“Chromosome Memory” of Parental Genomes in Embryonic Hybrid Cells

In the hybrid cells obtained by fusion of embryonic stem cells with adult differentiated cells, homologous chromosomes are in two ontogenetic configurations: pluripotent and differentiated. In order to assess the role of cis- and trans-regulation in the maintenance of these states, we studied a set of clones of hybrid cells of the type embryonic stem cells–splenocytes and used two approaches: segregation of parental chromosomes and comparison of pluripotency of the past hybrid cells and embryonic stem cells. The segregation test showed that the hybrid cells lost only the homologs of the somatic partner and this process was sharply accelerated when the cells were cultivated in nonselective conditions, thus suggesting the full or partial preservation of the initial differences in the organization of parental homologs. The descendants of the former hybrid cells, which had the karyotype similar to that of embryonic stem cells, demonstrated the level of pluripotency, comparable with that of embryonic stem cells despite the long-term effect of trans-acting factors from the somatic partner in the genome of hybrid cells. The data obtained are interpreted in the framework of the concept of chromosome memory, in the maintenance of which the key role is played bycis-regulatory factors.     

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.     

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.     

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.     

Dominant manifestation of pluripotency in embryonic stem cell hybrids with various numbers of somatic chromosomes

Developmental potential was assessed in 8 intra-specific and 20 inter-specific hybrid clones obtained by fusion of embryonic stem (ES) cells with either splenocytes or fetal fibroblasts. Number of chromosomes derived from ES cells in these hybrid clones was stable while contribution of somatic partner varied from single chromosomes to complete complement. This allowed us to compare pluripotency of the hybrid cells with various numbers of somatic chromosomes. Three criteria were used for the assessment: (i) expression of Oct-4 and Nanog genes; (ii) analyses of teratomas generated by subcutaneous injections of the tested cells into immunodeficient mice; (iii) contribution of the hybrid cells in chimeras generated by injection of the tested cells into C57BL blastocysts. All tested hybrid clones showed expression of Oct-4 and Nanog at level comparable to ES cells. Histological and immunofluorescent analyses demonstrated that most teratomas formed from the hybrid cells with different number of somatic chromosomes contained derivatives of three embryonic layers. Tested hybrid clones make similar contribution in various tissues of chimeras in spite of significant differences in the number of somatic chromosomes they contained. The data indicate that pluripotency is manifested as a dominant trait in the ES hybrid cells and does not depend substantially on the number of somatic chromosomes. The latter suggests that the developmental potential derived from ES cells is maintained in ES-somatic cell hybrids by cis-manner and is rather resistant to trans-acting factors emitted from the somatic one.     

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.__________Translated from Ontogenez, Vol. 36, No. 2, 2005, pp. 151–158.Original Russian Text Copyright © 2005 by Pristyazhnyuk, Temirova, Menzorov, Kruglova, Matveeva, Serov.     

Embryonal Cell Hybrids: New Opportunities for Studying Pluripotency and Reprogramming of the Differentiated Cell Chromosomes

Here we study the properties of cell hybrids produced by the fusion of embryonal stem cells and differentiated ones. During in vitrocultivation, such hybrids predominantly lose the somatic partner chromosomes, although the loss of the embryonic partner autosomes is also common in the clones; i.e., this is a bidirectional process. The use of a selective media allows the isolation of the clones, with the embryonal X chromosome replaced by the somatic genome homolog. The cell hybrids with a near-diploid chromosome set preserve the high-level pluripotency properties of the embryonal partner including the capacity to form chimeras after their introduction in the blastocoel. An investigation of the chimeric animals demonstrated a reprogramming of the somatic X chromosome in the course of development. The prospective identification of the chromosomes involved in the maintenance of pluripotency and studies of its cis-and trans-regulation in the cell hybrid genome are discussed.     

In vitro and in vivo study of pluripotency in intraspecific hybrid cells obtained by fusion of murine embryonic stem cells with splenocytes

Hypoxanthine phosphoribosyltransferase–deficient (HPRT^-) mouse embryonic stem (ES) cells, HM-1 cells (genotype XY), were fused with adult female DD/c mouse spleen cells. As a result, a set of HAT-resistant clones was isolated. Four hybrid clones most similar in morphology and growth characteristics to the HM-1 cells were studied in detail with respect to their pluripotency. Of these, three clones contained 41–43 chromosomes, and one clone was nearly tetraploid. All the clones had the XXY set of sex chromosomes and expressed the HPRT of the somatic partner only. The hybrid clones shared features with the HM-1 cells, indicating that they retained their pluripotent properties: (1) embryonic ECMA-7 antigen, not TROMA-1 antigen, was present in most cells; (2) the hybrid cells showed high activity of endogenous alkaline phosphatase (AP); (3) all the hybrid clones were able to form complex embryoid bodies containing derivatives of all the embryonic germinal layers; (4) the hybrid cells contained synchronously replicating X chromosomes, indicating that they were in an active state; and (5) a set of chimeric animals was generated by injecting hybrid cells into BALB/c and C57BL/6J mouse blastocysts. Evidence for chimerism was provided by the spotted coat derived from 129/Ola mice and identification of 129/Ola glucose phosphate isomerase (GPI) in many organs. Thus the results obtained demonstrated that the hybrid cells retain their high pluripotency level despite the close contact of the “pluripotent” HM-1 genome with the “somatic” spleen cell genome during hybrid cell formation and the presence of the “somatic” X chromosome during many cell generations. The presence of HPRT of the somatic partner in many organs and tissues, including the testes in chimeric animals, shows that the “somatic” X chromosome segregates weakly, if at all, during development of the chimeras. There were no individuals with the 129/Ola genotype among the more than 50 offspring from chimeric mice. The lack of the 129/Ola genotype is explained by the imbalance of the sex chromosomes in the hybrid cells rendering the passage of hybrid cell descendants through meiosis in chimeras impossible. As a result, chimeras become unable to produce gametes of the hybrid cell genotype. Mol. Reprod. Dev. 50:128–138, 1998. © 1998 Wiley-Liss, Inc.     

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.     

Fate of parental mitochondria in embryonic stem hybrid cells

In hybrid cells, not only are the nuclear genomes of parent cells fused, but their cytoplasm is as well. Mitochondrial DNA (mtDNA) is a convenient marker of cytoplasm that allows us to gain insight into the organization of hybrid-cell cytoplasm. We analyzed the parental mtDNA in hybrid cells resulting from the 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 parental mtDNA in hybrid cells was based on polymorphism among parental mtDNA for certain restriction endonucleases. We found that intra- and interspecific ES cell-splenocyte hybrid cells either entirely or partially lost mtDNA derived from a somatic partner, whereas ES cell-fibroblast hybrids retained mtDNA from both parents in similar ratios with a slight bias. The loss of somatic mitochondria by ES-splenocyte hybrids implies a nonrandom segregation of parental mitochondria, which was supported by a computer simulation of genetic drift. In contrast, ES cell-fibroblast hybrids show bilateral random segregation of the parental mitochondria judging from the analysis of mtDNA in single cells. Preferential segregation of somatic mitochondria does not depend on the differences in sequences of the parental mtDNA, but rather on the replicative state of parental cells.     

FISH analysis of regional replication of homologous chromosomes in hybrid cells obtained by fusion of embryonic stem cells with somatic cells

The paper deals with the FISH analysis of the regional replication of homologue of chromosomes 1, 3, and 6 in hybrid cells obtained by the fusion of Mus musculus embryonic stem cells (ESCs) and somatic cells—M. caroli splenocytes. The obtained data showed that, in hybrid cells with near-diploid karyotypes, the parental chromosomes were replicated synchronously in 70–75% of tested cells, similar to in diploid ESCs and diploid fibroblasts. In hybrid cells with near-triploid karyotypes, the asynchronous replication of the parental chromosomes increased to 46–57% of tested cells. However, this is true for hybrid cells with three copies of tested chromosomes, whereas, in triploid cells with two copies, the level of the homolog synchronous replication was close to that of diploid cells. In hybrid cells with near-tetraploid karyotypes, the level of asynchronous replication was observed in more than 50% of cells, which is comparable with the level in tetraploid ESCs and tetraploid fibroblasts. Thus, in hybrid cells with no more than two copies of an individual chromosome, the synchronous replication of homologue that initially had different levels of differentiation and parameters of replications was observed. However, the information value of the method of in situ hybridization on interphase nuclei changes significantly with an increase in the number of copies of individual chromosomes and thereby restricts possibilities of this approach for evaluation of synchronous homolog replication in hybrid cells.     

NANOG在哺乳动物早期胚胎发育与干细胞中的功能研究进展

哺乳动物的早期胚胎发育和干细胞多能性由转录因子构成的基因网络所调控。2003年,在胚胎干细胞中发现的重要转录因子NANOG位于基因网络调控中心,对胚胎第二次命运决定和基态多能性的建立至关重要。该文将在NANOG生物学特征的基础上,重点讨论其在早期胚胎发育、胚胎干细胞与诱导性多能干细胞中的功能。     

Pluripotency genes overexpressed in primate embryonic stem cells are localized on homologues of human chromosomes 16, 17, 19, and X

While human embryonic stem cells (hESCs) are predisposed toward chromosomal aneploidities on 12, 17, 20, and X, rendering them susceptible to transformation, the specific genes expressed are not yet known. Here, by identifying the genes overexpressed in pluripotent rhesus ESCs (nhpESCs) and comparing them both to their genetically identical differentiated progeny (teratoma fibroblasts) and to genetically related differentiated parental cells (parental skin fibroblasts from whom gametes were used for ESC derivation), we find that some of those overexpressed genes in nhpESCs cluster preferentially on rhesus chromosomes 16, 19, 20, and X, homologues of human chromosomes 17, 19, 16, and X, respectively. Differentiated parental skin fibroblasts display gene expression profiles closer to nhpESC profiles than to teratoma cells, which are genetically identical to the pluripotent nhpESCs. Twenty over- and underexpressed pluripotency modulators, some implicated in neurogenesis, have been identified. The overexpression of some of these genes discovered using pedigreed nhpESCs derived from prime embryos generated by fertile primates, which is impossible to perform with the anonymously donated clinically discarded embryos from which hESCs are derived, independently confirms the importance of chromosome 17 and X regions in pluripotency and suggests specific candidates for targeting differentiation and transformation decisions.     

The metabolome of induced pluripotent stem cells reveals metabolic changes occurring in somatic cell reprogramming

Metabolism is vital to every aspect of cell function, yet the metabolome of induced pluripotent stem cells (iPSCs) remains largely unexplored. Here we report, using an untargeted metabolomics approach, that human iPSCs share a pluripotent metabolomic signature with embryonic stem cells (ESCs) that is distinct from their parental cells, and that is characterized by changes in metabolites involved in cellular respiration. Examination of cellular bioenergetics corroborated with our metabolomic analysis, and demonstrated that somatic cells convert from an oxidative state to a glycolytic state in pluripotency. Interestingly, the bioenergetics of various somatic cells correlated with their reprogramming efficiencies. We further identified metabolites that differ between iPSCs and ESCs, which revealed novel metabolic pathways that play a critical role in regulating somatic cell reprogramming. Our findings are the first to globally analyze the metabolome of iPSCs, and provide mechanistic insight into a new layer of regulation involved in inducing pluripotency, and in evaluating iPSC and ESC equivalence.     

Accessing naïve human pluripotency

Pluripotency manifests during mammalian development through formation of the epiblast, founder tissue of the embryo proper. Rodent pluripotent stem cells can be considered as two distinct states: na?ve and primed. Na?ve pluripotent stem cell lines are distinguished from primed cells by self-renewal in response to LIF signaling and MEK/GSK3 inhibition (LIF/2i conditions) and two active X chromosomes in female cells. In rodent cells, the na?ve pluripotent state may be accessed through at least three routes: explantation of the inner cell mass, somatic cell reprogramming by ectopic Oct4, Sox2, Klf4, and C-myc, and direct reversion of primed post-implantation-associated epiblast stem cells (EpiSCs). In contrast to their rodent counterparts, human embryonic stem cells and induced pluripotent stem cells more closely resemble rodent primed EpiSCs. A critical question is whether na?ve human pluripotent stem cells with bona fide features of both a pluripotent state and na?ve-specific features can be obtained. In this review, we outline current understanding of the differences between these pluripotent states in mice, new perspectives on the origins of na?ve pluripotency in rodents, and recent attempts to apply the rodent paradigm to capture na?ve pluripotency in human cells. Unraveling how to stably induce na?ve pluripotency in human cells will influence the full realization of human pluripotent stem cell biology and medicine.