Generation of a complete set of human telomeric band painting probes by chromosome microdissection

Reciprocal Translocation Carrier Diagnosis in Preimplantation Human Embryos

Preimplantation genetic diagnosis (PGD) is widely applied in reciprocal translocation carriers to increase the chance for a successful live birth. However, reciprocal translocation carrier embryos were seldom discriminated from the normal ones mainly due to the technique restriction. Here we established a clinical applicable approach to identify precise breakpoint of reciprocal translocation and to further distinguish normal embryos in PGD. In the preclinical phase, rearrangement breakpoints and adjacent single nucleotide polymorphisms (SNPs) were characterized by next-generation sequencing following microdissecting junction region (MicroSeq) from 8 reciprocal translocation carriers. Junction-spanning PCR and sequencing further discovered precise breakpoints. The precise breakpoints were identified in 7/8 patients and we revealed that translocations in 6 patients caused 9 gene disruptions. In the clinical phase of embryo analysis, informative SNPs were chosen for linkage analyses combined with PCR analysis of the breakpoints to identify the carrier embryos. From 15 blastocysts diagnosed to be chromosomal balanced, 13 blastocysts were identified to be carriers and 2 to be normal. Late prenatal diagnoses for five carriers and one normal fetus confirmed the carrier diagnosis results. Our results suggest that MicroSeq can accurately evaluate the genetic risk of translocation carriers and carrier screen is possible in later PGD treatment.

Characterization of rearrangements involving 4q, 13q and 16q in hepatocellular carcinoma cell lines using region-specific multiplex-FISH probes

Deletions in 4q, 13q and 16q were frequently detected in hepatocellular carcinoma (HCC) by comparative genomic hybridization (CGH) studies. However, detailed chromosome structural aberrations are not fully explored. Using CGH combined with multiplex-color FISH (M-FISH) with chromosome region-specific probes (CRPs), chromosome structural aberrations in 4q, 13q and 16q in six HCC cell lines were studied. All CRPs, which were generated from microdissected DNA, were specific, strong in intensity and sensitive enough to detect chromosome structural aberrations including translocation and deletion. FISH with BAC probes was used to further characterize translocation breakpoints and deletions. A breakpoint at 16q22 was localized at a BAC clone (RP11-341K23) and another breakpoint at 4q28 was localized within a 620 kb-region. A minimal deleted region at 13q21 was found between BAC clones RP11-240M20 and RP11-435P18. This study demonstrated that the combination of CGH, M-FISH and BAC-FISH is a very useful tool to detect and characterize translocation breakpoint.

Characterization of 3p, 5p, and 3q in two nasopharyngeal carcinoma cell lines, using region-specific multiplex fluorescence in situ hybridization probes

Amplification of chromosome arms 3q and 5p and deletion of 3p were frequently detected in nasopharyngeal carcinoma (NPC) with comparative genomic hybridization and loss of heterozygosity studies. To identify the minimal amplified or deleted regions in these arms, structural aberrations in chromosome arms 3p, 3q, and 5p in two NPC cell lines, CNE1 and SUNE1, were studied with multiplex-color FISH (M-FISH) and chromosome region-specific probes (CRP). All CRPs, which were generated from microdissected DNA, were specific and strong in intensity, and sensitive enough to detect chromosome aberrations including translocations, deletions, and amplifications of target regions. In these two NPC cell lines, minimal regions of deletion and amplification were found at 3p12 and 3q26 approximately q27, respectively. On 5p, most of the regions were amplified as intact copies. Interregion translocations of these three arms were also observed. The amplification on 3q26 approximately q27 provided useful hints for further screening the minimal amplification at RP11-115J24 (3q26.2), containing candidate oncogene eIF-5A2. M-FISH with CRPs is thus not only useful in revealing a comprehensive picture of structural aberrations in target chromosomes, but also in narrowing down the minimal region for screening cancer-related genes.

The evolutionary history of human chromosome 7

We report on a comparative molecular cytogenetic and in silico study on evolutionary changes in human chromosome 7 homologs in all major primate lineages. The ancestral mammalian homologs comprise two chromosomes (7a and 7b/16p) and are conserved in carnivores. The subchromosomal organization of the ancestral primate segment 7a shared by a lemur and higher Old World monkeys is the result of a paracentric inversion. The ancestral higher primate chromosome form was then derived by a fission of 7b/16p, followed by a centric fusion of 7a/7b as observed in the orangutan. In hominoids two further inversions with four distinct breakpoints were described in detail: the pericentric inversion in the human/African ape ancestor and the paracentric inversion in the common ancestor of human and chimpanzee. FISH analysis employing BAC probes confined the 7p22.1 breakpoint of the pericentric inversion to 6.8 Mb on the human reference sequence map and the 7q22.1 breakpoint to 97.1 Mb. For the paracentric inversion the breakpoints were found in 7q11.23 between 76.1 and 76.3 Mb and in 7q22.1 at 101.9 Mb. All four breakpoints were flanked by large segmental duplications. Hybridization patterns of breakpoint-flanking BACs and the distribution of duplicons suggest their presence before the origin of both inversions. We propose a scenario by which segmental duplications may have been the cause rather than the result of these chromosome rearrangements.