Chromosomal control of early embryonic development in mice I. Experiments on embryos with autosomal monosomy

The effects of autosomal monosomy on early embryonic development were studied in mice with Robertsonian and reciprocal (non-Robertsonian) translocations. It was found that monosomy for autosomes 1, 2, 3, 5, 6, 16, 17 and 19 had substantially different effects on preimplantation development and survival of mouse embryos. Monosomy for autosomes 1, 3, 6, 16 and 19 does not affect cleavage, compaction and blastulation and in some cases is compatible with implantation. Most of these embryos, however, die as early blastocysts (Ms 3, 6 or 19) and some of them are eliminated at early postimplantation stages (Ms 1 or 16). The embryos with monosomy for autosomes 2, 5 or 17 can be identified during cleavage owing to the reduced blastomere number and pathological changes in the nuclei. Most of these monosomies do not survive beyond the morula stage. The results indicate that differential genetic activity of autosomes in mice becomes already evident in very early embryonic development. A hypothetical mechanism for homologous autosome activation at the onset of embryonic development in mice is suggested.     

Chromosomal control of early mammalian development

A review of recent studies on mammalian embryos, mostly mice, with chromosomal aberrations. Morphological, biochemical and cytological studies on mice with polyploidy, aneuploidy and some structural aberrations are discussed. Some types of chromosomal aberrations, especially monosomy for individual chromosomes (2, 5, 7, or 17), are already evident during early cleavage and are inevitably lethal by the morula stage. A direct relationship exists between the duration of survival and chromosome aberrations (trisomy and monosomy) for every chromosome. Differential gene activity of the mouse autosomes becomes evident already at the very early developmental stages. Some feasible causes of the early death of embryos with autosomal monosomy are discussed and a hypothetical mechanism for the activation of homologous autosomes at the early developmental stages is proposed. Perspectives of future studies in cytogenetics of mammalian development are outlined.     

Trisomy of an autosome in mice heterozygous by a Robertson translocation]

From 866 embryos of mice heterozygous by Roberstsonian translocations 54 ones (6,2%) had trisomy of one of translocated chromosomes. The frequency of trisomy is unique for each translocation, dependent on other chromosomal redistributions in the karyotype and on sex of heterozygous individuals. Trisomy of all the autosomes studied (N 1, 5, 8, 9, 14, 15, 17, 19) results in a characteristic complex of non-specific malformations which includes general delay in development, reduction of the cephalic portion of the nervous tube, cranio-fascial malformations, hypertrophy of the heart cavities. In a number of cases autosomal trisomy (N 15,8) is responsible for certain specific disturbances of morphogenesis. The excess of majority of autosomes (N 5, 8, 9, 15, 16 and 17) causes death of embryos in the period of active organogenesis. Embryos with trisomy of the 1st, 14th and 19th pairs of autosomes in certain cases reach the fetal period but have severe malformations and are non-survival. In mice karyotype there seems to be no autosomes whose trisomy is compatible with postnatal development. Signs of similarity and difference in manifestation of numericle chromosomal aberrations were noted in embryogenesis of mice and man. Principle possibility of modelling chromosomal embryopathy of man in mice with Robertsonian translocations is supposed.     

Sporadic aneuploidy in PHA-stimulated lymphocytes of trisomies 21, 18, and 13

Following the observation detected in a previous study that X chromosome monosomy in Turner's syndrome genotypes was associated with a sporadic loss and/or gain of other chromosomes, we studied here whether this instability is a consistent finding in constitutional autosomal trisomies. We used PHA-stimulated lymphocytes derived from 14 patients (10 patients with trisomy 21, 2 with trisomy 18, and 2 with trisomy 13). Fourteen healthy controls were compared. Fluorescence in situ hybridization, applied at interphase cells, was used to evaluate the level of aneuploidy for 3 randomly selected chromosomes (autosomes 8, 15, and 16) in each sample. For each tested chromosome, our results showed a significantly higher level of aneuploid cells in the samples from the patients than in those from controls, with no difference between the patient groups. The mean level of aneuploid cells (percentage) for all 3 tested autosomes was almost twice as high in the patient samples as in the control samples. The aneuploidy level was mainly due to monosomy, which was significantly higher in the samples from the patients than in those from controls for each one of the tested chromosomes, with no difference between the patient groups. The mean level of monosomic cells (percentage) for all 3 tested chromosomes was almost twice as high in the patient samples as in the control samples. Our study shows that various constitutional autosomal trisomies are associated with an increased frequency of non-chromosome specific aneuploidy and is a continuation of the previous study documenting sporadic aneuploidy in Turner's sample cells. It is possible that primary aneuploid cells destabilize their own genome resulting in variable aneuploidy of other chromosomes. It is also possible that one or several common factor(s) is/are involved in both constitutional and sporadic aneuploidy.     

The in vitro survival of human monosomies and trisomies as embryonic stem cells

Chromosomal aneuploidies are responsible for severe human genetic diseases. Aiming at creating models for such disorders, we have generated human embryonic stem cell (hESC) lines from pre-implantation genetic screened (PGS) embryos. The overall analysis of more than 400 aneuploid PGS embryos showed a similar risk of occurrence of monosomy or trisomy for any specific chromosome. However, the generation of hESCs from these embryos revealed a clear bias against monosomies in autosomes. Moreover, only specific trisomies showed a high chance of survival as hESC lines, enabling us to present another categorization of human aneuploidies. Our data suggest that chromosomal haploinsufficiency leads to lethality at very early stages of human development.     

The probability of fusions joining sex chromosomes and autosomes

Chromosome fusion and fission are primary mechanisms of karyotype evolution. In particular, the fusion of a sex chromosome and an autosome has been proposed as a mechanism to resolve intralocus sexual antagonism. If sexual antagonism is common throughout the genome, we should expect to see an excess of fusions that join sex chromosomes and autosomes. Here, we present a null model that provides the probability of a sex chromosome autosome fusion, assuming all chromosomes have an equal probability of being involved in a fusion. This closed-form expression is applicable to both male and female heterogametic sex chromosome systems and can accommodate unequal proportions of fusions originating in males and females. We find that over 25% of all chromosomal fusions are expected to join a sex chromosome and an autosome whenever the diploid autosome count is fewer than 16, regardless of the sex chromosome system. We also demonstrate the utility of our model by analysing two contrasting empirical datasets: one from Drosophila and one from the jumping spider genus Habronattus. We find that in the case of Habronattus, there is a significant excess of sex chromosome autosome fusions but that in Drosophila there are far fewer sex chromosome autosome fusions than would be expected under our null model.     

Detection of Aneuploidy in Spontaneous Abortions Using Comparative Genomic Hybridization

Comparative genomic hybridization (CGH) technique was used to examine a set of ten spontaneous abortions whose cell cultures were characterized by the lack of proliferation in vitro, and thereby, were not available for the analysis by means of routine cytogenetic methods. Five abortions (50%) had aneuploidy of autosomes, including trisomy 10, 14, 18, and 21, and monosomy 22. The latter variant of unbalanced chromosomal abnormalities is rarely detected in spontaneous abortions by use of conventional cytogenetic methods. The results were validated by using fluorescent in situ hybridization (FISH) analysis with centromere-specific DNA probes. Embryos with trisomy 10 and monosomy 22 displayed mosaicism with the frequencies of abnormal cell clones constituting 68 and 33% respectively. The advantages and limitations of the applying of CGH technique for detection of genomic abnormalities in both nonmosaic and mosaic forms are discussed.     

Detection of aneuploidy in spontaneous abortions using the comparative hybridization method

Comparative genomic hybridization (CGH) technique was used to examine a set of ten spontaneous abortions whose cell cultures were characterized by the lack of proliferation in vitro, and thereby, were not available for the analysis by means of routine cytogenetic methods. Five abortions (50%) had aneuploidy of autosomes, including trisomy 10, 14, 18, and 21, and monosomy 22. The latter variant of unbalanced chromosomal abnormalities is rarely detected in spontaneous abortions by use of conventional cytogenetic methods. The results were validated by using fluorescent in situ hybridization (FISH) analysis with centromere-specific DNA probes. Embryos with trisomy 10 and monosomy 22 displayed mosaicism with the frequencies of abnormal cell clones constituting 68 and 33% respectively. The advantages and limitations of the applying of CGH technique for detection of genomic abnormalities in both nonmosaic and mosaic forms are discussed.     

Crossover distribution and high interference for both the X chromosome and an autosome during oogenesis and spermatogenesis in Caenorhabditis elegans

Regulation of both the number and the location of crossovers during meiosis is important for normal chromosome segregation. We used sequence-tagged site polymorphisms to examine the distribution of all crossovers on the X chromosome during oogenesis and on one autosome during both oogenesis and spermatogenesis in Caenorhabditis elegans. The X chromosome has essentially one crossover during oogenesis, with only three possible double crossover exceptions among 220 recombinant X chromosomes. All three had one of the two crossovers in the same chromosomal interval, suggesting that crossovers in that interval do not cause interference. No other interval was associated with double crossovers. Very high interference was also found on an autosome during oogenesis, implying that each chromosome has only one crossover during oogenesis. During spermatogenesis, recombination on this autosome was reduced by approximately 30% compared to oogenesis, but the relative distribution of the residual crossovers was only slightly different. In contrast to previous results with other autosomes, no double crossover chromosomes were observed. Despite an increased frequency of nonrecombinant chromosomes, segregation of a nonrecombinant autosome during spermatogenesis appears to occur normally. This indicates that an achiasmate segregation system helps to ensure faithful disjunction of autosomes during spermatogenesis.     

Aneuploidy analysis of non-pronuclear embryos from IVF with use of array CGH: a case report

By using array comparative genomic hybridization (array CGH), to analyze the aneuploidy of the single blastomeres from non-pronuclear embryos on cleavage-stage in IVF cycle. Four non-pronuclear embryos were got from an IVF cycle, and the each single cell was biopsied from the four cleavage-stage embryos on the third day after the insemination which was investigated by using array CGH. After the biopsy, all the embryos continued to cleave, and lately entered the morula stage on the fifth day, just one embryo 3 was developed to early blastocyst stage on the sixth day. The four blastomere 24 chromosomes showed one X monomer and three normal XY diploids; the autosome chromosomes of blastomeres were abnormally gained or lost at different chromosome from four embryos, such as Embryo 1 : 49,X (?1, ?5, ?11, ?19, ?20, ?21, ?Y, +3, +6, +7, +8, +10, +13, +14, +16, +17, +18); Embryo 2 : 44,XY (?12, ?15); Embryo 3: 47,XY (?3, ?8, ?9, ?21, +7, +17, +18, +19, +20); Embryo 4 : 54,XY (+4, +7, +10, +12, +13, +16, +17, +22). With the use of the array CGH, the aneuploidy analysis could review the abnormal chromosomes of single blastomere from the non-pronuclear embryos, which can harbor the risk of abnormal sex chromosome and autosome chromosomes.     

Chromosome studies in human in vitro fertilization

Summary The chromosome constitution of 22 human preimplantation embryos from donor oocytes fertilized in vitro by donor sperm was studied to assess the contribution of lethal chromosome anomalies to the high failure rate of implantation of in vitro fertilized embryos after embryo transfer in infertile women. Evidence was found of nondisjunction, resulting in trisomy, monosomy, and nullosomy; structural abnormalities; haploidy; and triploidy. Despite the lethality of their chromosome complements, these embryos could not be distinguished morphologically from those with normal chromosomes.     

Double autosomal chromosomal aberration (3p trisomy/9p monosomy) and sex-reversal

A 26-year-old girl with multiple congenital malformations, sex-reversal, and partial trisomy 3p/monosomy 9p is described. A possible influence of autosome aberrations on sexual differentiation is discussed.     

Genomic changes following the reversal of a Y chromosome to an autosome in Drosophila pseudoobscura

Robertsonian translocations resulting in fusions between sex chromosomes and autosomes shape karyotype evolution by creating new sex chromosomes from autosomes. These translocations can also reverse sex chromosomes back into autosomes, which is especially intriguing given the dramatic differences between autosomes and sex chromosomes. To study the genomic events following a Y chromosome reversal, we investigated an autosome‐Y translocation in Drosophila pseudoobscura. The ancestral Y chromosome fused to a small autosome (the dot chromosome) approximately 10–15 Mya. We used single molecule real‐time sequencing reads to assemble the D. pseudoobscura dot chromosome, including this Y‐to‐dot translocation. We find that the intervening sequence between the ancestral Y and the rest of the dot chromosome is only ～78 Kb and is not repeat‐dense, suggesting that the centromere now falls outside, rather than between, the fused chromosomes. The Y‐to‐dot region is 100 times smaller than the D. melanogaster Y chromosome, owing to changes in repeat landscape. However, we do not find a consistent reduction in intron sizes across the Y‐to‐dot region. Instead, deletions in intergenic regions and possibly a small ancestral Y chromosome size may explain the compact size of the Y‐to‐dot translocation.     

C-Banding/DAPI and in situ hybridization reflect karyotype structure and sex chromosome differentiation in Humulus japonicus Siebold & Zucc

Japanese hop (Humulus japonicus Siebold & Zucc.) was karyotyped by chromosome measurements, fluorescence in situ hybridization with rDNA and telomeric probes, and C-banding/DAPI. The karyotype of this species consists of sex chromosomes (XX in female and XY1Y2 in male plants) and 14 autosomes difficult to distinguish by morphology. The chromosome complement also shows a rather monotonous terminal distribution of telomeric repeats, with the exception of a pair of autosomes possessing an additional cluster of telomeric sequences located within the shorter arm. Using C-banding/DAPI staining and 5S and 45S rDNA probes we constructed a fluorescent karyotype that can be used to distinguish all autosome pairs of this species except for the 2 largest autosome pairs, lacking rDNA signals and having similar size and DAPI-banding patterns. Sex chromosomes of H. japonicus display a unique banding pattern and different DAPI fluorescence intensity. The X chromosome possesses only one brightly stained AT-rich terminal segment, the Y1 has 2 such segments, and the Y2 is completely devoid of DAPI signal. After C-banding/DAPI, both Y chromosomes can be easily distinguished from the rest of the chromosome complement by the increased fluorescence of their arms. We discuss the utility of these methods for studying karyotype and sex chromosome evolution in hops.     

Distribution of heterochromatin on the mitotic chromosomes of Musca domestica L. in relation to the activity of male-determining factors

In the housefly, male sex is determined by a dominant factor, M, located either on the Y, on the X, or on any of the five autosomes. M factors on autosome I and on fragments of the Y chromosome show incomplete expressivity, whereas M factors on the other autosomes are fully expressive. To test whether these differences might be caused by heterochromatin-dependent position effects, we studied the distribution of heterochromatin on the mitotic chromosomes by C-banding and by fluorescence in situ hybridization of DNA fragments amplified from microdissected mitotic chromosomes. Our results show a correlation between the chromosomal position of M and the strength of its male-determining activity: weakly masculinizing M factors are exclusively located on chromosomes with extensive heterochromatic regions, i.e., on autosome I and on the Y chromosome. The Y is known to contain at least two copies of the M factor, which ensures a strong masculinizing effect despite the heterochromatic environment. The heterochromatic regions of the sex chromosomes consist of repetitive sequences that are unique to the X and the Y, whereas their euchromatic parts contain sequences that are ubiquitously found in the euchromatin of all chromosomes of the complement. Received: 20 February 1998; in revised form: 11 May 1998 / Accepted: 23 May 1998     

A retrospective study of preimplantation embryos diagnosed with monosomy by fluorescence in situ hybridization (FISH)

This report is a retrospective study of preimplantation embryos diagnosed with monosomy for chromosomes 13, 15, 16, 18, 21, 22, X and Y on day 3 to determine the rate of true positives, false positives and/or mosaicism and to assess if these embryos are suitable for in vitro fertilization (IVF) transfer. In a one year period, 80 patients went through preimplantation genetic diagnosis for aneuploidy screening (PGD-AS). Monosomy was diagnosed in 51 embryos. Fluorescence in situ hybridization (FISH) was then performed on the blastomeres at day 5-7 with commercially available probes using the same probe set that initially identified monosomy for chromosomes 13, 16, 21 and 22 or chromosomes 15, 18, X and Y. Based on FISH analysis, the monosomy diagnosed during routine PGD-AS analysis was confirmed in 17 of the 51 embryos. A euploid result for the specific chromosomes tested was observed in 16 of the 51 embryos while mosaicism was found in the remaining 18 embryos. This results in an estimated false positive rate of 3.8% for a diagnosis of monosomy. Reanalysis of these embryos demonstrates that the majority of monosomy diagnoses represents true monosomy or mosaicism and should be excluded for transfer in IVF. Furthermore, improved understanding from recent emerging data regarding the fate of oocytes in women with advanced maternal age undergoing IVF to the development of early embryos may provide a valuable insight into the mechanism of chromosome mosaicism.     

Characteristics of phenotypic expression of autosomal monosomies during pathological postimplantation human development

Autosomal monosomies represent a severe form of genomic disbalance which determines elimination of human embryos already at the preimplantation stages. As a rule, they occur very rarely in the materials of spontaneously aborted embryos and fetuses. Molecular-cytogenetic studies were carried out on the karyotype of cells of 60 spontaneous abortuses of I trimester of pregnancy with cell degeneration or absence of cell proliferation in the cultures, as a result of which the cells could not be studied using the standard metaphase analysis. The embryos were characterized by an unexpectedly high frequency of mosaic variants of monosomies for chromosomes 7, 15, 21, and 22, which amounted to 19% of all chromosome aberrations. Lethal forms of monosomies for human chromosomes 7 and 15 were described for the first time, since they are not found in spontaneous abortuses by standard cytogenetic methods. A hypothesis was proposed which accounts for the possibility of early postimplantation lethality of the embryos with mosaic forms of autosomal monosomies. The differences were found between the cells with monosomies for different autosomes in the mechanisms of origin, intertissue localization, and phenotypic effects. It was shown that monosomies for chromosomes 7, 15, 21, and 22 in a mosaic state with the normal cell line can be compatible with the early stages of postimplantation differentiation of the cytotrophoblast. Predominant compartmentalization of the cells with monosomies for chromosomes 21 and 22 in the extraembryonic mesoderm, a derivative of epiblast, can be a critical factor, which makes it impossible the normal morphogenesis of embryonic structures.     

Incidence of chromosomal mosaicism in human embryos at different developmental stages analyzed by fluorescence in situ hybridization

Chromosomal mosaicism has been reported in in vitro-cultured embryos at early cleavage stages, as well as in morulae and blastocysts. We have assessed the incidence and pattern of mosaicism during in vitro development of human embryos from early-cleavage stages to morula and blastocyst. Fifty spare embryos were fixed for fluorescence in situ hybridization (FISH) analysis for chromosomes X, Y, 13, 18, and 21 on days 2 or 3 (4- to 10-cell stage) (n = 16), on day 4 (morula stage) (n = 14), on day 5 (pre-expanded blastocyst) (n = 5), and the expanded blastocyst stages (n = 15). Blocked embryos (no cleavage observed within the last 24 hr) were not included. A total of 2367 cells were analyzed. Four early-cleavage stage embryos were found uniformly diploid; all of the others were mosaic for the chromosomes analyzed (mean diploid nuclei 48.3% +/- 28.7). All of the embryos at more advanced developmental stages, except one fully normal morula, had mosaic chromosome constitutions, with an increase in the percentage of diploid cells in morulae, pre-expanded, and expanded blastocysts, respectively (mean diploid nuclei 78.6% +/- 11.7, 66.0% +/- 20.8, 79.6% +/- 12.8), in comparison with earlier stages. Hypotheses about the origin of mosaicism and embryo regulation mechanisms will be discussed.     

Specific Features of Phenotypic Expression of Autosomal Monosomies during Pathological Postimplantation Development of Man

Autosomal monosomies represent a severe form of genomic disbalance which determines elimination of human embryos already at the preimplantation stages. As a rule, they occur very rarely in the materials of spontaneously aborted embryos and fetuses. Molecular-cytogenetic studies were carried out on the karyotype of cells of 60 spontaneous abortuses of I trimester of pregnancy with cell degeneration or absence of cell proliferation in the cultures, as a result of which the cells could not be studied using the standard metaphase analysis. The embryos were characterized by an unexpectedly high frequency of mosaic variants of monosomies for chromosomes 7, 15, 21, and 22, which amounted to 19% of all chromosome aberrations. Lethal forms of monosomies for human chromosomes 7 and 15 were described for the first time, since they are not found in spontaneous abortuses by standard cytogenetic methods. A hypothesis was proposed which accounts for the possibility of early postimplantation lethality of the embryos with mosaic forms of autosomal monosomies. The differences were found between the cells with monosomies for different autosomes in the mechanisms of origin, intertissue localization, and phenotypic effects. It was shown that monosomies for chromosomes 7, 15, 21, and 22 in a mosaic state with the normal cell line can be compatible with the early stages of postimplantation differentiation of the cytotrophoblast. Predominant compartmentalization of the cells with monosomies for chromosomes 21 and 22 in the extraembryonic mesoderm, a derivative of epiblast, can be a critical factor, which makes the normal morphogenesis of embryonic structures impossible.     

Transmission of chromosomal abnormalities: participation of chromosomally unbalanced gametes in fertilization and early development of unbalanced embryos in the Chinese hamster

Using 14 Chinese hamster stocks with various reciprocal translocations, chromosomally unbalanced gametes were produced and used to investigate the participation of the unbalanced gametes in fertilization and the development of unbalanced embryos. The selection of chromosomally abnormal gametes during fertilization was investigated by the chromosomal analysis of meiotic cells in heterozygotes for the 14 reciprocal translocations and pronuclei of fertilized ova obtained from crossing these heterozygotes. Compared with the expected frequencies from meiotic metaphase II (MII) scoring, the frequencies of male pronuclei having commonly a deficiency of chromosome 1 (q14-->q42) or chromosome 3 (p23-->q31) in one-cell embryos decreased significantly. However, the frequencies of male pronuclei with other abnormalities were all consistent with those expected from MII scoring. In contrast, the frequencies of female pronuclei with any karyotype including the same ones, as those decreased in male pronuclei from the translocation heterozygotes were all consistent with those estimated from MII scoring. These results suggest that gametes with nullisomies as well as disomies for any chromosomal segments may mostly participate in fertilization, whereas some sperm nullisomic for the specific segments of chromosomes 1 and 3 may fail to fertilize. On the other hand, the zygotic selection of chromosomal imbalance was investigated by direct analyses of pre-implantation embryos from crosses between chromosomally normal females and male heterozygotes from the 14 stocks with various reciprocal translocations. The chromosomal and morphological analysis revealed that some embryos were arrested in development at the two-cell stage and their common abnormality was partial monosomy for chromosome 1 or 2. Embryos with partial monosomy including chromosomes 1, 3 and 4 showed arrested development at four-eight-cell stages. Among day 4 embryos, some chromosomally unbalanced embryos, mainly with a deficiency of other segments, such as chromosomes 1p, 2q, 5q and 8, had fewer blastomeres than karyotypically normal and balanced embryos. The homology between the mouse and the Chinese hamster chromosomes relating to the developmental abnormalities at early stages was partially confirmed.