Genomic imprinting is a barrier to parthenogenesis in mammals

Only mammals have relinquished parthenogenesis as a means of producing descendants. Bi-parental reproduction is necessary due to parent-specific epigenetic modification of the genome during gametogenesis, which leads to non-equivalent expression of imprinted genes from the maternal and paternal alleles. However, a series of our work showed that alteration of maternal imprinting by oocyte reconstruction using non-growing oocytes, together with deletion of the H19 gene provide appropriate expression of imprinted genes from the maternal genome. The resulting ng (non-growing)/fg (fully-grown) parthenogenic embryos were developed to term. Here, we discuss how the parthenogenetic embryos survived as normal individuals.     

Imprint switching for non-random X-chromosome inactivation during mouse oocyte growth

In mammals, X-chromosome inactivation occurs in all female cells, leaving only a single active X chromosome. This serves to equalise the dosage of X-linked genes in male and female cells. In the mouse, the paternally derived X chromosome (X(P)) is imprinted and preferentially inactivated in the extraembryonic tissues whereas in the embryonic tissues inactivation is random. To investigate how X(P) is chosen as an inactivated X chromosome in the extraembryonic cells, we have produced experimental embryos by serial nuclear transplantation from non-growing (ng) oocytes and fully grown (fg) oocytes, in which the X chromosomes are marked with (1) an X-linked lacZ reporter gene to assay X-chromosome activity, or (2) the Rb(X.9)6H translocation as a cytogenetic marker for studying replication timing. In the extraembryonic tissues of these ng/fg embryos, the maternal X chromosome (X(M)) derived from the ng oocyte was preferentially inactivated whereas that from the fg oocyte remained active. However, in the embryonic tissues, X inactivation was random. This suggests that (1) a maternal imprint is set on the X(M) during oocyte growth, (2) the maternal imprint serves to render the X(M) resistant to inactivation in the extraembryonic tissues and (3) the X(M) derived from an ng oocyte resembles a normal X(P).     

High-frequency generation of viable mice from engineered bi-maternal embryos

Mammalian development to adulthood typically requires both maternal and paternal genomes, because genomic imprinting places stringent limitations on mammalian development, strictly precluding parthenogenesis. Here we report the generation of bi-maternal embryos that develop at a high success rate equivalent to the rate obtained with in vitro fertilization of normal embryos. These bi-maternal mice developed into viable and fertile female adults. The bi-maternal embryos, distinct from parthenogenetic or gynogenetic conceptuses, were produced by the construction of oocytes from fully grown oocytes and nongrowing oocytes that contain double deletions in the H19 differentially methylated region (DMR) and the Dlk1-Dio3 intergenic germline-derived DMR. The results provide conclusive evidence that imprinted genes regulated by these two paternally methylated imprinting-control regions are the only paternal barrier that prevents the normal development of bi-maternal mouse fetuses to term.     

Appropriate expression of imprinted genes on mouse chromosome 12 extends development of bi-maternal embryos to term

Recently, we reported that the restored regulation of imprinted gene expression from two regions -H19 differentially methylated region (H19-DMR) and intergenic germline-derived DMR (IG-DMR) - is sufficient for accomplishing full-term development in mice. In the present study, we determined the developmental ability of the bi-maternal embryos (BMEs) containing the non-growing oocyte genome with the IG-DMR deletion (ng(Deltach12)) and fully-grown (fg) oocyte genome. Foetuses derived from ng(Deltach12)/fg BMEs were alive at E19.5 but could not survive further. Comparison with BMEs derived from Igf2+/- ng/fg genomes suggests that bi-allelic H19 expression might be involved in foetal development.     

Maternal primary imprinting is established at a specific time for each gene throughout oocyte growth.

Primary imprinting during gametogenesis governs the monoallelic expression/repression of imprinted genes in embryogenesis. Previously, we showed that maternal primary imprinting is disrupted in neonate-derived non-growing oocytes. Here, to investigate precisely when and in what order maternal primary imprinting progresses, we produced parthenogenetic embryos containing one genome from a non-growing or growth-stage oocyte from 1- to 20-day-old mice and one from a fully grown oocyte of adult mice. We used these embryos to analyze the expression of eight imprinted genes: Peg1/Mest, Peg3, Snrpn, Znf127, Ndn, Impact, Igf2r, and p57(KIP2). The results showed that the imprinting signals for each gene were not all imposed together at a specific time during oocyte growth but rather occurred throughout the period from primary to antral follicle stage oocytes. The developmental ability of the constructed parthenogenetic embryos was gradually reduced as the nuclear donor oocytes grew. These studies provide the first insight into the process of primary imprinting during oocyte growth.     

Erasing genomic imprinting memory in mouse clone embryos produced from day 11.5 primordial germ cells

Genomic imprinting is an epigenetic mechanism that causes functional differences between paternal and maternal genomes, and plays an essential role in mammalian development. Stage-specific changes in the DNA methylation patterns of imprinted genes suggest that their imprints are erased some time during the primordial germ cell (PGC) stage, before their gametic patterns are re-established during gametogenesis according to the sex of individuals. To define the exact timing and pattern of the erasure process, we have analyzed parental-origin-specific expression of imprinted genes and DNA methylation patterns of differentially methylated regions (DMRs) in embryos, each derived from a single day 11.5 to day 13.5 PGC by nuclear transfer. Cloned embryos produced from day 12.5 to day 13.5 PGCs showed growth retardation and early embryonic lethality around day 9.5. Imprinted genes lost their parental-origin-specific expression patterns completely and became biallelic or silenced. We confirmed that clones derived from both male and female PGCs gave the same result, demonstrating the existence of a common default state of genomic imprinting to male and female germlines. When we produced clone embryos from day 11.5 PGCs, their development was significantly improved, allowing them to survive until at least the day 11.5 embryonic stage. Interestingly, several intermediate states of genomic imprinting between somatic cell states and the default states were seen in these embryos. Loss of the monoallelic expression of imprinted genes proceeded in a step-wise manner coordinated specifically for each imprinted gene. DNA demethylation of the DMRs of the imprinted genes in exact accordance with the loss of their imprinted monoallelic expression was also observed. Analysis of DNA methylation in day 10.5 to day 12.5 PGCs demonstrated that PGC clones represented the DNA methylation status of donor PGCs well. These findings provide strong evidence that the erasure process of genomic imprinting memory proceeds in the day 10.5 to day 11.5 PGCs, with the timing precisely controlled for each imprinted gene. The nuclear transfer technique enabled us to analyze the imprinting status of each PGC and clearly demonstrated a close relationship between expression and DNA methylation patterns and the ability of imprinted genes to support development.     

De novo DNA methylation independent establishment of maternal imprint on X chromosome in mouse oocytes

In female mouse embryos, the paternal X chromosome (Xp) is preferentially inactivated during preimplantation development and trophoblast differentiation. This imprinted X-chromosome inactivation (XCI) is partly due to an activating imprint on the maternal X chromosome (Xm), which is set during oocyte growth. However, the nature of this imprint is unknown. DNA methylation is one candidate, and therefore we examined whether disruptions of the two de novo DNA methyltransferases in growing oocytes affect imprinted XCI. We found that accumulation of histone H3 lysine-27 trimethylation, a hallmark of XCI, occurs normally on the Xp, and not on the Xm, in female blastocysts developed from the mutant oocytes. Furthermore, the allelic expression patterns of X-linked genes including Xist and Tsix were unchanged in preimplantation embryos and also in the trophoblast. These results show that a maternal disruption of the DNA methyltransferases has no effect on imprinted XCI and argue that de novo DNA methylation is dispensable for Xm imprinting. This underscores the difference between imprinted XCI and autosomal imprinting.     

Genomic imprinting and endosperm development in flowering plants

Genomic imprinting, the parent-of-origin-specific expression of genes, plays an important role in the seed development of flowering plants. As different sets of genes are imprinted and hence silenced in maternal and paternal gametophyte genomes, the contributions of the parental genomes to the offspring are not equal. Imbalance between paternally and maternally imprinted genes, for instance as a result of interploidy crosses, or in seeds in which imprinting has been manipulated, results in aberrant seed development. It is predominantly the endosperm, and not or to a far lesser extent the embryo, that is affected by such imbalance. Deviation from the normal 2m:1p ratio in the endosperm genome has a severe effect on endosperm development, and often leads to seed abortion. Molecular expression data for imprinted genes suggest that genomic imprinting takes place only in the endosperm of the developing seed. Although far from complete, a picture of how imprinting operates in flowering plants has begun to emerge. Imprinted genes on either the maternal or paternal side are marked and silenced in a process involving DNA methylation and chromatin condensation. In addition, on the maternal side, imprinted genes are most probably under control of the polycomb FIS genes.     

Genomic imprinting disrupted by a maternal effect mutation in the Dnmt1 gene

Maintenance of genomic methylation patterns in mammalian somatic cells depends on DNA methyltransferase-1 (Dnmt1). Mouse oocytes and preimplantation embryos lack Dnmt1 but express a variant of this protein called Dnmt1o. We eliminated Dnmt1o by deletion of the oocyte-specific promoter and first exon from the Dnmt1 locus. Homozygous animals were normal, but most heterozygous fetuses of homozygous females died during the last third of gestation. Although genomic methylation patterns were established normally in Dnmt1o-deficient oocytes, embryos derived from such oocytes showed a loss of allele-specific expression and methylation at certain imprinted loci. Transient nuclear localization of Dnmt1o in 8-cell embryos suggests that this variant of Dnmt1 provides maintenance methyltransferase activity specifically at imprinted loci during the fourth embryonic S phase.     

Efficiency and kinetics of the in vitro fertilization process in bovine oocytes with different meiotic competence

The aim of the study was to investigate the efficiency and kinetics of fertilization in oocytes with different meiotic competence, as defined by the phase of the follicular wave and follicle size. Oocytes were recovered from cows with synchronized estrus cycles, slaughtered in either the growth (day 3) or the dominant (day 7) phase, separately from large, medium and small follicles. The oocytes were matured and fertilized by a standard protocol. Twenty-four hours after fertilization, the oocytes were denuded from cumulus cells, fixed and stained with bisbensimid Hoechst-PBS. Fertilization was more efficient and the first cleavage was accelerated in growth phase-derived oocytes, as shown by significantly higher (p < or = 0.01) proportions of both normally fertilized and cleaved oocytes (68.8 and 25.1%), in comparison with dominant phase-derived oocytes (44.2 and 10.3%). In the growth-phase derived oocytes, proportions of normally fertilized and cleaved oocytes were significantly higher (p < or = 0.01) in oocytes from large (100.0 and 36.4%) and medium (83.3 and 36.5%) follicles than in those from small (54.8 and 14.6%) follicles. The dominant phase-derived oocytes showed higher proportions of normally fertilized and cleaved oocytes in the populations recovered from small (51.5 and 10.0%) and medium (43.1 and 12.0%) follicles than in those from large (25.0 and 0%) follicles; however, the differences were not significant. It can be concluded that: (i) efficiency and kinetics of fertilization differ in relation to oocyte's meiotic competence; (ii) improved development of embryos from oocytes with greater meiotic competence is associated with a more effective fertilization process.     

Reconstruction of the heteroparental diploid condition in rabbit zygotes by nuclear transfer

Studies on genomic imprinting showed that parental genomes have complementary roles during embryogenesis, are both essential and need to be synchronized in their embryonic stage for successful development to term. To our knowledge, these studies have not been performed in species other than mice. We studied the in vitro and in vivo development of reconstructed zygotes by combining female haploid nuclear donors and androgenetic hemizygous recipients. Haploid donor embryos at the 8- or 32-cell stage were obtained from electroactivated young rabbit ova (eight pulses maximum, consisting of 0 6 kVcm(-1) for 60 microsec each, 38 min apart) which were further cultured for 24 h or 32 h. Couplets formed by both the haploid male hemizygous recipients and haploid female donor cells were electrofused (2.2 kVcm(-1) for 60 microsec duration each, 30 min apart) and their nuclear configuration determined 122 of those fused (43%: 122/286) were diploid. Reconstructed diploid zygotes developed in vitro up to the compacted morula, blastocyst and hatched stages (1/8-nuclei x 50%, 18% and 9% vs. 1/32-nuclei: 47%, 25% and 19%; P > 0.05), respectively. In embryo transfer assays, both 1/32-reconstructed zygotes and control, non-manipulated zygotes were transferred to synchronized does Four live reconstructed fetuses (4/49: 8 1% survival rate) and five in regression stage (9/49: 18% implantation rate) were observed on Day 21 post-ovulation, whereas from control zygotes, 11 fetuses were alive (11/53 21% fetal survival rate) and 2 degenerated (13/53 x 24 5% implantation rate). Similar results were obtained from a final experiment, in which development was allowed to progress to term. Six live rabbit pups derived front experimentally reconstructed zygotes (11%; 6/54) and three fetuses in regression stage were obtained; values slightly lower than those derived from non-manipulated and transferred control zygotes (18% 9/50, live born rate).     

Extracellular and intracellular factors affecting nuclear and cytoplasmic maturation of porcine oocytes collected from different sizes of follicles

Nuclear and cytoplasmic maturation of porcine oocytes collected from different sizes of follicles were examined. Oocyte-cumulus complexes were collected from small (1-2 mm in diameter), medium (3-6 in diameter) and large (7-8 mm in diameter) follicles and cultured in a modified tissue culture medium 199 for 44 h. Nuclear maturation was evaluated after orcein staining, and cytoplasmic maturation was evaluated by intracellular glutathione (GSH) assay. Oocyte diameter, cumulus morphology, steroid hormones and glutathione in the follicular fluid (FF), were also examined. Significantly higher proportions of oocytes collected from large and medium follicles reached metaphase II than did oocytes from small follicles. Oocytes from small follicles also had a smaller size. GSH content was significantly higher (p < 0.05) in oocytes from large (14.24 +/- 2.1 pmol/oocyte) and medium (13.69 +/- 1.5 pmol/oocyte) follicles than in oocytes from small (9.44 +/- 1.28 pmol/oocyte) follicles just after collection. After maturation, oocytes from medium follicles had a higher GSH concentration than oocytes from small follicles. It was found that between 49.7 +/- 5.18 nM and 52.25 +/- 0.78 nM GSH was present in FF but there was no statistical difference between follicle sizes. A significantly higher (p < 0.001) estradiol level was present in FF from large follicles (299.2 +/- 68.6 ng/ml) than from medium (40.0 +/- 6.4 ng/ml) and small (41.2 +/- 3.7 ng/ml) follicles. Progesterone concentrations in FF from large (281.6 +/- 45.9 ng/ml) and medium (267.5 +/- 38.6 ng/ml) follicles were significantly higher than that (174.7 +/- 22.0 ng/ml) from small follicles. These results indicate that the oocyte's ability to accumulate intracellular GSH during maturation, and extracellular steroid hormones and cumulus cells, affect the competence of porcine oocytes to undergo nuclear and cytoplasmic maturation.     

Characterization of the IGF2 Imprinted Gene Methylation Status in Bovine Oocytes during Folliculogenesis

DNA methylation reprogramming occurs during mammalian gametogenesis and embryogenesis. Sex-specific DNA methylation patterns at specific CpG islands controlling imprinted genes are acquired during this window of development. Characterization of the DNA methylation dynamics of imprinted genes acquired by oocytes during folliculogenesis is essential for understanding the physiological and genetic aspects of female gametogenesis and to determine the parameters for oocyte competence. This knowledge can be used to improve in vitro embryo production (IVP), specifically because oocyte competence is one of the most important aspects determining the success of IVP. Imprinted genes, such as IGF2, play important roles in embryo development, placentation and fetal growth. The aim of this study was to characterize the DNA methylation profile of the CpG island located in IGF2 exon 10 in oocytes during bovine folliculogenesis. The methylation percentages in oocytes from primordial follicles, final secondary follicles, small antral follicles, large antral follicles, MII oocytes and spermatozoa were 73.74 ± 2.88%, 58.70 ± 7.46%, 56.00 ± 5.58%, 65.77 ± 5.10%, 56.35 ± 7.45% and 96.04 ± 0.78%, respectively. Oocytes from primordial follicles showed fewer hypomethylated alleles (15.5%) than MII oocytes (34.6%) (p = 0.039); spermatozoa showed only hypermethylated alleles. Moreover, MII oocytes were less methylated than spermatozoa (p<0.001). Our results showed that the methylation pattern of this region behaves differently between mature oocytes and spermatozoa. However, while this region has a classical imprinted pattern in spermatozoa that is fully methylated, it was variable in mature oocytes, showing hypermethylated and hypomethylated alleles. Furthermore, our results suggest that this CpG island may have received precocious reprogramming, considering that the hypermethylated pattern was already found in growing oocytes from primordial follicles. These results may contribute to our understanding of the reprogramming of imprinted genes during bovine oogenesis.     

PGC7/Stella protects against DNA demethylation in early embryogenesis

DNA methylation is an important means of epigenetic gene regulation and must be carefully controlled as a prerequisite for normal early embryogenesis. Although global demethylation occurs soon after fertilization, it is not evenly distributed throughout the genome. Genomic imprinting and epigenetic asymmetry between parental genomes, that is, delayed demethylation of the maternal genome after fertilization, are clear examples of the functional importance of DNA methylation. Here, we show that PGC7/Stella, a maternal factor essential for early development, protects the DNA methylation state of several imprinted loci and epigenetic asymmetry. After determining that PGC7/Stella binds to Ran binding protein 5 (RanBP5; a nuclear transport shuttle protein), mutant versions of the two proteins were used to examine exactly when and where PGC7/Stella functions within the cell. It is likely that PGC7/Stella protects the maternal genome from demethylation only after localizing to the nucleus, where it maintains the methylation of several imprinted genes. These results demonstrate that PGC7/Stella is indispensable for the maintenance of methylation involved in epigenetic reprogramming after fertilization.     

Selective loss of imprinting in the placenta following preimplantation development in culture

Preimplantation development is a period of dynamic epigenetic change that begins with remodeling of egg and sperm genomes, and ends with implantation. During this time, parental-specific imprinting marks are maintained to direct appropriate imprinted gene expression. We previously demonstrated that H19 imprinting could be lost during preimplantation development under certain culture conditions. To define the lability of genomic imprints during this dynamic period and to determine whether loss of imprinting continues at later stages of development, imprinted gene expression and methylation were examined after in vitro preimplantation culture. Following culture in Whitten's medium, the normally silent paternal H19 allele was aberrantly expressed and undermethylated. However, only a subset of individual cultured blastocysts (approximately 65%) exhibited biallelic expression, while others maintained imprinted H19 expression. Loss of H19 imprinting persisted in mid-gestation conceptuses. Placental tissues displayed activation of the normally silent allele for H19, Ascl2, Snrpn, Peg3 and Xist while in the embryo proper imprinted expression for the most part was preserved. Loss of imprinted expression was associated with a decrease in methylation at the H19 and Snrpn imprinting control regions. These results indicate that tissues of trophectoderm origin are unable to restore genomic imprints and suggest that mechanisms that safeguard imprinting might be more robust in the embryo than in the placenta.     

Effect of follicular size on meiotic and developmental competence of porcine oocytes

In several species, the developmental competence of the oocyte is acquired progressively during late follicular growth, after the acquisition of the competence to resume and complete meiosis. In the pig, full meiotic competence of the oocyte is reached in ovarian follicles with a diameter of 3 mm or more. However, there is no information about developmental competence acquisition. We analyzed the ability of oocytes from three foll icular size classes to resume and complete meiosis, to be fertilized, and to develop in vitro to the blastocyst stage. A total of 941 follicles were dissected from slaughterhouse gilt ovaries and classified as small (<3 mm, n = 330), medium (3-5 mm, n = 373), or large (>5 mm, n = 238). The cumulus-oocyte complexes recovered from these follicles were submitted to in vitro maturation for 44 h in TCM199 supplemented with 10 ng/ml EGF, 400 ng/ml pFSH and 570 microM cysteamine; in vitro fertilized for 18 h in mTBM with 10(5) frozen-thawed percoll-selected sperms/ml; and developed for 7 days in mSOF. Samples of oocytes or presumptive zygotes were fixed and stained at the end of maturation and fertilization. Groups of oocytes were cultured for 3 h in the presence of 35S-methionine before or after maturation for SDS-PAGE analysis of protein neosynthesis. More oocytes originating from medium and large follicles were competent for maturation than oocytes from small follicles (77 and 86% of metaphase II, respectively, versus 44%, P < 0.05). More oocytes from medium and large follicles werepenetratedby spermatozoa during in vitro fertilization, resulting in significantly more oocytes presenting two or more pronuclei at the end of fertilization (73 and 77% for medium and large follicles, respectively, versus 53% for small follicles, P < 0.05). More oocytes from medium and large follicles developed to the blastocyst stage (14 and 23%, respectively) than those from small follicles (3%, P < 0.05), even if the development rates were corrected by the maturation or fertilization rates. It is concluded that a high proportion of oocytes harvested from follicles of less than 3 mm in the pig are not fully competent for meiosis and are cytoplasmically deficient for development.     

A statistical model for dissecting genomic imprinting through genetic mapping

As a result of nonequivalent genetic contribution of maternal and paternal genomes to offsprings, genomic imprinting or called parent-of-origin effect, has been broadly identified in plants, animals and humans. Its role in shaping organism’s development has been unanimously recognized. However, statistical methods for identifying imprinted quantitative trait loci (iQTL) and estimating the imprinted effect have not been well developed. In this article, we propose an efficient statistical procedure for genomewide estimating and testing the effects of significant iQTL underlying the quantitative variation of interested traits. The developed model can be applied to two different genetic cross designs, backcross and F₂ families derived from inbred lines. The proposed procedure is built within the maximum likelihood framework and implemented with the EM algorithm. Extensive simulation studies show that the proposed model is well performed in a variety of situations. To demonstrate the usefulness of the proposed approach, we apply the model to a published data in an F₂ family derived from LG/S and SM/S mouse stains. Two partially maternal imprinting iQTL are identified which regulate the growth of body weight. Our approach provides a testable framework for identifying and estimating iQTL involved in the genetic control of complex traits.