Fluorescence in situ hybridization analysis with LIS1 specific probes reveals a high deletion mutation rate in isolated lissencephaly sequence.

PURPOSE: Recent revision of the lissencephaly critical region on chromosome 17p13.3 and confirmation of LIS1 as the causative gene for classical lissencephaly has allowed the development and application of fluorescence in situ hybridization (FISH) probes corresponding directly to this gene. METHOD: We have analyzed patients with isolated lissencephaly sequence (ILS) by FISH with probes at D17S379, an anonymous locus distal to LIS1, and with LIS1 specific probes. RESULTS: In 110 patients with ILS, a deletion at D17S379 was detected in 23.6%. Of those patients without a deletion, 32 were available for further study with LIS1 probes. Deletions were found in eight additional individuals. CONCLUSION: The overall deletion mutation rate detectable by FISH with LIS1 probes is approximately 40%. This rate is significantly higher than the deletion rate observed at D17S379. This indicates that FISH studies using probes specific to LIS1 should be undertaken as the initial diagnostic assay for the evaluation of patients with ILS, and the high frequency of deletions raises the possibility of "hotspots" for chromosome breakage in this region.

Refined molecular characterization of the breakpoints in small inv dup(15) chromosomes.

Inv dup(15) is the most common supernumerary marker chromosome in humans. To investigate the mechanism responsible for this frequent chromosome rearrangement, we characterized the breakpoints in 18 individuals with small inv dup(15) chromosomes [i.e., negative for the Prader-Willi (PWS)/Angelman syndrome (AS) critical region]. Since two proximal breakpoint regions ("hotspots") for PWS/AS deletions have been previously identified with the most proximal 15q markers D15S541/S542 and S543, we hypothesized that formation of the small inv dup(15) chromosomes may involve one or both of these breakpoint hotspots. By analysis with S542, both breakpoint regions were found to be involved in approximately equal frequencies. In ten cases, the inv dup(15) was negative for S542 (Class I), indicating the breakpoint is between the centromere and the most proximal marker on chromosome 15. For the other eight cases, S542 was positive by fluorescence in situ hybridization (5/5) and/or microsatellite analysis (7/7), but S543 was negative (Class II). These two breakpoint regions appear to be the same as the two proximal breakpoints reported in the common PWS/AS deletions. To initiate cloning and sequencing of the Class II breakpoint, the gap in the yeast artificial chromosome (YAC) contig between S541/S542 and S543 was filled by screening the CEPH YAC and mega-YAC libraries. YACs 705C2 and 368H3 were found to bridge this gap, and therefore contain the more distal breakpoint region. The finding of consistent breakpoints in small inv dup(15), like that found in PWS/AS deletions, provides strong evidence for hotspots for chromosome breakage in this region. In addition, our results show that two extra copies (tetrasomy) of the region from 15cen to the euchromatic region containing S542 are present in individuals with Class II breakpoints. Since most individuals carrying a small inv dup(15) are phenotypically normal, the euchromatin region included in the small inv dup(15) chromosomes does not appear to contain genes with clinically significant dosage effects.

Prenatal diagnosis and clinical findings in a case of hexasomy 12p.

We report the first case of hexasomy 12p mosaicism due to 2 copies of an apparent i(12p) [46,XX/48,XX, +i(12p), +i(12p)]. In every cell that contained the i(12p), 2 copies of the marker were found. The hexasomy was found in amniocytes (16%) and skin fibroblasts (95%) but not in peripheral blood lymphocytes. The chromosomal origin of the marker was confirmed with the use of in situ hybridization of alpha-satellite specific for the centromere of chromosome 12. The present case was diagnosed following chromosome analysis for anomalies on ultrasound. The hexasomy 12p patient showed striking phenotypic similarities with severely affected tetrasomy 12p cases and died shortly after birth. We propose that the more severe presentation of this case is due to the 4 extra copies of 12p.