An X-chromosome linked locus contributes to abnormal placental development in mouse interspecific hybrid.

Interspecific hybridization between closely related species is commonly associated with decreased fertility or viability of F1 hybrids. Thus, in mouse interspecific hybrids, several different hybrid sterility genes that impair gametogenesis of the male hybrids have been described. We describe a novel effect in hybrids between different mouse species that manifests itself in abnormal growth of the placenta. Opposite phenotypes, that is, placental hypotrophy versus hypertrophy, are observed in reciprocal crosses and backcrosses. The severity of the phenotype, which is mainly caused by abnormal development of the spongiotrophoblast, is influenced by the sex of the conceptus. In general, placental hypertrophy is associated with increased fetal growth. Hypotrophy of the placenta frequently leads to growth impairment or death of the fetus. One of the major genetic determinants of placental growth maps to the proximal part of the mouse X chromosome.

Positional cloning of the gene for X-linked retinitis pigmentosa 2.

X-linked retinitis pigmentosa (XLRP) results from mutations in at least two different loci, designated RP2 and RP3, located at Xp11.3 and Xp21.1, respectively. The RP3 gene was recently isolated by positional cloning, whereas the RP2 locus was mapped genetically to a 5-cM interval. We have screened this region for genomic rearrangements by the YAC representation hybridization (YRH) technique and detected a LINE1 (L1) insertion in one XLRP patient. The L1 retrotransposition occurred in an intron of a novel gene that consisted of five exons and encoded a polypeptide of 350 amino acids. Subsequently, nonsense, missense and frameshift mutations, as well as two small deletions, were identified in six additional patients. The predicted gene product shows homology with human cofactor C, a protein involved in the ultimate step of beta-tubulin folding. Our data provide evidence that mutations in this gene, designated RP2, are responsible for progressive retinal degeneration.

Spatial separation of parental genomes in preimplantation mouse embryos.

We have used two different experimental approaches to demonstrate topological separation of parental genomes in preimplantation mouse embryos: mouse eggs fertilized with 5-bromodeoxyuridine (BrdU)-labeled sperm followed by detection of BrdU in early diploid embryos, and differential heterochromatin staining in mouse interspecific hybrid embryos. Separation of chromatin according to parental origin was preserved up to the four-cell embryo stage and then gradually disappeared. In F1 hybrid animals, genome separation was also observed in a proportion of somatic cells. Separate nuclear compartments during preimplantation development, when extreme chromatin remodelling occurs, and possibly in some differentiated cell types, may be associated with epigenetic reprogramming.

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.

A high density of X-linked genes for general cognitive ability: a run-away process shaping human evolution?

The incidence of mental disability is 30% higher in males than in females. We have examined entries in the OMIM database that are associated with mental disability and for several other common defects. Our findings indicate that compared with the autosomes, the X chromosome contains a significantly higher number of genes that, when mutated, cause mental impairment. We propose that these genes are involved in the development of cognitive abilities and thus exert a large X-chromosome effect on general intelligence in humans. We discuss these conclusions with regard to the conservation of the vertebrate X-chromosomal linkage group and to human evolution.

Expression and function of the gene encoding the voltage-dependent calcium channel beta3-subunit in the mouse placenta.

Voltage-dependent Ca(2+) channels (VDCC) exist in most excitable cells and their properly regulated activity is essential for critical biological processes as many of these are sensitive to cellular Ca(2+) ion concentration. The ancillary cytoplasmic Ca(2+) channel beta subunits (CACNB) modulate Ca(2+) channel function and are required to enhance the number of functional channels in the plasma membrane. There are four genes encoding CACNB subunits and the gene encoding CACNB3 is over expressed in hyperplastic placentas of mouse interspecies hybrids. To determine the role of CACNB3 in the mouse placenta, we performed an expression and function analysis. Our results show that Cacnb3 exhibits specific spatial and temporal expression in the mouse placenta. Deletion of Cacnb3 does not produce a strong placental phenotype, which may be due to expression of other CACNB subunit encoding genes; however, sporadic occurrence of a labyrinthine architecture phenotype, characterized by reduced density of fetal blood vessels and decrease in pericyte number, could be observed. Down-regulation of Cacnb3 expression did not rescue placental hyperplasia in a model of interspecies hybrid placentas, which indicates that up-regulation in the hyperplastic placentas is a downstream event.

Expression and functional analysis of fibulin-1 (Fbln1) during normal and abnormal placental development of the mouse.

The extracellular matrix protein fibulin-1 (FBLN1) is an important component of blood vessel walls, as shown by the lethality of mice with homozygous targeted deletion of the Fbln1 gene. Here, we show that a murine placental overgrowth phenotype is associated with elevated Fbln1 transcript levels, suggesting that the gene and its product have a functional role in placentation. Fbln1 exhibits a specific expression pattern in the mouse placenta. Transcripts could not be detected prior to day 12. In subsequent stages, Fbln1 was expressed strongly in the spongiotrophoblast. Other sites of expression were endothelia of large fetal blood vessels, a tissue type reported to not express this gene. In addition, a subset of giant cells expressed the gene. This giant cell specific expression was strongly increased in hyperplastic placentas. Analysis of the placentation in fibulin null mice did not show any abnormality. Attempts to rescue the placental phenotypes of a congenic model of interspecies hybrid placental dysplasia (IHPD) by normalizing expression of Fbln1 proved that Fbln1 alone is not the key cause of phenotypes in these models of placental hyperplasia.

Paternal transmission of X-linked placental dysplasia in mouse interspecific hybrids.

It has previously been shown that abnormal placental development, i.e., hyper- and hypoplasia, occurs in crosses and backcrosses between different mouse (Mus) species. These defects are caused mainly by abnormal growth of the spongiotrophoblast. The precise genetic basis for these placental malformations has not been determined. However, a locus that contributes to the abnormal development (Ihpd: interspecific hybrid placental dysplasia) has been mapped to the X chromosome. The X-chromosomal location of Ihpd and its site of action, that is the spongiotrophoblast, mean that normally only the maternally inherited Ihpd locus is active even in female fetuses. However, by making use of the X-chromosomal inversion In(X)IH, we have produced interspecific hybrid Xp0, in which the active X chromosome was inherited from Mus macedonicus males. In contrast to XX female and XY male conceptuses from this cross, which have hypoplastic placentas, the Xp0 female conceptuses have hyperplastic placentas. This finding supports the view that it is expression of the M. macedonicus Ihpd locus in the spongiotrophoblast that leads to hyperplasia due to an abnormal interaction with M. musculus autosomal loci.

Genetic dissection of X-linked interspecific hybrid placental dysplasia in congenic mouse strains.

Interspecific hybridization in the genus Mus results in male sterility and X-linked placental dysplasia. We have generated several congenic laboratory mouse lines (Mus musculus) in which different parts of the maternal X chromosome were derived from M. spretus. A strict positive correlation between placental weight and length of the M. spretus-derived part of the X chromosome was shown. Detailed analysis was carried out with one congenic strain that retained a M. spretus interval between 12.0 and 30.74 cM. This strain consistently produced hyperplastic placentas that exhibited an average weight increase of 180% over the weight of control placentas. In derived subcongenic strains, however, increased placental weight could no longer be observed. Morphometric analysis of these placentas revealed persistence of abnormal morphology. Fully developed placental hyperplasia could be reconstituted by recombination of proximal and central M. spretus intervals with an intervening M. musculus region. These results may suggest that placental dysplasia of interspecific mouse hybrids is caused by multiple loci clustered on the X chromosome that act synergistically. Alternatively, it is possible that changes in chromatin structure in interspecific hybrids that influence gene expression are dependent on the length of the alien chromosome.

Genetic and developmental analysis of X-inactivation in interspecific hybrid mice suggests a role for the Y chromosome in placental dysplasia.

It has been shown previously that abnormal placental growth, i.e., hyper- and hypoplasia, occurs in crosses and backcrosses between different mouse (Mus) species. A locus that contributes to this abnormal development has been mapped to the X chromosome. Unexpectedly, an influence of fetal sex on placental development has been observed, in that placentas attached to male fetuses tended to exhibit a more pronounced phenotype than placentas attached to females. Here, we have analyzed this sex dependence in more detail. Our results show that differences between male and female placental weights are characteristic of interspecific matings and are not observed in intraspecific Mus musculus matings. The effect is retained in congenic lines that contain differing lengths of M. spretus-derived X chromosome. Expression of the X-linked gene Pgk1 from the maternal allele only and lack of overall activity of two paternally inherited X-linked transgenes indicate that reactivation or lack of inactivation of the paternal X chromosome in trophoblasts of interspecific hybrids is not a frequent occurrence. Thus, the difference between male and female placentas seems not to be caused by faulty preferential X-inactivation. Therefore, these data suggest that the sex difference of placental weights in interspecific hybrids is caused by interactions with the Y chromosome.

H19 is imprinted in the choroid plexus and leptomeninges of the mouse foetus.

It has been proposed that either the Igf-2 gene or the H19 gene--but not both--can be expressed from a given chromosome. Igf-2 is known to be biallelically expressed in the choroid plexus and leptomeninges, however, raising the question of whether H19 is down-regulated or absent there. We found by in situ hybridization that H19 is indeed expressed in the choroid plexus and leptomeninges of the developing mouse foetus. Comparison with the expression pattern of Igf-2 showed that the genes are coexpressed in all areas, with the exception of the choroid plexus epithelium. To evaluate whether H19 is also biallelically expressed in these tissues, we microdissected embryos from interspecific crosses and performed RNAse protection analysis on the isolated RNA. This revealed that H19 maintains its imprint in the choroid plexus/leptomeninges, being transcribed from the maternal allele at a level comparable to that in normal liver. We discuss the significance of these results for current models of Igf-2 and H19 imprinting.

The non-viability of uniparental mouse conceptuses correlates with the loss of the products of imprinted genes.

Diploid parthenogenetic or androgenetic mouse conceptuses produce characteristic and opposite mutant phenotypes and are non-viable, presumably due to different contributions from the maternal and paternal genomes. This is likely to be the result of the preferential expression of only one parent's copy of certain genes in the offspring. So far, four such endogenous imprinted genes are known: the paternal alleles of Igf2 and Snrpn and the maternal alleles of Igf2r and H19 are active, while their opposite parental alleles are inactive. Here we demonstrate that the expression patterns of the Igf2 and Igf2r genes in androgenetic and parthenogenetic conceptuses correlate with which parental alleles normally express them, implying that the imprint can be maintained in the absence of the other parent's genome for these genes. This also indicates that both types of uniparental conceptuses are lacking developmentally important gene products. We did find, however, that the H19 gene was highly expressed not only in the parthenogenetic conceptus, but also in giant trophoblasts and secondary giant cells in the androgenetic placenta, in spite of the imprinting of the H19 gene in normal mouse extra embryonic tissues. We discuss these observations with respect to the non-viability of uniparental conceptuses and the reciprocal imprinting patterns of the Igf2 and H19 genes.

Identification and characterization of G90, a novel mouse RNA that lacks an extensive open reading frame.

We describe the cloning and characterization of the murine G90 gene, identified by subtractive hybridization based on the differential presence of its transcript in large and small intestine. The full-length cDNA and genomic sequences were cloned and found to produce a 1.5kb transcript that is polyadenylated but has no open reading frame larger than 249bp. The G90 gene was mapped to the proximal region of mouse chromosome 6. Expression analysis by Northern blotting showed that G90 is transcribed at very high levels in the small intestine and at lower levels in large intestine, testis and kidney of the mouse. In situ hybridization analysis on sections of small and large intestine and testis showed that G90 transcripts are present only in post-mitotic cells.

Genomic imprinting and the differential roles of parental genomes in brain development.

Certain genes are expressed either from the maternal or the paternal genome as a result of genomic imprinting, a process that confers functional differences on parental genomes during mammalian development. In this study we focus on the cumulative effects of imprinted genes on brain development by examining the fate of androgenetic (Ag: duplicated paternal genome) and parthenogenetic/gynogenetic (Pg/Gg: duplicated maternal genome) cells in chimeric embryos. Striking cell autonomous differences in the phenotypic properties of the uniparental cells were observed. Ag cells contributed substantially to the hypothalamic structures and not the cortex. By contrast, Pg/Gg cells contributed substantially to the cortex, striatum and hippocampus but not to the hypothalamic structures. Furthermore growth of the brain was enhanced by Pg/Gg and retarded by Ag cells. We propose that genomic imprinting may be responsible for a change in strategy controlling brain development in mammals. In particular, genomic imprinting may have facilitated a rapid non-linear expansion of the brain, especially the cortex, during development over evolutionary time.

Lack of correlation between placenta and offspring size in mouse interspecific crosses.

The placenta plays a pivotal role in fetal growth control and is considered a major site of genetic conflict between maternal and paternal genomes within the conceptus and, in addition, the genome of the mother. Accordingly, placental development is a strictly controlled process, and both placental and fetal weights do not vary much in intraspecific crosses of laboratory mice (Mus musculus). In mouse interspecific crosses and backcrosses [(M. musculus x M. spretus) x M. musculus], tremendous variation of placental, but not of fetal weight was observed. We have studied trophoblast cell type distribution and differentiation, and their effect on the associated placentas and fetuses in such backcrosses. Differentiation of spongious trophoblast, but not size of materno-fetal interface, correlated with fetal weight. Giant fetuses were observed only if less than one third of the spongiotrophoblast was formed by glycogen cells. Thus, placental efficiency was inversely related to the amount of glycogen cells. This influence of a trophoblast-derived cell type on fetal growth was not anticipated. We conclude that: (1) glycogen cells are able to negatively modulate fetal growth by an as yet unidentified mechanism; (2) correlation between fetal and placental weights is weak or absent in interspecific hybrids; (3) impaired control over placental and embryonic development in hybrids may contribute to post-mating isolation of species.

Purification and properties of the phosphoglycerate mutase isozymes from the mouse.

The two homodimeric isozymes of phosphoglycerate mutase have been purified from murine kidney and muscle. No differences were observed in the Michaelis-Menten constant for the substrate 2-phospho-D-glycerate, in molecular weight, temperature and pH optima, when the purified isozymes were compared. The isozymes differ in their inhibition constants for phosphoenolpyruvate, in their Michaelis constants for 3-phospho-D-glycerate and 2,3-bisphospho-D-glycerate, their thermal and pH lability and in their sensitivity towards mercury ions.

Cytoskeletal characterization of a neuroectodermal cell line and embryonic mouse brain.

The cytoskeleton of a newly isolated mouse embryo brain-derived cell line and of dissected mesencephalon-rhombencephalon samples of the 10- to 11-day-old mouse embryo, constituted of a ventricular zone only, has been examined by immunocytochemistry, electrophoretic separation and Western blotting techniques. In accordance with their epithelial organization, the ventricular cells contain cytokeratins as main constituents of their cytoskeleton. Vimentin has been also revealed as early as day 10.5 of gestation. The complex cytokeratin polypeptide pattern puts this histological type of epithelia into the category of complex, rather than simple, epithelia and calls for explanations other than keratinization for the presence and functional role of the high-molecular weight, basic keratins. The cytoskeletal composition of the embryo brain-derived gliogenic cell line reflects the vimentin- and cytokeratin-positive character of the ventricular cells.

Developmental activation of phosphoglycerate mutase-2 in the testis of the mouse.

The expression of the phosphoglycerate mutase locus Pgam-2 which synthesizes the muscle-specific PGAM-B subunit was analyzed in the testis of the mouse. No PGAM-B activity was detected in testes of newborn mice, in which only the PGAM-AA isozyme was observed. PGAM-B was first observed between Day 14 and Day 16 of postnatal development. In adult males approximately 50% of total PGAM activity is contributed by the PGAM-B subunit and 50% by the PGAM-A subunit. Immunohistochemical studies show that in the testis PGAM-B is localized exclusively in germ cells. PGAM-B is detected in pachytene spermatocytes and in spermatids, but not in earlier stages of spermatogenesis. The muscle-specific PGAM isozyme was also found in testes of bull, cat, and rat, as well as in human sperm. PGAM-B might thus be useful as a marker for germ cell differentiation, along with other germ cell-specific proteins.