The absence of uniparental X-chromosome inheritance in spontaneous abortuses with a 46,XX karyotype

The problem of the presence of imprinted regions on the X-chromosome and the possible influence of the imprinted expression of X-linked genes on the embryonic development in man remains largely unsolved. A comparison of the uniparental inheritance of chromosomes or of their regions having different phenotypic manifestations provides an instrument with which to study the phenomenon of genomic imprinting at the chromosomal level. Assuming that the imprinted inactivation of X-chromosomes is functionally significant for embryonic development, we have studied several polymorphic micro- and minisatellite loci of X-chromosomes in 52 fetuses with karyotype 46,XX, which were spontaneously aborted during the first trimester of pregnancy. The purpose was to determine the contribution of uniparental disomy for the X-chromosome in any disturbances of the embryonic development. We found that inheritance of X-chromosomes was biparental in the studied embryos, suggesting the absence of any significant contribution of the parental origin of the X-chromosome to embryonic mortality occurring between 4 and 12 weeks of development.     

Evaluation of the Role of Uniparental Disomy in Early Embryolethality of Man

We carried out systematic studies of the contribution of uniparental disomy for eight human chromosomes, 2, 9, 11, 15, 16, 19, 20, and 21, to the etiology of embryolethality. Most of these chromosomes have regions with orthologous imprinted genes syntenic with those on mouse chromosomes, the disturbed expression of which is related to embryolethality in mice. Screening of uniparental disomy in spontaneous abortuses of 5–16 weeks of pregnancy was performed by evaluation of the pattern of inheritance of alleles of polymorphic microsatellite loci located in the studied chromosomes. A total of 100 human embryos with cytogenetically determined normal karyotype were studied, in which arrest at the early stages of intrauterine development was determined by ultrasound examination of pregnant women. During this study, 13 embryos were discarded due to revealed karyotype anomalies or nonpaternity. No cases of uniparental disomy were found among the 87 studied abortuses for any of chromosomes studied. The analysis of the results of this study and four other studies concerning the search for uniparental disomy in dead embryos and fetuses did not reveal its elevated frequency in spontaneous abortuses as compared to the theoretically expected value based on evaluation of the probable combination of meiotic errors in human gametes. The data we obtained suggest that, first, uniparental disomies for human chromosomes that have regions with orthologous imprinted genes syntenic with mouse chromosomes do not contribute noticeably to the death of human embryos at the early developmental stages and, second, the mechanisms underlying embryolethality as a result of disturbed expression of imprinted loci differ markedly in evolutionarily remote mammals.     

Evaluation of the role of uniparental disomy in early embryolethality of man

We carried out systematic studies of the contribution of uniparental disomy for eight human chromosomes, 2, 9, 11, 15, 16, 19, 20, and 21, to the etiology of spontaneous mortality of human embryos. Most of these chromosomes have regions with orthologous imprinted genes syntenic with those on mouse chromosomes, the disturbed expression of which is related to embryolethality in mice. Screening of uniparental disomy in spontaneous 5- to 16-week abortuses was performed by evaluation of the pattern of inheritance of alleles of polymorphic microsatellite loci located in the studied chromosomes. A total of 100 human embryos with cytogenetically determined normal karyotype were studied, in which arrest at the early stages of intrauterine development was determined by ultrasound examination of pregnant women. During this study, 13 embryos were discarded due to karyotype anomalies or nonpaternity. No cases of uniparental disomy were found among the 87 studied abortuses for any of chromosomes studied. The analysis of the results of this study and four other studies concerning the search for uniparental disomy in dead embryos and fetuses did not reveal its elevated frequency in spontaneous abortuses as compared to the theoretically expected value based on evaluation of the probable combination of meiotic errors in human gametes. The data we obtained suggest that, first, uniparental disomies for human chromosomes that have regions with orthologous imprinted genes syntenic with mouse chromosomes do not contribute noticeably to the death of human embryos at the early developmental stages and, second, the mechanisms underlying embryolethality as a result of disturbed expression of imprinted loci differ markedly in mammals evolutionarily remote from one other.     

Interactions between imprinting effects: summary and review

Mice with uniparental disomies (uniparental duplications) for defined regions of certain chromosomes, or certain disomies, show a range of developmental abnormalities most of which affect growth. These defects can be attributed to incorrect dosages of maternal or paternal copies of imprinted genes lying within the regions involved. Combinations of certain partial disomies result in interactions between the imprinting effects that seemingly independently affect foetal and/or placental growth in different ways or modify neonatal and postnatal development. The findings are generally in accord with the 'conflict hypothesis' for the evolution of genomic imprinting but do not demonstrate common growth axes within which imprinted genes may interact. Instead, it would seem that any gene that favours embryonic/foetal development, at consequent cost to the mother, will have been subject to evolutionary selection for only paternal allele expression. Reciprocally, any gene that reduces embryonic/foetal growth to limit disadvantage to the mother will have been selected for only maternal allele expression. It is concluded that survival of the placenta is core to the evolution of imprinting.     

Allele-specific replication of 15q11-q13 loci: a diagnostic test for detection of uniparental disomy.

Allele-specific replication differences have been observed in imprinted chromosomal regions. We have exploited this characteristic of an imprinted region by using FISH at D15S9 and SNRPN (small nuclear ribonucleo protein N) on interphase nuclei to distinguish between Angelman and Prader-Willi syndrome patient samples with uniparental disomy of chromosome 15q11-q13 (n = 11) from those with biparental inheritance (n = 13). The familial recurrence risks are low when the child has de novo uniparental disomy and may be as high as 50% when the child has biparental inheritance. The frequency of interphase cells with asynchronous replication was significantly lower in patients with uniparental disomy than in patients with biparental inheritance. Within the sample population of patients with biparental inheritance, those with altered methylation and presumably imprinting center mutations could not be distinguished from those with no currently detectable mutation. This test is cost effective because it is performed on interphase cells from the same hybridized cytological preparation in which a deletion is excluded, and additional specimens are not required to determine the parental origin of chromosome 15.     

Strong biases in the transmission of sex chromosomes in the aphid Rhopalosiphum padi

The typical life cycle of aphids involves several parthenogenetic generations followed by a single sexual one in autumn, i.e. cyclical parthenogenesis. Sexual females are genetically identical to their parthenogenetic mothers and carry two sex chromosomes (XX). Male production involves the elimination of one sex chromosome (to produce X0) that could give rise to genetic conflicts between X-chromosomes. In addition, deleterious recessive mutations could accumulate on sex chromosomes during the parthenogenetic phase and affect males differentially depending on the X-chromosome they inherit. Genetic conflicts and deleterious mutations thus may induce transmission bias that could be exaggerated in males. Here, the transmission of X-chromosomes has been studied in the laboratory in two cyclically parthenogenetic lineages of the bird cherry-oat aphid Rhopalosiphum padi . X-chromosome transmission was followed, using X-linked microsatellite loci, at male production in the two lineages and in their hybrids deriving from reciprocal crosses. Genetic analyses revealed non-Mendelian inheritance of X-chromosomes in both parental and hybrid lineages at different steps of male function. Putative mechanisms and evolutionary consequences of non-Mendelian transmission of X-chromosomes to males are discussed.     

Cell lineage specific distribution of H3K27 trimethylation accumulation in an in vitro model for human implantation

Female mammals inactivate one of their two X-chromosomes to compensate for the difference in gene-dosage with males that have just one X-chromosome. X-chromosome inactivation is initiated by the expression of the non-coding RNA Xist, which coats the X-chromosome in cis and triggers gene silencing. In early mouse development the paternal X-chromosome is initially inactivated in all cells of cleavage stage embryos (imprinted X-inactivation) followed by reactivation of the inactivated paternal X-chromosome exclusively in the epiblast precursors of blastocysts, resulting temporarily in the presence of two active X-chromosomes in this specific lineage. Shortly thereafter, epiblast cells randomly inactivate either the maternal or the paternal X-chromosome. XCI is accompanied by the accumulation of histone 3 lysine 27 trimethylation (H3K27me3) marks on the condensed X-chromosome. It is still poorly understood how XCI is regulated during early human development. Here we have investigated lineage development and the distribution of H3K27me3 foci in human embryos derived from an in-vitro model for human implantation. In this system, embryos are co-cultured on decidualized endometrial stromal cells up to day 8, which allows the culture period to be extended for an additional two days. We demonstrate that after the co-culture period, the inner cell masses have relatively high cell numbers and that the GATA4-positive hypoblast lineage and OCT4-positive epiblast cell lineage in these embryos have segregated. H3K27me3 foci were observed in ～25% of the trophectoderm cells and in ～7.5% of the hypoblast cells, but not in epiblast cells. In contrast with day 8 embryos derived from the co-cultures, foci of H3K27me3 were not observed in embryos at day 5 of development derived from regular IVF-cultures. These findings indicate that the dynamics of H3K27me3 accumulation on the X-chromosome in human development is regulated in a lineage specific fashion.     

Interactions between imprinting effects in the mouse

Mice with uniparental partial or complete disomies for any one of 11 identified chromosomes show abnormal phenotypes. The abnormalities, or imprinting effects, can be attributable to an incorrect dosage of maternal or paternal copies of imprinted gene(s) located within the regions involved. Here we show that combinations of partial disomies may result in interactions between imprinting effects that seemingly independently affect fetal and/or placental growth in different ways or modify neonatal and postnatal imprinting effects. Candidate genes within the regions have been identified. The findings are generally in accord with the "conflict hypothesis" for the evolution of genomic imprinting but do not clearly demonstrate common growth axes within which imprinted genes may interact. Instead, it would seem that any gene that represses or limits embryonic/fetal growth to the advantage of the mother--by any developmental means--will have been subject to evolutionary selection for paternal allele repression. Likewise, any gene that favors embryonic/fetal development at consequent cost to the mother--by any developmental means--will have faced selection for maternal allele repression. The classical Igf2-Igf2r axis may therefore be unique. The findings involve reinterpretation of older imprinting data and consequently revision of the mouse imprinting map.     

Female-limited X-chromosome evolution effects on male pre- and post-copulatory success

Intralocus sexual conflict arises when the expression of shared alleles at a single locus generates opposite fitness effects in each sex (i.e. sexually antagonistic alleles), preventing each sex from reaching its sex-specific optimum. Despite its importance to reproductive success, the relative contribution of intralocus sexual conflict to male pre- and post-copulatory success is not well-understood. Here, we used a female-limited X-chromosome (FLX) evolution experiment in Drosophila melanogaster to limit the inheritance of the X-chromosome to the matriline, eliminating possible counter-selection in males and allowing the X-chromosome to accumulate female-benefit alleles. After more than 100 generations of FLX evolution, we studied the effect of the evolved X-chromosome on male attractiveness and sperm competitiveness. We found a non-significant increase in attractiveness and decrease in sperm offence ability in males expressing the evolved X-chromosomes, but a significant increase in their ability to avoid displacement by other males'' sperm. This is consistent with a trade-off between these traits, perhaps mediated by differences in body size, causing a small net reduction in overall male fitness in the FLX lines. These results indicate that the X-chromosome in D. melanogaster is subject to selection via intralocus sexual conflict in males.     

Dosage compensation of sex-linked genes in Drosophila melanogaster. The activities of glucose-6-phosphate dehydrogenase and 6-phosphogluconate dehydrogenase in flies with normal and disturbed genetic balance

Summary The phenomenon of dosage compensation in Drosophila melanogaster which consists in doubling of the activity of the X-chromosome genes in males as compared to those in females was studied.The specific activities of 6-phosphogluconate dehydrogenase (6PGD) and glucose-6-phosphate dehydrogenase (G6PD) determined by the sex-linked structural genes Pgd and Zw respectively were studied in flies carrying duplications for different regions of the X-chromosome. The increase in dose of Pgd and Zw in females resulting from the addition of an extra X-chromosome or X-fragments leads to a proportional rise in the specific activities of 6PGD and G6PD. On the other had the addition to females of the X-chromosome carrying no Pgd gene or X-fragments lacking Pgd and Zw has no effect on the enzyme activities. Thus we failed to reveal in the X-chromosome any compensatory genes envisaged by Muller, which would repress sex-linked structural genes proportional to their dose.The 6PGD and G6PD levels in phenotypically male-like intersexes carrying two X-chromosomes and three autosome sets (2X3A) is 30% higher than in diploid (2X2A) or triploid (3X3A) females. However the specific activities of the enzymes in female-like intersexes are the same as in regular females. The levels of 6PGD and G6PD per one X-chromosome are 1.5–2.0 times higher in the intersexes than in the normal females and metafemales (3X2A). The results indicate that the level of expression of the X-chromosome is determined by the X:A ratio. It is suggested that the decreased X:A ratio in males is responsible for the hyperactivation of their X-chromosomes.     

Mobile elements in Drosophila natural populations in Azerbaijan

The distribution of four genome DNA fragments containing different mobile elements in chromosomes of Drosophila melanogaster individuals from Azerbaijan coast and mountain populations was studied. The average copy number of each element was shown to be approx. equal in both populations. Sites of preferential localization, where the elements were present in no less than in half of individuals could be revealed in each population for all the elements. A part of these sites coincided with regions of intercalary heterochromatin, the number of such coincidences being larger in mountain populations. The copy number of the mobile elements under study in X-chromosomes of individuals from natural populations as well as from laboratory strains was less than in autosomes. X-chromosomes of different individuals differed in mobile elements' localization more than autosomes. It was assumed that peculiarities of mobile elements' distribution in X-chromosome could reflect the effect of decondensed structure of chromatin in male X-chromosome on the transposition of mobile elements.     

Heterochromatin as a factor influencing X-chromosome inactivation in hybrids of the common vole (Microtinae, Rodentia)]

Expression of X-linked genes for G6PD and alpha-GAL was studied in female interspecific hybrids of Microtus. The G6PD and alpha-GAL isozymes of Microtus arvalis were found to predominate in all cases when a species carrying a heterochromatin block on the X-chromosome served as one partner of hybridization and M. arvalis containing no heterochromatin block served as another. The proportions of G6PD and alpha-GAL parental forms were approx. equal in hybrid females when both species participating in hybridization contained heterochromatin blocks on X-chromosomes. Cytological analysis for revealing active and nonactive X-chromosomes on metaphase spreads of hybrid females supports the biochemical data. Non-random inactivation of X-chromosomes carrying the heterochromatin blocks in the interspecific hybrids with M. arvalis and a random one, when both parents contain heterochromatin blocks on the X-chromosomes are supposed to be the cause for the phenomenon observed. The study provided data supporting our previous hypothesis that heterochromatin affects the X-chromosome inactivation process in interspecific hybrid voles.