Molecular identification of t(w5): Vps52 promotes pluripotential cell differentiation through cell-cell interactions.

After implantation, pluripotent epiblasts are converted to embryonic ectoderm through cell-cell interactions that significantly change the transcriptional and epigenetic networks. An entrée to understanding this vital developmental transition is the t(w5) mutation of the mouse t complex. This mutation produces highly specific defects in the embryonic ectoderm before gastrulation, leading to death of the embryonic ectoderm. Using a positional cloning approach, we have now identified the mutated gene, completing a decades-long search. The gene, vacuolar protein sorting 52 (Vps52), is a mouse homolog of yeast VPS52 that is involved in the retrograde trafficking of endosomes. Our data suggest that Vps52 acts in extraembryonic tissues to support the growth and differentiation of embryonic ectoderm via cell-cell interactions. It is also required in the formation of embryonic structures at a later stage of development, revealing hitherto unknown functions of Vps52 in the development of a multicellular organism.

Disruption of genetic interaction between two autosomal regions and the X chromosome causes reproductive isolation between mouse strains derived from different subspecies.

Reproductive isolation that initiates speciation is likely caused by incompatibility among multiple loci in organisms belonging to genetically diverging populations. Laboratory C57BL/6J mice, which predominantly originated from Mus musculus domesticus, and a MSM/Ms strain derived from Japanese wild mice (M. m. molossinus, genetically close to M. m. musculus) are reproductively isolated. Their F1 hybrids are fertile, but successive intercrosses result in sterility. A consomic strain, C57BL/6J-ChrX(MSM), which carries the X chromosome of MSM/Ms in the C57BL/6J background, shows male sterility, suggesting a genetic incompatibility of the MSM/Ms X chromosome and other C57BL/6J chromosome(s). In this study, we conducted genomewide linkage analysis and subsequent QTL analysis using the sperm shape anomaly that is the major cause of the sterility of the C57BL/6J-ChrX(MSM) males. These analyses successfully detected significant QTL on chromosomes 1 and 11 that interact with the X chromosome. The introduction of MSM/Ms chromosomes 1 and 11 into the C57BL/6J-ChrX(MSM) background failed to restore the sperm-head shape, but did partially restore fertility. This result suggests that this genetic interaction may play a crucial role in the reproductive isolation between the two strains. A detailed analysis of the male sterility by intracytoplasmic sperm injection and zona-free in vitro fertilization demonstrated that the C57BL/6J-ChrX(MSM) spermatozoa have a defect in penetration through the zona pellucida of eggs.

Attenuated spread of X-inactivation in an X;autosome translocation.

X inactivation in female mammals involves transcriptional silencing of an entire chromosome in response to a cis-acting noncoding RNA, the X inactive-specific transcript (Xist). Xist can also inactivate autosomal sequences, for example, in X;autosome translocations; but here, silencing appears to be relatively inefficient. This variation has been attributed to either attenuated spreading of Xist RNA at the onset of X inactivation or inefficient maintenance of autosomal silencing. Evidence to date has favored the latter. Here, we demonstrate attenuated spreading of Xist RNA at the onset of X inactivation in the T(X;4)37H X;autosome translocation. Our findings provide direct evidence that underlying chromosome/chromatin features can disrupt spreading of the primary inactivating signal.

X-chromosome inactivation in differentiating mouse embryonic stem cells carrying X-linked GFP and lacZ transgenes.

Three new female ES cell lines (GLM1, GLP1 and GLP2) were established from mouse embryos carrying GFP (green fluorescent protein) and HMG-lacZ transgenes on one of two X chromosomes in cis. Using these cell lines, we studied the temporal relationships among three events relevant to X-chromosome inactivation: replication asynchrony of the X chromosome, and quenching of GFP fluorescence and beta-galactosidase (beta-gal) activity, during cell differentiation induced by embryoid body (EB) formation and retinoic acid (RA) treatment. In embryoid bodies adhering to the bottom of culture dishes, GFP-negative cells appeared first in the peripheral outgrowths 4 days after the initiation of EB formation, followed about 24 hours later by the appearance of cells negative for beta-gal and those having a single allocyclic X chromosome. Although the frequency of cells with an allocyclic X chromosome could reach 80% in adherent embryoid bodies, it tended to remain low and variable in embryoid bodies maintained in suspension. In spite of apparently parallel extinction of GFP and lacZ in embryoid bodies, their concurrent occurrence did not always characterize RA-induced differentiation. Moreover, an allocyclic X chromosome was identified in not more than 20 percent of informative metaphase cells up to 10 days after initiation of RA treatment. These findings suggest that RA-induced differentiation of female ES cells does not always accompany X-inactivation.

Analysis of promoter region of X-linked pgk-1 gene polymorphisms: evidence for polyclonality of adult mouse gastric glands.

The clonality of gastric glands remains a controversial topic. Chimeric mouse studies suggested that all gastric glands were monoclonal. However, using the X-linked transgenic mouse model, we have suggested that most glands are polyclonal during development and that the fraction of monoclonal glands increases after birth. Nevertheless, a fraction of glands is perpetually polyclonal even in the adult murine stomach. To examine the existence of gastric polyclonal glands in the adult mouse, we studied an X-linked intrinsic polymorphic gene, pgk-1, in 6 week-old female mice heterozygous for the X-linked pgk-1a and pgk-1b. The sequence containing the seventh HpaII site in the promoter region of the gene and the polymorphic sites was utilized. Twenty-four of 225 fundic glands (10.7%) and 3 of 167 pyloric glands (1.8%) were clonally heterotypic. Only 0.6% of colonic crypts were heterotypic. Clonally heterotypic glands with inactive X-specific methylation were present in the adult murine stomach.

Hybrid breakdown caused by substitution of the X chromosome between two mouse subspecies.

Hybrid breakdown is a type of reproductive failure that appears after the F2 generation of crosses between different species or subspecies. It is caused by incompatibility between interacting genes. Genetic analysis of hybrid breakdown, particularly in higher animals, has been hampered by its complex nature (i.e., it involves more than two genes, and the phenotype is recessive). We studied hybrid breakdown using a new consomic strain, C57BL/6J-X(MSM), in which the X chromosome of C57BL/6J (derived mostly from Mus musculus domesticus) is substituted by the X chromosome of the MSM/Ms strain (M. m. molossinus). Males of this consomic strain are sterile, whereas F1 hybrids between C57BL/6J and MSM/Ms are completely fertile. The C57BL/6J-X(MSM) males showed reduced testis weight with variable defects in spermatogenesis and abnormal sperm head morphology. We conducted quantitative trait locus (QTL) analysis for these traits to map the X-linked genetic factors responsible for the sterility. This analysis successfully detected at least three distinct loci for the sperm head morphology and one for the testis weight. This study revealed that incompatibility of interactions of X-linked gene(s) with autosomal and/or Y-linked gene(s) causes the hybrid breakdown between the genetically distant C57BL/6J and MSM/Ms strains.

Tetraploid embryos rescue the early defects of tw5/tw5 mouse embryos.

tclw5 is a t-complex recessive lethal mutation of the tw5-haplotype. Since tw5/tw5 embryos die soon after implantation, the tclw5 gene is thought to play an important role in early embryogenesis. Previous histological studies have demonstrated that tw5 homozygotes do not survive past the gastrulation stage due to extensive death of the embryonic ectoderm, whereas the extraembryonic tissues were less affected. In the present study, we demonstrate that tw5/tw5 embryos may be distinguished from wildtype littermates at embryonic (E) day 5.5. At this stage, the visceral endoderm of tw5/tw5 embryos appeared to be different, possessing smaller and fewer vacuoles compared to normal littermates. This led us to hypothesize that the visceral endoderm may be affected by tclw5. Confirmation was provided by the rescue of tw5/tw5 embryos following aggregation with tetraploid embryos. However, rescued embryos did not survive past E9.0 and displayed an underdeveloped posterior region. This would indicate that the actions of tclw5 extend beyond the midgestation stage.

Imprinted X-chromosome inactivation: enlightenment from embryos in vivo.

There are two forms of X chromosome inactivation (XCI) in the laboratory mouse, random XCI in the fetus and imprinted paternal XCI limited to the extraembryonic tissues supporting the fetal life in utero. Imprinted XCI has been studied extensively because it takes place first in embryogenesis and it may hold clues to the mechanism of control of XCI in general and to the evolution of random' XCI. Classical microscopic and biochemical studies of embryos in vivo provide a basis for interpreting the multifaceted information yielded by various inventive approaches and for planning further experiments.

Developmental abnormalities in mouse embryos tetrasomic for chromosome 11: apparent similarity to embryos functionally disomic for the x chromosome.

Adopting a mating system involving two different Robertsonian translocations with monobrachial homology, we studied the early development of mouse embryos trisomic or tetrasomic for chromosome 11. A developmental delay of 12-24 hours was evident in trisomic embryos at embryonic day (E)7.5, whereas tetrasomic embryos apparently had stopped growth by E6.5 without formation of extraembryonic structures. This extremely severe developmental abnormality found in tetrasomic embryos is similar to that reported in embryos having two active X chromosomes in extraembryonic cell lineages. Autosomal tetrasomy, but not autosomal trisomy, can lead to such early developmental errors. Thus, a reasonable inference would be that the X chromosome is twice as active as the autosome. Probably, the X chromosome became upregulated in response to the evolutionary necessity of minimizing haplo-insufficiency brought about by miniaturization of the Y chromosome.

Developmental potential of mouse tetraploid cells in diploid <--> tetraploid chimeric embryos.

Mouse 2n (lacZ-) <--> 4n (lacZ+) aggregation chimeras were examined 5 or 10 days after uterine transfer to test the potential of 4n cells to contribute to embryonic tissues. Recovered embryos corresponded to embryonic day 7.5 approximately 8.0 and 12.5, respectively. Ten days after transfer, 4n cells were never detected, as reported earlier, in embryonic tissues of chimeras produced by the standard procedure in which one 2n embryo at the8-cell stage is aggregated with a4n embryo at the4-cell stage. However, beta-gal positive cells were present in embryonic tissues, though in a low number, in chimeras produced by a 2n and a 4n embryo at the 4-cell stage. Similar results were obtained when one 2n embryo atthe 8-cell stage was aggregated with two 4n embryos atthe 4-cell stage. beta-gal positive cells were found in the heart, liver, skin and intestinal epithelium. The majority of chimeras 5 days after uterine transfer retained beta-gal positive cells in embryonic tissues. The complete lack of 4n cell contribution to chimeras produced by the standard procedure is therefore attributed to the initial low proportion of 4n cells allocated to epiblast and their severe elimination from embryonic tissues.

Genomic imprinting contributes to thyroid hormone metabolism in the mouse embryo.

Many genes subject to genomic imprinting function in a number of endocrine/paracrine pathways that are important for normal mammalian development. Here, we show that an endocrine/paracrine pathway involving thyroid hormone metabolism is also regulated by imprinting. Thyroid hormone action depends on thyroid hormone receptors and their predominant ligand, 3,5,3'-triiodothyronine (T3). In vivo, thyroid hormone levels are maintained within the physiological range through the interaction of three iodothyronine deiodinases, D1, D2, and D3. D3 inactivates thyroxine (T4) and T3 by 5-deiodination, and the gene for this enzyme, Dio3, lies in the imprinted domain on human chromosome 14q32/distal mouse chromosome 12. Here, we report the imprinting of Dio3, which is expressed preferentially from the paternal allele. No differentially methylated region was identified in the CpG-island promoter, which is completely unmethylated. Localization of transcripts suggests that Dio3 may be exerting its function in both endocrine and autocrine/paracrine manners. An assay was developed for T3, and we show that its levels in maternal and paternal uniparental disomy (UPD) 12 fetuses are reciprocally affected. These results demonstrate that disruption of the imprinting status of Dio3 results in abnormal thyroid hormone levels and may contribute to the phenotypic abnormalities in UPD12 mice and UPD14 humans.

A Novel Mesoderm-Specific cDNA Isolated from a Mouse Embryonal Carcinoma Cell Line: (embryonal carcinoma cell/cDNA/in situ hybridization/mesoderm/mouse embryo).

A novel mesoderm-specific cDNA clone has been isolated by differential screening of cDNA library from an embryonal carcinoma (EC) cell line MC12. The cDNA clone 121a is about 2.5 kb in length and apparently encodes a putative polypeptide of 335 amino acids which may be secreted or membrane anchored glycoprotein since it has a possible signal sequence and a potential N-linked glycosylation site. In situ hybridization using mouse embryos revealed that 121a expression was confined to mesoderm and its derivatives such as allantois, the mesodermal layer of amnion, chorion and yolk sac, somites, heart, etc. These findings suggest that 121 a may be essential for mesodermal differentiation or function, although nothing definite is known. Conservation of 121a homolog in mammals and even in Drosophila seems to support this presumption. Fluorescence in situ hybridization successfully localized 121a to B1 band of mouse chromosome 6.

Abnormal X-Chromosome Dosage Compensation as a Possible Cause of Early Developmental Failure in Mice: (X-chromosome inactivation/trophectoderm/imprinting/embryonic development).

An extra maternally derived X chromosome (XM ) but not a paternally derived one (XP ) is detrimental in early mouse embryogenesis resulting in failure to form the ectoplacental cone and extra-embryonic ectoderm. Cytogenetic studies suggested that two XM chromosomes remain active in the trophectoderm and possibly also the primitive endoderm, in which XP is preferentially inactivated in normal female embyos. Two copies of an active X chromosome due to maternal imprinting seem to prevent further differentiation of the trophectoderm.

Construction of a DNA Library Enriched with Mouse 4x Chromosome of T(X;4)37H Translocation: (flow cytometry/mouse DNA library/hybrid cell/chromosome translocation/X-inactivation).

Normal mouse chromosomes are routinely separated into only 5 peaks by the current flow cytometry. Since this limited resolution hindered isolation of the normal mouse X chromosome with an appropriate purity, we attempted to sort the mouse 4x chromosome, a larger translocation chromosome of T(X;4)37H, consisting of nearly the entire chromosome 4 and chromosome X by flow cytometry. To obtain a large number of cells having 4x chromosome for flow sorting, we isolated a somatic hybrid cell line MHH-1 formed between S194 myelome cell line and normal splenocytes from a male mouse carrying T(X;4)37H. Flow karyotyping of propidium iodide-stained chromosomes from MHH-1 cell line revealed an additional peak containing 4x chromosomes at about 80%. DNA purified from sorted 4x chromosomes was cloned into phage lambda gtWES after complete digestion with EcoRl restriction endonuclease. Thus a 4x chromosome-enriched library of about 4.4 × 104 recombinant phages was made and 13 single copy DNA clones specific to the X chromosome were isolated from the library so far.

A New Monoclonal Antibody that Recognizes 180 kDa Polypeptide Expressed on Early Mouse Embryos and Mouse Embryonal Carcinoma Cells: (embryonal carcinoma/monoclonal antibody/intrasplenic primary immunization/180 kDa polypeptide).

A hybridoma clone 1F7 producing a monoclonal antibody against OTF9-63 mouse embryonal carcinoma cell line was isolated with the aid of the intrasplenic primary immunization technique. This antibody was capable of recognizing embryonal carcinoma cell lines originated from certain mouse strains, including 129/Sv, but not those which were established from other strains as well as human and other murine cell lines except FM3A, a mouse mammary carcinoma cell line. Indirect immunofluorescence study revealed that 1F7 antigen was expressed on early mouse embryos in a stage specific manner. In order to characterize the 1F7 antigenic molecules, we analyzed both glycoshingolipids and glycoproteins recovered from OTF9-63 by means of immunostaining after thin layer chromatography and SDS-polyacrylamide gel electrophoresis followed by Western blotting, respectively. It was concluded that 1F7 antigenic determinants were carried by 180 kDa polypeptides. One of the most interesting characteristics of 1F7 antigen is complete failure to express on the embryonic ectoderm of 5.5d and 6.5d embryos, one of cell types most closely related to embryonal carcinoma cells. 1F7 antibody may help analyse the process of teratocarcinogenesis in 129/Sv mice.

Presence of an Allocyclic Early Replicating X Chromosome in Female Embryos of the Rat, Chinese Hamster and Rabbit: (X chromosome inactivation/allocyclic X chromosome/rat/Chinese hamster/rabbit).

Previous studies on early female mouse embryos revealed the presence of two kinds of inactive X chromosomes, one replicating late and the other early in the DNA synthetic period. The X chromosome that replicates early is of special interest because of its paternal origin, preferential occurrence in trophectoderm and primitive endoderm derivatives, and programmed shift to the late replicator. This study by BrdU labeling and acridine orange fluorescence staining was undertaken to examine whether the inactive X chromosome behaves in a similar manner in other laboratory mammals. In rat embryos the paternal X chromosome was found to show the same behavior in extraembryonic tissues. Early replicating chromosomes were also found in the extraembryonic regions of Chinese hamster and rabbit embryos, although their parental origin could not be determined due to the absent of X chromosome polymorphism in these species. Probably the early replicating X chromosome occurs commonly in mammals. Its functional significance is unknown.