The involvement of U-type dicentric chromosomes in the formation of terminal deletions with or without adjacent inverted duplications.

An inverted duplication with a terminal deletion (inv-dup-del) is one of the complex constitutional structural rearrangements that can occur in a chromosome. Although breakages of dicentric chromosome have been suggested, the precise mechanism of this is yet to be fully understood. In our present study, we investigated the genomic structure of 10 inv-dup-del cases to elucidate this mechanism. Two recurrent 8p inv-dup-del cases harbored a large copy-number-neutral region between the duplication and deletion in common. Although the other non-recurrent cases did not appear to have this copy-number-neutral region, refined sequencing analysis identified that they contained a small intervening region at the junction between the inverted and non-inverted segment. The size of this small intervening region ranged from 1741 to 3728 bp. Combined with a presence of microhomology at the junction, a resolution of the replication fork stalling through template switching within the same replication fork is suggested. We further observed two cases with mosaicism of the dicentric chromosome and various structural rearrangements related to the dicentric chromosome. Refined analysis allowed us to identify different breakpoints on the same chromosome in the same case, implicating multiple rounds of U-type formation and its breakage. From these results, we propose that a replication-based mechanism generates unstable dicentric chromosomes and that their breakage leads to the formation of inv-dup-dels and other related derivative chromosomes.

Analysis of the Origin of Double Mosaic Aneuploidy in Two Cases.

We present 2 cases of double mosaic aneuploidy harboring 2 or more different aneuploid cell lines, but no line with a normal chromosome constitution. One of these cases presented mosaicism of sex chromosome aneuploid cell lines (47,XXX/45,X) along with another line containing an autosomal trisomy (47,XX,+8), while the other case showed mosaicism of 2 different autosomal trisomy cell lines (47,XY,+5 and 47,XY,+8). To elucidate the mechanisms underlying these mosaicisms, we conducted molecular cytogenetic analyses. Genotyping data from the SNP microarray indicated that 2 sequential meiotic or early postzygotic segregation errors likely had occurred followed by natural selection. These cases suggest that frequent segregation errors and selection events in the meiotic and early postzygotic stages lead to this condition.

Lethal persistent pulmonary hypertension of the newborn in Bohring-Opitz syndrome.

Bohring-Opitz syndrome (BOS) is a rare disease with a number of characteristic features, including hypertelorism, prominent metopic suture, exophthalmos, cleft palate, abnormal posture, and developmental retardation. Here, we report a BOS patient presenting with lethal persistent pulmonary hypertension of the newborn (PPHN) and inspiratory respiratory failure. The female infant was treated with nitric oxide and vasodilator, which did not improve her condition. The inspiratory respiratory failure required management with deep sedation. She died on postnatal day 60 due to progressed heart failure. Whole exome sequencing revealed de novo mutation in the ASXL1 gene, c.1934dupG, p.Gly646TrpfsTer12.

Genomic Characterization of Chromosomal Insertions: Insights into the Mechanisms Underlying Chromothripsis.

Chromosomal insertions are rare structural rearrangements, and the molecular mechanisms underlying their origin are unknown. In this study, we used whole genome sequencing to analyze breakpoints and junction sequences in 4 patients with chromosomal insertions. Our analysis revealed that none of the 4 cases involved a simple insertion mediated by a 3-chromosomal breakage and rejoining events. The inserted fragments consisted of multiple pieces derived from a localized genomic region, which were shuffled and rejoined in a disorderly fashion with variable copy number alterations. The junctions were blunt ended or with short microhomologies or short microinsertions, suggesting the involvement of nonhomologous end-joining. In one case, analysis of the parental origin of the chromosomes using nucleotide variations within the insertion revealed that maternal chromosomal segments were inserted into the paternal chromosome. This patient also carried both maternal alleles, suggesting the presence of zygotic trisomy. These data indicate that chromosomal shattering may occur in association with trisomy rescue in the early postzygotic stage.

Signature of backward replication slippage at the copy number variation junction.

Copy number abnormalities such as deletions and duplications give rise to a variety of medical problems and also manifest innocuous genomic variations. Aberrant DNA replication is suggested as the mechanism underlying de novo copy number abnormalities, but the precise details have remained unknown. In our present study, we analyzed the del(2)(q13q14.2) chromosomal junction site observed in a woman with a recurrent pregnancy loss. Microarray analyses allowed us to precisely demarcate a 2.8 Mb deletion in this case, which does not appear in the database of human genomic variations. This deletion includes only one brain-specific gene that could not be related to the reproduction failure of the patient. At the junction of the deletion, we found that 11-13-nucleotide sequence, originally located at the proximal breakpoint region, was repeated four times with a single-nucleotide microhomology at the joint between each repeat. The proximal region and the distal region was finally joined with six-nucleotide microhomology. The structure of the junction is consistent with backward replication slippage proposed previously. Our data lend support to the notion that a common DNA replication-mediated pathway generates copy number variation in the human genome.