Reprogramming a somatic nucleus by trans-modification activity in germ cells.

The germ cell lineage is totipotent insofar as it provides a link between an individual and the subsequent generations. There is a series of characteristic genomic modifications in germ cells that distinguish this lineage from somatic cells. These modifications include extensive demethylation of the genome, erasure of allele-specific methylation of imprinted loci and re-activation of the silent X chromosome. To test if this is an active process capable of reprogramming a somatic nucleus, we prepared germ cell-somatic cell hybrids. A dominant trans modification activity was detected in germ cells that was capable of inducing similar modifications in the somatic nucleus. This experimental system can therefore be used to study how determined cell state can be reversed by specific genomic modifications.     

Heterogeneity in imprinted methylation patterns of pluripotent embryonic germ cells derived from pre-migratory mouse germ cells

Pluripotent stem cells, termed embryonic germ (EG) cells, have been generated from both human and mouse primordial germ cells (PGCs). Like embryonic stem (ES) cells, EG cells have the potential to differentiate into all germ layer derivatives and may also be important for any future clinical applications. The development of PGCs in vivo is accompanied by major epigenetic changes including DNA demethylation and imprint erasure. We have investigated the DNA methylation pattern of several imprinted genes and repetitive elements in mouse EG cell lines before and after differentiation. Analysed cell lines were derived soon after PGC specification, “early”, in comparison with EG cells derived after PGC colonisation of the genital ridge, “late” and embryonic stem (ES) cell lines, derived from the inner cell mass (ICM). Early EG cell lines showed strikingly heterogeneous DNA methylation patterns, in contrast to the uniformity of methylation pattern seen in somatic cells (control), late EG cell and ES cell lines. We also observed that all analysed XX cell lines exhibited less methylation than XY. We suggest that this heterogeneity may reflect the changes in DNA methylation taking place in the germ cell lineage soon after specification.     

Epigenetic reprogramming in mouse primordial germ cells

Genome-wide epigenetic reprogramming in mammalian germ cells, zygote and early embryos, plays a crucial role in regulating genome functions at critical stages of development. We show here that mouse primordial germ cells (PGCs) exhibit dynamic changes in epigenetic modifications between days 10.5 and 12.5 post coitum (dpc). First, contrary to previous suggestions, we show that PGCs do indeed acquire genome-wide de novo methylation during early development and migration into the genital ridge. However, following their entry into the genital ridge, there is rapid erasure of DNA methylation of regions within imprinted and non-imprinted loci. For most genes, the erasure commences simultaneously in PGCs in both male and female embryos, which is completed within 1 day of development. Based on the kinetics of this process, we suggest that this is an active demethylation process initiated upon the entry of PGCs into the gonadal anlagen. The timing of reprogramming in PGCs is crucial since it ensures that germ cells of both sexes acquire an equivalent epigenetic state prior to the differentiation of the definitive male and female germ cells in which new parental imprints are established subsequently. Some repetitive elements, however, show incomplete erasure, which may be essential for chromosome stability and for preventing activation of transposons to reduce the risk of germline mutations. Aberrant epigenetic reprogramming in the germ line would cause the inheritance of epimutations that may have consequences for human diseases as suggested by studies on mouse models.     

Epigenetic reprogramming in mouse pre-implantation development and primordial germ cells

Epigenetic modifications are crucial for the identity and stability of cells, and, when aberrant, can lead to disease. During mouse development, the genome-wide epigenetic states of pre-implantation embryos and primordial germ cells (PGCs) undergo extensive reprogramming. An improved understanding of the epigenetic reprogramming mechanisms that occur in these cells should provide important new information about the regulation of the epigenetic state of a cell and the mechanisms of induced pluripotency. Here, we discuss recent findings about the potential mechanisms of epigenetic reprogramming, particularly genome-wide DNA demethylation, in pre-implantation mouse embryos and PGCs.     

Epigenotype switching of imprintable loci in embryonic germ cells

 Expression of imprinted genes is dependent on their parental origin. This is reflected in the heritable differential methylation of parental alleles. The gametic imprints are however reversible as they do not endure for more than one generation. To investigate if the epigenetic changes in male and female germ line are similar or not, we derived embryonic germ (EG) cells from primordial germ cells (PGCs) of day 11.5 and 12.5 male and female embryos. The results demonstrate that they have an equivalent epigenotype. First, chimeras made with EG cells derived from both male and female embryos showed comparable fetal overgrowth and skeletal abnormalities, which are similar to but less severe than those induced by androgenetic embryonic stem (ES) cells. Thus, EG cells derived from female embryos resemble androgenetic ES cells more than parthenogenetic cells. Furthermore, the methylation status of both alleles of a number of loci in EG cells was similar to that of the paternal allele in normal somatic cells. Hence, both alleles of Igf2r region 2, Peg1/Mest, Peg3, Nnat were consistently unmethylated in EG cells as well as in the primary embryonic fibroblasts (PEFs) rescued from chimeras. More strikingly, both alleles of p57kip2 that were also unmethylated in EG cells, underwent de novo methylation in PEFs to resemble a paternal allele in somatic cells. The exceptions were the H19 and Igf2 genes that retained the methylation pattern in PEFs as seen in normal somatic tissues. These studies suggest that the initial epigenetic changes in germ cells of male and female embryos are similar. Received: 1 September 1997 / Accepted: 15 October 1997     

Erasure of methylation imprinting of Igf2r during mouse primordial germ-cell development

During germ cell differentiation in mice, the genome undergoes specific epigenetic modifications. These include demethylation of imprinted genes and subsequent establishment of parental allele-specific methylation. The mouse Igf2r gene is an imprinted gene that shows maternal-specific expression. Maternal-specific methylation of differentially methylated region 2 (DMR2) of this gene may be necessary for its maternal-specific expression. Before the allele-specific methylation is established, DMR2 is demethylated in both male and female primordial germ cells (PGCs) by 13.5 days post coitum (dpc), indicating that the demethylation of this region occurs earlier in PGC development. The timing of the demethylation has been, however, unknown. In this study, we attempted to determine the timing of methylation erasure of Igf2r DMR2 in developing PGCs, using transgenic mice expressing green fluorescent protein specifically in the germ line. We purified migrating PGCs from the transgenic mice and examined the methylation status of DMR2. The results show that some CpG sites within DMR2 start demethylation at 9.5 dpc in some migrating PGCs, before the cells colonize genital ridges, and the progression of demethylation is rapid after colonization of the genital ridges. To examine whether the gonadal environment is involved in demethylation, we analyzed the methylation of DMR2 after culturing migrating PGCs in the absence of a gonadal environment. These culture experiments support the idea that a gonadal environment is not required for demethylation of the region in at least a fraction of PGCs.     

Reprogramming DNA methylation in the mammalian life cycle: building and breaking epigenetic barriers

In mammalian development, epigenetic modifications, including DNA methylation patterns, play a crucial role in defining cell fate but also represent epigenetic barriers that restrict developmental potential. At two points in the life cycle, DNA methylation marks are reprogrammed on a global scale, concomitant with restoration of developmental potency. DNA methylation patterns are subsequently re-established with the commitment towards a distinct cell fate. This reprogramming of DNA methylation takes place firstly on fertilization in the zygote, and secondly in primordial germ cells (PGCs), which are the direct progenitors of sperm or oocyte. In each reprogramming window, a unique set of mechanisms regulates DNA methylation erasure and re-establishment. Recent advances have uncovered roles for the TET3 hydroxylase and passive demethylation, together with base excision repair (BER) and the elongator complex, in methylation erasure from the zygote. Deamination by AID, BER and passive demethylation have been implicated in reprogramming in PGCs, but the process in its entirety is still poorly understood. In this review, we discuss the dynamics of DNA methylation reprogramming in PGCs and the zygote, the mechanisms involved and the biological significance of these events. Advances in our understanding of such natural epigenetic reprogramming are beginning to aid enhancement of experimental reprogramming in which the role of potential mechanisms can be investigated in vitro. Conversely, insights into in vitro reprogramming techniques may aid our understanding of epigenetic reprogramming in the germline and supply important clues in reprogramming for therapies in regenerative medicine.     

Reprogramming primordial germ cells into pluripotent stem cells

Background

Specification of primordial germ cells (PGCs) results in the conversion of pluripotent epiblast cells into monopotent germ cell lineage. Blimp1/Prmt5 complex plays a critical role in the specification and maintenance of the early germ cell lineage. However, PGCs can be induced to dedifferentiate back to a pluripotent state as embryonic germ (EG) cells when exposed to exogenous signaling molecules, FGF-2, LIF and SCF.

Methodology and Principal Findings

Here we show that Trichostatin A (TSA), an inhibitor of histone deacetylases, is a highly potent agent that can replace FGF-2 to induce dedifferentiation of PGCs into EG cells. A key early event during dedifferentiation of PGCs in response to FGF-2 or TSA is the down-regulation of Blimp1, which reverses and apparently relieves the cell fate restriction imposed by it. Notably, the targets of Blimp1, which include c-Myc and Klf-4, which represent two of the key factors known to promote reprogramming of somatic cells to pluripotent state, are up-regulated. We also found early activation of the LIF/Stat-3 signaling pathway with the translocation of Stat-3 into the nucleus. By contrast, while Prmt5 is retained in EG cells, it translocates from the nucleus to the cytoplasm where it probably has an independent role in regulating pluripotency.

Conclusions/Significance

We propose that dedifferentiation of PGCs into EG cells may provide significant mechanistic insights on early events associated with reprogramming of committed cells to a pluripotent state.     

Turning germ cells into stem cells

Primordial germ cells (PGCs), the embryonic precursors of the gametes of the adult animal, can give rise to two types of pluripotent stem cells. In vivo, PGCs can give rise to embryonal carcinoma cells, the pluripotent stem cells of testicular tumors. Cultured PGCs exposed to a specific cocktail of growth factors give rise to embryonic germ cells, pluripotent stem cells that can contribute to all the lineages of chimeric embryos including the germline. The conversion of PGCs into pluripotent stem cells is a remarkably similar process to nuclear reprogramming in which a somatic nucleus is reprogrammed in the egg cytoplasm. Understanding the genetics of embryonal carcinoma cell formation and the growth factor signaling pathways controlling embryonic germ cell derivation could tell us much about the molecular controls on developmental potency in mammals.     

Developmental potential of mouse primordial germ cells

There are distinctive and characteristic genomic modifications in primordial germ cells that distinguish the germ cell lineage from somatic cells. These modifications include, genome-wide demethylation, erasure of allele-specific methylation associated with imprinted genes, and the re-activation of the X chromosome. The allele-specific differential methylation is involved in regulating the monoallelic expression, and thus the gene dosage, of imprinted genes, which underlies functional differences between parental genomes. However, when the imprints are erased in the germ line, the parental genomes acquire an equivalent epigenetic and functional state. Therefore, one of the reasons why primordial germ cells are unique is because this is the only time in mammals when the distinction between parental genomes ceases to exist. To test how the potentially imprint-free primordial germ cell nuclei affect embryonic development, we transplanted them into enucleated oocytes. Here we show that the reconstituted oocyte developed to day 9.5 of gestation, consistently as a small embryo and a characteristic abnormal placenta. The embryo proper also did not progress much further even when the inner cell mass was 'rescued' from the abnormal placenta by transfer into a tetraploid host blastocyst. We found that development of the experimental conceptus was affected, at least in part, by a lack of gametic imprints, as judged by DNA methylation and expression analysis of several imprinted genes. The evidence suggests that gametic imprints are essential for normal development, and that they can neither be initiated nor erased in mature oocytes; these properties are unique to the developing germ line.     

Epigenetic reprogramming in early mammalian development and following somatic nuclear transfer

Epigenetic modifications of the genome play a significant role in the elaboration of the genetic code as established at fertilisation. These modifications affect early growth and development through their influence on gene expression especially on imprinted genes. Genome-wide epigenetic reprogramming in germ cells is essential in order to reset the parent-of-origin specific marking of imprinted genes, but may have a more general role in the restoration of totipotency in the early embryo. In a similar way, on somatic nuclear cloning, a differentiated cell must become 'reprogrammed' restoring totipotency in order to undergo development. Here we discuss the dynamic epigenetic reprogramming that takes place during normal development and highlight those areas with relevance to somatic nuclear cloning and the possibility of improving the efficiency of this process. We propose the concept of 'epigenetic checkpoints' for normal progression of development and the loss of totipotency.     

Epiblast stem cell-based system reveals reprogramming synergy of germline factors

Epigenetic reprogramming in early germ cells is critical toward the establishment of totipotency, but investigations of the germline events are intractable. An objective cell culture-based system could provide mechanistic insight on how the key determinants of primordial germ cells (PGCs), including Prdm14, induce reprogramming in germ cells to an epigenetic ground state. Here we show a Prdm14-Klf2 synergistic effect that can accelerate and enhance reversion of mouse epiblast stem cells (epiSCs) to a naive pluripotent state, including X reactivation and DNA demethylation. Notably, Prdm14 alone has little effect on epiSC reversion, but it enhances the competence for reprogramming and potentially PGC specification. Reprogramming of epiSCs by the combinatorial effect of Prdm14-Klf2 involves key epigenetic changes, which might have an analogous role in PGCs. Our study provides a paradigm toward a systematic analysis of how other key genes contribute to complex and dynamic events of reprogramming in the germline.     

Epigenetic marking correlates with developmental potential in cloned bovine preimplantation embryos

During differentiation, somatic nuclei acquire highly specialized DNA and chromatin modifications, which are thought to result in cellular memory of the differentiated state. Upon somatic nuclear transfer into oocytes, the donor nucleus may have to undergo reprogramming of these epigenetic marks in order to achieve totipotency. This may involve changes in epigenetic features similar to those that occur in normal embryos during early development. However, there is accumulating evidence that epigenetic reprogramming is severely deficient in cloned embryos. Several reports reveal inefficient demethylation and inappropriate reestablishment of DNA methylation in quantitative and qualitative patterns on somatic nuclear transfer. Here we examine histone H3 lysine 9 (H3-K9) methylation and acetylation in normal embryos and in those created by somatic nuclear transfer. We find that H3-K9 methylation is reprogrammed in parallel with DNA methylation in normal embryos. However, the majority of cloned embryos exhibit H3-K9 hypermethylation associated with DNA hypermethylation, suggesting a genome-wide failure of reprogramming. Strikingly, the precise epigenotype in cloned embryos depends on the donor cell type, and the proportion of embryos with normal epigenotypes correlates closely with the proportion developing to the blastocyst stage. These results suggest a mechanistic link between DNA and histone methylation in the mammalian embryo and reveal an association between epigenetic marks and developmental potential of cloned embryos.     

DNA methylation is a primary mechanism for silencing postmigratory primordial germ cell genes in both germ cell and somatic cell lineages

DNA methylation is necessary for the silencing of endogenous retrotransposons and the maintenance of monoallelic gene expression at imprinted loci and on the X chromosome. Dynamic changes in DNA methylation occur during the initial stages of primordial germ cell development; however, all consequences of this epigenetic reprogramming are not understood. DNA demethylation in postmigratory primordial germ cells coincides with erasure of genomic imprints and reactivation of the inactive X chromosome, as well as ongoing germ cell differentiation events. To investigate a possible role for DNA methylation changes in germ cell differentiation, we have studied several marker genes that initiate expression at this time. Here, we show that the postmigratory germ cell-specific genes Mvh, Dazl and Scp3 are demethylated in germ cells, but not in somatic cells. Premature loss of genomic methylation in Dnmt1 mutant embryos leads to early expression of these genes as well as GCNA1, a widely used germ cell marker. In addition, GCNA1 is ectopically expressed by somatic cells in Dnmt1 mutants. These results provide in vivo evidence that postmigratory germ cell-specific genes are silenced by DNA methylation in both premigratory germ cells and somatic cells. This is the first example of ectopic gene activation in Dnmt1 mutant mice and suggests that dynamic changes in DNA methylation regulate tissue-specific gene expression of a set of primordial germ cell-specific genes.