Disruption of primary imprinting during oocyte growth leads to the modified expression of imprinted genes during embryogenesis

Fundamental cryobiology of mammalian oocytes and ovarian tissue

Embryo cryopreservation is a widely used and relatively well-established procedure. By contrast, ovarian tissue and unfertilized oocytes are only rarely cryopreserved, even though for germ line storage these often would be preferable to embryo cryopreservation. There are many reasons for this discrepancy. Unfertilized mature (MII) stage oocytes are more difficult to cryopreserve than cleavage stage embryos of the same species. Many factors contribute to this including the oocyte's surface to volume ratio, single membrane, temperature-sensitive metaphase spindle and zona, and its susceptibility to parthenogenetic activation and chill-injury. A completely different set of problems applies to primordial follicles. Oocytes in primordial follicles are very small and tolerate cryopreservation by slow cooling very well. The problem lies in the difficulty in producing mature oocytes from these primordial follicles. Better and/or more convenient cryopreservation procedures for both oocytes and ovarian tissue are being developed. This paper describes some of the advances in this area and outlines the relative merits and limitations of several currently available egg and ovarian tissue cryopreservation procedures.

Offspring from one-month-old lambs: studies on the developmental capability of prepubertal oocytes

A wave of follicular growth in lamb ovaries occurs at about 4 weeks of age, generating a life-time peak in follicle numbers. In order to take advantage of the large number of oocytes available, and to substantially decrease the generation interval, embryos were derived from oocytes collected from 1-mo-old lambs. Animals were subjected to one of 3 regimes of hormonal stimulation: groups 1 and 2 were treated to obtain germinal vesicle-stage oocytes, and group 3 to produce mature metaphase II oocytes. Adult sheep stimulated by an appropriate dose of FSH served as control. The developmental ability of collected oocytes was evaluated by either in vivo or in vitro culture to the blastocyst stage after in vitro maturation and/or fertilization. Blastocysts were transferred immediately or after cryopreservation to suitable recipient sheep. In order to investigate the full developmental potential of these embryos, pregnancies were allowed to go to term. The results show significant differences (P < 0.001) between all experimental groups in blastocyst numbers produced. Embryos derived from group 1 animals produced the greatest number of blastocysts, under both in vivo (36. 7%), and in vitro (22.9%) culture systems. Group 2 gave lowest blastocyst production (5.0%), while group 3 yielded 13.2% blastocysts. The number of pregnant recipients carrying to term lamb-derived embryos was severely reduced for both in vivo- (2 of 9; 22.2%) and in vitro-cultured, fresh (3 of 10; 30.0%) and cryopreserved (1 of 6; 16.7%) lamb embryos. This study is the first report of the birth of live lambs derived from oocytes obtained from donors as young as 4 wk. Defects in the competence of lamb-derived embryos may account for the increased fetal loss during pregnancy and the occurrence of mummified fetuses delivered alongside normal healthy lambs.

A human p57(KIP2) transgene is not activated by passage through the maternal mouse germline

Genomic imprinting results in expression of some autosomal genes from one parental allele only. Human chromosome 11p15, and the syntenic region on mouse distal chromosome 7, contain several imprinted genes, including p57 (KIP2) ( CDKN1C ) and IGF2. These two genes, which are separated by >700 kb, are both implicated in the pathogenesis of Beckwith-Wiedemann syndrome. We have shown previously that an Igf2/H19 transgene is expressed appropriately and can imprint at ectopic chromosomal locations. To investigate the p57 (KIP2) region, we similarly tested the imprinting and function of a 38 kb human genomic fragment containing the p57 (KIP2) gene in transgenic mice. This transgene showed appropriate tissue-specific expression and transgene copy number-dependent expression at ectopic sites. However, the levels of expression are reminiscent of that found for the paternal allele in humans (10%). There was no change in expression levels when the transgene was inherited from the maternal germline. These results suggest that the cis -elements required for enhanced expression of the maternally inherited p57 (KIP2) allele lie at a distance from the gene. This finding has important implications for the role of this gene in the human disease, in particular with respect to the translocation breakpoints identified in some patients.

Methylation imprinting of H19 and SNRPN genes in human benign ovarian teratomas

In humans, studies of female germ cells are very limited by ethics. The current study investigated the usefulness of benign ovarian teratomas as a substitute for ova in analyses of imprinted genes. Twenty-five human benign ovarian teratomas were typed with 45 microsatellite DNA markers and classified according to their genotypic features. Two oppositely imprinted genes, H19 and SNRPN, were then chosen for analysis of their methylation states in these tumors. These analyses revealed that benign ovarian teratomas consist of a mixture of genetically and epigenetically heterogeneous cell populations. In contrast to previous reports, we could document only one case rising from germ cells by meiosis-II nondisjunction. H19 and SNRPN were methylated in individual teratomas to various degrees, ranging from normal somatic cell to expected ovum levels. The allele with residual methylation of H19 was consistent with that methylated in the patient's blood DNA, thus being of paternal origin. Degrees of H19 hypomethylation and SNRPN hypermethylation increased as the cellular origin of the tumors advanced in oogenesis and were closely correlated in individual teratomas. These results could be best explained by the assumption that the primary imprinting is a progressively organized process and suggest that the establishment of primary imprints on different genes might be mechanistically linked, even when those genes are oppositely imprinted.

Parental origin-specific expression of Mash2 is established at the time of implantation with its imprinting mechanism highly resistant to genome-wide demethylation

The Mash2 gene encodes a basic helix-loop-helix transcription factor, which is highly expressed in diploid trophoblast cells of the postimplantation mouse embryo and is required for development of the spongiotrophoblast in order to form a functional placenta. Genomic imprinting of Mash2 has been previously reported; transcriptional inactivation of the paternal wild-type allele in heterozygotes carrying a maternal null allele results in a null-equivalent embryonic lethal phenotype. In order to study the Mash2 imprinting mechanism, we have created a new allele at this locus carrying a targeted insertion of an IRES (internal ribosome entry site)-lacZ cassette within the 3' untranslated region of the gene (referred to as "Mash2-lacZ"). This new allele has made it feasible to monitor paternal Mash2 expression in a wild-type-equivalent background. Our data suggest that parental origin-specific expression of Mash2 begins in the early postimplantation conceptus (5.5 dpc) at the time when trophoblast-specific expression is observed. We also show that the paternal allele is continuously repressed up to 9.5 dpc in the developing ectoplacental cone (EPC) and early chorio-allantoic placenta, with some cells escaping paternal repression. When maternally inherited, lacZ expression from this allele reflects the expression pattern of endogenous Mash2 transcripts up to 8.5 dpc. Furthermore, we have addressed the question of a requirement for DNA methylation for the Mash2 imprinting mechanism by crossing our Mash2-lacZ mice with mice mutant for Dnmt1 (DNA-methyltransferase1). Our results show a partial loss of transcriptional repression of the paternal allele in Dnmt1 deficient background. Interestingly, however, this is not sufficient to eliminate the highly biased parental allele-specific expression of Mash2. Thus, the preferential maternal expression of the gene is still maintained in Dnmt1 null mutant embryos, although methylation analyses demonstrate that the Mash2 locus is highly demethylated in Dnmt1 null mutant embryos. The locus is also highly demythyled in wild-type EPCs. Our results suggest the possibility that a mechanism other than DNA methylation, such as allele-specific chromatin conformation, may be involved in maintenance of parental origin-specific expression of Mash2.

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.

Mechanisms of genomic imprinting

A small number of mammalian genes undergo the process of genomic imprinting whereby the expression level of the alleles of a gene depends upon their parental origin. In the past year, attention has focused on the mechanisms that determine parental-specific expression patterns. Many imprinted genes are located in conserved clusters and, although it is apparent that imprinting of adjacent genes is jointly regulated, multiple mechanisms among and within clusters may operate. Recent developments have also refined the timing of the gametic imprints and further defined the mechanism by which DNA methyltransferases confer allelic methylation patterns.

Genetic mapping of a maternal locus responsible for familial hydatidiform moles

Hydatidiform mole (HM) is the product of an aberrant human pregnancy in which there is an abnormal embryonic development and proliferation of placental villi. The incidence of HM varies between ethnic groups, and occurs in 1 in every 1500 pregnancies in the USA. All HM cases are sporadic, except for extremely rare familial cases. The exact mechanisms leading to molar pregnancies are unknown. We previously postulated that women with recurrent hydatidiform moles are homozygous for an autosomal recessive defective gene. To map this gene genetically, we initiated a genome-wide scan with highly polymorphic short tandem repeats in individuals from two families with recurrent HM. Here, we demonstrate that a defective maternal gene is responsible for recurrent HM. This gene resides on chromosome 19q13.3-13.4 in a 15.2 cM interval flanked by D19S924 and D19S890. The identification of a gene for HM adds new insights into the molecular genetics of early embryogenesis and may be relevant to the large number of patients with sporadic HM.

A short DNA methyltransferase isoform restores methylation in vivo

Two murine DNA methyltransferase isoforms (MTases) have been observed, a longer form in somatic and embryonic stem (ES) cells and a shorter form in oocytes and preimplantation embryos. While the longer MTase is associated with maintenance methyltransferase activity in replicating cells, little is known about the shorter form. We present genetic and biochemical evidence that both isoforms are expressed from the same Dnmt1 gene by using different translation initiation sites in exons 1 and 4. We further demonstrate that the shorter isoform can functionally rescue Dnmt1 null ES cells that have a hypomethylated genome. These rescued ES cells differentiate in vivo into a variety of cell types, unlike the Dnmt1 null ES cells that die upon induction of differentiation. These results show that the shorter isoform can substitute for the longer maintenance MTase in ES and differentiated cells. Our data further indicate that the shorter MTase isoform found in oocytes is fully functional in vivo and may play an active role in the regulation of DNA methylation and the establishment of imprinting patterns.

Imprinting mechanisms

A number of recent studies have provided new insights into mechanisms that regulate genomic imprinting in the mammalian genome. Regions of allele-specific differential methylation (DMRs) are present in all imprinted genes examined. Differential methylation is erased in germ cells at an early stage of their development, and germ-line-specific methylation imprints in DMRs are reestablished around the time of birth. After fertilization, differential methylation is retained in core DMRs despite genome-wide demethylation and de novo methylation during preimplantation and early postimplantation stages. Direct repeats near CG-rich DMRs may be involved in the establishment and maintenance of allele-specific methylation patterns. Imprinted genes tend to be clustered; one important component of clustering is enhancer competition, whereby promoters of linked imprinted genes compete for access to enhancers. Regional organization and spreading of the epigenotype during development is also important and depends on DMRs and imprinting centers. The mechanism of cis spreading of DNA methylation is not known, but precedent is provided by the Xist RNA, which results in X chromosome inactivation in cis. Reading of the somatic imprints could be carried out by transcription factors that are sensitive to methylation, or by methyl-cytosine-binding proteins that are involved in transcriptional repression through chromatin remodeling.