The pericentric inversion of chromosome 16 and the t(16;16) are two recurrent aberrations in bone marrow of patients with acute nonlymphocytic leukemia subtype M4 Eo, characterized by abnormal eosinophilic granulation. We describe here the precise localization of the breakpoints using fluorescence in situ hybridization (FISH) with cosmids spread over the short arm of chromosome 16 and the detection, isolation and characterization of a 14Kb EcoRI fragment containing a cluster of breakpoints. First, cosmids were mapped to intervals defined by constitutional 16p rearrangements, second, the inv(16) and t(16;16) breakpoints were mapped to one of the intervals using FISH with the mapped cosmids and third, cosmids within this interval were ordered using two color interphase FISH. An STS of the cosmid closest to the breakpoints was then used to isolate five YACs, which did span all of the 16 inv(16) breakpoints and one t(16;16) breakpoint analysed. In the DNA of one inv(16) patient we detected an additional submicroscopic deletion immediately proximal to the 16p breakpoint. Since this patient has the same phenotype, the 16p sequences proximal to the breakpoint seem non-essential to M4 Eo. This implies that the pathologic event is the juxtaposition of sequences distal to the 16p breakpoint with sequences proximal to the 16q breakpoint. While four of the five YACs showed instability of the region around the inv(16) breakpoint, DNA halo analysis allowed us to identify one YAC which was co-linear with normal genomic DNA and has yielded the actual breakpoint sequences which could be subcloned into cosmids and fosmids.(ABSTRACT TRUNCATED AT 250 WORDS)
The human dystrophin gene, mutations of which cause Duchenne and Becker muscular dystrophy, measures 2.4 Mb. This size seriously limits its cloning as a single DNA fragment and subsequent in-vitro expression studies. We have used stepwise in-vivo recombination between overlapping yeast artificial chromosomes (YACs) to reconstruct the dystrophin gene. The recombinant YACs are mitotically stable upon propagation in haploid yeast cells. In contrast, specific combinations of YACs display a remarkable mitotic and meiotic instability in diploid cells. Non-disjunction is rare for overlapping YACs, but increases upon sporulation of diploid cells containing non-overlapping molecules. We have exploited this feature in a three-point recombination to bridge a 280 kb gap between two non-overlapping YACs for which no YAC of proper polarity existed. Our largest recombinant YAC measures 2.3 Mb and contains the entire muscle specific DMD-gene with the exception of a 100 kb region containing the in-frame exon 60. The latter segment has a high tendency to undergo deletions in multi-molecular interactions, probably due to the presence of as yet unidentified instability-enhancing sequences. Fluorescent in situ hybridizations confirmed that the 2.3 Mb DMD YAC contained Xp21-sequences only and indicated a compact tertiary structure of the DMD-gene in interphase lymphocyte nuclei. We conclude that the yeast system is a flexible, efficient and generally applicable tool to reconstruct or build genomic regions from overlapping YAC constituents. Its application to the human dystrophin gene has provided many possibilities for future studies.
The aim of the present study was to investigate whether chromosome 16p presents breakpoint regions susceptible to radiation-induced rearrangements. The frequencies of translocations were determined by fluorescence in situ hybridization (FISH) using cosmid probes C40 and C55 mapping on chromosome 16p, and a chromosome 16 centromere-specific probe (pHUR195). Peripheral lymphocytes were collected from normal individuals and from seven victims of 137Cs in the Goiania (Brasil) accident (absorbed doses: 0.8–4.6 Gy) 10 years after exposure. In vitro irradiated lymphocytes (3 Gy) were also analyzed. The mean translocation frequency/cell obtained for the 137Cs exposed individuals was 2.4-fold higher than the control value (3.6 × 10–3 ± 0.001), and the in vitro irradiated lymphocytes showed a seven-fold increase. The genomic translocation frequencies (FGs) were calculated by the formula Fp = 2.05 fp(1 – fp)FG (Lucas et al., 1992). For the irradiated lymphocytes and victims of 137Cs, the FGs calculated on the basis of chromosome 16 were 2- to 8-fold higher than those for chromosomes 1, 4 and 12. Our results indicate that chromosome 16 is more prone to radiation-induced chromosome breaks, and demonstrate a non-random distribution of induced aberrations. This information is valuable for retrospective biological dosimetry in case of human exposure to radiation, since the estimates of absorbed doses are calculated by determining the translocation frequency for a sub-set of chromosomes, and the results are extrapolated to the whole genome, assuming a random distribution of induced aberrations. Furthermore, the demonstration of breakpoints on 16p is compatible with the reports about their involvement in neoplasias.
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