or mutations confined to ELN showed that hemizygosity for elastin is responsible for the cardiological features of WS. LIMK1 and STX1A are good candidates for cognitive or behavioral aspects of WS. Here we describe genetic and psychometric testing of patients who have small deletions within the WS critical region. Our results suggest that neither LIMK1 hemizygosity (contrary to a previous report) nor STX1A hemizygosity is likely to contribute to any part of the WS phenotype, and they emphasize the importance of such patients for dissecting subtle but highly penetrant phenotypes.
Seventeen patients presenting with either de novo or familial supernumerary marker (mar) 15 chromosomes were shown by fluorescent in situ hybridization techniques (FISH) to have markers derived from and composed entirely of chromosome 15 material. Using a combination of conventional cytogenetics, FISH, Southern blotting and multiplex polymerase chain reaction (PCR) methods, it was possible to sub-classify the 17 mar(15)s into six distinct morphological and molecular groups. Analysis of DNA and metaphase spreads from the probands and their parents using probes and primers from the pericentromeric and Prader-Willi/Angelman syndromes critical regions (PWS/AS), clearly differentiated between marker 15s which included the PWS/AS critical regions and those which did not. A direct correlation between the presence of the PWS/AS region in the mar(15) and severe mental retardation was observed. Based on these results, a system of classification of supernumerary marker 15 chromosomes is proposed.
Preliminary results on a large population-based molecular survey of FRAXA and FRAXE are reported. All boys with unexplained learning difficulties are eligible for inclusion in the study and data are presented on the first 1013 tested. Individuals were tested for the number of trinucleotide repeats at FRAXA and FRAXE and typed for four flanking microsatellite markers. Mothers of 760 boys were tested to determine the stability of the FRAXA and FRAXE repeats during transmission and to provide a population of control chromosomes. The frequency of FRAXA full mutations was 0.5%, which gives a population frequency of 1 in 4994, considerably less than previous reports suggest. No FRAXE full mutations were detected, confirming the rarity of this mutation. In the boys' X chromosomes, we detected one FRAXA premutation with 152 repeats and one putative FRAXE premutation of 87 repeats. No full or premutations were seen in the control chromosomes. A significant excess of intermediate alleles at both FRAXA and FRAXE was detected in the boys' X chromosomes by comparison with the maternal control chromosomes. This suggests that relatively large unmethylated repeats of sizes 41-60 for FRAXA and 31-60 for FRAXE may play some role in mental impairment. No instability was found in transmissions of minimal or common alleles in either FRAXA or FRAXE, but we saw two possible instabilities in transmission of FRAXA and two definite instabilities in transmission of FRAXE among 43 meioses involving intermediate or premutation sized alleles. We found no linkage disequilibrium between FRAXA and FRAXE but did find significant linkage disequilibrium between large alleles at FRAXE and allele 3 at the polymorphic locus DXS1691 situated 5 kb distal to FRAXE.
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