Analysis of nucleolar organizing regions in parents of trisomic spontaneous abortions

Complex distal 10q rearrangement in a girl with mild intellectual disability: follow up of the patient and review of the literature of non-acrocentric satellited chromosomes

We report on an intellectually disabled girl with a de novo satellited chromosome 10 (10qs) and performed a review of the literature of the non-acrocentric satellited chromosomes (NASC). Satellites and stalks normally occur on the short arms of acrocentric chromosomes; however, the literature cites several reports of satellited non-acrocentric chromosomes, which presumably result from a translocation with an acrocentric chromosome. This is, to our knowledge, the third report of a 10qs chromosome. The phenotype observed in the proband prompted a search for a structural rearrangement of chromosome 10q. By microsatellite analysis we observed a 4 Mb deletion on the long arm of chromosome 10, approximately 145 kb from the telomere. FISH and array CGH analyses revealed a complex rearrangement involving in range from the centromere to the telomere: A 9.64 Mb 10q26.11-q26.2 duplication, a 1.3 Mb region with no copy number change, followed by a 5.62 Mb 10q26.2-q26.3 deletion and a translocation of satellite material. The homology between the repeat sequences at 10q subtelomere region and the sequences on the acrocentric short arms may explain the origin of the rearrangement and it is likely that the submicroscopic microdeletion and microduplication are responsible for the abnormal phenotype in our patient. The patient presented here, with a 15-year follow-up, manifests a distinct phenotype different from the 10q26 pure distal monosomy and trisomy syndromes.

Acrocentric chromosome double NOR is not a risk factor for Down syndrome

Jackson-Cook et al. (American Journal of Human Genetics 37:1049-1061, 1985) predicted a high risk of Down syndrome (DS) children for parents carrying a double NOR on acrocentric chromosomes. Hassold et al. (Human Genetics 76:381-384, 1987) could not confirm Jackson-Cook et al.'s findings, thus casting doubts on their conclusions. We studied the NORs of 1) 60 parents of 30 unselected DS subjects; 2) 30 unselected healthy subjects without trisomic offspring, who asked for chromosome analysis; and 3) 100 slides randomly chosen among 1,000 prepared by routine standard techniques and belonging to subjects who were chromosomally normal. By applying rigorously established techniques and scoring criteria we found 4 subjects (6.7%) with strictly defined double NORs (dNORs) in the DS parents sample, 2 subjects (6.7%) in the first control sample, and 3 (3%) in the second control sample. No significant difference among the observed frequencies of dNORs in the 3 samples could be demonstrated. Therefore, our data do not support Jackson-Cook et al.'s statements on the association of dNOR carrier status with DS offspring and on a highly increased risk of meiotic nondisjunction of chromosome 21 for a dNOR carrier parent. A tentative interpretation of the apparently contrasting cytogenetic findings would indicate that sampling and assignment biases are the main causes of this discrepancy.

Evidence of differential chromosome loss in aneuploid karyotypes of the Pacific oyster, Crassostrea gigas

The G-banding technique was performed on aneuploid karyotypes from gill tissue of the Pacific oyster, Crassostrea gigas, to assess whether chromosome losses could be explained by differential chromosomal susceptibility and to clarify the negative correlation between aneuploidy and growth rate previously reported in different populations of this oyster. The study of 95 G-banded aneuploid karyotypes showed that only 4 of the 10 chromosome pairs (viz. 1, 5, 9, and 10) of C. gigas were affected by the loss of one homologous chromosome. Pairs 1, 9, and 10, which were lost in 56, 33, and 44% of cases, respectively, may be considered to be differentially affected. Hypotheses on this differential chromosomal susceptibility are discussed.Key words: aneuploidy, growth, G-banding, karyotype, oyster.

To err (meiotically) is human: the genesis of human aneuploidy

Aneuploidy (trisomy or monosomy) is the most commonly identified chromosome abnormality in humans, occurring in at least 5% of all clinically recognized pregnancies. Most aneuploid conceptuses perish in utero, which makes this the leading genetic cause of pregnancy loss. However, some aneuploid fetuses survive to term and, as a class, aneuploidy is the most common known cause of mental retardation. Despite the devastating clinical consequences of aneuploidy, relatively little is known of how trisomy and monosomy originate in humans. However, recent molecular and cytogenetic approaches are now beginning to shed light on the non-disjunctional processes that lead to aneuploidy.

Reproductive outcome in 3 families with a satellited chromosome 4 with review of the literature

We describe 3 families segregating for a translocation of the nucleolus organizer region (NOR) onto chromosome 4. Review of previously reported cases of translocations involving NOR and chromosome 4 shows that these translocations may be associated with variable reproductive outcomes. We provide evidence that imprinting is not the mechanism responsible for the variable reproductive outcomes in the case of satellited 4p chromosomes; this may offer indirect support for a ribosomal gene position effect. Translocated ribosomal genes may influence the expression of neighboring genes and could explain the variable phenotypes in individuals with satellited nonacrocentric chromosomes. We recommend that prenatal counseling of individuals with satellited nonacrocentric chromosomes should be cautious.

Double NOR is not a good indicator of risk for Down syndrome

The silver staining technique was applied to study the nucleolar organizer regions (NORs) of 38 parents of children with Down syndrome and 40 parents of healthy offspring. Double NOR (dNOR) variants were found in both groups of parents. We compared the incidence of dNOR between these two groups. Our results indicate that different conclusions can be drawn from the same data depending on how the analyses are carried out. It seems to us that dNOR is not a useful marker for predicting whether or not its carrier is at a higher risk of having children with Down syndrome.

Acrocentric interconnections and NOR variants in human lymphocytes

Acrocentric interconnections and NOR (nucleolus organizer region) variants are frequently observed in silver-stained metaphase preparations from lymphocytes of phenotypically normal individuals. The types of interconnections and of NOR variants are outlined. It is speculated that the satellite acrocentrics (both normal and variant) are the consequence of breakage and recoiling of these interconnections. Awareness of these two features of the human genome may facilitate understanding of the NOR/nucleolus interaction(s) in such important processes as nucleolus formation and in development and/or diagnosis of disease states (i.e., malignancy).

Nucleolar structures in chromosome and SC preparations from human oocytes at first meiotic prophase

We describe a comparative study of the behavior of nucleolar structures and their relationship with nucleolar chromosomes and synaptonemal complexes at first meiotic prophase of human oocytes in an attempt to elucidate the nature of this cellular organization and to learn more about maternal nondisjunction. The number of main nucleoli varies along the different stages of prophase I and is usually low. It shows an increase from leptotene to pachytene and a decrease from pachytene to diplotene related to a decrease and an increase of main nucleoli volume, respectively. The methodology employed has enabled us to analyze in detail dark bodies, round bodies, dense bodies, and main nucleoli in chromosome or synaptonemal complex spreads. The relationship between nucleolar chromosomes or synaptonemal complexes and the nucleoli implies the existence, in a very reduced space, of chromosomal regions that contain homologous sequences and that are often unpaired. This situation may facilitate the production of heterologous pairing and chromosomal exchanges between nonhomologous chromosomes and finally result in aneuploidy. Thus, the situation explained above together with the differences between the oocyte and spermatocyte NOR cycles could be one of the reasons for the higher incidence of aneuploidies of maternal origin at meiosis I.

Variant nucleolus organizing regions and the risk of Down syndrome

In order to determine whether nucleolus organizing region (NOR) heteromorphisms of the acrocentric chromosomes could identify individuals at risk for having offspring with trisomy 21, a comparison was made between 43 parents of individuals with Down syndrome and 39 controls. NORs, as visualized by silver staining, were analyzed by mean number per cell, average size, total NOR "mass" per cell (designated mean score per cell) and by mean number of acrocentric chromosome satellite associations per cell. No "double NOR" variants (dNOR) were found in either the control or study group in contrast to observations of others (Jackson-Cook et al. 1985). The risk for having a child with trisomy correlated with a higher frequency of associations and number of NORs per cell, but slightly lower average NOR size. Although these group differences were statistically significant, specific types of NOR variants such as enlarged or dNORs were not associated with the risk of having trisomy 21 offspring. The constancy of NOR mass per cell in our control and study groups indicates that NOR activity remains constant, even though distribution of the rRNA genes (variation in number and size of NORs on the 10 acrocentrics) may vary.

Association of double NOR variant with Turner syndrome

A study was made of the possible association of double nucleolus organizers (dNORs) with Turner syndrome. Occurrence of dNORs was determined using the silver staining method of Goodpasture and Bloom [1975]. In 45 control subjects, the incidence of dNORs was 8.8%. Studies were done on 33 Turner syndrome patients. In 28 cases with 45,X or 45,X/46,XX karyotypes, the incidence of the dNOR variant was 50%. Five cases of Turner syndrome with X rings or X isochromosomes were negative for dNORs. Analysis of the data indicates an association between the dNOR variant and the occurrence of Turner syndrome. It is proposed that the presence of the dNOR variant can increase the rate of nondisjunction of the X chromosome in meiosis or in mitotic divisions during early gestation.