Preferential occurrence of chromosome 21 malsegregation in peripheral blood lymphocytes of Alzheimer disease patients

To further investigate our finding of high levels of spontaneous aneuploidy in somatic cells of Alzheimer's disease (AD) patients (Migliore et al. 1997), we studied the molecular cytogenetics of eight patients with sporadic AD and six healthy controls of similar age. Cytochalasin B-blocked binucleated peripheral blood lymphocytes from the AD patients and unaffected controls were used to measure micronucleus induction or other aneuploidy events, such as the presence of malsegregation in interphase nuclei (representing chromosome loss and gain). Dual-color fluorescence in situ hybridization (FISH) with differential labeled DNA probes was applied. We used a probe specific for the centromeres of chromosomes 13 and 21 combined with a single cosmid for the Down's syndrome region (21q22.2) to obtain information on spontaneous chromosome loss and gain frequencies for both chromosomes (13 and 21). FISH data showed that AD lymphocytes had higher frequencies of chromosome loss (evaluated as fluorescently labeled micronuclei) for both chromosomes, as well as higher frequencies of aneuploid interphase nuclei, again involving both chromosomes, compared to control lymphocytes. However, aneuploidy for chromosome 21 was more frequent than for chromosome 13 in AD patients. This preferential occurrence of chromosome 21 in malsegregation in somatic cells of AD patients raises the hypothesis that mosaicism for trisomy of chromosome 21 could underlie the dementia phenotype in AD patients, as well as in elderly Down's syndrome patients.     

A monochromosomal hybrid cell assay for evaluating the genotoxicity of environmental chemicals

The development and utilization of a monochromosomal hybrid cell assay for detecting aneuploidy and chromosomal aberrations are described. The monochromosomal hybrid cell lines were produced by a two-step process involving transfer of a marker bacterial gene to a human chromosome and then by integration of that human chromosome into a mouse complement of chromosomes through microcell fusion. For chemically induced aneuploidy, the segregation of a single human chromosome among mouse chromosomes is used as a cytogenetic marker. The genetic assay for aneuploidy is based on the ability of the cells to grow in a medium that selects for the loss of the human chromosome. The assay for clastogenicity is based on survival of the cells after treatment with the chemicals in medium that selects for retention of the human chromosome but loss of its segment containing diphtheria toxin locus. The assays greatly simplify the detection of chromosomal aberrations induced by environmental factors at low-dose levels.     

Frequency and distribution of chromosome abnormalities in human oocytes

It was previously shown that more than half of the human oocytes obtained from IVF patients of advanced reproductive age are aneuploid, due to meiosis I and meiosis II errors. The present paper further confirms that 61.8% of the oocytes tested by fluorescent probes specific for chromosomes 13, 16, 18, 21 and 22 are abnormal, representing predominantly chromatid errors, which are the major source of aneuploidy in the resulting embryos. Almost half of the oocytes with meiosis I errors (49.3%) are prone to sequential meiosis II errors, which may lead to aneuploidy rescue in 30.8% of the cases. Half of the detected aneuploidies (49.8%) are of complex nature with involvement of two or more chromosomes, or the same chromosome in both meiotic divisions. The aneuploidy rates for individual chromosomes are different, with a higher prevalence of chromosome 21 and 22 errors. The origin of aneuploidy for the individual chromosomes is also not random, with chromosome 16 and 22 errors originating more frequently in meiosis II, and chromosome 18, 13 and 21 errors in meiosis I. There is an age dependence not only for the overall frequency of aneuploidies, but also for each chromosome error, aneuploidies originating from meiosis I, meiosis II, and both meiosis I and meiosis II errors, as well as for different types of aneuploidies. The data further suggest the practical relevance of oocyte aneuploidy testing for detection and avoidance from transfer of the embryos deriving from aneuploid oocytes, which should contribute significantly to the pregnancy outcomes of IVF patients of advanced reproduction age.     

Numerical chromosome variation and mitotic segregation defects in the adult brain of teleost fish

Teleost fish are distinguished by their enormous potential for the generation of new cells in both the intact and the injured adult brain. Here, we present evidence that these cells are a genetic mosaic caused by somatic genomic alteration. Metaphase chromosome spreads from whole brains of the teleost Apteronotus leptorhynchus revealed an euploid complement of 22 chromosomes in only 22% of the cells examined. The rate of aneuploidy is substantially higher in brain cells than in liver cells, as shown by both metaphase chromosome spreads and flow cytometric analysis. Among the aneuploid cells in the brain, approximately 84% had fewer, and the remaining 16% more, than 22 chromosomes. Typically, multiple chromosomes were lost or gained. The aneuploidy is putatively caused by segregation defects during mitotic division. Labeling of condensed chromosomes of M-phase cells by phosphorylated histone-H3 revealed laggards, anaphase bridges, and micronuclei, all three of which indicate displaced mitotic chromosomes. Quantitative analysis has shown that in the entire brain on average 14% of all phosphorylated histone-H3-labeled cells exhibit such signs of segregation defects. Together with the recent discovery of aneuploidy in the adult mammalian brain, the results of the present investigation suggest that the loss or gain of chromosomes might provide a mechanism to regulate gene expression during development of new cells in the adult vertebrate brain.     

Chromosome analysis of blastomeres from human embryos by using comparative genomic hybridization

Karyotypic studies of aborted fetuses have been used to draw the inference that the proportion of conceptuses with chromosome abnormalities is very high. Fluorescent in situ hybridization (FISH) studies of blastomeres from early cleavage embryos have provided some support for this inference but they are limited to the study of a few chromosomes. We describe the novel application of comparative genomic hybridization (CGH) to the study of numerical and structural abnormalities of single blastomeres from disaggregated 3-day-old human embryos. CGH results were obtained for 63 blastomeres from 12 embryos. Identification of all chromosomes with the exception of chromosomes 17, 19, 20 and 22 was possible. The embryos divided into four groups: (1) embryos with a normal CGH karyotype seen in all blastomeres; (2) embryos with consistent aneuploidy suggesting meiotic non-disjunction had occurred; (3) embryos that were mosaic generally with one or more cells showing aneuploidy for one or two chromosomes but some with cells showing extensive aneuploidy; and (4) one embryo with extensive aneuploidy in all blastomeres. The extensive aneuploidy in group 4 is interpreted as corresponding to the random aneuploidy seen in "chaotic" embryos reported by using interphase FISH. Partial chromosome loss and gain following chromosome breakage was observed in one embryo. Our analysis provides basic biological information on the occurrence of constitutional and post-zygotic chromosome abnormalities in early human embryos. Used in conjunction with embryo biopsy, diagnostic CGH should allow the exclusion of a proportion of embryos that appear normal but that have a poor probability of survival and, therefore, may improve the implantation rate after in vitro fertilization.     

Total aneuploidy and age-related sex chromosome aneuploidy in cultured lymphocytes of normal men and women

Summary In PHA-cultured lymphocytes, about 8% of metaphases from 32 women were aneuploid compared to 4% of metaphases from 35 men. A significant part of this aneuploidy was characterized by sex chromosome involvement: in women, the loss or gain of X chromosomes; in men, the gain of X chromosomes and the loss or gain of Y chromosomes. The incidence of this aneuploidy was positively age-related for both sexes. Premature division of the X-chromosome centromere was closely associated with X-chromosome aneuploidy in women and men, and appeared to be the mechanism of nondisjunction causing this aneuploidy. Premature centromere division (PCD) indicated a dysfunction of the X-chromosome centromere with aging, and this dysfunction was the basic cause of age-related aneuploidy. A similar mechanism of nondisjunction may operate for the Y chromosome of men, but could not be clearly demonstrated because of the low incidence of Y-chromosome aneuploidy.The balance of the aneuploidy was characterized by chromosome loss and the involvement of all chromosome groups. It was consistent with chromosome loss from metaphase cells damaged during preparation for cytogenetic examination.     

Endomembranes promote chromosome missegregation by ensheathing misaligned chromosomes

Errors in mitosis that cause chromosome missegregation lead to aneuploidy and micronucleus formation, which are associated with cancer. Accurate segregation requires the alignment of all chromosomes by the mitotic spindle at the metaphase plate, and any misalignment must be corrected before anaphase is triggered. The spindle is situated in a membrane-free “exclusion zone”; beyond this zone, endomembranes (mainly endoplasmic reticulum) are densely packed. We investigated what happens to misaligned chromosomes localized beyond the exclusion zone. Here we show that such chromosomes become ensheathed in multiple layers of endomembranes. Chromosome ensheathing delays mitosis and increases the frequency of chromosome missegregation and micronucleus formation. We use an induced organelle relocalization strategy in live cells to show that clearance of endomembranes allows for the rescue of chromosomes that were destined for missegregation. Our findings indicate that endomembranes promote the missegregation of misaligned chromosomes that are outside the exclusion zone and therefore constitute a risk factor for aneuploidy.     

植物非整倍体研究进展

非整倍体(aneuploid)是指相对于正常个体(euploid)的染色体组增加、减少一条或若干条染色体的生物个体。由于非整倍体个体存在基因剂量效应的不平衡性(gene-dosage imbalance),非整倍体个体往往会表现严重的表型缺陷(aneuploid syndrom),如发育迟缓,个体矮小,难以繁殖后代等。在人类中,最为典型的例子为导致新生儿智力缺陷的唐氏综合症,由额外的一个21号染色体拷贝(部分拷贝)引起。此外,大多数癌细胞类型表型为严重的非整倍体。在大多情况下,非整倍体对于动物及人类是致命的,而植物对于非整倍体则往往表现出较强的耐受力,特别是在异源多倍体植物中。植物非整倍体对于植物的遗传、育种研究有重要意义,在基因及分子标记的物理位置确定,基因转移,连锁群与染色体的对应关系的确立上具有无可比拟的优势。该文综述了近些年来有关植物非整倍体研究的结果,介绍了非整倍体的几种重要成因和有关非整倍体鉴定手段的变迁,阐述了植物非整倍体对个体表型、基因表达以及表观遗传方面的影响,重点讨论了非整倍体在植物进化、基因组序列测定以及遗传改良方面的潜在作用。同时,探讨了植物非整倍体研究的新思路,以及利用非整倍体促进相关植物遗传改良、育种研究的新方法。     

The frequency of aneuploidy among individual chromosomes in 6,821 human sperm chromosome complements

The human sperm/hamster egg fusion technique has been used to analyse 6,821 human sperm chromosome complements from 98 men to determine if all chromosomes are equally likely to be involved in aneuploid events or if some chromosomes are particularly susceptible to nondisjunction. The frequency of hypohaploidy and hyperhaploidy was compared among different chromosome groups and individual chromosomes. In general, hypohaploid sperm complements were more frequent than hyperhaploid complements. The distribution of chromosome loss in the hypohaploid complements indicated that significantly fewer of the large chromosomes and significantly more of the small chromosomes were lost, suggesting that technical loss predominantly affects small chromosomes. Among the autosomes, the observed frequency of hyperhaploid sperm equalled the expected frequency (assuming an equal frequency of nondisjunction for all chromosomes) for all chromosome groups. Among individual autosomes, only chromosome 9 showed an increased frequency of hyperhaploidy. The sex chromosomes also showed a significant increase in the frequency of hyperhaploidy. These results are consistent with studies of spontaneous abortions and liveborns demonstrating that aneuploidy for the sex chromosomes is caused by paternal meiotic error more commonly than aneuploidy for the autosomes.     

The relationship between male infertility and increased levels of sperm disomy

Sperm chromosome abnormalities cut across a number of areas relevant to ICC XV. The association between increased levels of sperm aneuploidy (usually disomy) and male infertility has implications for the sessions on reproduction, sex chromosomes, aneuploidy and meiosis and was, to the best of our knowledge, first reported in 1995. Since then most studies have reported similar increases of varying degrees but, despite this, a small number of laboratories have presented results that demonstrate no significant association. The purpose of this article is to review the state of the art in this area and to speculate as to reasons for the differences in reports from different laboratories. The findings are broken down by chromosome with studies of the sex chromosomes being broken down further to indicate meiotic stages of origin. We conclude that comparisons are difficult to make since many studies do not clearly define patient and control groups. Nevertheless, despite these and other differences (such as scoring criteria, technical differences, demographics, etc.), the consensus in the literature is that a strong correlation exists between sperm aneuploidy and male infertility. The nature of that relationship will be further defined when andrological criteria are more closely taken into account and protocols for preparation and scoring are standardised.     

Folate deficiency induces aneuploidy in human lymphocytes in vitro-evidence using cytokinesis-blocked cells and probes specific for chromosomes 17 and 21

Folate plays a critical role in the prevention of chromosome breakage and hypomethylation of DNA. Deficiency in this vitamin may lead to demethylation of heterochromatin causing structural centromere defects that could induce abnormal distribution of replicated chromosomes during nuclear division. Because aneuploidy of chromosomes 17 and 21 is often observed in breast cancer and leukaemia and increased risk for these cancers is associated with folate deficiency, we hypothesized that folate deficiency may lead to aneuploidy of chromosomes 17 and 21. To test these hypotheses we cultured lymphocytes from eight female volunteers (aged 40-48 years) in RPMI 1640 medium containing 12 or 120nM of folic acid (FA) or 5-methyltetrahydrofolate (MF) for 9 days. Chromosomes 17 and 21 aneuploidies induced by folate deficiency were measured in mononucleated (MONO) and cytokinesis-blocked binucleated (BN) lymphocytes after dual-color fluorescent in situ hybridization (FISH) with a digoxigenin-labeled probe for the alphoid satellite sequence of chromosome 17 and a biotin-labeled probe for the pericentric region of chromosome 21. The results showed that 12nm of MF or FA caused a significant 26-35% increment in frequency of aneuploidy of chromosome 17 (P = 0.0017) and aneupoidy of chromosome 21 (P = 0.0008) relative to 120nM MF or FA. The pattern of aneuploidy in binucleated cells was significantly correlated with that observed in mononucleated cells (R = 0.51-0.75, P < 0.0004) and was consistent with a model based on chromosome loss or partial aneusomy rescue as the cause rather than non-disjunction, although the latter mechanism could not be excluded. MF was not more efficient than FA in preventing aneuploidy in this in vitro system. We conclude that folate deficiency is a risk factor for chromosomes 17 and 21 aneuploidy.     

A combination of the micronucleus assay and a FISH technique for evaluation of the genotoxicity of 1,2,4-benzenetriol

The cytokinesis-block micronucleus (CBMN) assay has emerged as one of the preferred methods for assessing chromosome damage. Micronuclei (MN) are small, extranuclear bodies that are formed in mitosis from acentric chromosomal fragments or chromosomes that are not included in each daughter nucleus. Thus, MN contain either chromosomal fragments or whole chromosomes. The CBMN assay, together with a fluorescence in situ hybridization (FISH) technique using specific centromeric probes for chromosomes 7 and 8, were employed in mitogen-stimulated human lymphocytes pretreated with the benzene metabolite, 1,2,4-benzenetriol (BT). Treatment of human lymphocytes resulted in the induction of MN in a dose-dependent manner. The frequency of MN in control lymphocytes was 4.5 per 1000 binucleated (BN) cells and this increased to 9.5, 14, 28 and 40 per 1000 BN cells at 10, 25, 50 and 100 microM BT, respectively. The frequency of aneuploidy 7 and 8 in BN cells also increased at each concentration. Aneuploidy 8 was more frequent than aneuploidy 7, suggesting that chromosome 8 is more sensitive to aneuploidy induction by BT. The frequency of MN containing centromere positive signals for chromosomes 7 and 8 increased with the concentration of BT. The frequency of MN with centromere positive signals was higher for chromosome 8 than for chromosome 7, also suggesting a greater sensitivity of chromosome 8 to this agent. These results suggest that combined application of the CBMN assay with a FISH technique, using chromosome-specific centromeric probes, would allow the detection of aneuploidy in human lymphocytes and identify the mechanistic origin of MN induced by a clastogen or aneugen.     

Does human oocyte cryopreservation affect equally on embryo chromosome aneuploidy?

Oocytes cryopreservation as an important part of assisted reproductive technologies, which should ensure after warming not only intact oocyte morphological characteristics, but also their genetic apparatus stability. However, the meiotic spindle is very sensitive to the temperature fluctuations that can lead to unequal chromosome segregation during meiosis and as a consequence can cause embryo aneuploidy after oocyte fertilization. The aim of the study was to estimate the oocytes cryopreservation impact on human embryo chromosome aneuploidy. It has been shown that fertilization rate of the cryopreserved oocytes did not differ from fresh ones (83.1% vs 84% respectively). The number of blastocysts obtained from cryopreserved oocytes was less than that obtained from fresh oocytes, however, their morphological characteristics were better if compared the fresh oocytes. Our results showed different cryopreservation impact on aneuploidy rates of certain chromosomes in embryos obtained from cryopreserved oocytes. They had an increased aneuploidy of chromosome 13 and a decreased nondisjunction of chromosome 18 and sex chromosomes.     

Aneuploidy and tumorigenesis

Aneuploidy is a prominent phenotype of cancer. It refers to deviations from the normal number of chromosomes in a cell, as a result of whole-chromosome loss or gain. In most cases, aneuploidy is caused by mitotic errors due to defects in the mechanisms that have evolved to ensure faithful chromosome segregation, such as the spindle assembly checkpoint (SAC). The observation that SAC-deficient mice are tumor prone demonstrates that this checkpoint is important in suppressing tumor formation and suggests that aneuploidy can induce tumorigenesis. In this review, we will summarize our current knowledge about the cause of aneuploidy and discuss the cellular response to aneuploidy in the context of tumorigenesis.     

Distributive pairing of chromosomes and aneuploidy in man]

The up-to-date state of human cytogenetics allows to turn back to hypothesis of distributive pairing as a strongly fruitful for resolving a number of problems concerning etiology of chromosome aneuploidy. Distributive pairing could account for such phenomena as: 1. Prevalence of nondisjunction (ND) in the first meiosis, compared with the second; 2. Excess of males among children with the Down syndrome; 3. Recurrent cases of aneuploidy, including aneusomies for different chromosomes; 4. Appearance of individuals with double aneusomies; 5. High recurrent risk for young parents; 6. Increased chance of ND for chromosomes not involved in rearrangement in carriers of balanced translocations; 7. Increased frequency of ND of autosomes in individuals with quantitative and structural sex chromosome anomalies; 8. The role of heterochromatic regions in ND; 9. Increased frequency of spontaneous abortions in couples having children with chromosome anomalies and in persons with unusual heterochromatic variants. The hypothesis could predict: 1. Essential contribution of errors in gonial cells to the origin of aneuploidy; 2. Important role of the factors influencing the prophase; 3. The possibility of offering forecast for sex chromosome anomalies rate on the basis of trisomy 21 rate, due to the fact that both autosomal and gonosomal aneuploidies have to be induced by the same factors.     

Crossover Interference,Crossover Maturation,and Human Aneuploidy

A striking feature of human female sexual reproduction is the high level of gametes that exhibit an aberrant number of chromosomes (aneuploidy). A high baseline observed in women of prime reproductive age is followed by a dramatic increase in older women. Proper chromosome segregation requires one or more DNA crossovers (COs) between homologous maternal and paternal chromosomes, in combination with cohesion between sister chromatid arms. In human females, CO designations occur normally, according to the dictates of CO interference, giving early CO‐fated intermediates. However, ≈25% of these intermediates fail to mature to final CO products. This effect explains the high baseline of aneuploidy and is predicted to synergize with age‐dependent cohesion loss to explain the maternal age effect. Here, modern advances in the understanding of crossing over and CO interference are reviewed, the implications of human female CO maturation inefficiency are further discussed, and areas of interest for future studies are suggested.     

Meiotically asynapsis-induced aneuploidy in autopolyploid Arabidopsis thaliana

The patterns of homologue segregation are the basis for euploidy or aneuploidy formation in diploids and allo-/auto-polyploids. Homologue segregation in diploids resembles that in allopolyploids during meiosis; however, meiotic chromosome behavior in autopolyploids is complicated by multiplication of homologous chromosome components. Obviously, loss of single chromosomes (or segmented chromosomes) frequently leads to abortion of reproductive gametes in diploids and allopolyploids. In contrast, the consequence of chromosome loss in autopolyploids is effortlessly compensated for by the presence of multiplied chromosome complements. Here, we use the meiotically asynaptic gene asy1, in combination with polyploidization, to elucidate aneuploidy formation in autotetraploid Arabidopsis. The results indicate that, due to homologous asynapsis in meiotic prophase I, retarded chromosome losses could induce aneuploidy during gametogenesis in autotetraploid asy1. The severe loss of individual chromosomes probably reaches the haploid genome among selfed or backcrossed progeny, leading to stochastic chromosome loss in Arabidopsis. Reciprocal crosses of autotetraploid asy1 with wild-type prove a pathway of duoparental transmission of aneuploidy (hypoploidy and hyperploidy). Viable hypoploids over-transmit via male gametes; conversely, viable hyperploids transmit mainly in female gametogenesis. This result suggests a more stringent maternal restriction of ploidy transmission in autopolyploid Arabidopsis.     

Mechanisms of aneuploidy induction in human oogenesis and early embryogenesis

The mechanisms of aneuploidy induction in human oogenesis mainly involve nondisjunction arising during the first and second meiotic divisions. Nondisjunction equally affects both whole chromosomes and chromatids, in the latter case it is facilitated by "predivision" or precocious centromere division. Karyotyping and CGH studies show an excess of hypohaploidy, which is confirmed in studies of preimplantation embryos, providing evidence in favour of anaphase lag as a mechanism. Preferential involvement of the smaller autosomes has been clearly shown but the largest chromosomes are also abnormal in many cases. Overall, the rate of chromosomal imbalance in oocytes from women aged between 30 and 35 has been estimated at 11% from recent karyotyping data but accruing CGH results suggest that the true figure should be considerably higher. Clear evidence has been obtained in favour of germinal or gonadal mosaicism as a predisposing factor. Constitutional aneuploidy in embryos is most frequent for chromosomes 22, 16, 21 and 15; least frequently involved are chromosomes 14, X and Y, and 6. However, embryos of women under 37 are far more likely to be affected by mosaic aneuploidy, which is present in over 50% of 3-day-old embryos. There are two main types, diploid/aneuploid and chaotic mosaics. Chaotic mosaics arise independently of maternal age and may be related to centrosome anomalies and hence of male origin. Aneuploid mosaics most commonly arise by chromosome loss, followed by chromosome gain and least frequently by mitotic nondisjunction. All may be related to maternal age as well as to lack of specific gene products in the embryo. Partial aneuploidy as a result of chromosome breakage affects a minimum of 10% of embryos.     

Too much to handle — how gaining chromosomes destabilizes the genome

Most eukaryotic organisms are diploid, with 2 chromosome sets in their nuclei. Whole chromosomal aneuploidy, a deviation from multiples of the haploid chromosome number, arises from chromosome segregation errors and often has detrimental consequences for cells. In humans, numerical aneuploidy severely impairs embryonic development and the rare survivors develop disorders characterized by multiple pathologies. Moreover, as many as 75 % of malignant tumors display aneuploidy. Although the exact contribution of aneuploidy to tumorigenesis remains unclear, previous studies have suggested that aneuploidy may affect the maintenance of genome integrity. We found that human cells with extra chromosomes showed phenotypes suggestive of replication defects, a phenomenon which we went on to characterize as being due to the aneuploidy-driven downregulation of replication factors, in particular of the replicative helicase MCM2-7. Thus, missegregation of even a single chromosome can further promote genomic instability and thereby contribute to tumor development. In this review we will examine the possible causes of downregulation of replicative factors and discuss the consequences of genomic instability in aneuploid cells.