Reinald Fundele

Active demethylation of the paternal genome in the mouse zygote.

DNA methylation is essential for the control of a number of biological mechanisms in mammals [1]. Mammalian development is accompanied by two major waves of genome-wide demethylation and remethylation: one during germ-cell development and the other after fertilisation [2] [3] [4] [5] [6] [7]. Most previous studies have suggested that the genome-wide demethylation observed after fertilisation occurs passively, that is, by the lack of maintenance methylation following DNA replication and cell division [6] [7], although one other study has reported that replication-independent demethylation may also occur during early embryogenesis [8]. Here, we report that genes that are highly methylated in sperm are rapidly demethylated in the zygote only hours after fertilisation, before the first round of DNA replication commences. By contrast, the oocyte-derived maternal alleles are unaffected by this reprogramming. They either remain methylated after fertilisation or become further methylated de novo. These results provide the first direct evidence for active demethylation of single-copy genes in the mammalian zygote and, moreover, reveal a striking asymmetry in epigenetic methylation reprogramming. Whereas paternally (sperm)-derived sequences are exposed to putative active demethylases in the oocyte cytoplasm, maternally (oocyte)-derived sequences are protected from this reaction. These results, whose generality is supported by findings of Mayer et al. [9], have important implications for the establishment of biparental genetic totipotency after fertilisation, the establishment and maintenance of genomic imprinting, and the reprogramming of somatic cells during cloning.

Placental-specific IGF-II is a major modulator of placental and fetal growth

Imprinted genes in mammals are expressed from only one of the parental chromosomes, and are crucial for placental development and fetal growth. The insulin-like growth factor II gene (Igf2) is paternally expressed in the fetus and placenta. Here we show that deletion from the Igf2 gene of a transcript (P0) specifically expressed in the labyrinthine trophoblast of the placenta leads to reduced growth of the placenta, followed several days later by fetal growth restriction. The fetal to placental weight ratio is thus increased in the absence of the P0 transcript. We show that passive permeability for nutrients of the mutant placenta is decreased, but that secondary active placental amino acid transport is initially upregulated, compensating for the decrease in passive permeability. Later the compensation fails and fetal growth restriction ensues. Our study provides experimental evidence for imprinted gene action in the placenta that directly controls the supply of maternal nutrients to the fetus, and supports the genetic conflict theory of imprinting. We propose that the Igf2 gene, and perhaps other imprinted genes, control both the placental supply of, and the genetic demand for, maternal nutrients to the mammalian fetus.

Embryogenesis: Demethylation of the zygotic paternal genome

In mammals, both parental genomes undergo dramatic epigenetic changes after fertilization to form the diploid somatic genome. Here we show that the paternal genome in the mouse is significantly and actively demethylated within 6–8 hours of fertilization, before the onset of DNA replication, whereas the maternal genome is demethylated after several cleavage divisions. This active demethylation of the paternal genome may be associated with epigenetic remodelling of sperm chroma-tin, in order to establish parent-specific developmental programmes during early embryogenesis.

Heterochromatin, HP1 and methylation at lysine 9 of histone H3 in animals

Abstract. We show that methylated lysine 9 of histone H3 (Me9H3) is a marker of heterochromatin in divergent animal species. It localises to both constitutive and facultative heterochromatin and replicates late in S-phase of the cell cycle. Significantly, Me9H3 is enriched in the inactive mammalian X chromosome (Xi) in female cells, as well as in the XY body during meiosis in the male, and forms a G-band pattern along the arms of the autosomes. Me9H3 is a constituent of imprinted chromosomes that are repressed. The paternal and maternal pronuclei in one-cell mouse embryos show a striking non-equivalence in Me9H3: the paternal pronucleus contains no immunocytologically detectable Me9H3. The levels of Me9H3 on the parental chromosomes only become equivalent after the two-cell stage. Finally, we provide evidence that Me9H3 is neither necessary nor sufficient for localisation of heterochromatin protein 1 (HP1) to chromosomal DNA.

HP1-β is required for development of the cerebral neocortex and neuromuscular junctions

HP1 proteins are thought to be modulators of chromatin organization in all mammals, yet their exact physiological function remains unknown. In a first attempt to elucidate the function of these proteins in vivo, we disrupted the murine Cbx1 gene, which encodes the HP1-β isotype, and show that the Cbx1−/−-null mutation leads to perinatal lethality. The newborn mice succumbed to acute respiratory failure, whose likely cause is the defective development of neuromuscular junctions within the endplate of the diaphragm. We also observe aberrant cerebral cortex development in Cbx1−/− mutant brains, which have reduced proliferation of neuronal precursors, widespread cell death, and edema. In vitro cultures of neurospheres from Cbx1−/− mutant brains reveal a dramatic genomic instability. Our results demonstrate that HP1 proteins are not functionally redundant and that they are likely to regulate lineage-specific changes in heterochromatin organization.

Expression of the imprinted genes MEST/Mest in human and murine placenta suggests a role in angiogenesis.

In the mouse fetus, Mest is widely expressed in mesoderm derived tissues. In separate studies in mice and in humans, it has been shown to be maternally imprinted, that is, only the paternally inherited allele is active. Here, we show that starting with implantation, Mest is also expressed in maternal decidua of the mouse and in placenta of both humans and mice. Expression in murine decidua was restricted to endothelial cells. After Day 7, expression in the decidua gradually decreased. Mest‐specific RT‐PCR and restriction fragment length variant (RFLV) analysis of decidualized endometrium isolated from (M. musculus × M. spretus)F1 females showed that only the paternally derived Mest allele was activated in the decidual endothelium. In the mouse extraembryonic tissues, Mest transcripts were detected in derivatives of extraembryonic mesoderm only. Here, hemangioblast precursor cells and endothelial cells were positive. At all developmental stages of the mouse, trophoblast‐derived cells were clearly devoid of Mest transcripts. In the human placenta MEST transcripts were also detected in hemangioblast precursor cells, however, MEST was also expressed in villous and invasive cytotrophoblast. In a human choriocarcinoma/trophoblastic tumour grown in a nude mouse, human MEST was expressed in the tumour cells, whereas murine Mest was expressed in endothelia of the murine capillaries. The expression pattern exhibited by both Mest and MEST in extraembryonic tissues during development and during formation of choriocarcinoma/trophoblast tumour suggests a functional role of the MEST proteins related to oncofetal angiogenesis. Dev Dyn 2000;217:1–10. ©2000 Wiley‐Liss, Inc.

Different Molecular Mechanisms Underlie Placental Overgrowth Phenotypes Caused by Interspecies Hybridization, Cloning, and Esx1 Mutation

To obtain a deeper insight into the genes and gene networks involved in the development of placentopathies, we have assessed global gene expression in three different models of placental hyperplasia caused by interspecies hybridization (IHPD), cloning by nuclear transfer, and mutation of the Esx1 gene, respectively. Comparison of gene expression profiles of approximately 13,000 expressed sequence tags (ESTs) identified specific subsets of genes with changed expression levels in IHPD, cloned, and Esx1 mutant placentas. Of interest, only one gene of known function and one EST of unknown function were found common to all three placentopathies; however, a significant number of ESTs were common to IHPD and cloned placentas. In contrast, only one gene was shared between IHPD and Esx1 mutant, and cloned and Esx1 mutant placentas, respectively. These genes common to different abnormal placental growth genotypes are likely to be important in the occurrence of placentopathy. Developmental Dynamics 230:149–164, 2004.

H19 and Igf2 are expressed and differentially imprinted in neuroectoderm-derived cells in the mouse brain

Abstract Igf2 and H19 are reciprocally imprinted genes that are closely linked and coexpressed in tissues of mesodermal and endodermal origin. Here we report that coexpression of these genes is also found in specific fetal tissues of neuroectodermal origin, that is in the ventral midline region of both the hindbrain and spinal cord. For cells of neuroectodermal origin, complete absence of Igf2 and H19 transcription was previously described. Analysis of allele-specific expression of both Igf2 and H19 in the ventral midline region of the hindbrain shows that H19 is expressed monoallelically, with the paternal allele being silent, whereas Igf2 is expressed biallelically. Furthermore, we observed a strong influence of the parental species background, in that the Mus musculus allele was always expressed at higher levels than the M. spretus allele. This was observed when the M. spretus allele was contributed by the mother or by the father. An analysis of Igf2 methylation by bisulphite genomic sequencing provided no clear answer as to whether Igf2 expression and methylation are linked in a tissue of neuroectodermal origin. Taken together, our results provide novel information on H19 and Igf2 expression and imprinting patterns in the fetal mouse brain. In addition, they indicate that some aspects of Igf2 regulation in cells of neuroectodermal origin do not follow the pattern that exists in mesoderm- and endoderm-derived tissues. Apart from the ventral midline region, H19 and Igf2 were found to be coexpressed in the ectodermally derived Rathke’s pouch and in some circumventricular organs of the brain, such as the organum vasculosum of the lamina terminalis (OVLT) and the pineal gland.

Expression of mouse Tbx22 supports its role in palatogenesis and glossogenesis

TBX22 belongs to the T‐box family of transcription factors and was originally found in an in silico approach designed to identify new genes on the human Xq12‐q21 region. Mutations in TBX22 have been reported in families with X‐linked cleft palate and ankyloglossia (CPX), but the underlying pathogenetic mechanism remained unknown. We have identified mouse Tbx22 and analyzed its expression during embryogenesis by reverse transcriptase‐polymerase chain reaction and in situ hybridization. In mouse embryos, it is expressed in distinct areas of the head, namely the mesenchyme of the inferior nasal septum, the posterior palatal shelf before fusion, the attachment of the tongue, and mesenchymal cells surrounding the eye anlage. The localization in the tongue frenulum perfectly correlates with the ankyloglossia phenotype in CPX. Furthermore, we identified positionally conserved binding sites for transcription factors, two of which have been implicated previously in palatogenesis (MSX1, PRX2). Developmental Dynamics 226:579–586, 2003.

Proliferation and growth factor expression in abnormally enlarged placentas of mouse interspecific hybrids

It has been shown previously that abnormal placental growth occurs in crosses and backcrosses between different mouse (Mus) species. In such crosses, late gestation placentas may weigh between 13 and 848 mg compared with a mean placental weight of approximately 100 mg in late gestation M. musculus intraspecific crosses. A locus on the X‐chromosome was shown to segregate with placental dysplasia. Thus in the (M. musculus × M. spretus)F1 × M. musculus backcross, placental hyperplasia cosegregates with a M. spretus derived X‐chromosome. Here we have investigated whether increased cell proliferation and aberrant expression of two genes that are involved in placental growth control, Igf2 and Esx1, may cause, or contribute to placental hyperplasia. Increased bromodeoxyuridine labeling of nuclei, reflecting enhanced proliferation, was indeed observed in hyperplastic placentas when compared with normal littermate placentas. Also, increased expression of Igf2 was seen in giant cells and spongiotrophoblast. However, when M. musculus × M. spretus F1 females were backcrossed with males that were heterozygous for a targeted mutation of the Igf2 gene, placentas that carried a M. spretus derived X‐chromosome and were negative for a functional Igf2 allele exhibited an intermediate placental phenotype. Furthermore, in early developmental stages of placental hyperplasia, we observed a decreased expression of the X‐chromosomal Esx1 gene. This finding suggests that abnormal expression of both Igf2 and Esx1 contributes to abnormal placental development in mouse interspecific hybrids. However, Esx1 is not regulated by IGF2.