Sporadic aneuploidy in PHA-stimulated lymphocytes of Turner’s syndrome patients

Reish, Orit; Brosh, Nirit; Gobazov, Rima; Rosenblat, Malka; Libman, Vitalia; Mashevich, Maya

doi:10.1007/s10577-006-1050-9

Cited by 19 publications

(19 citation statements)

References 30 publications

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“…Various spindle abnormalities including abnormal shape, length, and chromosome loss from the spindle, presumably leading to chromosome malsegregation to the daughter cells was recently observed in a study using confocal laser scanning microscopy in embryos immunolabeled with antibodies against tubulin (54). These abnormal cell divisions can persist as long as the embryonic genome is not fully active and the cell cycle control is absent (59,60). Low level mosaicism could result in a viable fetus if a core of abnormal cells that form the fetus is overgrown by normal cells (32,40,61).…”

Section: Discussionmentioning

confidence: 92%

The cytogenetic constitution of embryos derived from immature (metaphase I) oocytes obtained after ovarian hyperstimulation

Strassburger

Goldstein

Friedler

et al. 2010

Fertility and Sterility

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Section: Discussionmentioning

confidence: 92%

The cytogenetic constitution of embryos derived from immature (metaphase I) oocytes obtained after ovarian hyperstimulation

Strassburger

Goldstein

Friedler

et al. 2010

Fertility and Sterility

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“…In addition, the few previous studies in which the issue has been addressed in nonneoplastic aneuploid cells, typically constitutional trisomy syndromes, have been confusing, even though constitutional aneuploidy ought to provide a cleaner system for studying the connection between chromosomal instability and aneuploidy than cancer cells. These studies also have shown very high frequencies (in excess of 20% when extrapolated to all chromosomes) of somatic aneuploidy in normal (control) blood lymphocytes, comparable with levels in cancerous cells (16,17). We hypothesized that these high estimates were at least partly caused by the high risk of finding cells falsely positive for aneuploidy when assessing minority cell populations in single-probe FISH experiments.…”

Section: Discussionmentioning

confidence: 94%

“…Such cells typically only have a single or a limited set of stem-line chromosome aberrations compared with tumor cell lines, which typically harbor a multitude of genetic lesions, as well as a cancer phenotype. The few earlier studies performed on patients with constitutional aneuploidy have shown high frequencies of additional somatic aneuploidy (somatic mosaicism) in peripheral blood lymphocytes (16,17), which may be interpreted as support for an immediate causal connection between aneuploidy and chromosomal instability. However, these studies are inconsistent, as healthy controls in one study showed a higher frequency of aneusomy than aneuploid cases in the other.…”

mentioning

confidence: 88%

Whole chromosome gain does not in itself confer cancer-like chromosomal instability

Valind

Jin

Baldetorp

et al. 2013

Proc. Natl. Acad. Sci. U.S.A.

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Constitutional aneuploidy is typically caused by a single-event meiotic or early mitotic error. In contrast, somatic aneuploidy, found mainly in neoplastic tissue, is attributed to continuous chromosomal instability. More debated as a cause of aneuploidy is aneuploidy itself; that is, whether aneuploidy per se causes chromosomal instability, for example, in patients with inborn aneuploidy. We have addressed this issue by quantifying the level of somatic mosaicism, a proxy marker of chromosomal instability, in patients with constitutional aneuploidy by precise backgroundfiltered dual-color FISH. In contrast to previous studies that used less precise methods, we find that constitutional trisomy, even for large chromosomes that are often trisomic in cancer, does not confer a significantly elevated rate of somatic chromosomal mosaicism in individual cases. Constitutional triploidy was associated with an increased level of somatic mosaicism, but this consisted mostly of reversion from trisomy to disomy and did not correspond to a proportionally elevated level of chromosome mis-segregation in triploids, indicating that the observed mosaicism resulted from a specific accumulation of cells with a hypotriploid chromosome number. In no case did the rate of somatic mosaicism in constitutional aneuploidy exceed that of "chromosomally stable" cancer cells. Our findings show that even though constitutional aneuploidy was in some cases associated with low-level somatic mosaicism, it was insufficient to generate the cancer-like levels expected if aneuploidy single-handedly triggered cancer-like chromosomal instability.neoplasia | Down syndrome | Edwards syndrome | Patau syndrome

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“…Another study from the same group PHA-stimulated lymphocytes from patients with monosomy X (Turner syndrome). The number of aneuploid cells in this monosomy was almost twice the control [21]. Interestingly, these studies observed more frequently monosomies than polysomies.…”

Section: The Effect Of Aneuploidy On Chromosome Instability In Mammalmentioning

confidence: 89%

Aneuploidy and chromosomal instability: a vicious cycle driving cellular evolution and cancer genome chaos

Potapova

Zhu

2013

Cancer Metastasis Rev

133

100

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Aneuploidy and chromosomal instability frequently co-exist, and aneuploidy is recognized as a direct outcome of chromosomal instability. However, chromosomal instability is widely viewed as a consequence of mutations in genes involved in DNA replication, chromosome segregation and cell cycle checkpoints. Telomere attrition and presence of extra centrosomes have also been recognized as causative for errors in genomic transmission. Here, we examine recent studies suggesting that aneuploidy itself can be responsible for the procreation of chromosomal instability. Evidence from both yeast and mammalian experimental models suggest that changes in chromosome copy number can cause changes in dosage of the products of many genes located on aneuploid chromosomes. These effects on gene expression can alter the balanced stoichiometry of various protein complexes, causing perturbations of their functions. Therefore, phenotypic consequences of aneuploidy will include chromosomal instability if the balanced stoichiometry of protein machineries responsible for accurate chromosome segregation is affected enough to perturb the function. The degree of chromosomal instability will depend on specific karyotypic changes, which may be due to dosage imbalances of specific genes or lack of scaling between chromosome segregation load and the capacity of the mitotic system. We propose that the relationship between aneuploidy and chromosomal instability can be envisioned as a “vicious cycle”, where aneuploidy potentiates chromosomal instability leading to further karyotype diversity in the affected population.

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Sporadic aneuploidy in PHA-stimulated lymphocytes of Turner’s syndrome patients

Cited by 19 publications

References 30 publications

The cytogenetic constitution of embryos derived from immature (metaphase I) oocytes obtained after ovarian hyperstimulation

The cytogenetic constitution of embryos derived from immature (metaphase I) oocytes obtained after ovarian hyperstimulation

Whole chromosome gain does not in itself confer cancer-like chromosomal instability

Aneuploidy and chromosomal instability: a vicious cycle driving cellular evolution and cancer genome chaos

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