Obligate short-arm exchange in de novo Robertsonian translocation formation influences placement of crossovers in chromosome 21 nondisjunction.

Robertsonian translocations (ROBs) involving chromosome 21 are found in approximately 5% of patients with Down syndrome (DS). The most common nonhomologous ROB in DS is rob(14q21q). Aberrant recombination is associated with nondisjunction (NDJ) leading to trisomy 21. Haplotype analysis of 23 patients with DS and de novo rob(14q21q) showed that all translocations and all nondisjoined chromosomes 21 were maternally derived. Meiosis II NDJ occurred in 21 of 23 families. For these, a ROB DS chromosome 21 genetic map was constructed and compared to a normal female map and a published trisomy 21 map derived from meiosis II NDJ. The location of exchanges differed significantly from both maps, with a significant shift to a more distal interval in the ROB DS map. The shift may perturb segregation, leading to the meiosis II NDJ in this study, and is further evidence for crossover interference. More importantly, because the event in the short arms that forms the de novo ROB influences the placement of chiasmata in the long arm, it is most likely that the translocation formation occurs through a recombination pathway in meiosis. Additionally, we have demonstrated that events that occur in meiosis I can influence events, such as chromatid segregation in meiosis II, many decades later.

Mosaicism in a patient with Down syndrome reveals post-fertilization formation of a Robertsonian translocation and isochromosome.

It has been estimated that a few hundred children are born each year in the United States with translocation Down syndrome. About 5% of the cases with Down syndrome carry a Robertsonian translocation involving chromosome 21. The case described here is a patient with Down syndrome who showed mosaicism for two cell lines. Each cell line contains a different, de novo acrocentric rearrangement. We constructed somatic cell hybrids from the patient's cells and determined the parental origins of the rearrangements by molecular and fluorescence in situ hybridization (FISH) analyses. The analysis showed that the rob(14q21q) formed between a paternally inherited chromosome 21 and a maternally inherited chromosome 14, indicating that this rearrangement formed post-zygotically. Further molecular analysis also determined that the rea(21q21q) is an isochromosome of paternal origin. The cell line containing the isochromosome is unbalanced, resulting in trisomy 21. Because the same paternal chromosome 21 was involved in both the isochromosome and the Robertsonian translocation, we speculate that an unstable chromosome 21 was stabilized either through formation of a rob(14q21q) or through formation of an isochromosome. The mechanism proposed for the formation of the rob(14q21q) in this case is different from that for most de novo rob(14q21q), but similar to a previously reported mosaic case of Down syndrome.

Parental origin and timing of de novo Robertsonian translocation formation.

Robertsonian translocations (ROBs) are the most common chromosomal rearrangements in humans. ROBs are whole-arm rearrangements between the acrocentric chromosomes 13-15, 21, and 22. ROBs can be classified into two groups depending on their frequency of occurrence, common (rob(13q14q) and rob(14q21q)), and rare (all remaining possible nonhomologous combinations). Herein, we have studied 29 case subjects of common and rare de novo ROBs to determine their parental origins and timing of formation. We compared these case subjects to 35 published case subjects of common ROBs and found that most common ROBs apparently have the same breakpoints and arise mainly during oogenesis (50/54). These probably form through a common mechanism and have been termed "class 1." Collectively, rare ROBs also occur mostly during oogenesis (7/10) but probably arise through a more "random" mechanism or a variety of mechanisms and have been termed "class 2." Thus, we demonstrate that although both classes of ROBs occur predominantly during meiosis, the common, class 1 ROBs occur primarily during oogenesis and likely form through a mechanism distinct from that forming class 2 ROBs.

Identification of uniparental disomy in phenotypically abnormal carriers of isochromosomes or Robertsonian translocations.

Carriers of either homologous or non-homologous acrocentric rearrangements are at an increased risk for aneuploidy, and, thus, for uniparental disomy (UPD). Abnormal phenotypes due to genomic imprinting are associated with UPD for the acrocentric chromosomes 14 and 15. The purpose of this study was to determine the prevalence of UPD in a population with acrocentric rearrangements (either an isochromosome or a Robertsonian translocation) and abnormal phenotypes. Fifty individuals were studied. Of the 50 rearrangements, two were homologous rearrangements and both showed UPD. Forty-eight were non-homologous Robertsonian translocations, of which two showed UPD. This study demonstrates that UPD explains the abnormal phenotypes in some balanced carriers of acrocentric rearrangements. Our results and the large number of case reports in the literature suggest that patients with abnormal phenotypes and acrocentric rearrangements of chromosomes 14 or 15 should be tested for UPD.

The importance of investigating for uniparental disomy in prenatally identified balanced acrocentric rearrangements.

We report the finding of paternal isodisomy for chromosome 14 in a fetus found to have a der(14;14)(q10;q10) by amniocentesis. The pregnancy was complicated by severe polyhydramnios and elevated amniotic fluid alpha-fetoprotein (AFP). The infant showed features consistent with paternal uniparental disomy (UPD) including postnatal growth retardation, poor respiratory function, feeding difficulties, and evidence of hypertrophic cardiomyopathy. The present case, in addition to other reported cases of UPD involving balanced acrocentric rearrangements, supports testing for UPD in prenatally detected Robertsonian translocations and isochromosomes.