Visible and "cryptic" segregation of parental chromosomes in embryonic stem hybrid cells

Chromosome segregation of the parental chromosomes was studied in 20 interspecific hybrid clones obtained by fusion of Mus musculus embryonic stem cells with Mus caroli splenocytes. FISH analysis with labeled species specific probes and microsatellite markers was used for identification of the parental chromosomes. Cytogenetic analysis has shown significant intra- and interclonal variability in chromosome numbers and ratios of the parental chromosomes in the hybrid cells: six clones contained all M. caroli chromosomes, nine clones showed moderate segregation of M. caroli chromosomes (from 1 to 7), and five clones showed extensive loss of M. caroli chromosomes (from 12 to complete loss of all M. caroli autosomes). Both methods demonstrated "cryptic" segregation of the somatic partner chromosomes. For instance, five clones with near-tetraploid chromosome sets contained only few M. caroli chromosomes (from 1 to 8). The data obtained suggest that the tetraploid chromosome set per se is not a sufficient criterion for conclusion on the absence of chromosome loss in the hybrid cells. Note that "cryptic" chromosome segregation occurred at a high frequency in the examined hybrid clones. Thus, "cryptic" segregation should be borne in mind for assessing pluripotency and genome reprogramming of embryonic stem hybrid cells.     

Unequal segregation of parental chromosomes in embryonic stem cell hybrids

Chromosome segregation was studied in 14 intra- and 20 inter-specific hybrid clones generated by fusion of Mus musculus embryonic stem (ES) cells with fibroblasts or splenocytes of DD/c mice or Mus caroli. As a control for in vitro evolution of tetraploid karyotype we used a set of hybrid clones obtained by fusion of ES cells (D3) with ES cells (TgTP6.3). Identification of the parental chromosomes in the clones was performed by microsatellite analysis and in situ hybridization with labeled species-specific probes. Both analyses have revealed three types of clones: (i) stable tetraploid, observed only for ES x ES cell hybrids; (ii) bilateral loss of chromosomes of both ES and somatic partners; (iii) unilateral segregation of chromosomes of the somatic partner. Observed unilateral segregation was extensive in ES-splenocyte cell hybrids, but lower in ES-fibroblast hybrid clones. Developmental state of the somatic partner is presumably responsible for directional chromosome loss. Nonrandom segregation implies that initial differences in the parental homologous chromosomes were not immediately equalized implying at least transient persistence of the differentiated epigenotype.     

Fate of parental mitochondria in embryonic stem hybrid cells

When hybrid cells are created, not only nuclear genomes of parental cells unite but their cytoplasm as well. Mitochondrial DNA (mtDNA) is a convenient marker of cytoplasm allowing one to gain insight into the organization of hybrid cell cytoplasm. We analyzed the parental mtDNAs in hybrid cells resulting from fusion of Mus musculus embryonic stem (ES) cells with splenocytes and fetal fibroblasts of DD/c mice or with splenocytes of M. caroli. Identification of the parental mtDNAs in hybrid cells was based on polymorphism among the parental mtDNAs for certain restrictases. We found that intra- and inter-specific ES cell-splenocyte hybrid cells lost entirely or partially mtDNA derived from the somatic partner, whereas ES cell-fibroblast hybrids retained mtDNAs from both parents in similar ratios with a slight bias. The lost of the "somatic" mitochondria by Es-splenocyte hybrids implies non-random segregation of the parental mitochondria as supported by a computer simulation of genetic drift. In contrast, ES cell-fibroblast hybrids show bilateral random segregation of the parental mitochondria judging from analysis of mtDNA in single cells. Preferential segregation of "somatic" mitochondria does not depend on the differences in sequences of the parental mtDNAs but depends on replicative state of the parental cells.     

X-chromosome epigenetic reprogramming in pluripotent stem cells via noncoding genes

Acquisition of the pluripotent state coincides with epigenetic reprogramming of the X-chromosome. Female embryonic stem cells are characterized by the presence of two active X-chromosomes, cell differentiation by inactivation of one of the two Xs, and induced pluripotent stem cells by reactivation of the inactivated X-chromosome in the originating somatic cell. The tight linkage between X- and stem cell reprogramming occurs through pluripotency factors acting on noncoding genes of the X-inactivation center. This review article will discuss the latest advances in our understanding at the molecular level. Mouse embryonic stem cells provide a standard for defining the pluripotent ground state, which is characterized by low levels of the noncoding Xist RNA and the absence of heterochromatin marks on the X-chromosome. Human pluripotent stem cells, however, exhibit X-chromosome epigenetic instability that may have implications for their use in regenerative medicine. XIST RNA and heterochromatin marks on the X-chromosome indicate whether human pluripotent stem cells are developmentally ‘naïve’, with characteristics of the pluripotent ground state. X-chromosome status and determination thereof via noncoding RNA expression thus provide valuable benchmarks of the epigenetic quality of pluripotent stem cells, an important consideration given their enormous potential for stem cell therapy.     

The absence of the uniparental inheritance of X-chromosomes in spontaneously aborted fetuses with karyotype 46.XX

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.     

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.     

Expression of glucose phosphate isomerase in interspecific hybrid (Mus musculus x Mus caroli) mouse embryos.

Hybrid Mus musculus x Mus caroli embryos were produced by inseminating M. musculus (C57BL/OlaWs) females with M. caroli sperm. Control M. caroli embryos developed more rapidly than did control M. musculus embryos and implanted approximately 1 day earlier. At 1 1/2 days, both the hybrid embryos and those of the maternal species (M. musculus) had cleaved to the 2-cell stage. By 2 1/2 days some of the hybrids were retarded compared to M. musculus, and by 3 1/2 days most were lagging behind. This is consistent with the idea that the rate of development of hybrid embryos declines once it becomes dependent on embryo-coded gene products. We have used this difference in rate of preimplantation development, between hybrid and M. musculus embryos, to try to determine whether the activation of embryonic Gpi-1s genes, that encode glucose phosphate isomerase (GPI-1), is age-related or stage-related. In control M. musculus embryos (both mated and Al groups), the GPI-1AB and GPI-1A allozyme, indicative of paternal gene expression, were detected in 7 of 9 samples of 3 1/2-day compacted morula stage embryos and were seen in all 19 samples of 3 1/2-day blastocysts. In hybrid embryos, these allozymes were detected 1 day later. They were not detected in any 3 1/2-day samples (12 samples of compacted morulae) but were consistently detected at 4 1/2 days (4 samples of blastocysts and 2 samples of uncompacted morulae). Our interpretation of the results is that gene activation in hybrid embryos is stage-specific, rather than age-specific, and probably begins around the 8-cell stage, with detectable levels of enzyme accumulating later. Analysis of GPI-1 electrophoresis indicated that both the paternal (M. caroli) and maternal (M. musculus) Gpi-1s alleles were equally expressed in hybrid embryos and that the paternally derived allele was not activated before the maternally derived allele.     

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.     

Chromosome composition of interspecies hybrid embryonic stem cells in mice

Chromosome complements of 20 hybrid clones obtained by fusing Mus musculus embryonic stem cells (ESCs) and Mus caroli splenocytes were studied. The use of two-color fluorescence hybridization in situ with chromosome- and species-specific probes has allowed us to reliably reveal the parental origin of homologs of any chromosome in hybrid cells. Depending on the ratio of parental chromosome homologs, all 20 hybrid clones were separated in several groups ranging from the clones that contain cells that are nearly tetraploid with two diploid sets of M. musculus and single M. caroli chromosomes to clones with a marked predominance of the M. caroli chromosome. In eight hybrid cell clones, we observed the pronounced prevalence of chromosomes of the pluripotent partner over chromosomes of the somatic partner in a ratio of 5: 1 to 3: 1. In other hybrid cell clones, the ratio of M. musculus to M. caroli chromosomes was either equal (1: 1; 2: 2) or with the prevalence of the pluripotent (2: 1) or differentiated (1: 2) partner. In three hybrid cell clones, for the first time, we observed the predominant segregation of ESC-derived pluripotent chromosomes. This might indicate the compensation for the epigenetic differences between parental chromosomes of the ESC and splenocyte origin.     

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.     

Effects of alterations in the immunocompetent status of Mus musculus females on the survival of transferred Mus caroli embryos

The role of the immune system in promoting the midterm death of Mus caroli embryos transferred to the Mus musculus uterus was studied in vivo by transferring M. caroli blastocysts to recipients with altered immune status. Transfers of embryos to chimaeric mothers (Mus musculus in equilibrium Mus caroli), which were expected to be tolerant of species antigens, resulted in survival of M. musculus embryos but death of M. caroli embryos. The preferential survival of M. musculus embryos was explained by showing that M. musculus embryos can survive in the M. caroli uterus. Transfers to T cell-deficient mice of genotype nu/nu and to NK cell-deficient mice of genotype bg/bg as well as treatment of normal transfer recipients with Cyclosporin A or anti-Ia antiserum failed to prolong survival. However, immunization of recipients with M. caroli lymphocytes promoted more rapid and uniform failure of the interspecies pregnancy. Cytotoxic cells were detected in the resorbing embryos on Day 10.5 in immune pregnancies and on Day 12.5 in non-immune pregnancies and these cells were promiscuous in their pattern of lysis, showing equal reactivity against M. caroli, transfer recipient and 3rd party target cells. These experiments show that failure of M. caroli embryos in the M. musculus uterus is complex, but probably does not involve responses by classical cytotoxic T lymphocyte or natural killer cell pathways. Participation of the immune system in the resorption process, however, is confirmed and is associated with generation of promiscuous cytolytic cells.     

Molecular cloning and long terminal repeat sequences of intracisternal A-particle genes in Mus caroli

We isolated DNA clones of intracisternal A-particle (IAP) genes from the genome of an Asian wild mouse, Mus caroli. A typical M. caroli IAP gene was 6.5 kilobase pairs in length and had long terminal repeat (LTR) sequences at both ends. The size of the LTR was 345 base pairs in clone L20, and two LTRs at both ends of this clone were linked to directly repeating cellular sequences of 6 base pairs. Each LTR possessed most of the structural features commonly associated with the retrovirus LTR. The restriction map of the M. caroli IAP gene resembled that of Mus musculus, although the M. caroli IAP gene was 0.4 kilobase pairs shorter than the M. musculus IAP gene in two regions. Sequence homology between the M. caroli and M. musculus IAP LTRs was calculated as about 80%, whereas the LTR sequence of the Syrian hamster IAP gene was about 60% homologous to the M. caroli LTR. The reiteration frequency of the M. caroli IAP genes was estimated as 200 to 400 copies per haploid genome, which is at least 10 times the reported value. These results suggest that the IAP genes observed in the genus Mus are present in multiple copies with structures closely resembling the integrated retrovirus gene.